Update prcxi.py

Update for discard tips
Update prcxi.py
2026-03-26 05:39:16 +00:00 · 2025-07-17 14:38:50 +08:00 · 2025-07-16 23:28:46 +08:00 · 2025-07-16 22:39:02 +08:00 · 2025-07-16 22:38:59 +08:00 · 2025-07-16 21:34:25 +08:00
159 changed files with 47052 additions and 4877 deletions
--- a/.github/workflows/multi-platform-build.yml
+++ b/.github/workflows/multi-platform-build.yml
@@ -0,0 +1,132 @@
 name: Multi-Platform Conda Build
 on:
  push:
    branches: [ main, dev ]
    tags: [ 'v*' ]
  pull_request:
    branches: [ main, dev ]
  workflow_dispatch:
    inputs:
      platforms:
        description: '选择构建平台 (逗号分隔): linux-64, osx-64, osx-arm64, win-64'
        required: false
        default: 'osx-arm64'
 jobs:
  build:
    strategy:
      fail-fast: false
      matrix:
        include:
        - os: ubuntu-latest
          platform: linux-64
          env_file: unilabos-linux-64.yaml
        - os: macos-13 # Intel
          platform: osx-64
          env_file: unilabos-osx-64.yaml
        - os: macos-latest # ARM64
          platform: osx-arm64
          env_file: unilabos-osx-arm64.yaml
        - os: windows-latest
          platform: win-64
          env_file: unilabos-win64.yaml
    runs-on: ${{ matrix.os }}
    defaults:
      run:
        shell: bash -l {0}
    steps:
    - uses: actions/checkout@v4
      with:
        fetch-depth: 0
    - name: Check if platform should be built
      id: should_build
      run: |
        if [[ "${{ github.event_name }}" != "workflow_dispatch" ]]; then
          echo "should_build=true" >> $GITHUB_OUTPUT
        elif [[ -z "${{ github.event.inputs.platforms }}" ]]; then
          echo "should_build=true" >> $GITHUB_OUTPUT
        elif [[ "${{ github.event.inputs.platforms }}" == *"${{ matrix.platform }}"* ]]; then
          echo "should_build=true" >> $GITHUB_OUTPUT
        else
          echo "should_build=false" >> $GITHUB_OUTPUT
        fi
    - name: Setup Miniconda
      if: steps.should_build.outputs.should_build == 'true'
      uses: conda-incubator/setup-miniconda@v3
      with:
        miniconda-version: "latest"
        channels: conda-forge,robostack-staging,defaults
        channel-priority: strict
        activate-environment: build-env
        auto-activate-base: false
        auto-update-conda: false
        show-channel-urls: true
    - name: Install boa and build tools
      if: steps.should_build.outputs.should_build == 'true'
      run: |
        conda install -c conda-forge boa conda-build
    - name: Show environment info
      if: steps.should_build.outputs.should_build == 'true'
      run: |
        conda info
        conda list | grep -E "(boa|conda-build)"
        echo "Platform: ${{ matrix.platform }}"
        echo "OS: ${{ matrix.os }}"
    - name: Build conda package
      if: steps.should_build.outputs.should_build == 'true'
      run: |
        if [[ "${{ matrix.platform }}" == "osx-arm64" ]]; then
          boa build -m ./recipes/conda_build_config.yaml -m ./recipes/macos_sdk_config.yaml ./recipes/ros-humble-unilabos-msgs
        else
          boa build -m ./recipes/conda_build_config.yaml ./recipes/ros-humble-unilabos-msgs
        fi
    - name: List built packages
      if: steps.should_build.outputs.should_build == 'true'
      run: |
        echo "Built packages in conda-bld:"
        find $CONDA_PREFIX/conda-bld -name "*.tar.bz2" | head -10
        ls -la $CONDA_PREFIX/conda-bld/${{ matrix.platform }}/ || echo "${{ matrix.platform }} directory not found"
        ls -la $CONDA_PREFIX/conda-bld/noarch/ || echo "noarch directory not found"
        echo "CONDA_PREFIX: $CONDA_PREFIX"
        echo "Full path would be: $CONDA_PREFIX/conda-bld/**/*.tar.bz2"
    - name: Prepare artifacts for upload
      if: steps.should_build.outputs.should_build == 'true'
      run: |
        mkdir -p ${{ runner.temp }}/conda-packages
        find $CONDA_PREFIX/conda-bld -name "*.tar.bz2" -exec cp {} ${{ runner.temp }}/conda-packages/ \;
        echo "Copied files to temp directory:"
        ls -la ${{ runner.temp }}/conda-packages/
    - name: Upload conda package artifacts
      if: steps.should_build.outputs.should_build == 'true'
      uses: actions/upload-artifact@v4
      with:
        name: conda-package-${{ matrix.platform }}
        path: ${{ runner.temp }}/conda-packages
        if-no-files-found: warn
        retention-days: 30
    - name: Create release assets (on tags)
      if: steps.should_build.outputs.should_build == 'true' && startsWith(github.ref, 'refs/tags/')
      run: |
        mkdir -p release-assets
        find $CONDA_PREFIX/conda-bld -name "*.tar.bz2" -exec cp {} release-assets/ \;
    - name: Upload to release
      if: steps.should_build.outputs.should_build == 'true' && startsWith(github.ref, 'refs/tags/')
      uses: softprops/action-gh-release@v1
      with:
        files: release-assets/*
        draft: false
        prerelease: false
--- a/.gitignore
+++ b/.gitignore
@@ -1,3 +1,5 @@
 configs/
 temp/
 ## Python
 # Byte-compiled / optimized / DLL files
@@ -234,3 +236,7 @@ CATKIN_IGNORE
 *.graphml
 unilabos/device_mesh/view_robot.rviz
 # Certs
 **/.certs
--- a/README.md
+++ b/README.md
@@ -49,7 +49,7 @@ conda env update --file unilabos-[YOUR_OS].yml -n environment_name
 # Currently, you need to install the `unilabos_msgs` package
 # You can download the system-specific package from the Release page
-conda install ros-humble-unilabos-msgs-0.9.5-xxxxx.tar.bz2
+conda install ros-humble-unilabos-msgs-0.9.10-xxxxx.tar.bz2
 # Install PyLabRobot and other prerequisites
 git clone https://github.com/PyLabRobot/pylabrobot plr_repo
--- a/README_zh.md
+++ b/README_zh.md
@@ -49,7 +49,7 @@ conda env update --file unilabos-[YOUR_OS].yml -n 环境名
 # 现阶段，需要安装 `unilabos_msgs` 包
 # 可以前往 Release 页面下载系统对应的包进行安装
-conda install ros-humble-unilabos-msgs-0.9.5-xxxxx.tar.bz2
+conda install ros-humble-unilabos-msgs-0.9.11-xxxxx.tar.bz2
 # 安装PyLabRobot等前置
 git clone https://github.com/PyLabRobot/pylabrobot plr_repo
--- a/recipes/conda_build_config.yaml
+++ b/recipes/conda_build_config.yaml
@@ -1,3 +1,6 @@
 channel_sources:
  - robostack,robostack-staging,conda-forge,defaults
 gazebo:
  - '11'
 libpqxx:
--- a/recipes/ros-humble-unilabos-msgs/recipe.yaml
+++ b/recipes/ros-humble-unilabos-msgs/recipe.yaml
@@ -1,6 +1,6 @@
 package:
  name: ros-humble-unilabos-msgs
-  version: 0.9.5
+  version: 0.9.11
 source:
  path: ../../unilabos_msgs
  folder: ros-humble-unilabos-msgs/src/work
@@ -50,12 +50,12 @@ requirements:
    - robostack-staging::ros-humble-rosidl-default-generators
    - robostack-staging::ros-humble-std-msgs
    - robostack-staging::ros-humble-geometry-msgs
-    - robostack-staging::ros2-distro-mutex=0.6.*
+    - robostack-staging::ros2-distro-mutex=0.5.*
  run:
    - robostack-staging::ros-humble-action-msgs
    - robostack-staging::ros-humble-ros-workspace
    - robostack-staging::ros-humble-rosidl-default-runtime
    - robostack-staging::ros-humble-std-msgs
    - robostack-staging::ros-humble-geometry-msgs
-    - robostack-staging::ros2-distro-mutex=0.6.*
+#    - robostack-staging::ros2-distro-mutex=0.6.*
    - sel(osx and x86_64): __osx >={{ MACOSX_DEPLOYMENT_TARGET|default('10.14') }}
--- a/recipes/unilabos/recipe.yaml
+++ b/recipes/unilabos/recipe.yaml
@@ -1,6 +1,6 @@
 package:
  name: unilabos
-  version: "0.9.5"
+  version: "0.9.11"
 source:
  path: ../..
--- a/setup.py
+++ b/setup.py
@@ -4,7 +4,7 @@ package_name = 'unilabos'
 setup(
    name=package_name,
-    version='0.9.5',
+    version='0.9.11',
    packages=find_packages(),
    include_package_data=True,
    install_requires=['setuptools'],
@@ -17,6 +17,7 @@ setup(
    entry_points={
        'console_scripts': [
            "unilab = unilabos.app.main:main",
            "unilab-register = unilabos.app.register:main"
        ],
    },
 )
--- a/test/commands/resource_add.md
+++ b/test/commands/resource_add.md
@@ -3,3 +3,9 @@
 ```bash
 ros2 action send_goal /devices/host_node/create_resource_detailed unilabos_msgs/action/_resource_create_from_outer/ResourceCreateFromOuter "{ resources: [ { 'category': '', 'children': [], 'config': { 'type': 'Well', 'size_x': 6.86, 'size_y': 6.86, 'size_z': 10.67, 'rotation': { 'x': 0, 'y': 0, 'z': 0, 'type': 'Rotation' }, 'category': 'well', 'model': null, 'max_volume': 360, 'material_z_thickness': 0.5, 'compute_volume_from_height': null, 'compute_height_from_volume': null, 'bottom_type': 'flat', 'cross_section_type': 'circle' }, 'data': { 'liquids': [], 'pending_liquids': [], 'liquid_history': [] }, 'id': 'plate_well_11_7', 'name': 'plate_well_11_7', 'pose': { 'orientation': { 'w': 1.0, 'x': 0.0, 'y': 0.0, 'z': 0.0 }, 'position': { 'x': 0.0, 'y': 0.0, 'z': 0.0 } }, 'sample_id': '', 'parent': 'plate', 'type': 'device' } ], device_ids: [ 'PLR_STATION' ], bind_parent_ids: [ 'plate' ], bind_locations: [ { 'x': 0.0, 'y': 0.0, 'z': 0.0 } ], other_calling_params: [ '{}' ] }"
 ```
 使用mock_all.json启动，重新捕获MockContainerForChiller1
 ```bash
 ros2 action send_goal /devices/host_node/create_resource unilabos_msgs/action/_resource_create_from_outer_easy/ResourceCreateFromOuterEasy "{ 'res_id': 'MockContainerForChiller1', 'device_id': 'MockChiller1', 'class_name': 'container', 'parent': 'MockChiller1', 'bind_locations': { 'x': 0.0, 'y': 0.0, 'z': 0.0 }, 'liquid_input_slot': [ -1 ], 'liquid_type': [ 'CuCl2' ], 'liquid_volume': [ 100.0 ], 'slot_on_deck': '' }"
 ```
--- a/test/experiments/Protocol_Test_Station/add_protocol_test_station.json
+++ b/test/experiments/Protocol_Test_Station/add_protocol_test_station.json
@@ -0,0 +1,563 @@
 {
    "nodes": [
        {
            "id": "AddProtocolTestStation",
            "name": "添加协议测试站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2", 
                "multiway_valve_1",
                "multiway_valve_2",
                "stirrer_1",
                "stirrer_2",
                "flask_DMF",
                "flask_ethyl_acetate", 
                "flask_methanol",
                "flask_acetone",
                "flask_water",
                "flask_air",
                "main_reactor",
                "secondary_reactor",
                "waste_workup",
                "collection_bottle_1",
                "collection_bottle_2"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": ["PumpTransferProtocol", "AddProtocol"]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "转移泵1",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 250,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "转移泵2",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 750,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "试剂分配阀",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 250,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "反应器分配阀",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 750,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "stirrer_1",
            "name": "主反应器搅拌器",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "device",
            "class": "virtual_stirrer",
            "position": {
                "x": 600,
                "y": 450,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_STIRRER1",
                "max_speed": 1500.0,
                "default_speed": 300.0
            },
            "data": {
                "speed": 0.0,
                "status": "Stopped"
            }
        },
        {
            "id": "stirrer_2",
            "name": "副反应器搅拌器",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "device",
            "class": "virtual_stirrer",
            "position": {
                "x": 900,
                "y": 450,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_STIRRER2",
                "max_speed": 1500.0,
                "default_speed": 300.0
            },
            "data": {
                "speed": 0.0,
                "status": "Stopped"
            }
        },
        {
            "id": "flask_DMF",
            "name": "DMF试剂瓶",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 50,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "DMF",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethyl_acetate",
            "name": "乙酸乙酯试剂瓶",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 150,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethyl_acetate",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_methanol",
            "name": "甲醇试剂瓶",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 250,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "methanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_acetone",
            "name": "丙酮试剂瓶",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 350,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "acetone",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_water",
            "name": "蒸馏水瓶",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 450,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "water",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 550,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "main_reactor",
            "name": "主反应器",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "secondary_reactor",
            "name": "副反应器",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 900,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_workup",
            "name": "废液处理瓶",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_1",
            "name": "收集瓶1",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_2",
            "name": "收集瓶2",
            "children": [],
            "parent": "AddProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 900,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump1_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_valve2",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "8",
                "multiway_valve_2": "1"
            }
        },
        {
            "id": "link_valve1_DMF",
            "source": "multiway_valve_1",
            "target": "flask_DMF",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_DMF": "outlet"
            }
        },
        {
            "id": "link_valve1_ethyl_acetate",
            "source": "multiway_valve_1",
            "target": "flask_ethyl_acetate",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_ethyl_acetate": "outlet"
            }
        },
        {
            "id": "link_valve1_methanol",
            "source": "multiway_valve_1",
            "target": "flask_methanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_methanol": "outlet"
            }
        },
        {
            "id": "link_valve1_acetone",
            "source": "multiway_valve_1",
            "target": "flask_acetone",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_acetone": "outlet"
            }
        },
        {
            "id": "link_valve1_water",
            "source": "multiway_valve_1",
            "target": "flask_water",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "5",
                "flask_water": "outlet"
            }
        },
        {
            "id": "link_valve1_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "6",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve2_main_reactor",
            "source": "multiway_valve_2",
            "target": "main_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "2",
                "main_reactor": "inlet"
            }
        },
        {
            "id": "link_valve2_secondary_reactor",
            "source": "multiway_valve_2",
            "target": "secondary_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "3",
                "secondary_reactor": "inlet"
            }
        },
        {
            "id": "link_valve2_waste",
            "source": "multiway_valve_2",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "6",
                "waste_workup": "inlet"
            }
        },
        {
            "id": "link_valve2_collection1",
            "source": "multiway_valve_2",
            "target": "collection_bottle_1",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "7",
                "collection_bottle_1": "inlet"
            }
        },
        {
            "id": "link_valve2_collection2",
            "source": "multiway_valve_2",
            "target": "collection_bottle_2",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "8",
                "collection_bottle_2": "inlet"
            }
        },
        {
            "id": "link_stirrer1_main_reactor",
            "source": "stirrer_1",
            "target": "main_reactor",
            "type": "mechanical",
            "port": {
                "stirrer_1": "stirrer_head",
                "main_reactor": "stirrer_port"
            }
        },
        {
            "id": "link_stirrer2_secondary_reactor",
            "source": "stirrer_2",
            "target": "secondary_reactor",
            "type": "mechanical",
            "port": {
                "stirrer_2": "stirrer_head",
                "secondary_reactor": "stirrer_port"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/centrifuge_protocol_test_station.json
+++ b/test/experiments/Protocol_Test_Station/centrifuge_protocol_test_station.json
@@ -0,0 +1,438 @@
 {
    "nodes": [
        {
            "id": "CentrifugeProtocolTestStation",
            "name": "离心协议测试站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2",
                "multiway_valve_1",
                "multiway_valve_2",
                "centrifuge_1",
                "reaction_mixture",
                "centrifuge_tube",
                "collection_bottle_1",
                "flask_water",
                "flask_ethanol",
                "flask_acetone",
                "flask_air",
                "waste_workup"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": [
                    "CentrifugeProtocol",
                    "PumpTransferProtocol"
                ]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "主转移泵",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 200,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 2.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "副转移泵",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 400,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 2.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "溶剂分配阀",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 200,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "样品分配阀",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 400,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "centrifuge_1",
            "name": "离心机",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "device",
            "class": "virtual_centrifuge",
            "position": {
                "x": 600,
                "y": 350,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_CENTRIFUGE1",
                "max_speed": 15000.0,
                "max_temp": 40.0,
                "min_temp": 4.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "reaction_mixture",
            "name": "反应混合物",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 500.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "cell_suspension",
                        "liquid_volume": 200.0
                    }
                ]
            }
        },
        {
            "id": "centrifuge_tube",
            "name": "离心管",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 15.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_1",
            "name": "上清液收集瓶",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 500.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_water",
            "name": "蒸馏水瓶",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 200,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "water",
                        "liquid_volume": 900.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethanol",
            "name": "乙醇清洗瓶",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 300,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_acetone",
            "name": "丙酮清洗瓶",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 400,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "acetone",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_workup",
            "name": "废液瓶",
            "children": [],
            "parent": "CentrifugeProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump1_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve1_water",
            "source": "multiway_valve_1",
            "target": "flask_water",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_water": "outlet"
            }
        },
        {
            "id": "link_valve1_ethanol",
            "source": "multiway_valve_1",
            "target": "flask_ethanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_ethanol": "outlet"
            }
        },
        {
            "id": "link_valve1_acetone",
            "source": "multiway_valve_1",
            "target": "flask_acetone",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_acetone": "outlet"
            }
        },
        {
            "id": "link_valve1_valve2",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "5",
                "multiway_valve_2": "1"
            }
        },
        {
            "id": "link_valve2_reaction_mixture",
            "source": "multiway_valve_2",
            "target": "reaction_mixture",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "2",
                "reaction_mixture": "inlet"
            }
        },
        {
            "id": "link_valve2_centrifuge_tube",
            "source": "multiway_valve_2",
            "target": "centrifuge_tube",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "3",
                "centrifuge_tube": "inlet"
            }
        },
        {
            "id": "link_valve2_collection",
            "source": "multiway_valve_2",
            "target": "collection_bottle_1",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "4",
                "collection_bottle_1": "inlet"
            }
        },
        {
            "id": "link_valve2_waste",
            "source": "multiway_valve_2",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "5",
                "waste_workup": "inlet"
            }
        },
        {
            "id": "link_centrifuge1_centrifuge_tube",
            "source": "centrifuge_1",
            "target": "centrifuge_tube",
            "type": "transport",
            "port": {
                "centrifuge_1": "centrifuge",
                "centrifuge_tube": "centrifuge_port"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/clean_vessel_protocol_test_station.json
+++ b/test/experiments/Protocol_Test_Station/clean_vessel_protocol_test_station.json
@@ -0,0 +1,446 @@
 {
    "nodes": [
        {
            "id": "CleanVesselProtocolTestStation",
            "name": "容器清洗协议测试站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2",
                "multiway_valve_1",
                "multiway_valve_2",
                "heatchill_1",
                "flask_water",
                "flask_acetone",
                "flask_ethanol",
                "flask_air",
                "main_reactor",
                "secondary_reactor",
                "waste_workup"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": [
                    "CleanVesselProtocol",
                    "PumpTransferProtocol",
                    "HeatChillProtocol",
                    "HeatChillStartProtocol",
                    "HeatChillStopProtocol"
                ]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "主清洗泵",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 250,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 2.5
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "副清洗泵",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 450,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 2.5
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "溶剂分配阀",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 250,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "容器分配阀",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 450,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "heatchill_1",
            "name": "加热清洗器",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "device",
            "class": "virtual_heatchill",
            "position": {
                "x": 600,
                "y": 350,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_HEATCHILL1",
                "max_temp": 100.0,
                "min_temp": 10.0,
                "max_stir_speed": 500.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "flask_water",
            "name": "蒸馏水瓶",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "container",
            "class": "container",
            "position": {
                "x": 50,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "water",
                        "liquid_volume": 900.0
                    }
                ]
            }
        },
        {
            "id": "flask_acetone",
            "name": "丙酮清洗瓶",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "container",
            "class": "container",
            "position": {
                "x": 150,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "acetone",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethanol",
            "name": "乙醇清洗瓶",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "container",
            "class": "container",
            "position": {
                "x": 250,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "container",
            "class": "container",
            "position": {
                "x": 350,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "main_reactor",
            "name": "主反应器",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "container",
            "class": "container",
            "position": {
                "x": 600,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "residue",
                        "liquid_volume": 50.0
                    }
                ]
            }
        },
        {
            "id": "secondary_reactor",
            "name": "副反应器",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "container",
            "class": "container",
            "position": {
                "x": 800,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "organic_residue",
                        "liquid_volume": 30.0
                    }
                ]
            }
        },
        {
            "id": "waste_workup",
            "name": "清洗废液瓶",
            "children": [],
            "parent": "CleanVesselProtocolTestStation",
            "type": "container",
            "class": "container",
            "position": {
                "x": 700,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 3000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
        "links": [
        {
            "id": "link_pump1_to_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_to_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_to_water",
            "source": "multiway_valve_1",
            "target": "flask_water",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_water": "top"
            }
        },
        {
            "id": "link_valve1_to_acetone",
            "source": "multiway_valve_1",
            "target": "flask_acetone",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_acetone": "top"
            }
        },
        {
            "id": "link_valve1_to_ethanol",
            "source": "multiway_valve_1",
            "target": "flask_ethanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_ethanol": "top"
            }
        },
        {
            "id": "link_valve1_to_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "6",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve1_to_valve2_for_cleaning",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "multiway_valve_2": "8"
            }
        },
        {
            "id": "link_valve2_to_main_reactor_in",
            "source": "multiway_valve_2",
            "target": "main_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "2",
                "main_reactor": "top"
            }
        },
        {
            "id": "link_valve2_to_secondary_reactor_in",
            "source": "multiway_valve_2",
            "target": "secondary_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "3",
                "secondary_reactor": "top"
            }
        },
        {
            "id": "link_main_reactor_out_to_valve2",
            "source": "main_reactor",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "main_reactor": "bottom",
                "multiway_valve_2": "6"
            }
        },
        {
            "id": "link_secondary_reactor_out_to_valve2",
            "source": "secondary_reactor",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "secondary_reactor": "bottom",
                "multiway_valve_2": "7"
            }
        },
        {
            "id": "link_valve2_to_waste",
            "source": "multiway_valve_2",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "4",
                "waste_workup": "top"
            }
        },
        {
            "id": "link_heatchill1_to_main_reactor",
            "source": "heatchill_1",
            "target": "main_reactor",
            "type": "mechanical",
            "port": {
                "heatchill_1": "heatchill",
                "main_reactor": "bind"
            }
        },
        {
            "id": "link_heatchill1_to_secondary_reactor",
            "source": "heatchill_1",
            "target": "secondary_reactor",
            "type": "mechanical",
            "port": {
                "heatchill_1": "heatchill",
                "secondary_reactor": "bind"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/dual_valve_pump_test_station.json
+++ b/test/experiments/Protocol_Test_Station/dual_valve_pump_test_station.json
@@ -0,0 +1,367 @@
 {
    "nodes": [
        {
            "id": "DualValvePumpStation",
            "name": "双阀门泵站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2", 
                "multiway_valve_1",
                "multiway_valve_2",
                "flask_DMF",
                "flask_ethyl_acetate", 
                "flask_methanol",
                "flask_air",
                "main_reactor",
                "waste_workup",
                "collection_bottle_1"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": ["PumpTransferProtocol"]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "转移泵1",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 300,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "转移泵2",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 700,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "第一个八通阀",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 300,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "第二个八通阀",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 700,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "flask_DMF",
            "name": "DMF试剂瓶",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "DMF",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethyl_acetate",
            "name": "乙酸乙酯试剂瓶",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 200,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethyl_acetate",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_methanol",
            "name": "甲醇试剂瓶",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 300,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "methanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 400,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "main_reactor",
            "name": "主反应器",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_workup",
            "name": "废液处理瓶",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_1",
            "name": "收集瓶1",
            "children": [],
            "parent": "DualValvePumpStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump1_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_valve2",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "8",
                "multiway_valve_2": "1"
            }
        },
        {
            "id": "link_valve1_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve1_DMF",
            "source": "multiway_valve_1",
            "target": "flask_DMF",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_DMF": "outlet"
            }
        },
        {
            "id": "link_valve1_ethyl_acetate",
            "source": "multiway_valve_1",
            "target": "flask_ethyl_acetate",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_ethyl_acetate": "outlet"
            }
        },
        {
            "id": "link_valve1_methanol",
            "source": "multiway_valve_1",
            "target": "flask_methanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_methanol": "outlet"
            }
        },
        {
            "id": "link_valve2_reactor",
            "source": "multiway_valve_2",
            "target": "main_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "5",
                "main_reactor": "inlet"
            }
        },
        {
            "id": "link_valve2_waste",
            "source": "multiway_valve_2",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "6",
                "waste_workup": "inlet"
            }
        },
        {
            "id": "link_valve2_collection",
            "source": "multiway_valve_2",
            "target": "collection_bottle_1",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "7",
                "collection_bottle_1": "inlet"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/evacuateandrefill_test_station.json
+++ b/test/experiments/Protocol_Test_Station/evacuateandrefill_test_station.json
@@ -0,0 +1,557 @@
 {
    "nodes": [
        {
            "id": "EvacuateRefillTestStation",
            "name": "抽真空充气测试站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2", 
                "multiway_valve_1",
                "multiway_valve_2",
                "flask_DMF",
                "flask_ethyl_acetate", 
                "flask_methanol",
                "flask_air",
                "vacuum_pump_1",
                "gas_source_nitrogen",
                "gas_source_air",
                "solenoid_valve_vacuum",
                "solenoid_valve_gas",
                "main_reactor",
                "stirrer_1",
                "waste_workup",
                "collection_bottle_1"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": ["PumpTransferProtocol", "EvacuateAndRefillProtocol"]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "转移泵1",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 300,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "转移泵2",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 700,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "第一个八通阀",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 300,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "第二个八通阀",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 700,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "vacuum_pump_1",
            "name": "真空泵1",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_vacuum_pump",
            "position": {
                "x": 150,
                "y": 200,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VACUUM1",
                "max_pressure": -0.9
            },
            "data": {
                "status": "OFF",
                "pressure": 0.0
            }
        },
        {
            "id": "gas_source_nitrogen",
            "name": "氮气源",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_gas_source",
            "position": {
                "x": 850,
                "y": 200,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_GAS_N2",
                "gas_type": "nitrogen",
                "max_pressure": 5.0
            },
            "data": {
                "status": "OFF",
                "flow_rate": 0.0
            }
        },
        {
            "id": "gas_source_air",
            "name": "空气源",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_gas_source",
            "position": {
                "x": 950,
                "y": 200,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_GAS_AIR",
                "gas_type": "air",
                "max_pressure": 3.0
            },
            "data": {
                "status": "OFF",
                "flow_rate": 0.0
            }
        },
        {
            "id": "solenoid_valve_vacuum",
            "name": "真空电磁阀",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_solenoid_valve",
            "position": {
                "x": 225,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_SOLENOID_VACUUM"
            },
            "data": {
                "valve_position": "CLOSED"
            }
        },
        {
            "id": "solenoid_valve_gas",
            "name": "气源电磁阀",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_solenoid_valve",
            "position": {
                "x": 775,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_SOLENOID_GAS"
            },
            "data": {
                "valve_position": "CLOSED"
            }
        },
        {
            "id": "flask_DMF",
            "name": "DMF试剂瓶",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "DMF",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethyl_acetate",
            "name": "乙酸乙酯试剂瓶",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 200,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethyl_acetate",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_methanol",
            "name": "甲醇试剂瓶",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 300,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "methanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 400,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "main_reactor",
            "name": "主反应器",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "stirrer_1",
            "name": "搅拌器1",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "device",
            "class": "virtual_stirrer",
            "position": {
                "x": 600,
                "y": 450,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_STIRRER1",
                "max_speed": 1500.0
            },
            "data": {
                "speed": 0.0,
                "status": "OFF"
            }
        },
        {
            "id": "waste_workup",
            "name": "废液处理瓶",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_1",
            "name": "收集瓶1",
            "children": [],
            "parent": "EvacuateRefillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump1_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_valve2",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "8",
                "multiway_valve_2": "1"
            }
        },
        {
            "id": "link_vacuum_solenoid",
            "source": "vacuum_pump_1",
            "target": "solenoid_valve_vacuum",
            "type": "fluid",
            "port": {
                "vacuum_pump_1": "outlet",
                "solenoid_valve_vacuum": "inlet"
            }
        },
        {
            "id": "link_solenoid_vacuum_valve1",
            "source": "solenoid_valve_vacuum",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "solenoid_valve_vacuum": "outlet",
                "multiway_valve_1": "7"
            }
        },
        {
            "id": "link_gas_solenoid",
            "source": "gas_source_nitrogen",
            "target": "solenoid_valve_gas",
            "type": "fluid",
            "port": {
                "gas_source_nitrogen": "outlet",
                "solenoid_valve_gas": "inlet"
            }
        },
        {
            "id": "link_solenoid_gas_valve2",
            "source": "solenoid_valve_gas",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "solenoid_valve_gas": "outlet",
                "multiway_valve_2": "8"
            }
        },
        {
            "id": "link_air_source_valve2",
            "source": "gas_source_air",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "gas_source_air": "outlet",
                "multiway_valve_2": "2"
            }
        },
        {
            "id": "link_valve1_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve1_DMF",
            "source": "multiway_valve_1",
            "target": "flask_DMF",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_DMF": "outlet"
            }
        },
        {
            "id": "link_valve1_ethyl_acetate",
            "source": "multiway_valve_1",
            "target": "flask_ethyl_acetate",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_ethyl_acetate": "outlet"
            }
        },
        {
            "id": "link_valve1_methanol",
            "source": "multiway_valve_1",
            "target": "flask_methanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_methanol": "outlet"
            }
        },
        {
            "id": "link_valve2_reactor",
            "source": "multiway_valve_2",
            "target": "main_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "5",
                "main_reactor": "inlet"
            }
        },
        {
            "id": "link_valve2_waste",
            "source": "multiway_valve_2",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "6",
                "waste_workup": "inlet"
            }
        },
        {
            "id": "link_valve2_collection",
            "source": "multiway_valve_2",
            "target": "collection_bottle_1",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "7",
                "collection_bottle_1": "inlet"
            }
        },
        {
            "id": "link_stirrer_reactor",
            "source": "stirrer_1",
            "target": "main_reactor",
            "type": "mechanical",
            "port": {
                "stirrer_1": "stirrer",
                "main_reactor": "stirrer"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/evaporate_protocol_test_station.json
+++ b/test/experiments/Protocol_Test_Station/evaporate_protocol_test_station.json
@@ -0,0 +1,503 @@
 {
    "nodes": [
        {
            "id": "EvaporateProtocolTestStation",
            "name": "蒸发协议测试站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2", 
                "multiway_valve_1",
                "multiway_valve_2",
                "rotavap_1",
                "heatchill_1",
                "reaction_mixture",
                "rotavap_flask",
                "rotavap_condenser",
                "flask_distillate",
                "flask_ethanol",
                "flask_acetone",
                "flask_water",
                "flask_air",
                "waste_workup"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": [
                    "EvaporateProtocol",
                    "PumpTransferProtocol",
                    "HeatChillProtocol",
                    "HeatChillStartProtocol",
                    "HeatChillStopProtocol"
                ]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "主转移泵",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 200,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 2.5
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "副转移泵",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 400,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 2.5
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "溶剂分配阀",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 200,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "容器分配阀",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 400,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "rotavap_1",
            "name": "旋转蒸发仪",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "device",
            "class": "virtual_rotavap",
            "position": {
                "x": 700,
                "y": 350,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_ROTAVAP1",
                "max_temp": 180.0,
                "max_rotation_speed": 280.0
            },
            "data": {
                "status": "Ready"
            }
        },
        {
            "id": "heatchill_1",
            "name": "预加热器",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "device",
            "class": "virtual_heatchill",
            "position": {
                "x": 100,
                "y": 550,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_HEATCHILL1",
                "max_temp": 100.0,
                "min_temp": 10.0,
                "max_stir_speed": 500.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "reaction_mixture",
            "name": "反应混合物",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "reaction_mixture",
                        "liquid_volume": 600.0
                    }
                ]
            }
        },
        {
            "id": "rotavap_flask",
            "name": "旋蒸样品瓶",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 500.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "rotavap_condenser",
            "name": "旋蒸冷凝器",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 350,
                "z": 0
            },
            "config": {
                "max_volume": 500.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_distillate",
            "name": "溶剂回收瓶",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_ethanol",
            "name": "乙醇清洗瓶",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 50,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_acetone",
            "name": "丙酮清洗瓶",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 150,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "acetone",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_water",
            "name": "蒸馏水瓶",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 250,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "water",
                        "liquid_volume": 900.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 350,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_workup",
            "name": "废液瓶",
            "children": [],
            "parent": "EvaporateProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 3000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump1_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve1_ethanol",
            "source": "multiway_valve_1",
            "target": "flask_ethanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_ethanol": "outlet"
            }
        },
        {
            "id": "link_valve1_acetone",
            "source": "multiway_valve_1",
            "target": "flask_acetone",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_acetone": "outlet"
            }
        },
        {
            "id": "link_valve1_water",
            "source": "multiway_valve_1",
            "target": "flask_water",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_water": "outlet"
            }
        },
        {
            "id": "link_valve1_valve2",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "5",
                "multiway_valve_2": "1"
            }
        },
        {
            "id": "link_valve2_reaction_mixture",
            "source": "multiway_valve_2",
            "target": "reaction_mixture",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "2",
                "reaction_mixture": "inlet"
            }
        },
        {
            "id": "link_valve2_rotavap_flask",
            "source": "multiway_valve_2",
            "target": "rotavap_flask",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "3",
                "rotavap_flask": "inlet"
            }
        },
        {
            "id": "link_valve2_rotavap_condenser",
            "source": "multiway_valve_2",
            "target": "rotavap_condenser",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "4",
                "rotavap_condenser": "inlet"
            }
        },
        {
            "id": "link_valve2_distillate",
            "source": "multiway_valve_2",
            "target": "flask_distillate",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "5",
                "flask_distillate": "inlet"
            }
        },
        {
            "id": "link_valve2_waste",
            "source": "multiway_valve_2",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "6",
                "waste_workup": "inlet"
            }
        },
        {
            "id": "link_rotavap1_rotavap_flask",
            "source": "rotavap_1",
            "target": "rotavap_flask",
            "type": "fluid",
            "port": {
                "rotavap_1": "rotavap-sample",
                "rotavap_flask": "rotavap_port"
            }
        },
        {
            "id": "link_heatchill1_reaction_mixture",
            "source": "heatchill_1",
            "target": "reaction_mixture",
            "type": "mechanical",
            "port": {
                "heatchill_1": "heatchill",
                "reaction_mixture": "heating_jacket"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/filter_protocol_test_station.json
+++ b/test/experiments/Protocol_Test_Station/filter_protocol_test_station.json
@@ -0,0 +1,534 @@
 {
    "nodes": [
        {
            "id": "FilterProtocolTestStation",
            "name": "过滤协议测试站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2",
                "multiway_valve_1",
                "multiway_valve_2",
                "filter_1",
                "heatchill_1",
                "reaction_mixture",
                "filter_vessel",
                "filtrate_vessel",
                "collection_bottle_1",
                "collection_bottle_2",
                "flask_water",
                "flask_ethanol",
                "flask_acetone",
                "flask_air",
                "waste_workup"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": [
                    "FilterProtocol",
                    "PumpTransferProtocol",
                    "HeatChillProtocol",
                    "HeatChillStartProtocol",
                    "HeatChillStopProtocol"
                ]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "主转移泵",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 200,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 2.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "副转移泵",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 400,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 2.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "溶剂分配阀",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 200,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "样品分配阀",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 400,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "filter_1",
            "name": "过滤器",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "device",
            "class": "virtual_filter",
            "position": {
                "x": 600,
                "y": 350,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_FILTER1",
                "max_temp": 100.0,
                "max_stir_speed": 1000.0,
                "max_volume": 500.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "heatchill_1",
            "name": "加热搅拌器",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "device",
            "class": "virtual_heatchill",
            "position": {
                "x": 600,
                "y": 450,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_HEATCHILL1",
                "max_temp": 100.0,
                "min_temp": 4.0,
                "max_stir_speed": 1000.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "reaction_mixture",
            "name": "反应混合物",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "cell_suspension",
                        "liquid_volume": 200.0
                    }
                ]
            }
        },
        {
            "id": "filter_vessel",
            "name": "过滤器容器",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 500.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "filtrate_vessel",
            "name": "滤液收集容器",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 500.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_1",
            "name": "收集瓶1",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_2",
            "name": "收集瓶2",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 900,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_water",
            "name": "蒸馏水瓶",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 200,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "water",
                        "liquid_volume": 900.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethanol",
            "name": "乙醇清洗瓶",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 300,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_acetone",
            "name": "丙酮清洗瓶",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 400,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "acetone",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_workup",
            "name": "废液瓶",
            "children": [],
            "parent": "FilterProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump1_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve1_water",
            "source": "multiway_valve_1",
            "target": "flask_water",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_water": "outlet"
            }
        },
        {
            "id": "link_valve1_ethanol",
            "source": "multiway_valve_1",
            "target": "flask_ethanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_ethanol": "outlet"
            }
        },
        {
            "id": "link_valve1_acetone",
            "source": "multiway_valve_1",
            "target": "flask_acetone",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_acetone": "outlet"
            }
        },
        {
            "id": "link_valve1_valve2",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "5",
                "multiway_valve_2": "1"
            }
        },
        {
            "id": "link_valve2_reaction_mixture",
            "source": "multiway_valve_2",
            "target": "reaction_mixture",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "2",
                "reaction_mixture": "inlet"
            }
        },
        {
            "id": "link_valve2_filter_vessel",
            "source": "multiway_valve_2",
            "target": "filter_vessel",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "3",
                "filter_vessel": "inlet"
            }
        },
        {
            "id": "link_valve2_filtrate_vessel",
            "source": "multiway_valve_2",
            "target": "filtrate_vessel",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "4",
                "filtrate_vessel": "inlet"
            }
        },
        {
            "id": "link_valve2_collection1",
            "source": "multiway_valve_2",
            "target": "collection_bottle_1",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "5",
                "collection_bottle_1": "inlet"
            }
        },
        {
            "id": "link_valve2_collection2",
            "source": "multiway_valve_2",
            "target": "collection_bottle_2",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "6",
                "collection_bottle_2": "inlet"
            }
        },
        {
            "id": "link_valve2_waste",
            "source": "multiway_valve_2",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "7",
                "waste_workup": "inlet"
            }
        },
        {
            "id": "link_filter1_filter_vessel",
            "source": "filter_1",
            "target": "filter_vessel",
            "type": "transport",
            "port": {
                "filter_1": "filter",
                "filter_vessel": "filter_port"
            }
        },
        {
            "id": "link_heatchill1_filter_vessel",
            "source": "heatchill_1",
            "target": "filter_vessel",
            "type": "mechanical",
            "port": {
                "heatchill_1": "heatchill",
                "filter_vessel": "heating_jacket"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/heatchill_protocol_test_station.json
+++ b/test/experiments/Protocol_Test_Station/heatchill_protocol_test_station.json
@@ -0,0 +1,671 @@
 {
    "nodes": [
        {
            "id": "HeatChillProtocolTestStation",
            "name": "加热冷却协议测试站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2", 
                "multiway_valve_1",
                "multiway_valve_2",
                "stirrer_1",
                "stirrer_2",
                "heatchill_1",
                "heatchill_2",
                "flask_DMF",
                "flask_ethyl_acetate", 
                "flask_methanol",
                "flask_acetone",
                "flask_water",
                "flask_ethanol",
                "flask_air",
                "main_reactor",
                "secondary_reactor",
                "waste_workup",
                "collection_bottle_1",
                "collection_bottle_2"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": [
                    "PumpTransferProtocol", 
                    "AddProtocol", 
                    "HeatChillProtocol", 
                    "HeatChillStartProtocol", 
                    "HeatChillStopProtocol",
                    "DissolveProtocol"
                ]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "转移泵1",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 250,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "转移泵2",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 750,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "试剂分配阀",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 250,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "反应器分配阀",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 750,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "stirrer_1",
            "name": "主反应器搅拌器",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "device",
            "class": "virtual_stirrer",
            "position": {
                "x": 600,
                "y": 450,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_STIRRER1",
                "max_speed": 1500.0,
                "default_speed": 300.0
            },
            "data": {
                "speed": 0.0,
                "status": "Stopped"
            }
        },
        {
            "id": "stirrer_2",
            "name": "副反应器搅拌器",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "device",
            "class": "virtual_stirrer",
            "position": {
                "x": 900,
                "y": 450,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_STIRRER2",
                "max_speed": 1500.0,
                "default_speed": 300.0
            },
            "data": {
                "speed": 0.0,
                "status": "Stopped"
            }
        },
        {
            "id": "heatchill_1",
            "name": "主反应器加热冷却器",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "device",
            "class": "virtual_heatchill",
            "position": {
                "x": 550,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_HEATCHILL1",
                "max_temp": 200.0,
                "min_temp": -80.0,
                "max_stir_speed": 1000.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "heatchill_2",
            "name": "副反应器加热冷却器",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "device",
            "class": "virtual_heatchill",
            "position": {
                "x": 850,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_HEATCHILL2",
                "max_temp": 200.0,
                "min_temp": -80.0,
                "max_stir_speed": 1000.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "flask_DMF",
            "name": "DMF试剂瓶",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 50,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "DMF",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethyl_acetate",
            "name": "乙酸乙酯试剂瓶",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 150,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethyl_acetate",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_methanol",
            "name": "甲醇试剂瓶",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 250,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "methanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
                {
            "id": "flask_ethanol",
            "name": "乙醇试剂瓶",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 650,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_acetone",
            "name": "丙酮试剂瓶",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 350,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "acetone",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_water",
            "name": "蒸馏水瓶",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 450,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "water",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 550,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "main_reactor",
            "name": "主反应器",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "secondary_reactor",
            "name": "副反应器",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 900,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_workup",
            "name": "废液处理瓶",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_1",
            "name": "收集瓶1",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_2",
            "name": "收集瓶2",
            "children": [],
            "parent": "HeatChillProtocolTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 900,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump1_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_valve2",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "8",
                "multiway_valve_2": "1"
            }
        },
        {
            "id": "link_valve1_DMF",
            "source": "multiway_valve_1",
            "target": "flask_DMF",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_DMF": "outlet"
            }
        },
        {
            "id": "link_valve1_ethyl_acetate",
            "source": "multiway_valve_1",
            "target": "flask_ethyl_acetate",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_ethyl_acetate": "outlet"
            }
        },
        {
            "id": "link_valve1_methanol",
            "source": "multiway_valve_1",
            "target": "flask_methanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_methanol": "outlet"
            }
        },
        {
            "id": "link_valve1_acetone",
            "source": "multiway_valve_1",
            "target": "flask_acetone",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_acetone": "outlet"
            }
        },
        {
            "id": "link_valve1_water",
            "source": "multiway_valve_1",
            "target": "flask_water",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "5",
                "flask_water": "outlet"
            }
        },
        {
            "id": "link_valve1_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "6",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve2_main_reactor",
            "source": "multiway_valve_2",
            "target": "main_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "2",
                "main_reactor": "inlet"
            }
        },
        {
            "id": "link_valve2_secondary_reactor",
            "source": "multiway_valve_2",
            "target": "secondary_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "3",
                "secondary_reactor": "inlet"
            }
        },
        {
            "id": "link_valve2_waste",
            "source": "multiway_valve_2",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "6",
                "waste_workup": "inlet"
            }
        },
        {
            "id": "link_valve2_collection1",
            "source": "multiway_valve_2",
            "target": "collection_bottle_1",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "7",
                "collection_bottle_1": "inlet"
            }
        },
        {
            "id": "link_valve2_collection2",
            "source": "multiway_valve_2",
            "target": "collection_bottle_2",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "8",
                "collection_bottle_2": "inlet"
            }
        },
        {
            "id": "link_stirrer1_main_reactor",
            "source": "stirrer_1",
            "target": "main_reactor",
            "type": "mechanical",
            "port": {
                "stirrer_1": "stirrer_head",
                "main_reactor": "stirrer_port"
            }
        },
        {
            "id": "link_stirrer2_secondary_reactor",
            "source": "stirrer_2",
            "target": "secondary_reactor",
            "type": "mechanical",
            "port": {
                "stirrer_2": "stirrer_head",
                "secondary_reactor": "stirrer_port"
            }
        },
        {
            "id": "link_heatchill1_main_reactor",
            "source": "heatchill_1",
            "target": "main_reactor",
            "type": "thermal",
            "port": {
                "heatchill_1": "heating_surface",
                "main_reactor": "heating_jacket"
            }
        },
        {
            "id": "link_heatchill2_secondary_reactor",
            "source": "heatchill_2",
            "target": "secondary_reactor",
            "type": "thermal",
            "port": {
                "heatchill_2": "heating_surface",
                "secondary_reactor": "heating_jacket"
            }
        },
        {
            "id": "link_valve1_ethanol",
            "source": "multiway_valve_1",
            "target": "flask_ethanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "7",
                "flask_ethanol": "outlet"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/pumptransfer_filterthrough_test_station.json
+++ b/test/experiments/Protocol_Test_Station/pumptransfer_filterthrough_test_station.json
@@ -0,0 +1,778 @@
 {
    "nodes": [
        {
            "id": "PumpTransferFilterThroughTestStation",
            "name": "泵转移+过滤介质测试站",
            "children": [
                "transfer_pump_1",
                "transfer_pump_2",
                "multiway_valve_1",
                "multiway_valve_2",
                "reaction_mixture",
                "crude_product",
                "filter_celite",
                "column_silica_gel",
                "filter_C18",
                "pure_product",
                "collection_bottle_1",
                "collection_bottle_2",
                "collection_bottle_3",
                "intermediate_vessel_1",
                "intermediate_vessel_2",
                "flask_water",
                "flask_ethanol",
                "flask_methanol",
                "flask_ethyl_acetate",
                "flask_acetone",
                "flask_hexane",
                "flask_air",
                "waste_workup"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": [
                    "PumpTransferProtocol",
                    "FilterThroughProtocol"
                ]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "主转移泵",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 200,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 25.0,
                "transfer_rate": 2.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "transfer_pump_2",
            "name": "副转移泵",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 400,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP2",
                "max_volume": 25.0,
                "transfer_rate": 2.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "溶剂分配阀",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 200,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "multiway_valve_2",
            "name": "样品分配阀",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 400,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE2",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "reaction_mixture",
            "name": "反应混合物",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "organic_reaction_mixture",
                        "liquid_volume": 250.0
                    }
                ]
            }
        },
        {
            "id": "crude_product",
            "name": "粗产品",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 200,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "crude_organic_compound",
                        "liquid_volume": 150.0
                    }
                ]
            }
        },
        {
            "id": "filter_celite",
            "name": "硅藻土过滤器",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 300.0,
                "filter_type": "celite_pad"
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "column_silica_gel",
            "name": "硅胶柱",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 200.0,
                "filter_type": "silica_gel_column"
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "filter_C18",
            "name": "C18固相萃取柱",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 100.0,
                "filter_type": "C18_cartridge"
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "pure_product",
            "name": "纯产品",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 900,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_1",
            "name": "收集瓶1",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_2",
            "name": "收集瓶2",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_3",
            "name": "收集瓶3",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 550,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "intermediate_vessel_1",
            "name": "中间容器1",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 300,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "intermediate_vessel_2",
            "name": "中间容器2",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 400,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_water",
            "name": "蒸馏水瓶",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "water",
                        "liquid_volume": 900.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethanol",
            "name": "乙醇瓶",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 200,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_methanol",
            "name": "甲醇瓶",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 300,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "methanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethyl_acetate",
            "name": "乙酸乙酯瓶",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 400,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethyl_acetate",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_acetone",
            "name": "丙酮瓶",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 500,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "acetone",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_hexane",
            "name": "正己烷瓶",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "hexane",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_workup",
            "name": "废液瓶",
            "children": [],
            "parent": "PumpTransferFilterThroughTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 600,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump1_valve1",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_pump2_valve2",
            "source": "transfer_pump_2",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "transfer_pump_2": "transferpump",
                "multiway_valve_2": "transferpump"
            }
        },
        {
            "id": "link_valve1_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve1_water",
            "source": "multiway_valve_1",
            "target": "flask_water",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_water": "outlet"
            }
        },
        {
            "id": "link_valve1_ethanol",
            "source": "multiway_valve_1",
            "target": "flask_ethanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_ethanol": "outlet"
            }
        },
        {
            "id": "link_valve1_methanol",
            "source": "multiway_valve_1",
            "target": "flask_methanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_methanol": "outlet"
            }
        },
        {
            "id": "link_valve1_ethyl_acetate",
            "source": "multiway_valve_1",
            "target": "flask_ethyl_acetate",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "5",
                "flask_ethyl_acetate": "outlet"
            }
        },
        {
            "id": "link_valve1_acetone",
            "source": "multiway_valve_1",
            "target": "flask_acetone",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "6",
                "flask_acetone": "outlet"
            }
        },
        {
            "id": "link_valve1_hexane",
            "source": "multiway_valve_1",
            "target": "flask_hexane",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "7",
                "flask_hexane": "outlet"
            }
        },
        {
            "id": "link_valve1_valve2",
            "source": "multiway_valve_1",
            "target": "multiway_valve_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "8",
                "multiway_valve_2": "1"
            }
        },
        {
            "id": "link_valve2_reaction_mixture",
            "source": "multiway_valve_2",
            "target": "reaction_mixture",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "2",
                "reaction_mixture": "inlet"
            }
        },
        {
            "id": "link_valve2_crude_product",
            "source": "multiway_valve_2",
            "target": "crude_product",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "3",
                "crude_product": "inlet"
            }
        },
        {
            "id": "link_valve2_intermediate1",
            "source": "multiway_valve_2",
            "target": "intermediate_vessel_1",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "4",
                "intermediate_vessel_1": "inlet"
            }
        },
        {
            "id": "link_valve2_intermediate2",
            "source": "multiway_valve_2",
            "target": "intermediate_vessel_2",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "5",
                "intermediate_vessel_2": "inlet"
            }
        },
        {
            "id": "link_valve2_celite",
            "source": "multiway_valve_2",
            "target": "filter_celite",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "6",
                "filter_celite": "inlet"
            }
        },
        {
            "id": "link_valve2_silica_gel",
            "source": "multiway_valve_2",
            "target": "column_silica_gel",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "7",
                "column_silica_gel": "inlet"
            }
        },
        {
            "id": "link_valve2_C18",
            "source": "multiway_valve_2",
            "target": "filter_C18",
            "type": "fluid",
            "port": {
                "multiway_valve_2": "8",
                "filter_C18": "inlet"
            }
        },
        {
            "id": "link_celite_collection1",
            "source": "filter_celite",
            "target": "collection_bottle_1",
            "type": "fluid",
            "port": {
                "filter_celite": "outlet",
                "collection_bottle_1": "inlet"
            }
        },
        {
            "id": "link_silica_gel_collection2",
            "source": "column_silica_gel",
            "target": "collection_bottle_2",
            "type": "fluid",
            "port": {
                "column_silica_gel": "outlet",
                "collection_bottle_2": "inlet"
            }
        },
        {
            "id": "link_C18_collection3",
            "source": "filter_C18",
            "target": "collection_bottle_3",
            "type": "fluid",
            "port": {
                "filter_C18": "outlet",
                "collection_bottle_3": "inlet"
            }
        },
        {
            "id": "link_collection1_pure_product",
            "source": "collection_bottle_1",
            "target": "pure_product",
            "type": "fluid",
            "port": {
                "collection_bottle_1": "outlet",
                "pure_product": "inlet"
            }
        },
        {
            "id": "link_collection2_pure_product",
            "source": "collection_bottle_2",
            "target": "pure_product",
            "type": "fluid",
            "port": {
                "collection_bottle_2": "outlet",
                "pure_product": "inlet"
            }
        },
        {
            "id": "link_collection3_pure_product",
            "source": "collection_bottle_3",
            "target": "pure_product",
            "type": "fluid",
            "port": {
                "collection_bottle_3": "outlet",
                "pure_product": "inlet"
            }
        },
        {
            "id": "link_waste_connection",
            "source": "pure_product",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "pure_product": "waste_outlet",
                "waste_workup": "inlet"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/pumptransfer_test_station.json
+++ b/test/experiments/Protocol_Test_Station/pumptransfer_test_station.json
@@ -0,0 +1,304 @@
 {
    "nodes": [
        {
            "id": "SimpleProtocolStation",
            "name": "简单协议工作站",
            "children": [
                "transfer_pump_1",
                "multiway_valve_1",
                "flask_DMF",
                "flask_ethyl_acetate", 
                "flask_methanol",
                "main_reactor",
                "waste_workup",
                "collection_bottle_1",
                "flask_air"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": ["PumpTransferProtocol"]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "转移泵1",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 500,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL",
                "max_volume": 25.0,
                "transfer_rate": 5.0
            },
            "data": {
                "position": 0.0,
                "status": "Idle",
                "valve_position": "0"
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "八通阀1",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 500,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "flask_DMF",
            "name": "DMF试剂瓶",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 200,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "DMF",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_ethyl_acetate",
            "name": "乙酸乙酯试剂瓶",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 300,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "ethyl_acetate",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "flask_methanol",
            "name": "甲醇试剂瓶",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 400,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "methanol",
                        "liquid_volume": 800.0
                    }
                ]
            }
        },
        {
            "id": "main_reactor",
            "name": "主反应器",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_workup",
            "name": "废液处理瓶",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_bottle_1",
            "name": "收集瓶1",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_air",
            "name": "空气瓶",
            "children": [],
            "parent": "SimpleProtocolStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_pump_valve",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump", 
                "multiway_valve_1": "transferpump"  
            }
        },
        {
            "id": "link_valve_air",
            "source": "multiway_valve_1",
            "target": "flask_air",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_air": "top"
            }
        },
        {
            "id": "link_valve_DMF",
            "source": "multiway_valve_1",
            "target": "flask_DMF",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_DMF": "outlet"
            }
        },
        {
            "id": "link_valve_ethyl_acetate",
            "source": "multiway_valve_1",
            "target": "flask_ethyl_acetate",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_ethyl_acetate": "outlet"
            }
        },
        {
            "id": "link_valve_methanol",
            "source": "multiway_valve_1",
            "target": "flask_methanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_methanol": "outlet"
            }
        },
        {
            "id": "link_valve_reactor",
            "source": "multiway_valve_1",
            "target": "main_reactor",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "5",
                "main_reactor": "inlet"
            }
        },
        {
            "id": "link_valve_waste",
            "source": "multiway_valve_1",
            "target": "waste_workup",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "6",
                "waste_workup": "inlet"
            }
        },
        {
            "id": "link_valve_collection",
            "source": "multiway_valve_1",
            "target": "collection_bottle_1",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "7",
                "collection_bottle_1": "inlet"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/run_column_protocol_test_station.json
+++ b/test/experiments/Protocol_Test_Station/run_column_protocol_test_station.json
@@ -0,0 +1,432 @@
 {
    "nodes": [
        {
            "id": "RunColumnTestStation",
            "name": "柱层析测试工作站",
            "children": [
                "transfer_pump_1",
                "multiway_valve_1",
                "column_1",
                "flask_sample",
                "flask_hexane",
                "flask_ethyl_acetate",
                "flask_methanol",
                "column_vessel",
                "collection_flask_1",
                "collection_flask_2",
                "collection_flask_3",
                "waste_flask",
                "main_reactor"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": ["RunColumnProtocol", "PumpTransferProtocol"]
            },
            "data": {}
        },
        {
            "id": "transfer_pump_1",
            "name": "转移泵",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "device",
            "class": "virtual_transfer_pump",
            "position": {
                "x": 300,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_PUMP1",
                "max_volume": 50.0,
                "transfer_rate": 10.0
            },
            "data": {
                "status": "Idle",
                "position": 0.0
            }
        },
        {
            "id": "multiway_valve_1",
            "name": "八通阀门",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 300,
                "y": 400,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_VALVE1",
                "positions": 8
            },
            "data": {
                "current_position": 1
            }
        },
        {
            "id": "column_1",
            "name": "柱层析设备",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "device",
            "class": "virtual_column",
            "position": {
                "x": 600,
                "y": 350,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_COLUMN1",
                "max_flow_rate": 5.0,
                "column_length": 30.0,
                "column_diameter": 2.5
            },
            "data": {
                "status": "Idle",
                "column_state": "Ready"
            }
        },
        {
            "id": "flask_sample",
            "name": "样品瓶",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 500.0
            },
            "data": {
                "liquid": [
                    {
                        "name": "crude_mixture",
                        "volume": 200.0,
                        "concentration": 70.0
                    }
                ]
            }
        },
        {
            "id": "flask_hexane",
            "name": "正己烷洗脱剂",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 200,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": [
                    {
                        "name": "hexane",
                        "volume": 1500.0,
                        "concentration": 99.8
                    }
                ]
            }
        },
        {
            "id": "flask_ethyl_acetate",
            "name": "乙酸乙酯洗脱剂",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 300,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": [
                    {
                        "name": "ethyl_acetate",
                        "volume": 1500.0,
                        "concentration": 99.5
                    }
                ]
            }
        },
        {
            "id": "flask_methanol",
            "name": "甲醇洗脱剂",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 400,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "name": "methanol",
                        "volume": 800.0,
                        "concentration": 99.9
                    }
                ]
            }
        },
        {
            "id": "column_vessel",
            "name": "柱容器",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 300.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_flask_1",
            "name": "收集瓶1",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_flask_2",
            "name": "收集瓶2",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "collection_flask_3",
            "name": "收集瓶3",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 900,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "waste_flask",
            "name": "废液瓶",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 1000,
                "y": 500,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "main_reactor",
            "name": "反应器",
            "children": [],
            "parent": "RunColumnTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 600,
                "y": 300,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "name": "reaction_mixture",
                        "volume": 300.0,
                        "concentration": 85.0
                    }
                ]
            }
        }
    ],
    "links": [
        {
            "id": "link_pump_valve",
            "source": "transfer_pump_1",
            "target": "multiway_valve_1",
            "type": "fluid",
            "port": {
                "transfer_pump_1": "transferpump",
                "multiway_valve_1": "transferpump"
            }
        },
        {
            "id": "link_valve_sample",
            "source": "multiway_valve_1",
            "target": "flask_sample",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "1",
                "flask_sample": "outlet"
            }
        },
        {
            "id": "link_valve_hexane",
            "source": "multiway_valve_1",
            "target": "flask_hexane",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "2",
                "flask_hexane": "outlet"
            }
        },
        {
            "id": "link_valve_ethyl_acetate",
            "source": "multiway_valve_1",
            "target": "flask_ethyl_acetate",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "3",
                "flask_ethyl_acetate": "outlet"
            }
        },
        {
            "id": "link_valve_methanol",
            "source": "multiway_valve_1",
            "target": "flask_methanol",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "4",
                "flask_methanol": "outlet"
            }
        },
        {
            "id": "link_valve_column_vessel",
            "source": "multiway_valve_1",
            "target": "column_vessel",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "5",
                "column_vessel": "inlet"
            }
        },
        {
            "id": "link_valve_collection1",
            "source": "multiway_valve_1",
            "target": "collection_flask_1",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "6",
                "collection_flask_1": "inlet"
            }
        },
        {
            "id": "link_valve_collection2",
            "source": "multiway_valve_1",
            "target": "collection_flask_2",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "7",
                "collection_flask_2": "inlet"
            }
        },
        {
            "id": "link_valve_waste",
            "source": "multiway_valve_1",
            "target": "waste_flask",
            "type": "fluid",
            "port": {
                "multiway_valve_1": "8",
                "waste_flask": "inlet"
            }
        },
        {
            "id": "link_column_device_vessel",
            "source": "column_1",
            "target": "column_vessel",
            "type": "transport",
            "port": {
                "column_1": "columnin",
                "column_vessel": "column_port"
            }
        },
        {
            "id": "link_column_collection3",
            "source": "column_1",
            "target": "collection_flask_3",
            "type": "transport",
            "port": {
                "column_1": "columnout",
                "collection_flask_3": "column_outlet"
            }
        }
    ]
 }
--- a/test/experiments/Protocol_Test_Station/simple_stir_heatchill_test_station.json
+++ b/test/experiments/Protocol_Test_Station/simple_stir_heatchill_test_station.json
@@ -0,0 +1,141 @@
 {
    "nodes": [
        {
            "id": "SimpleStirHeatChillTestStation",
            "name": "搅拌加热测试站",
            "children": [
                "stirrer_1",
                "heatchill_1",
                "main_reactor",
                "secondary_reactor"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
                "x": 500,
                "y": 200,
                "z": 0
            },
            "config": {
                "protocol_type": [
                    "StirProtocol",
                    "StartStirProtocol", 
                    "StopStirProtocol",
                    "HeatChillProtocol", 
                    "HeatChillStartProtocol", 
                    "HeatChillStopProtocol"
                ]
            },
            "data": {}
        },
        {
            "id": "stirrer_1",
            "name": "主搅拌器",
            "children": [],
            "parent": "SimpleStirHeatChillTestStation",
            "type": "device",
            "class": "virtual_stirrer",
            "position": {
                "x": 400,
                "y": 350,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_STIRRER1",
                "max_speed": 1500.0,
                "min_speed": 50.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "heatchill_1",
            "name": "主加热冷却器",
            "children": [],
            "parent": "SimpleStirHeatChillTestStation",
            "type": "device",
            "class": "virtual_heatchill",
            "position": {
                "x": 600,
                "y": 350,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL_HEATCHILL1",
                "max_temp": 200.0,
                "min_temp": -80.0,
                "max_stir_speed": 1000.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "main_reactor",
            "name": "主反应器",
            "children": [],
            "parent": "SimpleStirHeatChillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 500,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 2000.0
            },
            "data": {
                "liquid": [
                    {
                        "liquid_type": "water",
                        "liquid_volume": 500.0
                    }
                ]
            }
        },
        {
            "id": "secondary_reactor",
            "name": "副反应器",
            "children": [],
            "parent": "SimpleStirHeatChillTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 700,
                "y": 450,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": []
            }
        }
    ],
    "links": [
        {
            "id": "link_stirrer1_main_reactor",
            "source": "stirrer_1",
            "target": "main_reactor",
            "type": "mechanical",
            "port": {
                "stirrer_1": "stirrer",
                "main_reactor": "stirrer_port"
            }
        },
        {
            "id": "link_heatchill1_main_reactor",
            "source": "heatchill_1",
            "target": "main_reactor",
            "type": "mechanical",
            "port": {
                "heatchill_1": "heatchill",
                "main_reactor": "heating_jacket"
            }
        }
    ]
 }
--- a/test/experiments/camera.json
+++ b/test/experiments/camera.json
@@ -0,0 +1,45 @@
 {
    "nodes": [
        {
            "id": "Camera",
            "name": "摄像头",
            "children": [
            ],
            "parent": null,
            "type": "device",
            "class": "camera",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "camera_index": 0,
                "period": 0.05
            },
            "data": {
            }
        },
        {
            "id": "Gripper1",
            "name": "假夹爪",
            "children": [
            ],
            "parent": null,
            "type": "device",
            "class": "gripper.mock",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
            },
            "data": {
            }
        }
    ],
    "links": [
    ]
 }
--- a/test/experiments/comprehensive_protocol/checklist.md
+++ b/test/experiments/comprehensive_protocol/checklist.md
@@ -0,0 +1,258 @@
 1. 用到的仪器
                virtual_multiway_valve(√)                                                     八通阀门
                virtual_transfer_pump(√)                                                        转移泵
                virtual_centrifuge()                                                            离心机
                virtual_rotavap()                                                               旋蒸仪
                virtual_heatchill()                                                             加热器
                virtual_stirrer()                                                               搅拌器
                virtual_solenoid_valve()                                                        电磁阀
                virtual_vacuum_pump(√)                       vacuum_pump.mock                            真空泵
                virtual_gas_source(√)                                                                    气源
                virtual_filter()                                                                过滤器
                virtual_column(√)                                                               层析柱
                separator()                         homemade_grbl_conductivity                  分液漏斗
 2. 用到的protocol
    PumpTransferProtocol: generate_pump_protocol_with_rinsing,                      (√)
    这个重复了，删掉CleanProtocol: generate_clean_protocol,
    SeparateProtocol: generate_separate_protocol,                           (×)
    EvaporateProtocol: generate_evaporate_protocol,                                 (√)
    EvacuateAndRefillProtocol: generate_evacuateandrefill_protocol,                 (√)
    CentrifugeProtocol: generate_centrifuge_protocol,                               (√)
    AddProtocol: generate_add_protocol,                                             (√)
    FilterProtocol: generate_filter_protocol,                                       (√)
    HeatChillProtocol: generate_heat_chill_protocol,                                (√)
    HeatChillStartProtocol: generate_heat_chill_start_protocol,                     (√)
    HeatChillStopProtocol: generate_heat_chill_stop_protocol,                       (√)
    HeatChillToTempProtocol:
    StirProtocol: generate_stir_protocol,                                           (√)
    StartStirProtocol: generate_start_stir_protocol,                                (√)
    StopStirProtocol: generate_stop_stir_protocol,                                  (√)
    这个重复了，删掉TransferProtocol: generate_transfer_protocol,
    CleanVesselProtocol: generate_clean_vessel_protocol,                            (√)
    DissolveProtocol: generate_dissolve_protocol,                                   (√)
    FilterThroughProtocol: generate_filter_through_protocol,                        (√)
    RunColumnProtocol: generate_run_column_protocol,                                (√)<RunColumn Rf="?" column="column" from_vessel="rotavap" ratio="5:95" solvent1="methanol" solvent2="chloroform" to_vessel="rotavap"/>
 上下文体积搜索
 3. 还没创建的protocol
    ResetHandling                         写完了                               <ResetHandling solvent="methanol"/>
    Dry                                  写完了                                 <Dry compound="product" vessel="filter"/>
    AdjustPH                               写完了                                <AdjustPH pH="8.0" reagent="hydrochloric acid" vessel="main_reactor"/>
    Recrystallize                          写完了                              <Recrystallize ratio="?" solvent1="dichloromethane" solvent2="methanol" vessel="filter" volume="?"/>
    TakeSample                                                                  <TakeSample id="a" vessel="rotavap"/>
    Hydrogenate                                                                 <Hydrogenate temp="45 °C" time="?" vessel="main_reactor"/>
 4. 参数对齐
 class PumpTransferProtocol(BaseModel):
    from_vessel: str
    to_vessel: str
    volume: float
    amount: str = ""
    time: float = 0
    viscous: bool = False
    rinsing_solvent: str = "air"        <Transfer from_vessel="main_reactor" to_vessel="rotavap"/>
    rinsing_volume: float = 5000        <Transfer event="A" from_vessel="reactor" rate_spec="dropwise" to_vessel="main_reactor"/>
    rinsing_repeats: int = 2            <Transfer from_vessel="separator" through="cartridge" to_vessel="rotavap"/>
    solid: bool = False                 测完了三个都能跑✅
    flowrate: float = 500
    transfer_flowrate: float = 2500
 class SeparateProtocol(BaseModel):
    purpose: str
    product_phase: str
    from_vessel: str
    separation_vessel: str
    to_vessel: str
    waste_phase_to_vessel: str
    solvent: str
    solvent_volume: float               <Separate product_phase="bottom" purpose="wash" solvent="water" vessel="separator" volume="?"/>
    through: str                        <Separate product_phase="top" purpose="separate" vessel="separator"/>
    repeats: int                        <Separate product_phase="bottom" purpose="extract" repeats="3" solvent="CH2Cl2" vessel="separator" volume="?"/>
    stir_time: float                    <Separate product_phase="top" product_vessel="flask" purpose="separate" vessel="separator" waste_vessel="separator"/>
    stir_speed: float
    settling_time: float                测完了能跑✅
 class EvaporateProtocol(BaseModel):
    vessel: str
    pressure: float
    temp: float                         <Evaporate solvent="ethanol" vessel="rotavap"/>
    time: float                         测完了能跑✅
    stir_speed: float
 class EvacuateAndRefillProtocol(BaseModel):
    vessel: str
    gas: str                            <EvacuateAndRefill gas="nitrogen" vessel="main_reactor"/>
    repeats: int                        测完了能跑✅
 class AddProtocol(BaseModel):
    vessel: str
    reagent: str
    volume: float
    mass: float
    amount: str
    time: float
    stir: bool
    stir_speed: float                   <Add reagent="ethanol" vessel="main_reactor" volume="2.7 mL"/>
    <Add event="A" mass="19.3 g" mol="0.28 mol" rate_spec="portionwise" reagent="sodium nitrite" time="1 h" vessel="main_reactor"/>
    <Add mass="4.5 g" mol="16.2 mmol" reagent="(S)-2-phthalimido-6-hydroxyhexanoic acid" vessel="main_reactor"/>
    <Add purpose="dilute" reagent="hydrochloric acid" vessel="main_reactor" volume="?"/>
    <Add equiv="1.1" event="B" mol="25.2 mmol" rate_spec="dropwise" reagent="1-fluoro-2-nitrobenzene" time="20 min" 
    vessel="main_reactor" volume="2.67 mL"/>
    <Add ratio="?" reagent="tetrahydrofuran|tert-butanol" vessel="main_reactor" volume="?"/>
    viscous: bool
    purpose: str                        测完了能跑✅
 class CentrifugeProtocol(BaseModel):
    vessel: str
    speed: float
    time: float                         没毛病
    temp: float
 class FilterProtocol(BaseModel):
    vessel: str
    filtrate_vessel: str
    stir: bool                          <Filter vessel="filter"/>
    stir_speed: float                   <Filter filtrate_vessel="rotavap" vessel="filter"/>
    temp: float                         测完了能跑✅
    continue_heatchill: bool
    volume: float
 class HeatChillProtocol(BaseModel):
    vessel: str
    temp: float
    time: float                         <HeatChill pressure="1 mbar" temp_spec="room temperature" time="?" vessel="main_reactor"/>
                                        <HeatChill temp_spec="room temperature" time_spec="overnight" vessel="main_reactor"/>
                                        <HeatChill temp="256 °C" time="?" vessel="main_reactor"/>
                                        <HeatChill reflux_solvent="methanol" temp_spec="reflux" time="2 h" vessel="main_reactor"/>
                                        <HeatChillToTemp temp_spec="room temperature" vessel="main_reactor"/>
    stir: bool                          测完了能跑✅
    stir_speed: float
    purpose: str
 class HeatChillStartProtocol(BaseModel):
    vessel: str
    temp: float                     疑似没有
    purpose: str
 class HeatChillStopProtocol(BaseModel):
    vessel: str                     疑似没有
 class StirProtocol(BaseModel):
    stir_time: float
    stir_speed: float               <Stir time="0.5 h" vessel="main_reactor"/>
                                    <Stir event="A" time="30 min" vessel="main_reactor"/>
                                    <Stir time_spec="several minutes" vessel="filter"/>
    settling_time: float            测完了能跑✅
 class StartStirProtocol(BaseModel):
    vessel: str
    stir_speed: float               疑似没有
    purpose: str
 class StopStirProtocol(BaseModel):
    vessel: str                     疑似没有
 class TransferProtocol(BaseModel):
    from_vessel: str
    to_vessel: str
    volume: float
    amount: str = ""
    time: float = 0
    viscous: bool = False   
    rinsing_solvent: str = ""
    rinsing_volume: float = 0.0
    rinsing_repeats: int = 0
    solid: bool = False             这个protocol早该删掉了
 class CleanVesselProtocol(BaseModel):
    vessel: str
    solvent: str
    volume: float
    temp: float
    repeats: int = 1                    <CleanVessel vessel="centrifuge"/>
 class DissolveProtocol(BaseModel):
    vessel: str
    solvent: str
    volume: float       <Dissolve mass="2.9 g" mol="0.12 mol" reagent="magnesium" vessel="main_reactor"/>
    amount: str = ""    <Dissolve mass="12.9 g" reagent="4-tert-butylbenzyl bromide" vessel="main_reactor"/>
    temp: float = 25.0  <Dissolve solvent="diisopropyl ether" vessel="rotavap" volume="?"/>
    time: float = 0.0   <Dissolve event="A" mass="?" reagent="pyridinone" vessel="main_reactor"/>
    stir_speed: float = 0.0     测完了能跑✅
 class FilterThroughProtocol(BaseModel):
    from_vessel: str
    to_vessel: str
    filter_through: str
    eluting_solvent: str = ""
    eluting_volume: float = 0.0                 疑似没有
    eluting_repeats: int = 0
    residence_time: float = 0.0
 class RunColumnProtocol(BaseModel):
    from_vessel: str
    to_vessel: str              <RunColumn Rf="?" column="column" from_vessel="rotavap" pct1="40 %" pct2="50 %" solvent1="ethyl acetate" solvent2="hexane" to_vessel="rotavap"/>
    column: str                 测完了能跑✅
 class WashSolidProtocol(BaseModel):
    vessel: str
    solvent: str
    volume: float
    filtrate_vessel: str = ""   <WashSolid repeats="4" solvent="water" vessel="main_reactor" volume="400 mL"/>
    temp: float = 25.0          <WashSolid filtrate_vessel="rotavap" solvent="formic acid" vessel="main_reactor" volume="?"/>
    stir: bool = False          <WashSolid solvent="acetone" vessel="rotavap" volume="5 mL"/>
                                <WashSolid solvent="ethyl alcohol" vessel="main_reactor" volume_spec="small volume"/>
                                <WashSolid filtrate_vessel="rotavap" mass="10 g" solvent="toluene" vessel="separator"/>
                                <WashSolid repeats_spec="several" solvent="water" vessel="main_reactor" volume="?"/>
    stir_speed: float = 0.0     测完了能跑✅
    time: float = 0.0
    repeats: int = 1
 class AdjustPHProtocol(BaseModel):
    vessel: str = Field(..., description="目标容器")
    ph_value: float = Field(..., description="目标pH值")  # 改为 ph_value
    reagent: str = Field(..., description="酸碱试剂名称")
    # 移除其他可选参数，使用默认值                                                   <新写的，没问题>
 class ResetHandlingProtocol(BaseModel):
    solvent: str = Field(..., description="溶剂名称")                               <新写的，没问题>
 class DryProtocol(BaseModel):
    compound: str = Field(..., description="化合物名称")                            <新写的，没问题>
    vessel: str = Field(..., description="目标容器")
 class RecrystallizeProtocol(BaseModel):
    ratio: str = Field(..., description="溶剂比例（如 '1:1', '3:7'）")
    solvent1: str = Field(..., description="第一种溶剂名称")                        <新写的，没问题>
    solvent2: str = Field(..., description="第二种溶剂名称")
    vessel: str = Field(..., description="目标容器")
    volume: float = Field(..., description="总体积 (mL)")
 class HydrogenateProtocol(BaseModel):
    temp: str = Field(..., description="反应温度（如 '45 °C'）")
    time: str = Field(..., description="反应时间（如 '2 h'）")                          <新写的，没问题>
    vessel: str = Field(..., description="反应容器")
    还差
    <dissolve>
    <separate>
    <CleanVessel vessel="centrifuge"/>
 单位修复：
    evaporate
    heatchill
    recrysitallize
    stir
    wash solid
--- a/test/experiments/comprehensive_protocol/comprehensive_station.json
+++ b/test/experiments/comprehensive_protocol/comprehensive_station.json
--- a/test/experiments/mock_devices/mock_all.json
+++ b/test/experiments/mock_devices/mock_all.json
@@ -3,7 +3,9 @@
        {  
            "id": "MockChiller1",  
            "name": "模拟冷却器",  
-            "children": [],  
+            "children": [
                "MockContainerForChiller1"
            ],
            "parent": null,  
            "type": "device",  
            "class": "mock_chiller",  
@@ -25,6 +27,22 @@
                "purpose": ""
            }  
        },
        {
            "id": "MockContainerForChiller1",
            "name": "模拟容器",
            "type": "container",
            "parent": "MockChiller1",
            "position": {
                "x": 5,
                "y": 0,
                "z": 0
            },
            "data": {
                "liquid_type": "CuCl2",
                "liquid_volume": "100"
            },
            "children": []
        },
        {  
            "id": "MockFilter1",  
            "name": "模拟过滤器",  
--- a/test/experiments/mock_protocol/addteststation.json
+++ b/test/experiments/mock_protocol/addteststation.json
@@ -4,58 +4,83 @@
            "id": "AddTestStation",
            "name": "添加试剂测试工作站",
            "children": [
-                "pump_add",
+                "transfer_pump",
-                "flask_1",
+                "multiway_valve", 
                "flask_2", 
                "flask_3",
                "flask_4",
                "reactor",
                "stirrer",
-                "flask_air"
+                "flask_reagent1",
                "flask_reagent2",
                "flask_reagent3",
                "flask_reagent4",
                "reactor",
                "flask_waste",
                "flask_rinsing",
                "flask_buffer"
            ],
            "parent": null,
            "type": "device",
            "class": "workstation",
            "position": {
-                "x": 620.6111111111111,
+                "x": 620,
                "y": 171,
                "z": 0
            },
            "config": {
-                "protocol_type": ["AddProtocol", "PumpTransferProtocol", "CleanProtocol"]
+                "protocol_type": ["AddProtocol", "TransferProtocol", "StartStirProtocol", "StopStirProtocol"]
            },
            "data": {}
        },
        {
-            "id": "pump_add",
+            "id": "transfer_pump",
-            "name": "pump_add",
+            "name": "注射器泵",
            "children": [],
            "parent": "AddTestStation",
            "type": "device",
-            "class": "virtual_pump",
+            "class": "virtual_transfer_pump",
            "position": {
-                "x": 520.6111111111111,
+                "x": 520,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL",
-                "max_volume": 25.0
+                "max_volume": 50.0,
                "transfer_rate": 5.0
            },
            "data": {
                "status": "Idle"
            }
        },
        {
            "id": "multiway_valve",
            "name": "八通阀门",
            "children": [],
            "parent": "AddTestStation",
            "type": "device",
            "class": "virtual_multiway_valve",
            "position": {
                "x": 420,
                "y": 300,
                "z": 0
            },
            "config": {
                "port": "VIRTUAL",
                "positions": 8
            },
            "data": {
                "status": "Idle",
                "current_position": 1
            }
        },
        {
            "id": "stirrer",
-            "name": "stirrer",
+            "name": "搅拌器",
            "children": [],
            "parent": "AddTestStation",
            "type": "device",
            "class": "virtual_stirrer",
            "position": {
-                "x": 698.1111111111111,
+                "x": 720,
-                "y": 478,
+                "y": 450,
                "z": 0
            },
            "config": {
@@ -68,110 +93,115 @@
            }
        },
        {
-            "id": "flask_1",
+            "id": "flask_reagent1",
-            "name": "通用试剂瓶1",
+            "name": "试剂瓶1 (甲醇)",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 100,
-                "y": 428,
+                "y": 400,
                "z": 0
            },
            "config": {
-                "max_volume": 2000.0
+                "max_volume": 1000.0
            },
            "data": {
-                "liquid": []
+                "liquid": [
                    {
                        "name": "甲醇",
                        "volume": 800.0,
                        "concentration": "99.9%"
                    }
                ]
            }
        },
        {
-            "id": "flask_2",
+            "id": "flask_reagent2",
-            "name": "通用试剂瓶2",
+            "name": "试剂瓶2 (乙醇)",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
-                "x": 250,
+                "x": 180,
-                "y": 428,
+                "y": 400,
                "z": 0
            },
            "config": {
-                "max_volume": 2000.0
+                "max_volume": 1000.0
            },
            "data": {
-                "liquid": []
+                "liquid": [
                    {
                        "name": "乙醇",
                        "volume": 750.0,
                        "concentration": "95%"
                    }
                ]
            }
        },
        {
-            "id": "flask_3",
+            "id": "flask_reagent3",
-            "name": "通用试剂瓶3",
+            "name": "试剂瓶3 (丙酮)",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
-                "x": 400,
+                "x": 260,
-                "y": 428,
+                "y": 400,
                "z": 0
            },
            "config": {
-                "max_volume": 2000.0
+                "max_volume": 1000.0
            },
            "data": {
-                "liquid": []
+                "liquid": [
                    {
                        "name": "丙酮",
                        "volume": 900.0,
                        "concentration": "99.5%"
                    }
                ]
            }
        },
        {
-            "id": "flask_4",
+            "id": "flask_reagent4",
-            "name": "通用试剂瓶4",
+            "name": "试剂瓶4 (二氯甲烷)",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
-                "x": 550,
+                "x": 340,
-                "y": 428,
+                "y": 400,
                "z": 0
            },
            "config": {
-                "max_volume": 2000.0
+                "max_volume": 1000.0
            },
            "data": {
-                "liquid": []
+                "liquid": [
                    {
                        "name": "二氯甲烷",
                        "volume": 850.0,
                        "concentration": "99.8%"
                    }
                ]
            }
        },
        {
            "id": "reactor",
-            "name": "reactor",
+            "name": "反应器",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
-                "x": 698.1111111111111,
+                "x": 720,
-                "y": 428,
+                "y": 400,
                "z": 0
            },
            "config": {
                "max_volume": 5000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_air",
            "name": "flask_air",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 800,
                "y": 300,
                "z": 0
            },
            "config": {
@@ -180,70 +210,166 @@
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_waste",
            "name": "废液瓶",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 850,
                "y": 400,
                "z": 0
            },
            "config": {
                "max_volume": 3000.0
            },
            "data": {
                "liquid": []
            }
        },
        {
            "id": "flask_rinsing",
            "name": "冲洗液瓶",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 950,
                "y": 300,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "name": "去离子水",
                        "volume": 800.0,
                        "concentration": "纯净"
                    }
                ]
            }
        },
        {
            "id": "flask_buffer",
            "name": "缓冲液瓶",
            "children": [],
            "parent": "AddTestStation",
            "type": "container",
            "class": null,
            "position": {
                "x": 950,
                "y": 400,
                "z": 0
            },
            "config": {
                "max_volume": 1000.0
            },
            "data": {
                "liquid": [
                    {
                        "name": "磷酸盐缓冲液",
                        "volume": 700.0,
                        "concentration": "0.1M, pH 7.4"
                    }
                ]
            }
        }
    ],
    "links": [
        {
-            "source": "stirrer",
+            "source": "transfer_pump",
            "target": "multiway_valve",
            "type": "physical",
            "port": {
                "transfer_pump": "syringe-port",
                "multiway_valve": "multiway-valve-inlet"
            }
        },
        {
            "source": "multiway_valve",
            "target": "flask_reagent1",
            "type": "physical",
            "port": {
                "multiway_valve": "multiway-valve-port-1",
                "flask_reagent1": "top"
            }
        },
        {
            "source": "multiway_valve",
            "target": "flask_reagent2",
            "type": "physical",
            "port": {
                "multiway_valve": "multiway-valve-port-2",
                "flask_reagent2": "top"
            }
        },
        {
            "source": "multiway_valve",
            "target": "flask_reagent3",
            "type": "physical",
            "port": {
                "multiway_valve": "multiway-valve-port-3",
                "flask_reagent3": "top"
            }
        },
        {
            "source": "multiway_valve",
            "target": "flask_reagent4",
            "type": "physical",
            "port": {
                "multiway_valve": "multiway-valve-port-4",
                "flask_reagent4": "top"
            }
        },
        {
            "source": "multiway_valve",
            "target": "reactor",
            "type": "physical",
            "port": {
-                "stirrer": "top",
+                "multiway_valve": "multiway-valve-port-5",
                "reactor": "bottom"
            }
        },
        {
            "source": "pump_add",
            "target": "flask_1",
            "type": "physical",
            "port": {
                "pump_add": "outlet",
                "flask_1": "top"
            }
        },
        {
            "source": "pump_add",
            "target": "flask_2",
            "type": "physical",
            "port": {
                "pump_add": "inlet",
                "flask_2": "top"
            }
        },
        {
            "source": "pump_add",
            "target": "flask_3",
            "type": "physical",
            "port": {
                "pump_add": "inlet",
                "flask_3": "top"
            }
        },
        {
            "source": "pump_add",
            "target": "flask_4",
            "type": "physical",
            "port": {
                "pump_add": "inlet",
                "flask_4": "top"
            }
        },
        {
            "source": "pump_add",
            "target": "reactor",
            "type": "physical",
            "port": {
                "pump_add": "outlet",
                "reactor": "top"
            }
        },
        {
-            "source": "pump_add",
+            "source": "multiway_valve",
-            "target": "flask_air",
+            "target": "flask_waste",
            "type": "physical",
            "port": {
-                "pump_add": "inlet",
+                "multiway_valve": "multiway-valve-port-6",
-                "flask_air": "top"
+                "flask_waste": "top"
            }
        },
        {
            "source": "multiway_valve",
            "target": "flask_rinsing",
            "type": "physical",
            "port": {
                "multiway_valve": "multiway-valve-port-7",
                "flask_rinsing": "top"
            }
        },
        {
            "source": "multiway_valve",
            "target": "flask_buffer",
            "type": "physical",
            "port": {
                "multiway_valve": "multiway-valve-port-8",
                "flask_buffer": "top"
            }
        },
        {
            "source": "stirrer",
            "target": "reactor",
            "type": "physical",
            "port": {
                "stirrer": "stirrer-vessel",
                "reactor": "bottom"
            }
        }
    ]
--- a/test/experiments/mock_protocol/evaporateteststation.json
+++ b/test/experiments/mock_protocol/evaporateteststation.json
--- a/test/experiments/mock_reactor.json
+++ b/test/experiments/mock_reactor.json
@@ -30,14 +30,17 @@
            "children": [],
            "parent": "ReactorX",
            "type": "container",
-            "class": null,
+            "class": "container",
            "position": {
                "x": 698.1111111111111,
                "y": 428,
                "z": 0
            },
            "config": {
-                "max_volume": 5000.0
+                "max_volume": 5000.0,
                "size_x": 200.0,
                "size_y": 200.0,
                "size_z": 200.0
            },
            "data": {
                "liquid": [
@@ -71,7 +74,7 @@
            "type": "device",
            "class": "solenoid_valve.mock",
            "position": {
-                "x": 620.6111111111111,
+                "x": 780,
                "y": 171,
                "z": 0
            },
@@ -89,7 +92,7 @@
            "type": "device",
            "class": "vacuum_pump.mock",
            "position": {
-                "x": 620.6111111111111,
+                "x": 500,
                "y": 171,
                "z": 0
            },
@@ -107,7 +110,7 @@
            "type": "device",
            "class": "gas_source.mock",
            "position": {
-                "x": 620.6111111111111,
+                "x": 900,
                "y": 171,
                "z": 0
            },
@@ -119,39 +122,39 @@
    ],
    "links": [
        {
-            "source": "reactor",
+            "source": "vacuum_valve",
-            "target": "vacuum_valve",
+            "target": "reactor",
-            "type": "physical",
+            "type": "fluid",
            "port": {
                "reactor": "top",
-                "vacuum_valve": "1"
+                "vacuum_valve": "out"
            }
        },
        {
-            "source": "reactor",
+            "source": "gas_valve",
-            "target": "gas_valve",
+            "target": "reactor",
-            "type": "physical",
+            "type": "fluid",
            "port": {
                "reactor": "top",
-                "gas_valve": "1"
+                "gas_valve": "out"
            }
        },
        {
            "source": "vacuum_pump",
            "target": "vacuum_valve",
-            "type": "physical",
+            "type": "fluid",
            "port": {
                "vacuum_pump": "out",
-                "vacuum_valve": "0"
+                "vacuum_valve": "in"
            }
        },
        {
            "source": "gas_source",
            "target": "gas_valve",
-            "type": "physical",
+            "type": "fluid",
            "port": {
                "gas_source": "out",
-                "gas_valve": "0"
+                "gas_valve": "in"
            }
        }
    ]
--- a/test/experiments/prcxi.json
+++ b/test/experiments/prcxi.json
@@ -0,0 +1,217 @@
 {
    "nodes": [
        {
            "id": "PRCXI",
            "name": "PRCXI",
            "parent": null,
            "type": "device",
            "class": "liquid_handler.prcxi",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "deck": {
                    "_resource_child_name": "deck",
                    "_resource_type": "unilabos.devices.liquid_handling.prcxi.prcxi:PRCXI9300Deck"
                },
                "host": "192.168.3.9",
                "port": 9999,
                "timeout": 10.0,
                "setup": false,
                "debug": true
            },
            "data": {},
            "children": [
                "deck"
            ]
        },
        {
            "id": "deck",
            "name": "deck",
            "sample_id": null,
            "children": [
                "rackT1",
                "plateT2",
                "plateT3",
                "rackT4",
                "plateT5",
                "plateT6"
            ],
            "parent": "PRCXI",
            "type": "device",
            "class": "",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "type": "PRCXI9300Deck"
            },
            "data": {}
        },
        {
            "id": "rackT1",
            "name": "rackT1",
            "sample_id": null,
            "children": [],
            "parent": "deck",
            "type": "device",
            "class": "",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "type": "PRCXI9300Container",
                "size_x": 120.98,
                "size_y": 82.12,
                "size_z": 50.3
            },
            "data": {
                "Material": {
                    "uuid": "80652665f6a54402b2408d50b40398df",
                    "Code": "ZX-001-1000",
                    "Name": "1000μL Tip头",
                    "SummaryName": "1000μL Tip头",
                    "PipetteHeight": 100,
                    "materialEnum": 1
                }
            }
        },
        {
            "id": "plateT2",
            "name": "plateT2",
            "sample_id": null,
            "children": [],
            "parent": "deck",
            "type": "device",
            "class": "",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "type": "PRCXI9300Container",
                "size_x": 120.98,
                "size_y": 82.12,
                "size_z": 50.3
            },
            "data": {
                "Material": {
                    "uuid": "57b1e4711e9e4a32b529f3132fc5931f"
                }
            }
        },
        {
            "id": "plateT3",
            "name": "plateT3",
            "sample_id": null,
            "children": [],
            "parent": "deck",
            "type": "device",
            "class": "",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "type": "PRCXI9300Container",
                "size_x": 120.98,
                "size_y": 82.12,
                "size_z": 50.3
            },
            "data": {
                "Material": {
                    "uuid": "57b1e4711e9e4a32b529f3132fc5931f"
                }
            }
        },
        {
            "id": "rackT4",
            "name": "rackT4",
            "sample_id": null,
            "children": [],
            "parent": "deck",
            "type": "device",
            "class": "",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "type": "PRCXI9300Container",
                "size_x": 120.98,
                "size_y": 82.12,
                "size_z": 50.3
            },
            "data": {
                "Material": {
                    "uuid": "80652665f6a54402b2408d50b40398df",
                    "Code": "ZX-001-1000",
                    "Name": "1000μL Tip头",
                    "SummaryName": "1000μL Tip头",
                    "PipetteHeight": 100,
                    "materialEnum": 1
                }
            }
        },
        {
            "id": "plateT5",
            "name": "plateT5",
            "sample_id": null,
            "children": [],
            "parent": "deck",
            "type": "device",
            "class": "",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "type": "PRCXI9300Container",
                "size_x": 120.98,
                "size_y": 82.12,
                "size_z": 50.3
            },
            "data": {
                "Material": {
                    "uuid": "57b1e4711e9e4a32b529f3132fc5931f"
                }
            }
        },
        {
            "id": "plateT6",
            "name": "plateT6",
            "sample_id": null,
            "children": [],
            "parent": "deck",
            "type": "device",
            "class": "",
            "position": {
                "x": 0,
                "y": 0,
                "z": 0
            },
            "config": {
                "type": "PRCXI9300Container",
                "size_x": 120.98,
                "size_y": 82.12,
                "size_z": 50.3
            },
            "data": {
                "Material": {
                    "uuid": "57b1e4711e9e4a32b529f3132fc5931f"
                }
            }
        }
    ],
    "links": []
 }
--- a/unilabos-linux-64.yaml
+++ b/unilabos-linux-64.yaml
@@ -48,8 +48,9 @@ dependencies:
  - ros-humble-ros2-control
  - ros-humble-robot-state-publisher
  - ros-humble-joint-state-publisher
-  # web
+  # web and visualization
  - ros-humble-rosbridge-server
  - ros-humble-cv-bridge
  # geometry & motion planning
  - ros-humble-tf2
  - ros-humble-moveit
--- a/unilabos-osx-arm64.yaml
+++ b/unilabos-osx-arm64.yaml
@@ -50,8 +50,9 @@ dependencies:
  - ros-humble-ros2-control
  - ros-humble-robot-state-publisher
  - ros-humble-joint-state-publisher
-  # web
+  # web and visualization
  - ros-humble-rosbridge-server
  - ros-humble-cv-bridge
  # geometry & motion planning
  - ros-humble-tf2
  - ros-humble-moveit
--- a/unilabos-win64.yaml
+++ b/unilabos-win64.yaml
@@ -6,12 +6,12 @@ channels:
 dependencies:
  # Basics
  - python=3.11.11
-  - compilers
+  # - compilers
-  - cmake
+  # - cmake
-  - make
+  # - make
-  - ninja
+  # - ninja
-  - sphinx
+  # - sphinx
-  - sphinx_rtd_theme
+  # - sphinx_rtd_theme
  # Data Visualization
  - numpy
  - scipy
@@ -23,7 +23,7 @@ dependencies:
  - pyserial
  - pyusb
  - pylibftdi
-  - pymodbus
+  - pymodbus==3.6.9
  - python-can
  - pyvisa
  - opencv
@@ -48,8 +48,9 @@ dependencies:
  - ros-humble-ros2-control
  - ros-humble-robot-state-publisher
  - ros-humble-joint-state-publisher
-  # web
+  # web and visualization
  - ros-humble-rosbridge-server
  - ros-humble-cv-bridge
  # geometry & motion planning
  - ros-humble-tf2
  - ros-humble-moveit
@@ -61,5 +62,12 @@ dependencies:
  # ros-humble-gazebo-ros // ignored because of the conflict with ign-gazebo
  # ilab equipments
  # ros-humble-unilabos-msgs
  # driver
  #- crcmod
  - pip:
      - paho-mqtt
      # driver
      #- ur-rtde  # set PYTHONUTF8=1
      #- pyautogui
      #- pywinauto
      #- pywinauto_recorder
--- a/unilabos/app/backend.py
+++ b/unilabos/app/backend.py
@@ -8,6 +8,7 @@ def start_backend(
    backend: str,
    devices_config: dict = {},
    resources_config: list = [],
    resources_edge_config: list = [],
    graph=None,
    controllers_config: dict = {},
    bridges=[],
@@ -31,7 +32,7 @@ def start_backend(
    backend_thread = threading.Thread(
        target=main if not without_host else slave,
-        args=(devices_config, resources_config, graph, controllers_config, bridges, visual, resources_mesh_config),
+        args=(devices_config, resources_config, resources_edge_config, graph, controllers_config, bridges, visual, resources_mesh_config),
        name="backend_thread",
        daemon=True,
    )
--- a/unilabos/app/controler.py
+++ b/unilabos/app/controler.py
@@ -1,8 +1,10 @@
 import json
 import traceback
 import uuid
 from unilabos.app.model import JobAddReq, JobData
 from unilabos.ros.nodes.presets.host_node import HostNode
 from unilabos.utils.type_check import serialize_result_info
 def get_resources() -> tuple:
@@ -25,12 +27,18 @@ def job_add(req: JobAddReq) -> JobData:
    if req.job_id is None:
        req.job_id = str(uuid.uuid4())
    action_name = req.data["action"]
-    action_kwargs = req.data["action_kwargs"]
+    action_type = req.data.get("action_type", "LocalUnknown")
-    req.data['action'] = action_name
+    action_args = req.data.get("action_kwargs", None)  # 兼容老版本，后续删除
-    if action_name == "execute_command_from_outer":
+    if action_args is None:
-        action_kwargs = {"command": json.dumps(action_kwargs)}
+        action_args = req.data.get("action_args")
-    elif "command" in action_kwargs:
+    else:
-        action_kwargs = action_kwargs["command"]
+        if "command" in action_args:
            action_args = action_args["command"]
    # print(f"job_add:{req.device_id} {action_name} {action_kwargs}")
-    HostNode.get_instance().send_goal(req.device_id, action_name=action_name, action_kwargs=action_kwargs, goal_uuid=req.job_id, server_info=req.server_info)
+    try:
        HostNode.get_instance().send_goal(req.device_id, action_type=action_type, action_name=action_name, action_kwargs=action_args, goal_uuid=req.job_id, server_info=req.server_info)
    except Exception as e:
        for bridge in HostNode.get_instance().bridges:
            if hasattr(bridge, "publish_job_status"):
                bridge.publish_job_status({}, req.job_id, "failed", serialize_result_info(traceback.format_exc(), False, {}))
    return JobData(jobId=req.job_id)
--- a/unilabos/app/main.py
+++ b/unilabos/app/main.py
@@ -10,7 +10,7 @@ from copy import deepcopy
 import yaml
-from unilabos.resources.graphio import tree_to_list
+from unilabos.resources.graphio import tree_to_list, modify_to_backend_format
 # 首先添加项目根目录到路径
 current_dir = os.path.dirname(os.path.abspath(__file__))
@@ -22,6 +22,21 @@ from unilabos.config.config import load_config, BasicConfig, _update_config_from
 from unilabos.utils.banner_print import print_status, print_unilab_banner
 def load_config_from_file(config_path):
    if config_path is None:
        config_path = os.environ.get("UNILABOS.BASICCONFIG.CONFIG_PATH", None)
    if config_path:
        if not os.path.exists(config_path):
            print_status(f"配置文件 {config_path} 不存在", "error")
        elif not config_path.endswith(".py"):
            print_status(f"配置文件 {config_path} 不是Python文件，必须以.py结尾", "error")
        else:
            load_config(config_path)
    else:
        print_status(f"启动 UniLab-OS时，配置文件参数未正确传入 --config '{config_path}' 尝试本地配置...", "warning")
        load_config(config_path)
 def parse_args():
    """解析命令行参数"""
    parser = argparse.ArgumentParser(description="Start Uni-Lab Edge server.")
@@ -58,6 +73,11 @@ def parse_args():
        action="store_true",
        help="Slave模式下跳过等待host服务",
    )
    parser.add_argument(
        "--upload_registry",
        action="store_true",
        help="启动unilab时同时报送注册表信息",
    )
    parser.add_argument(
        "--config",
        type=str,
@@ -97,22 +117,12 @@ def main():
    # 加载配置文件，优先加载config，然后从env读取
    config_path = args_dict.get("config")
-    if config_path is None:
+    load_config_from_file(config_path)
        config_path = os.environ.get("UNILABOS.BASICCONFIG.CONFIG_PATH", None)
    if config_path:
        if not os.path.exists(config_path):
            print_status(f"配置文件 {config_path} 不存在", "error")
        elif not config_path.endswith(".py"):
            print_status(f"配置文件 {config_path} 不是Python文件，必须以.py结尾", "error")
        else:
            load_config(config_path)
    else:
        print_status(f"启动 UniLab-OS时，配置文件参数未正确传入 --config '{config_path}' 尝试本地配置...", "warning")
        load_config(config_path)
    # 设置BasicConfig参数
    BasicConfig.is_host_mode = not args_dict.get("without_host", False)
    BasicConfig.slave_no_host = args_dict.get("slave_no_host", False)
    BasicConfig.upload_registry = args_dict.get("upload_registry", False)
    machine_name = os.popen("hostname").read().strip()
    machine_name = "".join([c if c.isalnum() or c == "_" else "_" for c in machine_name])
    BasicConfig.machine_name = machine_name
@@ -136,15 +146,16 @@ def main():
    # 注册表
    build_registry(args_dict["registry_path"])
-
+    resource_edge_info = []
    devices_and_resources = None
    if args_dict["graph"] is not None:
        import unilabos.resources.graphio as graph_res
-        graph_res.physical_setup_graph = (
+        if args_dict["graph"].endswith(".json"):
-            read_node_link_json(args_dict["graph"])
+            graph, data = read_node_link_json(args_dict["graph"])
-            if args_dict["graph"].endswith(".json")
+        else:
-            else read_graphml(args_dict["graph"])
+            graph, data = read_graphml(args_dict["graph"])
-        )
+        graph_res.physical_setup_graph = graph
        resource_edge_info = modify_to_backend_format(data["links"])
        devices_and_resources = dict_from_graph(graph_res.physical_setup_graph)
        # args_dict["resources_config"] = initialize_resources(list(deepcopy(devices_and_resources).values()))
        args_dict["resources_config"] = list(devices_and_resources.values())
@@ -185,6 +196,7 @@ def main():
        signal.signal(signal.SIGTERM, _exit)
        mqtt_client.start()
    args_dict["resources_mesh_config"] = {}
    args_dict["resources_edge_config"] = resource_edge_info
    # web visiualize 2D
    if args_dict["visual"] != "disable":
        enable_rviz = args_dict["visual"] == "rviz"
--- a/unilabos/app/mq.py
+++ b/unilabos/app/mq.py
@@ -56,6 +56,10 @@ class MQTTClient:
                    payload_json["data"] = {}
                if "action" in payload_json:
                    payload_json["data"]["action"] = payload_json.pop("action")
                if "action_type" in payload_json:
                    payload_json["data"]["action_type"] = payload_json.pop("action_type")
                if "action_args" in payload_json:
                    payload_json["data"]["action_args"] = payload_json.pop("action_args")
                if "action_kwargs" in payload_json:
                    payload_json["data"]["action_kwargs"] = payload_json.pop("action_kwargs")
                job_req = JobAddReq.model_validate(payload_json)
@@ -159,7 +163,7 @@ class MQTTClient:
        # status = device_status.get(device_id, {})
        if self.mqtt_disable:
            return
-        status = {"data": device_status.get(device_id, {}), "device_id": device_id}
+        status = {"data": device_status.get(device_id, {}), "device_id": device_id, "timestamp": time.time()}
        address = f"labs/{MQConfig.lab_id}/devices/"
        self.client.publish(address, json.dumps(status), qos=2)
        logger.debug(f"Device status published: address: {address}, {status}")
@@ -172,13 +176,14 @@ class MQTTClient:
        jobdata = {"job_id": job_id, "data": feedback_data, "status": status, "return_info": return_info}
        self.client.publish(f"labs/{MQConfig.lab_id}/job/list/", json.dumps(jobdata), qos=2)
-    def publish_registry(self, device_id: str, device_info: dict):
+    def publish_registry(self, device_id: str, device_info: dict, print_debug: bool = True):
        if self.mqtt_disable:
            return
        address = f"labs/{MQConfig.lab_id}/registry/"
        registry_data = json.dumps({device_id: device_info}, ensure_ascii=False, cls=TypeEncoder)
        self.client.publish(address, registry_data, qos=2)
-        logger.debug(f"Registry data published: address: {address}, {registry_data}")
+        if print_debug:
            logger.debug(f"Registry data published: address: {address}, {registry_data}")
    def publish_actions(self, action_id: str, action_info: dict):
        if self.mqtt_disable:
--- a/unilabos/app/register.py
+++ b/unilabos/app/register.py
@@ -0,0 +1,73 @@
 import argparse
 import time
 from unilabos.registry.registry import build_registry
 from unilabos.app.main import load_config_from_file
 from unilabos.utils.log import logger
 def register_devices_and_resources(mqtt_client, lab_registry):
    """
    注册设备和资源到 MQTT
    """
    logger.info("[UniLab Register] 开始注册设备和资源...")
    # 注册设备信息
    for device_info in lab_registry.obtain_registry_device_info():
        mqtt_client.publish_registry(device_info["id"], device_info, False)
        logger.debug(f"[UniLab Register] 注册设备: {device_info['id']}")
    # 注册资源信息
    for resource_info in lab_registry.obtain_registry_resource_info():
        mqtt_client.publish_registry(resource_info["id"], resource_info, False)
        logger.debug(f"[UniLab Register] 注册资源: {resource_info['id']}")
    time.sleep(10)
    logger.info("[UniLab Register] 设备和资源注册完成.")
 def main():
    """
    命令行入口函数
    """
    parser = argparse.ArgumentParser(description="注册设备和资源到 MQTT")
    parser.add_argument(
        "--registry",
        type=str,
        default=None,
        action="append",
        help="注册表路径",
    )
    parser.add_argument(
        "--config",
        type=str,
        default=None,
        help="配置文件路径，支持.py格式的Python配置文件",
    )
    parser.add_argument(
        "--complete_registry",
        action="store_true",
        default=False,
        help="是否补全注册表",
    )
    args = parser.parse_args()
    # 构建注册表
    build_registry(args.registry, args.complete_registry)
    load_config_from_file(args.config)
    from unilabos.app.mq import mqtt_client
    # 连接mqtt
    mqtt_client.start()
    from unilabos.registry.registry import lab_registry
    # 注册设备和资源
    register_devices_and_resources(mqtt_client, lab_registry)
 if __name__ == "__main__":
    main()
--- a/unilabos/app/web/client.py
+++ b/unilabos/app/web/client.py
@@ -30,7 +30,27 @@ class HTTPClient:
            self.auth = MQConfig.lab_id
        info(f"HTTPClient 初始化完成: remote_addr={self.remote_addr}")
-    def resource_add(self, resources: List[Dict[str, Any]], database_process_later:bool) -> requests.Response:
+    def resource_edge_add(self, resources: List[Dict[str, Any]], database_process_later: bool) -> requests.Response:
        """
        添加资源
        Args:
            resources: 要添加的资源列表
            database_process_later: 后台处理资源
        Returns:
            Response: API响应对象
        """
        response = requests.post(
            f"{self.remote_addr}/lab/resource/edge/batch_create/?database_process_later={1 if database_process_later else 0}",
            json=resources,
            headers={"Authorization": f"lab {self.auth}"},
            timeout=100,
        )
        if response.status_code != 200 and response.status_code != 201:
            logger.error(f"添加物料关系失败: {response.status_code}, {response.text}")
        return response
    def resource_add(self, resources: List[Dict[str, Any]], database_process_later: bool) -> requests.Response:
        """
        添加资源
@@ -44,8 +64,10 @@ class HTTPClient:
            f"{self.remote_addr}/lab/resource/?database_process_later={1 if database_process_later else 0}",
            json=resources,
            headers={"Authorization": f"lab {self.auth}"},
-            timeout=5,
+            timeout=100,
        )
        if response.status_code != 200:
            logger.error(f"添加物料失败: {response.text}")
        return response
    def resource_get(self, id: str, with_children: bool = False) -> Dict[str, Any]:
@@ -63,7 +85,7 @@ class HTTPClient:
            f"{self.remote_addr}/lab/resource/?edge_format=1",
            params={"id": id, "with_children": with_children},
            headers={"Authorization": f"lab {self.auth}"},
-            timeout=5,
+            timeout=20,
        )
        return response.json()
@@ -81,7 +103,7 @@ class HTTPClient:
            f"{self.remote_addr}/lab/resource/batch_delete/",
            params={"id": id},
            headers={"Authorization": f"lab {self.auth}"},
-            timeout=5,
+            timeout=20,
        )
        return response
@@ -99,7 +121,7 @@ class HTTPClient:
            f"{self.remote_addr}/lab/resource/batch_update/?edge_format=1",
            json=resources,
            headers={"Authorization": f"lab {self.auth}"},
-            timeout=5,
+            timeout=100,
        )
        return response
--- a/unilabos/app/web/pages.py
+++ b/unilabos/app/web/pages.py
@@ -7,6 +7,7 @@ Web页面模块
 import json
 import os
 import sys
 import traceback
 from pathlib import Path
 from typing import Dict
@@ -16,9 +17,8 @@ from jinja2 import Environment, FileSystemLoader
 from unilabos.config.config import BasicConfig
 from unilabos.registry.registry import lab_registry
 from unilabos.app.mq import mqtt_client
 from unilabos.ros.msgs.message_converter import msg_converter_manager
-from unilabos.utils.log import error
+from unilabos.utils.log import error, debug
 from unilabos.utils.type_check import TypeEncoder
 from unilabos.app.web.utils.device_utils import get_registry_info
 from unilabos.app.web.utils.host_utils import get_host_node_info
@@ -124,6 +124,7 @@ def setup_web_pages(router: APIRouter) -> None:
            return html
        except Exception as e:
            debug(traceback.format_exc())
            error(f"生成状态页面时出错: {str(e)}")
            raise HTTPException(status_code=500, detail=f"Error generating status page: {str(e)}")
--- a/unilabos/app/web/utils/action_utils.py
+++ b/unilabos/app/web/utils/action_utils.py
@@ -65,6 +65,8 @@ def get_yaml_from_goal_type(goal_type) -> str:
    Returns:
        str: 默认Goal参数的YAML格式字符串
    """
    if isinstance(goal_type, str):
        return "{}"
    if not goal_type:
        return "{}"
--- a/unilabos/compile/init.py
+++ b/unilabos/compile/init.py
@@ -8,7 +8,12 @@ from .agv_transfer_protocol import generate_agv_transfer_protocol
 from .add_protocol import generate_add_protocol
 from .centrifuge_protocol import generate_centrifuge_protocol
 from .filter_protocol import generate_filter_protocol
-from .heatchill_protocol import generate_heat_chill_protocol, generate_heat_chill_start_protocol, generate_heat_chill_stop_protocol
+from .heatchill_protocol import (
    generate_heat_chill_protocol, 
    generate_heat_chill_start_protocol, 
    generate_heat_chill_stop_protocol,
    generate_heat_chill_to_temp_protocol  # 保留导入，但不注册为协议
 )
 from .stir_protocol import generate_stir_protocol, generate_start_stir_protocol, generate_stop_stir_protocol
 from .transfer_protocol import generate_transfer_protocol
 from .clean_vessel_protocol import generate_clean_vessel_protocol
@@ -16,29 +21,39 @@ from .dissolve_protocol import generate_dissolve_protocol
 from .filter_through_protocol import generate_filter_through_protocol
 from .run_column_protocol import generate_run_column_protocol
 from .wash_solid_protocol import generate_wash_solid_protocol
 from .adjustph_protocol import generate_adjust_ph_protocol
 from .reset_handling_protocol import generate_reset_handling_protocol
 from .dry_protocol import generate_dry_protocol
 from .recrystallize_protocol import generate_recrystallize_protocol
 from .hydrogenate_protocol import generate_hydrogenate_protocol
 # Define a dictionary of protocol generators.
 action_protocol_generators = {
    PumpTransferProtocol: generate_pump_protocol_with_rinsing,
    CleanProtocol: generate_clean_protocol,
    SeparateProtocol: generate_separate_protocol,
    EvaporateProtocol: generate_evaporate_protocol,
    EvacuateAndRefillProtocol: generate_evacuateandrefill_protocol,
    AGVTransferProtocol: generate_agv_transfer_protocol,
    CentrifugeProtocol: generate_centrifuge_protocol,
    AddProtocol: generate_add_protocol,
    AGVTransferProtocol: generate_agv_transfer_protocol,
    AdjustPHProtocol: generate_adjust_ph_protocol,
    CentrifugeProtocol: generate_centrifuge_protocol,
    CleanProtocol: generate_clean_protocol,
    CleanVesselProtocol: generate_clean_vessel_protocol,
    DissolveProtocol: generate_dissolve_protocol,
    DryProtocol: generate_dry_protocol,
    EvacuateAndRefillProtocol: generate_evacuateandrefill_protocol,
    EvaporateProtocol: generate_evaporate_protocol,
    FilterProtocol: generate_filter_protocol,
    FilterThroughProtocol: generate_filter_through_protocol,
    HeatChillProtocol: generate_heat_chill_protocol,
    HeatChillStartProtocol: generate_heat_chill_start_protocol,
    HeatChillStopProtocol: generate_heat_chill_stop_protocol,
-    StirProtocol: generate_stir_protocol,
+    HydrogenateProtocol: generate_hydrogenate_protocol,
    PumpTransferProtocol: generate_pump_protocol_with_rinsing,
    RecrystallizeProtocol: generate_recrystallize_protocol,
    ResetHandlingProtocol: generate_reset_handling_protocol,
    RunColumnProtocol: generate_run_column_protocol,
    SeparateProtocol: generate_separate_protocol,
    StartStirProtocol: generate_start_stir_protocol,
    StirProtocol: generate_stir_protocol,
    StopStirProtocol: generate_stop_stir_protocol,
    TransferProtocol: generate_transfer_protocol,
    CleanVesselProtocol: generate_clean_vessel_protocol,
    DissolveProtocol: generate_dissolve_protocol,
    FilterThroughProtocol: generate_filter_through_protocol,
    RunColumnProtocol: generate_run_column_protocol,
    WashSolidProtocol: generate_wash_solid_protocol,
 }
--- a/unilabos/compile/add_protocol.py
+++ b/unilabos/compile/add_protocol.py
@@ -1,74 +1,702 @@
 import networkx as nx
-from typing import List, Dict, Any  
+import re
 import logging
 from typing import List, Dict, Any, Union
 from .pump_protocol import generate_pump_protocol_with_rinsing
 logger = logging.getLogger(__name__)
 def debug_print(message):
    """调试输出"""
    print(f"[ADD] {message}", flush=True)
    logger.info(f"[ADD] {message}")
 def parse_volume_input(volume_input: Union[str, float]) -> float:
    """
    解析体积输入，支持带单位的字符串
    Args:
        volume_input: 体积输入（如 "2.7 mL", "2.67 mL", "?", 10.0）
    Returns:
        float: 体积（毫升）
    """
    if isinstance(volume_input, (int, float)):
        debug_print(f"📏 体积输入为数值: {volume_input}")
        return float(volume_input)
    if not volume_input or not str(volume_input).strip():
        debug_print(f"⚠️ 体积输入为空，返回0.0mL")
        return 0.0
    volume_str = str(volume_input).lower().strip()
    debug_print(f"🔍 解析体积输入: '{volume_str}'")
    # 处理未知体积
    if volume_str in ['?', 'unknown', 'tbd', 'to be determined']:
        default_volume = 10.0  # 默认10mL
        debug_print(f"❓ 检测到未知体积，使用默认值: {default_volume}mL 🎯")
        return default_volume
    # 移除空格并提取数字和单位
    volume_clean = re.sub(r'\s+', '', volume_str)
    # 匹配数字和单位的正则表达式
    match = re.match(r'([0-9]*\.?[0-9]+)\s*(ml|l|μl|ul|microliter|milliliter|liter)?', volume_clean)
    if not match:
        debug_print(f"❌ 无法解析体积: '{volume_str}'，使用默认值10mL")
        return 10.0
    value = float(match.group(1))
    unit = match.group(2) or 'ml'  # 默认单位为毫升
    # 转换为毫升
    if unit in ['l', 'liter']:
        volume = value * 1000.0  # L -> mL
        debug_print(f"🔄 体积转换: {value}L → {volume}mL")
    elif unit in ['μl', 'ul', 'microliter']:
        volume = value / 1000.0  # μL -> mL
        debug_print(f"🔄 体积转换: {value}μL → {volume}mL")
    else:  # ml, milliliter 或默认
        volume = value  # 已经是mL
        debug_print(f"✅ 体积已为mL: {volume}mL")
    return volume
 def parse_mass_input(mass_input: Union[str, float]) -> float:
    """
    解析质量输入，支持带单位的字符串
    Args:
        mass_input: 质量输入（如 "19.3 g", "4.5 g", 2.5）
    Returns:
        float: 质量（克）
    """
    if isinstance(mass_input, (int, float)):
        debug_print(f"⚖️ 质量输入为数值: {mass_input}g")
        return float(mass_input)
    if not mass_input or not str(mass_input).strip():
        debug_print(f"⚠️ 质量输入为空，返回0.0g")
        return 0.0
    mass_str = str(mass_input).lower().strip()
    debug_print(f"🔍 解析质量输入: '{mass_str}'")
    # 移除空格并提取数字和单位
    mass_clean = re.sub(r'\s+', '', mass_str)
    # 匹配数字和单位的正则表达式
    match = re.match(r'([0-9]*\.?[0-9]+)\s*(g|mg|kg|gram|milligram|kilogram)?', mass_clean)
    if not match:
        debug_print(f"❌ 无法解析质量: '{mass_str}'，返回0.0g")
        return 0.0
    value = float(match.group(1))
    unit = match.group(2) or 'g'  # 默认单位为克
    # 转换为克
    if unit in ['mg', 'milligram']:
        mass = value / 1000.0  # mg -> g
        debug_print(f"🔄 质量转换: {value}mg → {mass}g")
    elif unit in ['kg', 'kilogram']:
        mass = value * 1000.0  # kg -> g
        debug_print(f"🔄 质量转换: {value}kg → {mass}g")
    else:  # g, gram 或默认
        mass = value  # 已经是g
        debug_print(f"✅ 质量已为g: {mass}g")
    return mass
 def parse_time_input(time_input: Union[str, float]) -> float:
    """
    解析时间输入，支持带单位的字符串
    Args:
        time_input: 时间输入（如 "1 h", "20 min", "30 s", 60.0）
    Returns:
        float: 时间（秒）
    """
    if isinstance(time_input, (int, float)):
        debug_print(f"⏱️ 时间输入为数值: {time_input}秒")
        return float(time_input)
    if not time_input or not str(time_input).strip():
        debug_print(f"⚠️ 时间输入为空，返回0秒")
        return 0.0
    time_str = str(time_input).lower().strip()
    debug_print(f"🔍 解析时间输入: '{time_str}'")
    # 处理未知时间
    if time_str in ['?', 'unknown', 'tbd']:
        default_time = 60.0  # 默认1分钟
        debug_print(f"❓ 检测到未知时间，使用默认值: {default_time}s (1分钟) ⏰")
        return default_time
    # 移除空格并提取数字和单位
    time_clean = re.sub(r'\s+', '', time_str)
    # 匹配数字和单位的正则表达式
    match = re.match(r'([0-9]*\.?[0-9]+)\s*(s|sec|second|min|minute|h|hr|hour|d|day)?', time_clean)
    if not match:
        debug_print(f"❌ 无法解析时间: '{time_str}'，返回0s")
        return 0.0
    value = float(match.group(1))
    unit = match.group(2) or 's'  # 默认单位为秒
    # 转换为秒
    if unit in ['min', 'minute']:
        time_sec = value * 60.0  # min -> s
        debug_print(f"🔄 时间转换: {value}分钟 → {time_sec}秒")
    elif unit in ['h', 'hr', 'hour']:
        time_sec = value * 3600.0  # h -> s
        debug_print(f"🔄 时间转换: {value}小时 → {time_sec}秒")
    elif unit in ['d', 'day']:
        time_sec = value * 86400.0  # d -> s
        debug_print(f"🔄 时间转换: {value}天 → {time_sec}秒")
    else:  # s, sec, second 或默认
        time_sec = value  # 已经是s
        debug_print(f"✅ 时间已为秒: {time_sec}秒")
    return time_sec
 def find_reagent_vessel(G: nx.DiGraph, reagent: str) -> str:
    """增强版试剂容器查找，支持固体和液体"""
    debug_print(f"🔍 开始查找试剂 '{reagent}' 的容器...")
    # 🔧 方法1：直接搜索 data.reagent_name 和 config.reagent
    debug_print(f"📋 方法1: 搜索reagent字段...")
    for node in G.nodes():
        node_data = G.nodes[node].get('data', {})
        node_type = G.nodes[node].get('type', '')
        config_data = G.nodes[node].get('config', {})
        # 只搜索容器类型的节点
        if node_type == 'container':
            reagent_name = node_data.get('reagent_name', '').lower()
            config_reagent = config_data.get('reagent', '').lower()
            # 精确匹配
            if reagent_name == reagent.lower() or config_reagent == reagent.lower():
                debug_print(f"✅ 通过reagent字段精确匹配到容器: {node} 🎯")
                return node
            # 模糊匹配
            if (reagent.lower() in reagent_name and reagent_name) or \
               (reagent.lower() in config_reagent and config_reagent):
                debug_print(f"✅ 通过reagent字段模糊匹配到容器: {node} 🔍")
                return node
    # 🔧 方法2：常见的容器命名规则
    debug_print(f"📋 方法2: 使用命名规则查找...")
    reagent_clean = reagent.lower().replace(' ', '_').replace('-', '_')
    possible_names = [
        reagent_clean,
        f"flask_{reagent_clean}",
        f"bottle_{reagent_clean}",
        f"vessel_{reagent_clean}", 
        f"{reagent_clean}_flask",
        f"{reagent_clean}_bottle",
        f"reagent_{reagent_clean}",
        f"reagent_bottle_{reagent_clean}",
        f"solid_reagent_bottle_{reagent_clean}",
        f"reagent_bottle_1",  # 通用试剂瓶
        f"reagent_bottle_2",
        f"reagent_bottle_3"
    ]
    debug_print(f"🔍 尝试的容器名称: {possible_names[:5]}... (共{len(possible_names)}个)")
    for name in possible_names:
        if name in G.nodes():
            node_type = G.nodes[name].get('type', '')
            if node_type == 'container':
                debug_print(f"✅ 通过命名规则找到容器: {name} 📝")
                return name
    # 🔧 方法3：节点名称模糊匹配
    debug_print(f"📋 方法3: 节点名称模糊匹配...")
    for node_id in G.nodes():
        node_data = G.nodes[node_id]
        if node_data.get('type') == 'container':
            # 检查节点名称是否包含试剂名称
            if reagent_clean in node_id.lower():
                debug_print(f"✅ 通过节点名称模糊匹配到容器: {node_id} 🔍")
                return node_id
            # 检查液体类型匹配
            vessel_data = node_data.get('data', {})
            liquids = vessel_data.get('liquid', [])
            for liquid in liquids:
                if isinstance(liquid, dict):
                    liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
                    if liquid_type.lower() == reagent.lower():
                        debug_print(f"✅ 通过液体类型匹配到容器: {node_id} 💧")
                        return node_id
    # 🔧 方法4：使用第一个试剂瓶作为备选
    debug_print(f"📋 方法4: 查找备选试剂瓶...")
    for node_id in G.nodes():
        node_data = G.nodes[node_id]
        if (node_data.get('type') == 'container' and 
            ('reagent' in node_id.lower() or 'bottle' in node_id.lower())):
            debug_print(f"⚠️ 未找到专用容器，使用备选试剂瓶: {node_id} 🔄")
            return node_id
    debug_print(f"❌ 所有方法都失败了，无法找到容器!")
    raise ValueError(f"找不到试剂 '{reagent}' 对应的容器")
 def find_connected_stirrer(G: nx.DiGraph, vessel: str) -> str:
    """查找连接到指定容器的搅拌器"""
    debug_print(f"🔍 查找连接到容器 '{vessel}' 的搅拌器...")
    stirrer_nodes = []
    for node in G.nodes():
        node_class = G.nodes[node].get('class', '').lower()
        if 'stirrer' in node_class:
            stirrer_nodes.append(node)
            debug_print(f"📋 发现搅拌器: {node}")
    debug_print(f"📊 共找到 {len(stirrer_nodes)} 个搅拌器")
    # 查找连接到容器的搅拌器
    for stirrer in stirrer_nodes:
        if G.has_edge(stirrer, vessel) or G.has_edge(vessel, stirrer):
            debug_print(f"✅ 找到连接的搅拌器: {stirrer} 🔗")
            return stirrer
    # 返回第一个搅拌器
    if stirrer_nodes:
        debug_print(f"⚠️ 未找到直接连接的搅拌器，使用第一个: {stirrer_nodes[0]} 🔄")
        return stirrer_nodes[0]
    debug_print(f"❌ 未找到任何搅拌器")
    return ""
 def find_solid_dispenser(G: nx.DiGraph) -> str:
    """查找固体加样器"""
    debug_print(f"🔍 查找固体加样器...")
    for node in G.nodes():
        node_class = G.nodes[node].get('class', '').lower()
        if 'solid_dispenser' in node_class or 'dispenser' in node_class:
            debug_print(f"✅ 找到固体加样器: {node} 🥄")
            return node
    debug_print(f"❌ 未找到固体加样器")
    return ""
 # 🆕 创建进度日志动作
 def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
    """创建一个动作日志"""
    full_message = f"{emoji} {message}"
    debug_print(full_message)
    logger.info(full_message)
    print(f"[ACTION] {full_message}", flush=True)
    return {
        "action_name": "wait",
        "action_kwargs": {
            "time": 0.1,
            "log_message": full_message
        }
    }
 def generate_add_protocol(
    G: nx.DiGraph,
    vessel: str,
    reagent: str,
-    volume: float,  
+    # 🔧 修复：所有参数都用 Union 类型，支持字符串和数值
-    mass: float,  
+    volume: Union[str, float] = 0.0,
-    amount: str,  
+    mass: Union[str, float] = 0.0,
-    time: float,  
+    amount: str = "",
-    stir: bool,  
+    time: Union[str, float] = 0.0,
-    stir_speed: float,  
+    stir: bool = False,
-    viscous: bool,  
+    stir_speed: float = 300.0,
-    purpose: str  
+    viscous: bool = False,
    purpose: str = "添加试剂",
    # XDL扩展参数
    mol: str = "",
    event: str = "",
    rate_spec: str = "",
    equiv: str = "",
    ratio: str = "",
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
-    生成添加试剂的协议序列 - 严格按照 Add.action
+    生成添加试剂协议 - 修复版
    支持所有XDL参数和单位：
    - volume: "2.7 mL", "2.67 mL", "?" 或数值
    - mass: "19.3 g", "4.5 g" 或数值
    - time: "1 h", "20 min" 或数值（秒）
    - mol: "0.28 mol", "16.2 mmol", "25.2 mmol"
    - rate_spec: "portionwise", "dropwise"
    - event: "A", "B"
    - equiv: "1.1"
    - ratio: "?", "1:1"
    """
    debug_print("=" * 60)
    debug_print("🚀 开始生成添加试剂协议")
    debug_print(f"📋 原始参数:")
    debug_print(f"  🥼 vessel: '{vessel}'")
    debug_print(f"  🧪 reagent: '{reagent}'")
    debug_print(f"  📏 volume: {volume} (类型: {type(volume)})")
    debug_print(f"  ⚖️ mass: {mass} (类型: {type(mass)})")
    debug_print(f"  ⏱️ time: {time} (类型: {type(time)})")
    debug_print(f"  🧬 mol: '{mol}'")
    debug_print(f"  🎯 event: '{event}'")
    debug_print(f"  ⚡ rate_spec: '{rate_spec}'")
    debug_print(f"  🌪️ stir: {stir}")
    debug_print(f"  🔄 stir_speed: {stir_speed} rpm")
    debug_print("=" * 60)
    action_sequence = []
-    # 如果指定了体积，执行液体转移  
+    # === 参数验证 ===
-    if volume > 0:  
+    debug_print("🔍 步骤1: 参数验证...")
-        # 查找可用的试剂瓶
+    action_sequence.append(create_action_log(f"开始添加试剂 '{reagent}' 到容器 '{vessel}'", "🎬"))
        available_flasks = [node for node in G.nodes() 
                           if node.startswith('flask_') 
                           and G.nodes[node].get('type') == 'container']
-        if not available_flasks:
+    if not vessel:
-            raise ValueError("没有找到可用的试剂容器")
+        debug_print("❌ vessel 参数不能为空")
        raise ValueError("vessel 参数不能为空")
    if not reagent:
        debug_print("❌ reagent 参数不能为空")
        raise ValueError("reagent 参数不能为空")
-        reagent_vessel = available_flasks[0]
+    if vessel not in G.nodes():
        debug_print(f"❌ 容器 '{vessel}' 不存在于系统中")
        raise ValueError(f"容器 '{vessel}' 不存在于系统中")
-        # 查找泵设备
+    debug_print("✅ 基本参数验证通过")
        pump_nodes = [node for node in G.nodes() 
                     if G.nodes[node].get('class') == 'virtual_pump']
-        if pump_nodes:
+    # === 🔧 关键修复：参数解析 ===
-            pump_id = pump_nodes[0]
+    debug_print("🔍 步骤2: 参数解析...")
-            action_sequence.append({
+    action_sequence.append(create_action_log("正在解析添加参数...", "🔍"))
                "device_id": pump_id,
                "action_name": "transfer",
                "action_kwargs": {
                    "from_vessel": reagent_vessel,
                    "to_vessel": vessel,
                    "volume": volume,
                    "amount": amount,
                    "time": time,
                    "viscous": viscous,
                    "rinsing_solvent": "",
                    "rinsing_volume": 0.0,
                    "rinsing_repeats": 0,
                    "solid": False
                }
            })
-    # 如果需要搅拌，使用 StartStir 而不是 Stir  
+    # 解析各种参数为数值
-    if stir:  
+    final_volume = parse_volume_input(volume)
-        stirrer_nodes = [node for node in G.nodes()   
+    final_mass = parse_mass_input(mass)
-                        if G.nodes[node].get('class') == 'virtual_stirrer']  
+    final_time = parse_time_input(time)
-        if stirrer_nodes:  
+    debug_print(f"📊 解析结果:")
-            stirrer_id = stirrer_nodes[0]  
+    debug_print(f"  📏 体积: {final_volume}mL")
-            action_sequence.append({  
+    debug_print(f"  ⚖️ 质量: {final_mass}g")
-                "device_id": stirrer_id,  
+    debug_print(f"  ⏱️ 时间: {final_time}s")
-                "action_name": "start_stir",  # 使用 start_stir 而不是 stir
+    debug_print(f"  🧬 摩尔: '{mol}'")
-                "action_kwargs": {  
+    debug_print(f"  🎯 事件: '{event}'")
    debug_print(f"  ⚡ 速率: '{rate_spec}'")
    # === 判断添加类型 ===
    debug_print("🔍 步骤3: 判断添加类型...")
    # 🔧 修复：现在使用解析后的数值进行比较
    is_solid = (final_mass > 0 or (mol and mol.strip() != ""))
    is_liquid = (final_volume > 0)
    if not is_solid and not is_liquid:
        # 默认为液体，10mL
        is_liquid = True
        final_volume = 10.0
        debug_print("⚠️ 未指定体积或质量，默认为10mL液体")
    add_type = "固体" if is_solid else "液体"
    add_emoji = "🧂" if is_solid else "💧"
    debug_print(f"📋 添加类型: {add_type} {add_emoji}")
    action_sequence.append(create_action_log(f"确定添加类型: {add_type} {add_emoji}", "📋"))
    # === 执行添加流程 ===
    debug_print("🔍 步骤4: 执行添加流程...")
    try:
        if is_solid:
            # === 固体添加路径 ===
            debug_print(f"🧂 使用固体添加路径")
            action_sequence.append(create_action_log("开始固体试剂添加流程", "🧂"))
            solid_dispenser = find_solid_dispenser(G)
            if solid_dispenser:
                action_sequence.append(create_action_log(f"找到固体加样器: {solid_dispenser}", "🥄"))
                # 启动搅拌
                if stir:
                    debug_print("🌪️ 准备启动搅拌...")
                    action_sequence.append(create_action_log("准备启动搅拌器", "🌪️"))
                    stirrer_id = find_connected_stirrer(G, vessel)
                    if stirrer_id:
                        action_sequence.append(create_action_log(f"启动搅拌器 {stirrer_id} (速度: {stir_speed} rpm)", "🔄"))
                        action_sequence.append({
                            "device_id": stirrer_id,
                            "action_name": "start_stir",
                            "action_kwargs": {
                                "vessel": vessel,
                                "stir_speed": stir_speed,
                                "purpose": f"准备添加固体 {reagent}"
                            }
                        })
                        # 等待搅拌稳定
                        action_sequence.append(create_action_log("等待搅拌稳定...", "⏳"))
                        action_sequence.append({
                            "action_name": "wait",
                            "action_kwargs": {"time": 3}
                        })
                # 固体加样
                add_kwargs = {
                    "vessel": vessel,
-                    "stir_speed": stir_speed,
+                    "reagent": reagent,
-                    "purpose": f"添加 {reagent} 后搅拌"
+                    "purpose": purpose,
                    "event": event,
                    "rate_spec": rate_spec
                }
-            })  
+                
                if final_mass > 0:
                    add_kwargs["mass"] = str(final_mass)
                    action_sequence.append(create_action_log(f"准备添加固体: {final_mass}g", "⚖️"))
                if mol and mol.strip():
                    add_kwargs["mol"] = mol
                    action_sequence.append(create_action_log(f"按摩尔数添加: {mol}", "🧬"))
                if equiv and equiv.strip():
                    add_kwargs["equiv"] = equiv
                    action_sequence.append(create_action_log(f"当量: {equiv}", "🔢"))
                action_sequence.append(create_action_log("开始固体加样操作", "🥄"))
                action_sequence.append({
                    "device_id": solid_dispenser,
                    "action_name": "add_solid",
                    "action_kwargs": add_kwargs
                })
                action_sequence.append(create_action_log("固体加样完成", "✅"))
                # 添加后等待
                if final_time > 0:
                    wait_minutes = final_time / 60
                    action_sequence.append(create_action_log(f"等待反应进行 ({wait_minutes:.1f}分钟)", "⏰"))
                    action_sequence.append({
                        "action_name": "wait",
                        "action_kwargs": {"time": final_time}
                    })
                debug_print(f"✅ 固体添加完成")
            else:
                debug_print("❌ 未找到固体加样器，跳过固体添加")
                action_sequence.append(create_action_log("未找到固体加样器，无法添加固体", "❌"))
        else:
            # === 液体添加路径 ===
            debug_print(f"💧 使用液体添加路径")
            action_sequence.append(create_action_log("开始液体试剂添加流程", "💧"))
            # 查找试剂容器
            action_sequence.append(create_action_log("正在查找试剂容器...", "🔍"))
            reagent_vessel = find_reagent_vessel(G, reagent)
            action_sequence.append(create_action_log(f"找到试剂容器: {reagent_vessel}", "🧪"))
            # 启动搅拌
            if stir:
                debug_print("🌪️ 准备启动搅拌...")
                action_sequence.append(create_action_log("准备启动搅拌器", "🌪️"))
                stirrer_id = find_connected_stirrer(G, vessel)
                if stirrer_id:
                    action_sequence.append(create_action_log(f"启动搅拌器 {stirrer_id} (速度: {stir_speed} rpm)", "🔄"))
                    action_sequence.append({
                        "device_id": stirrer_id,
                        "action_name": "start_stir",
                        "action_kwargs": {
                            "vessel": vessel,
                            "stir_speed": stir_speed,
                            "purpose": f"准备添加液体 {reagent}"
                        }
                    })
                    # 等待搅拌稳定
                    action_sequence.append(create_action_log("等待搅拌稳定...", "⏳"))
                    action_sequence.append({
                        "action_name": "wait",
                        "action_kwargs": {"time": 5}
                    })
            # 计算流速
            if final_time > 0:
                flowrate = final_volume / final_time * 60  # mL/min
                transfer_flowrate = flowrate
                debug_print(f"⚡ 根据时间计算流速: {flowrate:.2f} mL/min")
            else:
                if rate_spec == "dropwise":
                    flowrate = 0.5  # 滴加，很慢
                    transfer_flowrate = 0.2
                    debug_print(f"💧 滴加模式，流速: {flowrate} mL/min")
                elif viscous:
                    flowrate = 1.0  # 粘性液体
                    transfer_flowrate = 0.3
                    debug_print(f"🍯 粘性液体，流速: {flowrate} mL/min")
                else:
                    flowrate = 2.5  # 正常流速
                    transfer_flowrate = 0.5
                    debug_print(f"⚡ 正常流速: {flowrate} mL/min")
            action_sequence.append(create_action_log(f"设置流速: {flowrate:.2f} mL/min", "⚡"))
            action_sequence.append(create_action_log(f"开始转移 {final_volume}mL 液体", "🚰"))
            # 调用pump protocol
            pump_actions = generate_pump_protocol_with_rinsing(
                G=G,
                from_vessel=reagent_vessel,
                to_vessel=vessel,
                volume=final_volume,
                amount=amount,
                time=final_time,
                viscous=viscous,
                rinsing_solvent="",
                rinsing_volume=0.0,
                rinsing_repeats=0,
                solid=False,
                flowrate=flowrate,
                transfer_flowrate=transfer_flowrate,
                rate_spec=rate_spec,
                event=event,
                through="",
                **kwargs
            )
            action_sequence.extend(pump_actions)
            debug_print(f"✅ 液体转移完成，添加了 {len(pump_actions)} 个动作")
            action_sequence.append(create_action_log(f"液体转移完成 ({len(pump_actions)} 个操作)", "✅"))
    except Exception as e:
        debug_print(f"❌ 试剂添加失败: {str(e)}")
        action_sequence.append(create_action_log(f"试剂添加失败: {str(e)}", "❌"))
        # 添加错误日志
        action_sequence.append({
            "device_id": "system",
            "action_name": "log_message",
            "action_kwargs": {
                "message": f"试剂 '{reagent}' 添加失败: {str(e)}"
            }
        })
    # === 最终结果 ===
    debug_print("=" * 60)
    debug_print(f"🎉 添加试剂协议生成完成")
    debug_print(f"📊 总动作数: {len(action_sequence)}")
    debug_print(f"📋 处理总结:")
    debug_print(f"  🧪 试剂: {reagent}")
    debug_print(f"  {add_emoji} 添加类型: {add_type}")
    debug_print(f"  🥼 目标容器: {vessel}")
    if is_liquid:
        debug_print(f"  📏 体积: {final_volume}mL")
    if is_solid:
        debug_print(f"  ⚖️ 质量: {final_mass}g")
        debug_print(f"  🧬 摩尔: {mol}")
    debug_print("=" * 60)
    # 添加完成日志
    summary_msg = f"试剂添加协议完成: {reagent} → {vessel}"
    if is_liquid:
        summary_msg += f" ({final_volume}mL)"
    if is_solid:
        summary_msg += f" ({final_mass}g)"
    action_sequence.append(create_action_log(summary_msg, "🎉"))
    return action_sequence
 # === 便捷函数 ===
 def add_liquid_volume(G: nx.DiGraph, vessel: str, reagent: str, volume: Union[str, float], 
                     time: Union[str, float] = 0.0, rate_spec: str = "") -> List[Dict[str, Any]]:
    """添加指定体积的液体试剂"""
    debug_print(f"💧 快速添加液体: {reagent} ({volume}) → {vessel}")
    return generate_add_protocol(
        G, vessel, reagent, 
        volume=volume, 
        time=time, 
        rate_spec=rate_spec
    )
 def add_solid_mass(G: nx.DiGraph, vessel: str, reagent: str, mass: Union[str, float], 
                   event: str = "") -> List[Dict[str, Any]]:
    """添加指定质量的固体试剂"""
    debug_print(f"🧂 快速添加固体: {reagent} ({mass}) → {vessel}")
    return generate_add_protocol(
        G, vessel, reagent, 
        mass=mass, 
        event=event
    )
 def add_solid_moles(G: nx.DiGraph, vessel: str, reagent: str, mol: str, 
                    event: str = "") -> List[Dict[str, Any]]:
    """按摩尔数添加固体试剂"""
    debug_print(f"🧬 按摩尔数添加固体: {reagent} ({mol}) → {vessel}")
    return generate_add_protocol(
        G, vessel, reagent, 
        mol=mol, 
        event=event
    )
 def add_dropwise_liquid(G: nx.DiGraph, vessel: str, reagent: str, volume: Union[str, float], 
                        time: Union[str, float] = "20 min", event: str = "") -> List[Dict[str, Any]]:
    """滴加液体试剂"""
    debug_print(f"💧 滴加液体: {reagent} ({volume}) → {vessel} (用时: {time})")
    return generate_add_protocol(
        G, vessel, reagent, 
        volume=volume, 
        time=time, 
        rate_spec="dropwise", 
        event=event
    )
 def add_portionwise_solid(G: nx.DiGraph, vessel: str, reagent: str, mass: Union[str, float], 
                          time: Union[str, float] = "1 h", event: str = "") -> List[Dict[str, Any]]:
    """分批添加固体试剂"""
    debug_print(f"🧂 分批添加固体: {reagent} ({mass}) → {vessel} (用时: {time})")
    return generate_add_protocol(
        G, vessel, reagent, 
        mass=mass, 
        time=time, 
        rate_spec="portionwise", 
        event=event
    )
 # 测试函数
 def test_add_protocol():
    """测试添加协议的各种参数解析"""
    print("=== ADD PROTOCOL 增强版测试 ===")
    # 测试体积解析
    debug_print("🧪 测试体积解析...")
    volumes = ["2.7 mL", "2.67 mL", "?", 10.0, "1 L", "500 μL"]
    for vol in volumes:
        result = parse_volume_input(vol)
        print(f"📏 体积解析: {vol} → {result}mL")
    # 测试质量解析
    debug_print("⚖️ 测试质量解析...")
    masses = ["19.3 g", "4.5 g", 2.5, "500 mg", "1 kg"]
    for mass in masses:
        result = parse_mass_input(mass)
        print(f"⚖️ 质量解析: {mass} → {result}g")
    # 测试时间解析
    debug_print("⏱️ 测试时间解析...")
    times = ["1 h", "20 min", "30 s", 60.0, "?"]
    for time in times:
        result = parse_time_input(time)
        print(f"⏱️ 时间解析: {time} → {result}s")
    print("✅ 测试完成")
 if __name__ == "__main__":
    test_add_protocol()
--- a/unilabos/compile/adjustph_protocol.py
+++ b/unilabos/compile/adjustph_protocol.py
@@ -0,0 +1,588 @@
 import networkx as nx
 import logging
 from typing import List, Dict, Any
 from .pump_protocol import generate_pump_protocol_with_rinsing
 logger = logging.getLogger(__name__)
 def debug_print(message):
    """调试输出"""
    print(f"[ADJUST_PH] {message}", flush=True)
    logger.info(f"[ADJUST_PH] {message}")
 # 🆕 创建进度日志动作
 def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
    """创建一个动作日志"""
    full_message = f"{emoji} {message}"
    debug_print(full_message)
    logger.info(full_message)
    print(f"[ACTION] {full_message}", flush=True)
    return {
        "action_name": "wait",
        "action_kwargs": {
            "time": 0.1,
            "log_message": full_message
        }
    }
 def find_acid_base_vessel(G: nx.DiGraph, reagent: str) -> str:
    """
    查找酸碱试剂容器，支持多种匹配模式
    Args:
        G: 网络图
        reagent: 试剂名称（如 "hydrochloric acid", "sodium hydroxide"）
    Returns:
        str: 试剂容器ID
    """
    debug_print(f"🔍 正在查找试剂 '{reagent}' 的容器...")
    # 常见酸碱试剂的别名映射
    reagent_aliases = {
        "hydrochloric acid": ["HCl", "hydrochloric_acid", "hcl", "muriatic_acid"],
        "sodium hydroxide": ["NaOH", "sodium_hydroxide", "naoh", "caustic_soda"],
        "sulfuric acid": ["H2SO4", "sulfuric_acid", "h2so4"],
        "nitric acid": ["HNO3", "nitric_acid", "hno3"],
        "acetic acid": ["CH3COOH", "acetic_acid", "glacial_acetic_acid"],
        "ammonia": ["NH3", "ammonium_hydroxide", "nh3"],
        "potassium hydroxide": ["KOH", "potassium_hydroxide", "koh"]
    }
    # 构建搜索名称列表
    search_names = [reagent.lower()]
    debug_print(f"📋 基础搜索名称: {reagent.lower()}")
    # 添加别名
    for base_name, aliases in reagent_aliases.items():
        if reagent.lower() in base_name.lower() or base_name.lower() in reagent.lower():
            search_names.extend([alias.lower() for alias in aliases])
            debug_print(f"🔗 添加别名: {aliases}")
            break
    debug_print(f"📝 完整搜索列表: {search_names}")
    # 构建可能的容器名称
    possible_names = []
    for name in search_names:
        name_clean = name.replace(" ", "_").replace("-", "_")
        possible_names.extend([
            f"flask_{name_clean}",
            f"bottle_{name_clean}",
            f"reagent_{name_clean}",
            f"acid_{name_clean}" if "acid" in name else f"base_{name_clean}",
            f"{name_clean}_bottle",
            f"{name_clean}_flask",
            name_clean
        ])
    debug_print(f"🎯 可能的容器名称 (前5个): {possible_names[:5]}... (共{len(possible_names)}个)")
    # 第一步：通过容器名称匹配
    debug_print(f"📋 方法1: 精确名称匹配...")
    for vessel_name in possible_names:
        if vessel_name in G.nodes():
            debug_print(f"✅ 通过名称匹配找到容器: {vessel_name} 🎯")
            return vessel_name
    # 第二步：通过模糊匹配
    debug_print(f"📋 方法2: 模糊名称匹配...")
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            node_name = G.nodes[node_id].get('name', '').lower()
            # 检查是否包含任何搜索名称
            for search_name in search_names:
                if search_name in node_id.lower() or search_name in node_name:
                    debug_print(f"✅ 通过模糊匹配找到容器: {node_id} 🔍")
                    return node_id
    # 第三步：通过液体类型匹配
    debug_print(f"📋 方法3: 液体类型匹配...")
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            vessel_data = G.nodes[node_id].get('data', {})
            liquids = vessel_data.get('liquid', [])
            for liquid in liquids:
                if isinstance(liquid, dict):
                    liquid_type = (liquid.get('liquid_type') or liquid.get('name', '')).lower()
                    reagent_name = vessel_data.get('reagent_name', '').lower()
                    for search_name in search_names:
                        if search_name in liquid_type or search_name in reagent_name:
                            debug_print(f"✅ 通过液体类型匹配找到容器: {node_id} 💧")
                            return node_id
    # 列出可用容器帮助调试
    debug_print(f"📊 列出可用容器帮助调试...")
    available_containers = []
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            vessel_data = G.nodes[node_id].get('data', {})
            liquids = vessel_data.get('liquid', [])
            liquid_types = [liquid.get('liquid_type', '') or liquid.get('name', '') 
                           for liquid in liquids if isinstance(liquid, dict)]
            available_containers.append({
                'id': node_id,
                'name': G.nodes[node_id].get('name', ''),
                'liquids': liquid_types,
                'reagent_name': vessel_data.get('reagent_name', '')
            })
    debug_print(f"📋 可用容器列表:")
    for container in available_containers:
        debug_print(f"  - 🧪 {container['id']}: {container['name']}")
        debug_print(f"    💧 液体: {container['liquids']}")
        debug_print(f"    🏷️ 试剂: {container['reagent_name']}")
    debug_print(f"❌ 所有匹配方法都失败了")
    raise ValueError(f"找不到试剂 '{reagent}' 对应的容器。尝试了: {possible_names[:10]}...")
 def find_connected_stirrer(G: nx.DiGraph, vessel: str) -> str:
    """查找与容器相连的搅拌器"""
    debug_print(f"🔍 查找连接到容器 '{vessel}' 的搅拌器...")
    stirrer_nodes = [node for node in G.nodes() 
                    if (G.nodes[node].get('class') or '') == 'virtual_stirrer']
    debug_print(f"📊 发现 {len(stirrer_nodes)} 个搅拌器: {stirrer_nodes}")
    for stirrer in stirrer_nodes:
        if G.has_edge(stirrer, vessel) or G.has_edge(vessel, stirrer):
            debug_print(f"✅ 找到连接的搅拌器: {stirrer} 🔗")
            return stirrer
    if stirrer_nodes:
        debug_print(f"⚠️ 未找到直接连接的搅拌器，使用第一个: {stirrer_nodes[0]} 🔄")
        return stirrer_nodes[0]
    debug_print(f"❌ 未找到任何搅拌器")
    return None
 def calculate_reagent_volume(target_ph_value: float, reagent: str, vessel_volume: float = 100.0) -> float:
    """
    估算需要的试剂体积来调节pH
    Args:
        target_ph_value: 目标pH值
        reagent: 试剂名称
        vessel_volume: 容器体积 (mL)
    Returns:
        float: 估算的试剂体积 (mL)
    """
    debug_print(f"🧮 计算试剂体积...")
    debug_print(f"  📍 目标pH: {target_ph_value}")
    debug_print(f"  🧪 试剂: {reagent}")
    debug_print(f"  📏 容器体积: {vessel_volume}mL")
    # 简化的pH调节体积估算（实际应用中需要更精确的计算）
    if "acid" in reagent.lower() or "hcl" in reagent.lower():
        debug_print(f"🍋 检测到酸性试剂")
        # 酸性试剂：pH越低需要的体积越大
        if target_ph_value < 3:
            volume = vessel_volume * 0.05  # 5%
            debug_print(f"  💪 强酸性 (pH<3): 使用 5% 体积")
        elif target_ph_value < 5:
            volume = vessel_volume * 0.02  # 2%
            debug_print(f"  🔸 中酸性 (pH<5): 使用 2% 体积")
        else:
            volume = vessel_volume * 0.01  # 1%
            debug_print(f"  🔹 弱酸性 (pH≥5): 使用 1% 体积")
    elif "hydroxide" in reagent.lower() or "naoh" in reagent.lower():
        debug_print(f"🧂 检测到碱性试剂")
        # 碱性试剂：pH越高需要的体积越大
        if target_ph_value > 11:
            volume = vessel_volume * 0.05  # 5%
            debug_print(f"  💪 强碱性 (pH>11): 使用 5% 体积")
        elif target_ph_value > 9:
            volume = vessel_volume * 0.02  # 2%
            debug_print(f"  🔸 中碱性 (pH>9): 使用 2% 体积")
        else:
            volume = vessel_volume * 0.01  # 1%
            debug_print(f"  🔹 弱碱性 (pH≤9): 使用 1% 体积")
    else:
        # 未知试剂，使用默认值
        volume = vessel_volume * 0.01
        debug_print(f"❓ 未知试剂类型，使用默认 1% 体积")
    debug_print(f"📊 计算结果: {volume:.2f}mL")
    return volume
 def generate_adjust_ph_protocol(
    G: nx.DiGraph,
    vessel: str,
    ph_value: float,
    reagent: str,
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
    生成调节pH的协议序列
    Args:
        G: 有向图，节点为容器和设备
        vessel: 目标容器（需要调节pH的容器）
        ph_value: 目标pH值（从XDL传入）
        reagent: 酸碱试剂名称（从XDL传入）
        **kwargs: 其他可选参数，使用默认值
    Returns:
        List[Dict[str, Any]]: 动作序列
    """
    debug_print("=" * 60)
    debug_print("🧪 开始生成pH调节协议")
    debug_print(f"📋 原始参数:")
    debug_print(f"  🥼 vessel: '{vessel}'")
    debug_print(f"  📊 ph_value: {ph_value}")
    debug_print(f"  🧪 reagent: '{reagent}'")
    debug_print(f"  📦 kwargs: {kwargs}")
    debug_print("=" * 60)
    action_sequence = []
    # 从kwargs中获取可选参数，如果没有则使用默认值
    volume = kwargs.get('volume', 0.0)           # 自动估算体积
    stir = kwargs.get('stir', True)              # 默认搅拌
    stir_speed = kwargs.get('stir_speed', 300.0) # 默认搅拌速度
    stir_time = kwargs.get('stir_time', 60.0)    # 默认搅拌时间
    settling_time = kwargs.get('settling_time', 30.0)  # 默认平衡时间
    debug_print(f"🔧 处理后的参数:")
    debug_print(f"  📏 volume: {volume}mL (0.0表示自动估算)")
    debug_print(f"  🌪️ stir: {stir}")
    debug_print(f"  🔄 stir_speed: {stir_speed}rpm")
    debug_print(f"  ⏱️ stir_time: {stir_time}s")
    debug_print(f"  ⏳ settling_time: {settling_time}s")
    # 开始处理
    action_sequence.append(create_action_log(f"开始调节pH至 {ph_value}", "🧪"))
    action_sequence.append(create_action_log(f"目标容器: {vessel}", "🥼"))
    action_sequence.append(create_action_log(f"使用试剂: {reagent}", "⚗️"))
    # 1. 验证目标容器存在
    debug_print(f"🔍 步骤1: 验证目标容器...")
    if vessel not in G.nodes():
        debug_print(f"❌ 目标容器 '{vessel}' 不存在于系统中")
        raise ValueError(f"目标容器 '{vessel}' 不存在于系统中")
    debug_print(f"✅ 目标容器验证通过")
    action_sequence.append(create_action_log("目标容器验证通过", "✅"))
    # 2. 查找酸碱试剂容器
    debug_print(f"🔍 步骤2: 查找试剂容器...")
    action_sequence.append(create_action_log("正在查找试剂容器...", "🔍"))
    try:
        reagent_vessel = find_acid_base_vessel(G, reagent)
        debug_print(f"✅ 找到试剂容器: {reagent_vessel}")
        action_sequence.append(create_action_log(f"找到试剂容器: {reagent_vessel}", "🧪"))
    except ValueError as e:
        debug_print(f"❌ 无法找到试剂容器: {str(e)}")
        action_sequence.append(create_action_log(f"试剂容器查找失败: {str(e)}", "❌"))
        raise ValueError(f"无法找到试剂 '{reagent}': {str(e)}")
    # 3. 体积估算
    debug_print(f"🔍 步骤3: 体积处理...")
    if volume <= 0:
        action_sequence.append(create_action_log("开始自动估算试剂体积", "🧮"))
        # 获取目标容器的体积信息
        vessel_data = G.nodes[vessel].get('data', {})
        vessel_volume = vessel_data.get('max_volume', 100.0)  # 默认100mL
        debug_print(f"📏 容器最大体积: {vessel_volume}mL")
        estimated_volume = calculate_reagent_volume(ph_value, reagent, vessel_volume)
        volume = estimated_volume
        debug_print(f"✅ 自动估算试剂体积: {volume:.2f} mL")
        action_sequence.append(create_action_log(f"估算试剂体积: {volume:.2f}mL", "📊"))
    else:
        debug_print(f"📏 使用指定体积: {volume}mL")
        action_sequence.append(create_action_log(f"使用指定体积: {volume}mL", "📏"))
    # 4. 验证路径存在
    debug_print(f"🔍 步骤4: 路径验证...")
    action_sequence.append(create_action_log("验证转移路径...", "🛤️"))
    try:
        path = nx.shortest_path(G, source=reagent_vessel, target=vessel)
        debug_print(f"✅ 找到路径: {' → '.join(path)}")
        action_sequence.append(create_action_log(f"找到转移路径: {' → '.join(path)}", "🛤️"))
    except nx.NetworkXNoPath:
        debug_print(f"❌ 无法找到转移路径")
        action_sequence.append(create_action_log("转移路径不存在", "❌"))
        raise ValueError(f"从试剂容器 '{reagent_vessel}' 到目标容器 '{vessel}' 没有可用路径")
    # 5. 搅拌器设置
    debug_print(f"🔍 步骤5: 搅拌器设置...")
    stirrer_id = None
    if stir:
        action_sequence.append(create_action_log("准备启动搅拌器", "🌪️"))
        try:
            stirrer_id = find_connected_stirrer(G, vessel)
            if stirrer_id:
                debug_print(f"✅ 找到搅拌器 {stirrer_id}，启动搅拌")
                action_sequence.append(create_action_log(f"启动搅拌器 {stirrer_id} (速度: {stir_speed}rpm)", "🔄"))
                action_sequence.append({
                    "device_id": stirrer_id,
                    "action_name": "start_stir",
                    "action_kwargs": {
                        "vessel": vessel,
                        "stir_speed": stir_speed,
                        "purpose": f"pH调节: 启动搅拌，准备添加 {reagent}"
                    }
                })
                # 等待搅拌稳定
                action_sequence.append(create_action_log("等待搅拌稳定...", "⏳"))
                action_sequence.append({
                    "action_name": "wait",
                    "action_kwargs": {"time": 5}
                })
            else:
                debug_print(f"⚠️ 未找到搅拌器，继续执行")
                action_sequence.append(create_action_log("未找到搅拌器，跳过搅拌", "⚠️"))
        except Exception as e:
            debug_print(f"❌ 搅拌器配置出错: {str(e)}")
            action_sequence.append(create_action_log(f"搅拌器配置失败: {str(e)}", "❌"))
    else:
        debug_print(f"📋 跳过搅拌设置")
        action_sequence.append(create_action_log("跳过搅拌设置", "⏭️"))
    # 6. 试剂添加
    debug_print(f"🔍 步骤6: 试剂添加...")
    action_sequence.append(create_action_log(f"开始添加试剂 {volume:.2f}mL", "🚰"))
    # 计算添加时间（pH调节需要缓慢添加）
    addition_time = max(30.0, volume * 2.0)  # 至少30秒，每mL需要2秒
    debug_print(f"⏱️ 计算添加时间: {addition_time}s (缓慢注入)")
    action_sequence.append(create_action_log(f"设置添加时间: {addition_time:.0f}s (缓慢注入)", "⏱️"))
    try:
        action_sequence.append(create_action_log("调用泵协议进行试剂转移", "🔄"))
        pump_actions = generate_pump_protocol_with_rinsing(
            G=G,
            from_vessel=reagent_vessel,
            to_vessel=vessel,
            volume=volume,
            amount="",
            time=addition_time,
            viscous=False,
            rinsing_solvent="",  # pH调节不需要清洗
            rinsing_volume=0.0,
            rinsing_repeats=0,
            solid=False,
            flowrate=0.5,  # 缓慢注入
            transfer_flowrate=0.3
        )
        action_sequence.extend(pump_actions)
        debug_print(f"✅ 泵协议生成完成，添加了 {len(pump_actions)} 个动作")
        action_sequence.append(create_action_log(f"试剂转移完成 ({len(pump_actions)} 个操作)", "✅"))
    except Exception as e:
        debug_print(f"❌ 生成泵协议时出错: {str(e)}")
        action_sequence.append(create_action_log(f"泵协议生成失败: {str(e)}", "❌"))
        raise ValueError(f"生成泵协议时出错: {str(e)}")
    # 7. 混合搅拌
    if stir and stirrer_id:
        debug_print(f"🔍 步骤7: 混合搅拌...")
        action_sequence.append(create_action_log(f"开始混合搅拌 {stir_time:.0f}s", "🌀"))
        action_sequence.append({
            "device_id": stirrer_id,
            "action_name": "stir",
            "action_kwargs": {
                "stir_time": stir_time,
                "stir_speed": stir_speed,
                "settling_time": settling_time,
                "purpose": f"pH调节: 混合试剂，目标pH={ph_value}"
            }
        })
        debug_print(f"✅ 混合搅拌设置完成")
    else:
        debug_print(f"⏭️ 跳过混合搅拌")
        action_sequence.append(create_action_log("跳过混合搅拌", "⏭️"))
    # 8. 等待平衡
    debug_print(f"🔍 步骤8: 反应平衡...")
    action_sequence.append(create_action_log(f"等待pH平衡 {settling_time:.0f}s", "⚖️"))
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": settling_time,
            "description": f"等待pH平衡到目标值 {ph_value}"
        }
    })
    # 9. 完成总结
    total_time = addition_time + stir_time + settling_time
    debug_print("=" * 60)
    debug_print(f"🎉 pH调节协议生成完成")
    debug_print(f"📊 协议统计:")
    debug_print(f"  📋 总动作数: {len(action_sequence)}")
    debug_print(f"  ⏱️ 预计总时间: {total_time:.0f}s ({total_time/60:.1f}分钟)")
    debug_print(f"  🧪 试剂: {reagent}")
    debug_print(f"  📏 体积: {volume:.2f}mL")
    debug_print(f"  📊 目标pH: {ph_value}")
    debug_print(f"  🥼 目标容器: {vessel}")
    debug_print("=" * 60)
    # 添加完成日志
    summary_msg = f"pH调节协议完成: {vessel} → pH {ph_value} (使用 {volume:.2f}mL {reagent})"
    action_sequence.append(create_action_log(summary_msg, "🎉"))
    return action_sequence
 def generate_adjust_ph_protocol_stepwise(
    G: nx.DiGraph,
    vessel: str,
    ph_value: float,
    reagent: str,
    max_volume: float = 10.0,
    steps: int = 3
 ) -> List[Dict[str, Any]]:
    """
    分步调节pH的协议（更安全，避免过度调节）
    Args:
        G: 网络图
        vessel: 目标容器
        ph_value: 目标pH值
        reagent: 酸碱试剂
        max_volume: 最大试剂体积
        steps: 分步数量
    Returns:
        List[Dict[str, Any]]: 动作序列
    """
    debug_print("=" * 60)
    debug_print(f"🔄 开始分步pH调节")
    debug_print(f"📋 分步参数:")
    debug_print(f"  🥼 vessel: {vessel}")
    debug_print(f"  📊 ph_value: {ph_value}")
    debug_print(f"  🧪 reagent: {reagent}")
    debug_print(f"  📏 max_volume: {max_volume}mL")
    debug_print(f"  🔢 steps: {steps}")
    debug_print("=" * 60)
    action_sequence = []
    # 每步添加的体积
    step_volume = max_volume / steps
    debug_print(f"📊 每步体积: {step_volume:.2f}mL")
    action_sequence.append(create_action_log(f"开始分步pH调节 ({steps}步)", "🔄"))
    action_sequence.append(create_action_log(f"每步添加: {step_volume:.2f}mL", "📏"))
    for i in range(steps):
        debug_print(f"🔄 执行第 {i+1}/{steps} 步，添加 {step_volume:.2f}mL")
        action_sequence.append(create_action_log(f"第 {i+1}/{steps} 步开始", "🚀"))
        # 生成单步协议
        step_actions = generate_adjust_ph_protocol(
            G=G,
            vessel=vessel,
            ph_value=ph_value,
            reagent=reagent,
            volume=step_volume,
            stir=True,
            stir_speed=300.0,
            stir_time=30.0,
            settling_time=20.0
        )
        action_sequence.extend(step_actions)
        debug_print(f"✅ 第 {i+1}/{steps} 步完成，添加了 {len(step_actions)} 个动作")
        action_sequence.append(create_action_log(f"第 {i+1}/{steps} 步完成", "✅"))
        # 步骤间等待
        if i < steps - 1:
            debug_print(f"⏳ 步骤间等待30s")
            action_sequence.append(create_action_log("步骤间等待...", "⏳"))
            action_sequence.append({
                "action_name": "wait",
                "action_kwargs": {
                    "time": 30,
                    "description": f"pH调节第{i+1}步完成，等待下一步"
                }
            })
    debug_print(f"🎉 分步pH调节完成，共 {len(action_sequence)} 个动作")
    action_sequence.append(create_action_log("分步pH调节全部完成", "🎉"))
    return action_sequence
 # 便捷函数：常用pH调节
 def generate_acidify_protocol(
    G: nx.DiGraph,
    vessel: str,
    target_ph: float = 2.0,
    acid: str = "hydrochloric acid"
 ) -> List[Dict[str, Any]]:
    """酸化协议"""
    debug_print(f"🍋 生成酸化协议: {vessel} → pH {target_ph} (使用 {acid})")
    return generate_adjust_ph_protocol(
        G, vessel, target_ph, acid
    )
 def generate_basify_protocol(
    G: nx.DiGraph,
    vessel: str,
    target_ph: float = 12.0,
    base: str = "sodium hydroxide"
 ) -> List[Dict[str, Any]]:
    """碱化协议"""
    debug_print(f"🧂 生成碱化协议: {vessel} → pH {target_ph} (使用 {base})")
    return generate_adjust_ph_protocol(
        G, vessel, target_ph, base
    )
 def generate_neutralize_protocol(
    G: nx.DiGraph,
    vessel: str,
    reagent: str = "sodium hydroxide"
 ) -> List[Dict[str, Any]]:
    """中和协议（pH=7）"""
    debug_print(f"⚖️ 生成中和协议: {vessel} → pH 7.0 (使用 {reagent})")
    return generate_adjust_ph_protocol(
        G, vessel, 7.0, reagent
    )
 # 测试函数
 def test_adjust_ph_protocol():
    """测试pH调节协议"""
    debug_print("=== ADJUST PH PROTOCOL 增强版测试 ===")
    # 测试体积计算
    debug_print("🧮 测试体积计算...")
    test_cases = [
        (2.0, "hydrochloric acid", 100.0),
        (4.0, "hydrochloric acid", 100.0),
        (12.0, "sodium hydroxide", 100.0),
        (10.0, "sodium hydroxide", 100.0),
        (7.0, "unknown reagent", 100.0)
    ]
    for ph, reagent, volume in test_cases:
        result = calculate_reagent_volume(ph, reagent, volume)
        debug_print(f"📊 {reagent} → pH {ph}: {result:.2f}mL")
    debug_print("✅ 测试完成")
 if __name__ == "__main__":
    test_adjust_ph_protocol()
--- a/unilabos/compile/centrifuge_protocol.py
+++ b/unilabos/compile/centrifuge_protocol.py
@@ -1,5 +1,59 @@
 from typing import List, Dict, Any
 import networkx as nx
 from .pump_protocol import generate_pump_protocol
 def get_vessel_liquid_volume(G: nx.DiGraph, vessel: str) -> float:
    """
    获取容器中的液体体积
    """
    if vessel not in G.nodes():
        return 0.0
    vessel_data = G.nodes[vessel].get('data', {})
    liquids = vessel_data.get('liquid', [])
    total_volume = 0.0
    for liquid in liquids:
        if isinstance(liquid, dict) and 'liquid_volume' in liquid:
            total_volume += liquid['liquid_volume']
    return total_volume
 def find_centrifuge_device(G: nx.DiGraph) -> str:
    """
    查找离心机设备
    """
    centrifuge_nodes = [node for node in G.nodes() 
                       if (G.nodes[node].get('class') or '') == 'virtual_centrifuge']
    if centrifuge_nodes:
        return centrifuge_nodes[0]
    raise ValueError("系统中未找到离心机设备")
 def find_centrifuge_vessel(G: nx.DiGraph) -> str:
    """
    查找离心机专用容器
    """
    possible_names = [
        "centrifuge_tube",
        "centrifuge_vessel", 
        "tube_centrifuge",
        "vessel_centrifuge",
        "centrifuge",
        "tube_15ml",
        "tube_50ml"
    ]
    for vessel_name in possible_names:
        if vessel_name in G.nodes():
            return vessel_name
    raise ValueError(f"未找到离心机容器。尝试了以下名称: {possible_names}")
 def generate_centrifuge_protocol(
    G: nx.DiGraph,
@@ -9,115 +63,223 @@ def generate_centrifuge_protocol(
    temp: float = 25.0
 ) -> List[Dict[str, Any]]:
    """
-    生成离心操作的协议序列
+    生成离心操作的协议序列，复用 pump_protocol 的成熟算法
    离心流程：
    1. 液体转移：将待离心溶液从源容器转移到离心机容器
    2. 离心操作：执行离心分离
    3. 上清液转移：将离心后的上清液转移回原容器或新容器
    4. 沉淀处理：处理离心沉淀（可选）
    Args:
-        G: 有向图，节点为设备和容器
+        G: 有向图，节点为设备和容器，边为流体管道
-        vessel: 离心容器名称
+        vessel: 包含待离心溶液的容器名称
        speed: 离心速度 (rpm)
        time: 离心时间 (秒)
-        temp: 温度 (摄氏度，可选)
+        temp: 离心温度 (°C)，默认25°C
    Returns:
        List[Dict[str, Any]]: 离心操作的动作序列
    Raises:
-        ValueError: 当找不到离心机设备时抛出异常
+        ValueError: 当找不到必要的设备时抛出异常
    Examples:
-        centrifuge_protocol = generate_centrifuge_protocol(G, "reactor", 5000, 300, 4.0)
+        centrifuge_actions = generate_centrifuge_protocol(G, "reaction_mixture", 5000, 600, 4.0)
    """
    action_sequence = []
-    # 查找离心机设备
+    print(f"CENTRIFUGE: 开始生成离心协议")
-    centrifuge_nodes = [node for node in G.nodes() 
+    print(f"  - 源容器: {vessel}")
-                       if G.nodes[node].get('class') == 'virtual_centrifuge']
+    print(f"  - 离心速度: {speed} rpm")
    print(f"  - 离心时间: {time}s ({time/60:.1f}分钟)")
    print(f"  - 离心温度: {temp}°C")
-    if not centrifuge_nodes:
+    # 验证源容器存在
        raise ValueError("没有找到可用的离心机设备")
    # 使用第一个可用的离心机
    centrifuge_id = centrifuge_nodes[0]
    # 验证容器是否存在
    if vessel not in G.nodes():
-        raise ValueError(f"容器 {vessel} 不存在于图中")
+        raise ValueError(f"源容器 '{vessel}' 不存在于系统中")
-    # 执行离心操作
+    # 获取源容器中的液体体积
-    action_sequence.append({
+    source_volume = get_vessel_liquid_volume(G, vessel)
    print(f"CENTRIFUGE: 源容器 {vessel} 中有 {source_volume} mL 液体")
    # 查找离心机设备
    try:
        centrifuge_id = find_centrifuge_device(G)
        print(f"CENTRIFUGE: 找到离心机: {centrifuge_id}")
    except ValueError as e:
        raise ValueError(f"无法找到离心机: {str(e)}")
    # 查找离心机容器
    try:
        centrifuge_vessel = find_centrifuge_vessel(G)
        print(f"CENTRIFUGE: 找到离心机容器: {centrifuge_vessel}")
    except ValueError as e:
        raise ValueError(f"无法找到离心机容器: {str(e)}")
    # === 简化的体积计算策略 ===
    if source_volume > 0:
        # 如果能检测到液体体积，使用实际体积的大部分
        transfer_volume = min(source_volume * 0.9, 15.0)  # 90%或最多15mL（离心管通常较小）
        print(f"CENTRIFUGE: 检测到液体体积，将转移 {transfer_volume} mL")
    else:
        # 如果检测不到液体体积，默认转移标准量
        transfer_volume = 10.0  # 标准离心管体积
        print(f"CENTRIFUGE: 未检测到液体体积，默认转移 {transfer_volume} mL")
    # === 第一步：将待离心溶液转移到离心机容器 ===
    print(f"CENTRIFUGE: 将 {transfer_volume} mL 溶液从 {vessel} 转移到 {centrifuge_vessel}")
    try:
        # 使用成熟的 pump_protocol 算法进行液体转移
        transfer_to_centrifuge_actions = generate_pump_protocol(
            G=G,
            from_vessel=vessel,
            to_vessel=centrifuge_vessel,
            volume=transfer_volume,
            flowrate=1.0,  # 离心转移用慢速，避免气泡
            transfer_flowrate=1.0
        )
        action_sequence.extend(transfer_to_centrifuge_actions)
    except Exception as e:
        raise ValueError(f"无法将溶液转移到离心机: {str(e)}")
    # 转移后等待
    wait_action = {
        "action_name": "wait",
        "action_kwargs": {"time": 5}
    }
    action_sequence.append(wait_action)
    # === 第二步：执行离心操作 ===
    print(f"CENTRIFUGE: 执行离心操作")
    centrifuge_action = {
        "device_id": centrifuge_id,
        "action_name": "centrifuge",
        "action_kwargs": {
-            "vessel": vessel,
+            "vessel": centrifuge_vessel,
            "speed": speed,
            "time": time,
            "temp": temp
        }
-    })
+    }
    action_sequence.append(centrifuge_action)
    # 离心后等待系统稳定
    wait_action = {
        "action_name": "wait",
        "action_kwargs": {"time": 10}  # 离心后等待稍长，让沉淀稳定
    }
    action_sequence.append(wait_action)
    # === 第三步：将上清液转移回原容器 ===
    print(f"CENTRIFUGE: 将上清液从离心机转移回 {vessel}")
    try:
        # 估算上清液体积（约为转移体积的80% - 假设20%成为沉淀）
        supernatant_volume = transfer_volume * 0.8
        print(f"CENTRIFUGE: 预计上清液体积 {supernatant_volume} mL")
        transfer_back_actions = generate_pump_protocol(
            G=G,
            from_vessel=centrifuge_vessel,
            to_vessel=vessel,
            volume=supernatant_volume,
            flowrate=0.5,  # 上清液转移更慢，避免扰动沉淀
            transfer_flowrate=0.5
        )
        action_sequence.extend(transfer_back_actions)
    except Exception as e:
        print(f"CENTRIFUGE: 将上清液转移回容器失败: {str(e)}")
    # === 第四步：清洗离心机容器 ===
    print(f"CENTRIFUGE: 清洗离心机容器")
    try:
        # 查找清洗溶剂
        cleaning_solvent = None
        for solvent in ["flask_water", "flask_ethanol", "flask_acetone"]:
            if solvent in G.nodes():
                cleaning_solvent = solvent
                break
        if cleaning_solvent:
            # 用少量溶剂清洗离心管
            cleaning_volume = 5.0  # 5mL清洗
            print(f"CENTRIFUGE: 用 {cleaning_volume} mL {cleaning_solvent} 清洗")
            # 清洗溶剂加入
            cleaning_actions = generate_pump_protocol(
                G=G,
                from_vessel=cleaning_solvent,
                to_vessel=centrifuge_vessel,
                volume=cleaning_volume,
                flowrate=2.0,
                transfer_flowrate=2.0
            )
            action_sequence.extend(cleaning_actions)
            # 将清洗液转移到废液
            if "waste_workup" in G.nodes():
                waste_actions = generate_pump_protocol(
                    G=G,
                    from_vessel=centrifuge_vessel,
                    to_vessel="waste_workup",
                    volume=cleaning_volume,
                    flowrate=2.0,
                    transfer_flowrate=2.0
                )
                action_sequence.extend(waste_actions)
    except Exception as e:
        print(f"CENTRIFUGE: 清洗步骤失败: {str(e)}")
    print(f"CENTRIFUGE: 生成了 {len(action_sequence)} 个动作")
    print(f"CENTRIFUGE: 离心协议生成完成")
    print(f"CENTRIFUGE: 总处理体积: {transfer_volume} mL")
    return action_sequence
-def generate_multi_step_centrifuge_protocol(
+# 便捷函数：常用离心方案
 def generate_low_speed_centrifuge_protocol(
    G: nx.DiGraph,
    vessel: str,
-    steps: List[Dict[str, Any]]
+    time: float = 300.0  # 5分钟
 ) -> List[Dict[str, Any]]:
-    """
+    """低速离心：细胞分离或大颗粒沉淀"""
-    生成多步骤离心操作的协议序列
+    return generate_centrifuge_protocol(G, vessel, 1000.0, time, 4.0)
    Args:
        G: 有向图，节点为设备和容器
        vessel: 离心容器名称
        steps: 离心步骤列表，每个步骤包含 speed, time, temp 参数
-    Returns:
+def generate_high_speed_centrifuge_protocol(
-        List[Dict[str, Any]]: 多步骤离心操作的动作序列
+    G: nx.DiGraph,
    vessel: str,
    time: float = 600.0  # 10分钟
 ) -> List[Dict[str, Any]]:
    """高速离心：蛋白质沉淀或小颗粒分离"""
    return generate_centrifuge_protocol(G, vessel, 12000.0, time, 4.0)
    Examples:
        steps = [
            {"speed": 1000, "time": 60, "temp": 4.0},   # 低速预离心
            {"speed": 12000, "time": 600, "temp": 4.0}  # 高速离心
        ]
        protocol = generate_multi_step_centrifuge_protocol(G, "reactor", steps)
    """
    action_sequence = []
-    # 查找离心机设备
+def generate_standard_centrifuge_protocol(
-    centrifuge_nodes = [node for node in G.nodes() 
+    G: nx.DiGraph,
-                       if G.nodes[node].get('class') == 'virtual_centrifuge']
+    vessel: str,
    time: float = 600.0  # 10分钟
 ) -> List[Dict[str, Any]]:
    """标准离心：常规样品处理"""
    return generate_centrifuge_protocol(G, vessel, 5000.0, time, 25.0)
    if not centrifuge_nodes:
        raise ValueError("没有找到可用的离心机设备")
-    centrifuge_id = centrifuge_nodes[0]
+def generate_cold_centrifuge_protocol(
    G: nx.DiGraph,
    vessel: str,
    speed: float = 5000.0,
    time: float = 600.0
 ) -> List[Dict[str, Any]]:
    """冷冻离心：热敏感样品处理"""
    return generate_centrifuge_protocol(G, vessel, speed, time, 4.0)
    # 验证容器是否存在
    if vessel not in G.nodes():
        raise ValueError(f"容器 {vessel} 不存在于图中")
-    # 执行每个离心步骤
+def generate_ultra_centrifuge_protocol(
-    for i, step in enumerate(steps):
+    G: nx.DiGraph,
-        speed = step.get('speed', 5000)
+    vessel: str,
-        time = step.get('time', 300)
+    time: float = 1800.0  # 30分钟
-        temp = step.get('temp', 25.0)
+) -> List[Dict[str, Any]]:
-        
+    """超高速离心：超细颗粒分离"""
-        action_sequence.append({
+    return generate_centrifuge_protocol(G, vessel, 15000.0, time, 4.0)
            "device_id": centrifuge_id,
            "action_name": "centrifuge",
            "action_kwargs": {
                "vessel": vessel,
                "speed": speed,
                "time": time,
                "temp": temp
            }
        })
        # 步骤间等待时间（除了最后一步）
        if i < len(steps) - 1:
            action_sequence.append({
                "action_name": "wait", 
                "action_kwargs": {"time": 3}
            })
    return action_sequence
--- a/unilabos/compile/clean_vessel_protocol.py
+++ b/unilabos/compile/clean_vessel_protocol.py
@@ -1,5 +1,147 @@
 from typing import List, Dict, Any
 import networkx as nx
 from .pump_protocol import generate_pump_protocol
 def find_solvent_vessel(G: nx.DiGraph, solvent: str) -> str:
    """
    查找溶剂容器，支持多种匹配模式：
    1. 容器名称匹配（如 flask_water, reagent_bottle_1-DMF）
    2. 容器内液体类型匹配（如 liquid_type: "DMF", "ethanol"）
    """
    print(f"CLEAN_VESSEL: 正在查找溶剂 '{solvent}' 的容器...")
    # 第一步：通过容器名称匹配
    possible_names = [
        f"flask_{solvent}",           # flask_water, flask_ethanol
        f"bottle_{solvent}",          # bottle_water, bottle_ethanol  
        f"vessel_{solvent}",          # vessel_water, vessel_ethanol
        f"{solvent}_flask",           # water_flask, ethanol_flask
        f"{solvent}_bottle",          # water_bottle, ethanol_bottle
        f"{solvent}",                 # 直接用溶剂名
        f"solvent_{solvent}",         # solvent_water, solvent_ethanol
        f"reagent_bottle_{solvent}",  # reagent_bottle_DMF
    ]
    # 尝试名称匹配
    for vessel_name in possible_names:
        if vessel_name in G.nodes():
            print(f"CLEAN_VESSEL: 通过名称匹配找到容器: {vessel_name}")
            return vessel_name
    # 第二步：通过模糊名称匹配（名称中包含溶剂名）
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            # 检查节点ID或名称中是否包含溶剂名
            node_name = G.nodes[node_id].get('name', '').lower()
            if (solvent.lower() in node_id.lower() or 
                solvent.lower() in node_name):
                print(f"CLEAN_VESSEL: 通过模糊名称匹配找到容器: {node_id} (名称: {node_name})")
                return node_id
    # 第三步：通过液体类型匹配
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            vessel_data = G.nodes[node_id].get('data', {})
            liquids = vessel_data.get('liquid', [])
            for liquid in liquids:
                if isinstance(liquid, dict):
                    # 支持两种格式的液体类型字段
                    liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
                    reagent_name = vessel_data.get('reagent_name', '')
                    config_reagent = G.nodes[node_id].get('config', {}).get('reagent', '')
                    # 检查多个可能的字段
                    if (liquid_type.lower() == solvent.lower() or 
                        reagent_name.lower() == solvent.lower() or
                        config_reagent.lower() == solvent.lower()):
                        print(f"CLEAN_VESSEL: 通过液体类型匹配找到容器: {node_id}")
                        print(f"  - liquid_type: {liquid_type}")
                        print(f"  - reagent_name: {reagent_name}")
                        print(f"  - config.reagent: {config_reagent}")
                        return node_id
    # 第四步：列出所有可用的容器信息帮助调试
    available_containers = []
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            vessel_data = G.nodes[node_id].get('data', {})
            config_data = G.nodes[node_id].get('config', {})
            liquids = vessel_data.get('liquid', [])
            container_info = {
                'id': node_id,
                'name': G.nodes[node_id].get('name', ''),
                'liquid_types': [],
                'reagent_name': vessel_data.get('reagent_name', ''),
                'config_reagent': config_data.get('reagent', '')
            }
            for liquid in liquids:
                if isinstance(liquid, dict):
                    liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
                    if liquid_type:
                        container_info['liquid_types'].append(liquid_type)
            available_containers.append(container_info)
    print(f"CLEAN_VESSEL: 可用容器列表:")
    for container in available_containers:
        print(f"  - {container['id']}: {container['name']}")
        print(f"    液体类型: {container['liquid_types']}")
        print(f"    试剂名称: {container['reagent_name']}")
        print(f"    配置试剂: {container['config_reagent']}")
    raise ValueError(f"未找到溶剂 '{solvent}' 的容器。尝试了名称匹配: {possible_names}")
 def find_solvent_vessel_by_any_match(G: nx.DiGraph, solvent: str) -> str:
    """
    增强版溶剂容器查找，支持各种匹配方式的别名函数
    """
    return find_solvent_vessel(G, solvent)
 def find_waste_vessel(G: nx.DiGraph) -> str:
    """
    查找废液容器
    """
    possible_waste_names = [
        "waste_workup",
        "flask_waste", 
        "bottle_waste",
        "waste",
        "waste_vessel",
        "waste_container"
    ]
    for waste_name in possible_waste_names:
        if waste_name in G.nodes():
            return waste_name
    raise ValueError(f"未找到废液容器。尝试了以下名称: {possible_waste_names}")
 def find_connected_heatchill(G: nx.DiGraph, vessel: str) -> str:
    """
    查找与指定容器相连的加热冷却设备
    """
    # 查找所有加热冷却设备节点
    heatchill_nodes = [node for node in G.nodes() 
                      if (G.nodes[node].get('class') or '') == 'virtual_heatchill']
    # 检查哪个加热设备与目标容器相连（机械连接）
    for heatchill in heatchill_nodes:
        if G.has_edge(heatchill, vessel) or G.has_edge(vessel, heatchill):
            return heatchill
    # 如果没有直接连接，返回第一个可用的加热设备
    if heatchill_nodes:
        return heatchill_nodes[0]
    return None  # 没有加热设备也可以工作，只是不能加热
 def generate_clean_vessel_protocol(
    G: nx.DiGraph,
@@ -10,13 +152,22 @@ def generate_clean_vessel_protocol(
    repeats: int = 1
 ) -> List[Dict[str, Any]]:
    """
-    生成容器清洗操作的协议序列，使用transfer操作实现清洗
+    生成容器清洗操作的协议序列，复用 pump_protocol 的成熟算法
    清洗流程：
    1. 查找溶剂容器和废液容器
    2. 如果需要加热，启动加热设备
    3. 重复以下操作 repeats 次：
       a. 使用 pump_protocol 将溶剂从溶剂容器转移到目标容器
       b. (可选) 等待清洗作用时间
       c. 使用 pump_protocol 将清洗液从目标容器转移到废液容器
    4. 如果加热了，停止加热
    Args:
-        G: 有向图，节点为设备和容器
+        G: 有向图，节点为设备和容器，边为流体管道
        vessel: 要清洗的容器名称
-        solvent: 用于清洗容器的溶剂名称
+        solvent: 用于清洗的溶剂名称  
-        volume: 清洗溶剂的体积
+        volume: 每次清洗使用的溶剂体积
        temp: 清洗时的温度
        repeats: 清洗操作的重复次数，默认为 1
@@ -24,103 +175,265 @@ def generate_clean_vessel_protocol(
        List[Dict[str, Any]]: 容器清洗操作的动作序列
    Raises:
-        ValueError: 当找不到必要的设备时抛出异常
+        ValueError: 当找不到必要的容器或设备时抛出异常
    Examples:
-        clean_vessel_protocol = generate_clean_vessel_protocol(G, "reactor", "water", 50.0, 25.0, 2)
+        clean_protocol = generate_clean_vessel_protocol(G, "main_reactor", "water", 100.0, 60.0, 2)
    """
    action_sequence = []
-    # 查找虚拟转移泵设备进行清洗操作
+    print(f"CLEAN_VESSEL: 开始生成容器清洗协议")
-    pump_nodes = [node for node in G.nodes() 
+    print(f"  - 目标容器: {vessel}")
-                  if G.nodes[node].get('class') == 'virtual_transfer_pump']
+    print(f"  - 清洗溶剂: {solvent}")
    print(f"  - 清洗体积: {volume} mL")
    print(f"  - 清洗温度: {temp}°C")
    print(f"  - 重复次数: {repeats}")
-    if not pump_nodes:
+    # 验证目标容器存在
        raise ValueError("没有找到可用的转移泵设备进行容器清洗")
    pump_id = pump_nodes[0]
    # 验证容器是否存在
    if vessel not in G.nodes():
-        raise ValueError(f"容器 {vessel} 不存在于图中")
+        raise ValueError(f"目标容器 '{vessel}' 不存在于系统中")
    # 查找溶剂容器
-    solvent_vessel = f"flask_{solvent}"
+    try:
-    if solvent_vessel not in G.nodes():
+        solvent_vessel = find_solvent_vessel(G, solvent)
-        raise ValueError(f"溶剂容器 {solvent_vessel} 不存在于图中")
+        print(f"CLEAN_VESSEL: 找到溶剂容器: {solvent_vessel}")
    except ValueError as e:
        raise ValueError(f"无法找到溶剂容器: {str(e)}")
    # 查找废液容器
-    waste_vessel = "flask_waste"
+    try:
-    if waste_vessel not in G.nodes():
+        waste_vessel = find_waste_vessel(G)
-        raise ValueError(f"废液容器 {waste_vessel} 不存在于图中")
+        print(f"CLEAN_VESSEL: 找到废液容器: {waste_vessel}")
    except ValueError as e:
        raise ValueError(f"无法找到废液容器: {str(e)}")
-    # 查找加热设备（如果需要加热）
+    # 查找加热设备（可选）
-    heatchill_nodes = [node for node in G.nodes() 
+    heatchill_id = find_connected_heatchill(G, vessel)
-                      if G.nodes[node].get('class') == 'virtual_heatchill']
+    if heatchill_id:
        print(f"CLEAN_VESSEL: 找到加热设备: {heatchill_id}")
    else:
        print(f"CLEAN_VESSEL: 未找到加热设备，将在室温下清洗")
-    heatchill_id = heatchill_nodes[0] if heatchill_nodes else None
+    # 第一步：如果需要加热且有加热设备，启动加热
    if temp > 25.0 and heatchill_id:
        print(f"CLEAN_VESSEL: 启动加热至 {temp}°C")
        heatchill_start_action = {
            "device_id": heatchill_id,
            "action_name": "heat_chill_start",
            "action_kwargs": {
                "vessel": vessel,
                "temp": temp,
                "purpose": f"cleaning with {solvent}"
            }
        }
        action_sequence.append(heatchill_start_action)
-    # 执行清洗操作序列
+        # 等待温度稳定
        wait_action = {
            "action_name": "wait", 
            "action_kwargs": {"time": 30}  # 等待30秒让温度稳定
        }
        action_sequence.append(wait_action)
    # 第二步：重复清洗操作
    for repeat in range(repeats):
-        # 1. 如果需要加热，先设置温度
+        print(f"CLEAN_VESSEL: 执行第 {repeat + 1} 次清洗")
        if temp > 25.0 and heatchill_id:
            action_sequence.append({
                "device_id": heatchill_id,
                "action_name": "heat_chill_start",
                "action_kwargs": {
                    "vessel": vessel,
                    "temp": temp,
                    "purpose": "cleaning"
                }
            })
-        # 2. 使用transfer操作：从溶剂容器转移清洗溶剂到目标容器
+        # 2a. 使用 pump_protocol 将溶剂转移到目标容器
-        action_sequence.append({
+        print(f"CLEAN_VESSEL: 将 {volume} mL {solvent} 转移到 {vessel}")
-            "device_id": pump_id,
+        try:
-            "action_name": "transfer",
+            # 调用成熟的 pump_protocol 算法
-            "action_kwargs": {
+            add_solvent_actions = generate_pump_protocol(
-                "from_vessel": solvent_vessel,
+                G=G,
-                "to_vessel": vessel,
+                from_vessel=solvent_vessel,
-                "volume": volume,
+                to_vessel=vessel,
-                "amount": f"cleaning with {solvent} - cycle {repeat + 1}",
+                volume=volume,
-                "time": 0.0,
+                flowrate=2.5,  # 适中的流速，避免飞溅
-                "viscous": False,
+                transfer_flowrate=2.5
-                "rinsing_solvent": "",
+            )
-                "rinsing_volume": 0.0,
+            action_sequence.extend(add_solvent_actions)
-                "rinsing_repeats": 0,
+        except Exception as e:
-                "solid": False
+            raise ValueError(f"无法将溶剂转移到容器: {str(e)}")
        # 2b. 等待清洗作用时间（让溶剂充分清洗容器）
        cleaning_wait_time = 60 if temp > 50.0 else 30  # 高温下等待更久
        print(f"CLEAN_VESSEL: 等待清洗作用 {cleaning_wait_time} 秒")
        wait_action = {
            "action_name": "wait", 
            "action_kwargs": {"time": cleaning_wait_time}
        }
        action_sequence.append(wait_action)
        # 2c. 使用 pump_protocol 将清洗液转移到废液容器
        print(f"CLEAN_VESSEL: 将清洗液从 {vessel} 转移到废液容器")
        try:
            # 调用成熟的 pump_protocol 算法
            remove_waste_actions = generate_pump_protocol(
                G=G,
                from_vessel=vessel,
                to_vessel=waste_vessel,
                volume=volume,
                flowrate=2.5,  # 适中的流速
                transfer_flowrate=2.5
            )
            action_sequence.extend(remove_waste_actions)
        except Exception as e:
            raise ValueError(f"无法将清洗液转移到废液容器: {str(e)}")
        # 2d. 清洗循环间的短暂等待
        if repeat < repeats - 1:  # 不是最后一次清洗
            print(f"CLEAN_VESSEL: 清洗循环间等待")
            wait_action = {
                "action_name": "wait", 
                "action_kwargs": {"time": 10}
            }
-        })
+            action_sequence.append(wait_action)
-        # 3. 等待清洗作用时间（可选，可以添加wait操作）
+    # 第三步：如果加热了，停止加热
-        # 这里省略wait操作，直接进行下一步
+    if temp > 25.0 and heatchill_id:
-        
+        print(f"CLEAN_VESSEL: 停止加热")
-        # 4. 将清洗后的溶剂转移到废液容器
+        heatchill_stop_action = {
-        action_sequence.append({
+            "device_id": heatchill_id,
-            "device_id": pump_id,
+            "action_name": "heat_chill_stop",
            "action_name": "transfer",
            "action_kwargs": {
-                "from_vessel": vessel,
+                "vessel": vessel
                "to_vessel": waste_vessel,
                "volume": volume,
                "amount": f"waste from cleaning {vessel} - cycle {repeat + 1}",
                "time": 0.0,
                "viscous": False,
                "rinsing_solvent": "",
                "rinsing_volume": 0.0,
                "rinsing_repeats": 0,
                "solid": False
            }
-        })
+        }
        action_sequence.append(heatchill_stop_action)
-        # 5. 如果加热了，停止加热
+    print(f"CLEAN_VESSEL: 生成了 {len(action_sequence)} 个动作")
-        if temp > 25.0 and heatchill_id:
+    print(f"CLEAN_VESSEL: 清洗协议生成完成")
            action_sequence.append({
                "device_id": heatchill_id,
                "action_name": "heat_chill_stop",
                "action_kwargs": {
                    "vessel": vessel
                }
            })
    return action_sequence
 # 便捷函数：常用清洗方案
 def generate_quick_clean_protocol(
    G: nx.DiGraph, 
    vessel: str, 
    solvent: str = "water", 
    volume: float = 100.0
 ) -> List[Dict[str, Any]]:
    """快速清洗：室温，单次清洗"""
    return generate_clean_vessel_protocol(G, vessel, solvent, volume, 25.0, 1)
 def generate_thorough_clean_protocol(
    G: nx.DiGraph, 
    vessel: str, 
    solvent: str = "water", 
    volume: float = 150.0,
    temp: float = 60.0
 ) -> List[Dict[str, Any]]:
    """深度清洗：加热，多次清洗"""
    return generate_clean_vessel_protocol(G, vessel, solvent, volume, temp, 3)
 def generate_organic_clean_protocol(
    G: nx.DiGraph, 
    vessel: str, 
    volume: float = 100.0
 ) -> List[Dict[str, Any]]:
    """有机清洗：先用有机溶剂，再用水清洗"""
    action_sequence = []
    # 第一步：有机溶剂清洗
    try:
        organic_actions = generate_clean_vessel_protocol(
            G, vessel, "acetone", volume, 25.0, 2
        )
        action_sequence.extend(organic_actions)
    except ValueError:
        # 如果没有丙酮，尝试乙醇
        try:
            organic_actions = generate_clean_vessel_protocol(
                G, vessel, "ethanol", volume, 25.0, 2
            )
            action_sequence.extend(organic_actions)
        except ValueError:
            print("警告：未找到有机溶剂，跳过有机清洗步骤")
    # 第二步：水清洗
    water_actions = generate_clean_vessel_protocol(
        G, vessel, "water", volume, 25.0, 2
    )
    action_sequence.extend(water_actions)
    return action_sequence
 def get_vessel_liquid_volume(G: nx.DiGraph, vessel: str) -> float:
    """获取容器中的液体体积（修复版）"""
    if vessel not in G.nodes():
        return 0.0
    vessel_data = G.nodes[vessel].get('data', {})
    liquids = vessel_data.get('liquid', [])
    total_volume = 0.0
    for liquid in liquids:
        if isinstance(liquid, dict):
            # 支持两种格式：新格式 (name, volume) 和旧格式 (liquid_type, liquid_volume)
            volume = liquid.get('volume') or liquid.get('liquid_volume', 0.0)
            total_volume += volume
    return total_volume
 def get_vessel_liquid_types(G: nx.DiGraph, vessel: str) -> List[str]:
    """获取容器中所有液体的类型"""
    if vessel not in G.nodes():
        return []
    vessel_data = G.nodes[vessel].get('data', {})
    liquids = vessel_data.get('liquid', [])
    liquid_types = []
    for liquid in liquids:
        if isinstance(liquid, dict):
            # 支持两种格式的液体类型字段
            liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
            if liquid_type:
                liquid_types.append(liquid_type)
    return liquid_types
 def find_vessel_by_content(G: nx.DiGraph, content: str) -> List[str]:
    """
    根据内容物查找所有匹配的容器
    返回匹配容器的ID列表
    """
    matching_vessels = []
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            # 检查容器名称匹配
            node_name = G.nodes[node_id].get('name', '').lower()
            if content.lower() in node_id.lower() or content.lower() in node_name:
                matching_vessels.append(node_id)
                continue
            # 检查液体类型匹配
            vessel_data = G.nodes[node_id].get('data', {})
            liquids = vessel_data.get('liquid', [])
            config_data = G.nodes[node_id].get('config', {})
            # 检查 reagent_name 和 config.reagent
            reagent_name = vessel_data.get('reagent_name', '').lower()
            config_reagent = config_data.get('reagent', '').lower()
            if (content.lower() == reagent_name or 
                content.lower() == config_reagent):
                matching_vessels.append(node_id)
                continue
            # 检查液体列表
            for liquid in liquids:
                if isinstance(liquid, dict):
                    liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
                    if liquid_type.lower() == content.lower():
                        matching_vessels.append(node_id)
                        break
    return matching_vessels
--- a/unilabos/compile/dissolve_protocol.py
+++ b/unilabos/compile/dissolve_protocol.py
--- a/unilabos/compile/dry_protocol.py
+++ b/unilabos/compile/dry_protocol.py
@@ -0,0 +1,185 @@
 import networkx as nx
 from typing import List, Dict, Any
 def find_connected_heater(G: nx.DiGraph, vessel: str) -> str:
    """
    查找与容器相连的加热器
    Args:
        G: 网络图
        vessel: 容器名称
    Returns:
        str: 加热器ID，如果没有则返回None
    """
    print(f"DRY: 正在查找与容器 '{vessel}' 相连的加热器...")
    # 查找所有加热器节点
    heater_nodes = [node for node in G.nodes() 
                   if ('heater' in node.lower() or 
                       'heat' in node.lower() or
                       G.nodes[node].get('class') == 'virtual_heatchill' or
                       G.nodes[node].get('type') == 'heater')]
    print(f"DRY: 找到的加热器节点: {heater_nodes}")
    # 检查是否有加热器与目标容器相连
    for heater in heater_nodes:
        if G.has_edge(heater, vessel) or G.has_edge(vessel, heater):
            print(f"DRY: 找到与容器 '{vessel}' 相连的加热器: {heater}")
            return heater
    # 如果没有直接连接，查找距离最近的加热器
    for heater in heater_nodes:
        try:
            path = nx.shortest_path(G, source=heater, target=vessel)
            if len(path) <= 3:  # 最多2个中间节点
                print(f"DRY: 找到距离较近的加热器: {heater}, 路径: {' → '.join(path)}")
                return heater
        except nx.NetworkXNoPath:
            continue
    print(f"DRY: 未找到与容器 '{vessel}' 相连的加热器")
    return None
 def generate_dry_protocol(
    G: nx.DiGraph,
    compound: str,
    vessel: str,
    **kwargs  # 接收其他可能的参数但不使用
 ) -> List[Dict[str, Any]]:
    """
    生成干燥协议序列
    Args:
        G: 有向图，节点为容器和设备
        compound: 化合物名称（从XDL传入）
        vessel: 目标容器（从XDL传入）
        **kwargs: 其他可选参数，但不使用
    Returns:
        List[Dict[str, Any]]: 动作序列
    """
    action_sequence = []
    # 默认参数
    dry_temp = 60.0  # 默认干燥温度 60°C
    dry_time = 3600.0  # 默认干燥时间 1小时（3600秒）
    simulation_time = 60.0  # 模拟时间 1分钟
    print(f"🌡️ DRY: 开始生成干燥协议 ✨")
    print(f"  🧪 化合物: {compound}")
    print(f"  🥽 容器: {vessel}")
    print(f"  🔥 干燥温度: {dry_temp}°C")
    print(f"  ⏰ 干燥时间: {dry_time/60:.0f} 分钟")
    # 1. 验证目标容器存在
    print(f"\n📋 步骤1: 验证目标容器 '{vessel}' 是否存在...")
    if vessel not in G.nodes():
        print(f"⚠️ DRY: 警告 - 容器 '{vessel}' 不存在于系统中，跳过干燥 😢")
        return action_sequence
    print(f"✅ 容器 '{vessel}' 验证通过!")
    # 2. 查找相连的加热器
    print(f"\n🔍 步骤2: 查找与容器相连的加热器...")
    heater_id = find_connected_heater(G, vessel)
    if heater_id is None:
        print(f"😭 DRY: 警告 - 未找到与容器 '{vessel}' 相连的加热器，跳过干燥")
        print(f"🎭 添加模拟干燥动作...")
        # 添加一个等待动作，表示干燥过程（模拟）
        action_sequence.append({
            "action_name": "wait",
            "action_kwargs": {
                "time": 10.0,  # 模拟等待时间
                "description": f"模拟干燥 {compound} (无加热器可用)"
            }
        })
        print(f"📄 DRY: 协议生成完成，共 {len(action_sequence)} 个动作 🎯")
        return action_sequence
    print(f"🎉 找到加热器: {heater_id}!")
    # 3. 启动加热器进行干燥
    print(f"\n🚀 步骤3: 开始执行干燥流程...")
    print(f"🔥 启动加热器 {heater_id} 进行干燥")
    # 3.1 启动加热
    print(f"  ⚡ 动作1: 启动加热到 {dry_temp}°C...")
    action_sequence.append({
        "device_id": heater_id,
        "action_name": "heat_chill_start",
        "action_kwargs": {
            "vessel": vessel,
            "temp": dry_temp,
            "purpose": f"干燥 {compound}"
        }
    })
    print(f"  ✅ 加热器启动命令已添加 🔥")
    # 3.2 等待温度稳定
    print(f"  ⏳ 动作2: 等待温度稳定...")
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": 10.0,
            "description": f"等待温度稳定到 {dry_temp}°C"
        }
    })
    print(f"  ✅ 温度稳定等待命令已添加 🌡️")
    # 3.3 保持干燥温度
    print(f"  🔄 动作3: 保持干燥温度 {simulation_time/60:.0f} 分钟...")
    action_sequence.append({
        "device_id": heater_id,
        "action_name": "heat_chill",
        "action_kwargs": {
            "vessel": vessel,
            "temp": dry_temp,
            "time": simulation_time,
            "purpose": f"干燥 {compound}，保持温度 {dry_temp}°C"
        }
    })
    print(f"  ✅ 温度保持命令已添加 🌡️⏰")
    # 3.4 停止加热
    print(f"  ⏹️ 动作4: 停止加热...")
    action_sequence.append({
        "device_id": heater_id,
        "action_name": "heat_chill_stop",
        "action_kwargs": {
            "vessel": vessel,
            "purpose": f"干燥完成，停止加热"
        }
    })
    print(f"  ✅ 停止加热命令已添加 🛑")
    # 3.5 等待冷却
    print(f"  ❄️ 动作5: 等待冷却...")
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": 10.0,  # 等待10秒冷却
            "description": f"等待 {compound} 冷却"
        }
    })
    print(f"  ✅ 冷却等待命令已添加 🧊")
    print(f"\n🎊 DRY: 协议生成完成，共 {len(action_sequence)} 个动作 🎯")
    print(f"⏱️ DRY: 预计总时间: {(dry_time + 360)/60:.0f} 分钟 ⌛")
    print(f"🏁 所有动作序列准备就绪! ✨")
    return action_sequence
 # 测试函数
 def test_dry_protocol():
    """测试干燥协议"""
    print("=== DRY PROTOCOL 测试 ===")
    print("测试完成")
 if __name__ == "__main__":
    test_dry_protocol()
--- a/unilabos/compile/evacuateandrefill_protocol.py
+++ b/unilabos/compile/evacuateandrefill_protocol.py
@@ -1,143 +1,772 @@
 import numpy as np
 import networkx as nx
 import logging
 import uuid
 import sys
 from typing import List, Dict, Any, Optional
 from .pump_protocol import generate_pump_protocol_with_rinsing, generate_pump_protocol
 # 设置日志
 logger = logging.getLogger(__name__)
 # 确保输出编码为UTF-8
 if hasattr(sys.stdout, 'reconfigure'):
    try:
        sys.stdout.reconfigure(encoding='utf-8')
        sys.stderr.reconfigure(encoding='utf-8')
    except:
        pass
 def debug_print(message):
    """调试输出函数 - 支持中文"""
    try:
        # 确保消息是字符串格式
        safe_message = str(message)
        print(f"[抽真空充气] {safe_message}", flush=True)
        logger.info(f"[抽真空充气] {safe_message}")
    except UnicodeEncodeError:
        # 如果编码失败，尝试替换不支持的字符
        safe_message = str(message).encode('utf-8', errors='replace').decode('utf-8')
        print(f"[抽真空充气] {safe_message}", flush=True)
        logger.info(f"[抽真空充气] {safe_message}")
    except Exception as e:
        # 最后的安全措施
        fallback_message = f"日志输出错误: {repr(message)}"
        print(f"[抽真空充气] {fallback_message}", flush=True)
        logger.info(f"[抽真空充气] {fallback_message}")
 def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
    """创建一个动作日志 - 支持中文和emoji"""
    try:
        full_message = f"{emoji} {message}"
        debug_print(full_message)
        logger.info(full_message)
        return {
            "action_name": "wait",
            "action_kwargs": {
                "time": 0.1,
                "log_message": full_message,
                "progress_message": full_message
            }
        }
    except Exception as e:
        # 如果emoji有问题，使用纯文本
        safe_message = f"[日志] {message}"
        debug_print(safe_message)
        logger.info(safe_message)
        return {
            "action_name": "wait", 
            "action_kwargs": {
                "time": 0.1,
                "log_message": safe_message,
                "progress_message": safe_message
            }
        }
 def find_gas_source(G: nx.DiGraph, gas: str) -> str:
    """
    根据气体名称查找对应的气源，支持多种匹配模式：
    1. 容器名称匹配
    2. 气体类型匹配（data.gas_type）
    3. 默认气源
    """
    debug_print(f"🔍 正在查找气体 '{gas}' 的气源...")
    # 第一步：通过容器名称匹配
    debug_print(f"📋 方法1: 容器名称匹配...")
    gas_source_patterns = [
        f"gas_source_{gas}",
        f"gas_{gas}",
        f"flask_{gas}",
        f"{gas}_source",
        f"source_{gas}",
        f"reagent_bottle_{gas}",
        f"bottle_{gas}"
    ]
    debug_print(f"🎯 尝试的容器名称: {gas_source_patterns}")
    for pattern in gas_source_patterns:
        if pattern in G.nodes():
            debug_print(f"✅ 通过名称找到气源: {pattern}")
            return pattern
    # 第二步：通过气体类型匹配 (data.gas_type)
    debug_print(f"📋 方法2: 气体类型匹配...")
    for node_id in G.nodes():
        node_data = G.nodes[node_id]
        node_class = node_data.get('class', '') or ''
        # 检查是否是气源设备
        if ('gas_source' in node_class or 
            'gas' in node_id.lower() or 
            node_id.startswith('flask_')):
            # 检查 data.gas_type
            data = node_data.get('data', {})
            gas_type = data.get('gas_type', '')
            if gas_type.lower() == gas.lower():
                debug_print(f"✅ 通过气体类型找到气源: {node_id} (气体类型: {gas_type})")
                return node_id
            # 检查 config.gas_type  
            config = node_data.get('config', {})
            config_gas_type = config.get('gas_type', '')
            if config_gas_type.lower() == gas.lower():
                debug_print(f"✅ 通过配置气体类型找到气源: {node_id} (配置气体类型: {config_gas_type})")
                return node_id
    # 第三步：查找所有可用的气源设备
    debug_print(f"📋 方法3: 查找可用气源...")
    available_gas_sources = []
    for node_id in G.nodes():
        node_data = G.nodes[node_id]
        node_class = node_data.get('class', '') or ''
        if ('gas_source' in node_class or 
            'gas' in node_id.lower() or
            (node_id.startswith('flask_') and any(g in node_id.lower() for g in ['air', 'nitrogen', 'argon']))):
            data = node_data.get('data', {})
            gas_type = data.get('gas_type', '未知')
            available_gas_sources.append(f"{node_id} (气体类型: {gas_type})")
    debug_print(f"📊 可用气源: {available_gas_sources}")
    # 第四步：如果找不到特定气体，使用默认的第一个气源
    debug_print(f"📋 方法4: 查找默认气源...")
    default_gas_sources = [
        node for node in G.nodes() 
        if ((G.nodes[node].get('class') or '').find('virtual_gas_source') != -1
            or 'gas_source' in node)
    ]
    if default_gas_sources:
        default_source = default_gas_sources[0]
        debug_print(f"⚠️ 未找到特定气体 '{gas}'，使用默认气源: {default_source}")
        return default_source
    debug_print(f"❌ 所有方法都失败了！")
    raise ValueError(f"无法找到气体 '{gas}' 的气源。可用气源: {available_gas_sources}")
 def find_vacuum_pump(G: nx.DiGraph) -> str:
    """查找真空泵设备"""
    debug_print("🔍 正在查找真空泵...")
    vacuum_pumps = []
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if ('virtual_vacuum_pump' in node_class or 
            'vacuum_pump' in node.lower() or 
            'vacuum' in node_class.lower()):
            vacuum_pumps.append(node)
            debug_print(f"📋 发现真空泵: {node}")
    if not vacuum_pumps:
        debug_print(f"❌ 系统中未找到真空泵")
        raise ValueError("系统中未找到真空泵")
    debug_print(f"✅ 使用真空泵: {vacuum_pumps[0]}")
    return vacuum_pumps[0]
 def find_connected_stirrer(G: nx.DiGraph, vessel: str) -> Optional[str]:
    """查找与指定容器相连的搅拌器"""
    debug_print(f"🔍 正在查找与容器 {vessel} 连接的搅拌器...")
    stirrer_nodes = []
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if 'virtual_stirrer' in node_class or 'stirrer' in node.lower():
            stirrer_nodes.append(node)
            debug_print(f"📋 发现搅拌器: {node}")
    debug_print(f"📊 找到的搅拌器总数: {len(stirrer_nodes)}")
    # 检查哪个搅拌器与目标容器相连
    for stirrer in stirrer_nodes:
        if G.has_edge(stirrer, vessel) or G.has_edge(vessel, stirrer):
            debug_print(f"✅ 找到连接的搅拌器: {stirrer}")
            return stirrer
    # 如果没有连接的搅拌器，返回第一个可用的
    if stirrer_nodes:
        debug_print(f"⚠️ 未找到直接连接的搅拌器，使用第一个可用的: {stirrer_nodes[0]}")
        return stirrer_nodes[0]
    debug_print("❌ 未找到搅拌器")
    return None
 def find_vacuum_solenoid_valve(G: nx.DiGraph, vacuum_pump: str) -> Optional[str]:
    """查找真空泵相关的电磁阀"""
    debug_print(f"🔍 正在查找真空泵 {vacuum_pump} 的电磁阀...")
    # 查找所有电磁阀
    solenoid_valves = []
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if ('solenoid' in node_class.lower() or 'solenoid_valve' in node.lower()):
            solenoid_valves.append(node)
            debug_print(f"📋 发现电磁阀: {node}")
    debug_print(f"📊 找到的电磁阀: {solenoid_valves}")
    # 检查连接关系
    debug_print(f"📋 方法1: 检查连接关系...")
    for solenoid in solenoid_valves:
        if G.has_edge(solenoid, vacuum_pump) or G.has_edge(vacuum_pump, solenoid):
            debug_print(f"✅ 找到连接的真空电磁阀: {solenoid}")
            return solenoid
    # 通过命名规则查找
    debug_print(f"📋 方法2: 检查命名规则...")
    for solenoid in solenoid_valves:
        if 'vacuum' in solenoid.lower() or solenoid == 'solenoid_valve_1':
            debug_print(f"✅ 通过命名找到真空电磁阀: {solenoid}")
            return solenoid
    debug_print("⚠️ 未找到真空电磁阀")
    return None
 def find_gas_solenoid_valve(G: nx.DiGraph, gas_source: str) -> Optional[str]:
    """查找气源相关的电磁阀"""
    debug_print(f"🔍 正在查找气源 {gas_source} 的电磁阀...")
    # 查找所有电磁阀
    solenoid_valves = []
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if ('solenoid' in node_class.lower() or 'solenoid_valve' in node.lower()):
            solenoid_valves.append(node)
    debug_print(f"📊 找到的电磁阀: {solenoid_valves}")
    # 检查连接关系
    debug_print(f"📋 方法1: 检查连接关系...")
    for solenoid in solenoid_valves:
        if G.has_edge(gas_source, solenoid) or G.has_edge(solenoid, gas_source):
            debug_print(f"✅ 找到连接的气源电磁阀: {solenoid}")
            return solenoid
    # 通过命名规则查找
    debug_print(f"📋 方法2: 检查命名规则...")
    for solenoid in solenoid_valves:
        if 'gas' in solenoid.lower() or solenoid == 'solenoid_valve_2':
            debug_print(f"✅ 通过命名找到气源电磁阀: {solenoid}")
            return solenoid
    debug_print("⚠️ 未找到气源电磁阀")
    return None
 def generate_evacuateandrefill_protocol(
    G: nx.DiGraph,
    vessel: str,
    gas: str,
-    repeats: int = 1
+    **kwargs
-) -> list[dict]:
+) -> List[Dict[str, Any]]:
    """
-    生成泵操作的动作序列。
+    生成抽真空和充气操作的动作序列 - 中文版
-    :param G: 有向图, 节点为容器和注射泵, 边为流体管道, A→B边的属性为管道接A端的阀门位置
+    Args:
-    :param from_vessel: 容器A
+        G: 设备图
-    :param to_vessel: 容器B
+        vessel: 目标容器名称（必需）
-    :param volume: 转移的体积
+        gas: 气体名称（必需）  
-    :param flowrate: 最终注入容器B时的流速
+        **kwargs: 其他参数（兼容性）
-    :param transfer_flowrate: 泵骨架中转移流速（若不指定，默认与注入流速相同）
+    
-    :return: 泵操作的动作序列
+    Returns:
        List[Dict[str, Any]]: 动作序列
    """
-    # 生成电磁阀、真空泵、气源操作的动作序列
+    # 硬编码重复次数为 3
-    vacuum_action_sequence = []
+    repeats = 3
    nodes = G.nodes(data=True)
-    # 找到和 vessel 相连的电磁阀和真空泵、气源
+    # 生成协议ID
-    vacuum_backbone = {"vessel": vessel}
+    protocol_id = str(uuid.uuid4())
    debug_print(f"🆔 生成协议ID: {protocol_id}")
-    for neighbor in G.neighbors(vessel):
+    debug_print("=" * 60)
-        if nodes[neighbor]["class"].startswith("solenoid_valve"):
+    debug_print("🧪 开始生成抽真空充气协议")
-            for neighbor2 in G.neighbors(neighbor):
+    debug_print(f"📋 原始参数:")
-                if neighbor2 == vessel:
+    debug_print(f"  🥼 容器: '{vessel}'")
-                    continue
+    debug_print(f"  💨 气体: '{gas}'")
-                if nodes[neighbor2]["class"].startswith("vacuum_pump"):
+    debug_print(f"  🔄 循环次数: {repeats} (硬编码)")
-                    vacuum_backbone.update({"vacuum_valve": neighbor, "pump": neighbor2})
+    debug_print(f"  📦 其他参数: {kwargs}")
-                    break
+    debug_print("=" * 60)
                elif nodes[neighbor2]["class"].startswith("gas_source"):
                    vacuum_backbone.update({"gas_valve": neighbor, "gas": neighbor2})
                    break
    # 判断是否设备齐全
    if len(vacuum_backbone) < 5:
        print(f"\n\n\n{vacuum_backbone}\n\n\n")
        raise ValueError("Not all devices are connected to the vessel.")
-    # 生成操作的动作序列
+    action_sequence = []
-    for i in range(repeats):
+    
-        # 打开真空泵阀门、关闭气源阀门
+    # === 参数验证和修正 ===
-        vacuum_action_sequence.append([
+    debug_print("🔍 步骤1: 参数验证和修正...")
-            {
+    action_sequence.append(create_action_log(f"开始抽真空充气操作 - 容器: {vessel}", "🎬"))
-                "device_id": vacuum_backbone["vacuum_valve"],
+    action_sequence.append(create_action_log(f"目标气体: {gas}", "💨"))
-                "action_name": "set_valve_position",
+    action_sequence.append(create_action_log(f"循环次数: {repeats}", "🔄"))
-                "action_kwargs": {
+    
-                    "command": "OPEN"
+    # 验证必需参数
-                }
+    if not vessel:
-            },
+        debug_print("❌ 容器参数不能为空")
-            {
+        raise ValueError("容器参数不能为空")
-                "device_id": vacuum_backbone["gas_valve"],
+    
-                "action_name": "set_valve_position",
+    if not gas:
-                "action_kwargs": {
+        debug_print("❌ 气体参数不能为空")
-                    "command": "CLOSED"
+        raise ValueError("气体参数不能为空")
-                }
+    
    if vessel not in G.nodes():
        debug_print(f"❌ 容器 '{vessel}' 在系统中不存在")
        raise ValueError(f"容器 '{vessel}' 在系统中不存在")
    debug_print("✅ 基本参数验证通过")
    action_sequence.append(create_action_log("参数验证通过", "✅"))
    # 标准化气体名称
    debug_print("🔧 标准化气体名称...")
    gas_aliases = {
        'n2': 'nitrogen',
        'ar': 'argon',
        'air': 'air',
        'o2': 'oxygen',
        'co2': 'carbon_dioxide',
        'h2': 'hydrogen',
        '氮气': 'nitrogen',
        '氩气': 'argon',
        '空气': 'air',
        '氧气': 'oxygen',
        '二氧化碳': 'carbon_dioxide',
        '氢气': 'hydrogen'
    }
    original_gas = gas
    gas_lower = gas.lower().strip()
    if gas_lower in gas_aliases:
        gas = gas_aliases[gas_lower]
        debug_print(f"🔄 标准化气体名称: {original_gas} -> {gas}")
        action_sequence.append(create_action_log(f"气体名称标准化: {original_gas} -> {gas}", "🔄"))
    debug_print(f"📋 最终参数: 容器={vessel}, 气体={gas}, 重复={repeats}")
    # === 查找设备 ===
    debug_print("🔍 步骤2: 查找设备...")
    action_sequence.append(create_action_log("正在查找相关设备...", "🔍"))
    try:
        vacuum_pump = find_vacuum_pump(G)
        action_sequence.append(create_action_log(f"找到真空泵: {vacuum_pump}", "🌪️"))
        gas_source = find_gas_source(G, gas)
        action_sequence.append(create_action_log(f"找到气源: {gas_source}", "💨"))
        vacuum_solenoid = find_vacuum_solenoid_valve(G, vacuum_pump)
        if vacuum_solenoid:
            action_sequence.append(create_action_log(f"找到真空电磁阀: {vacuum_solenoid}", "🚪"))
        else:
            action_sequence.append(create_action_log("未找到真空电磁阀", "⚠️"))
        gas_solenoid = find_gas_solenoid_valve(G, gas_source)
        if gas_solenoid:
            action_sequence.append(create_action_log(f"找到气源电磁阀: {gas_solenoid}", "🚪"))
        else:
            action_sequence.append(create_action_log("未找到气源电磁阀", "⚠️"))
        stirrer_id = find_connected_stirrer(G, vessel)
        if stirrer_id:
            action_sequence.append(create_action_log(f"找到搅拌器: {stirrer_id}", "🌪️"))
        else:
            action_sequence.append(create_action_log("未找到搅拌器", "⚠️"))
        debug_print(f"📊 设备配置:")
        debug_print(f"  🌪️ 真空泵: {vacuum_pump}")
        debug_print(f"  💨 气源: {gas_source}")
        debug_print(f"  🚪 真空电磁阀: {vacuum_solenoid}")
        debug_print(f"  🚪 气源电磁阀: {gas_solenoid}")
        debug_print(f"  🌪️ 搅拌器: {stirrer_id}")
    except Exception as e:
        debug_print(f"❌ 设备查找失败: {str(e)}")
        action_sequence.append(create_action_log(f"设备查找失败: {str(e)}", "❌"))
        raise ValueError(f"设备查找失败: {str(e)}")
    # === 参数设置 ===
    debug_print("🔍 步骤3: 参数设置...")
    action_sequence.append(create_action_log("设置操作参数...", "⚙️"))
    # 根据气体类型调整参数
    if gas.lower() in ['nitrogen', 'argon']:
        VACUUM_VOLUME = 25.0
        REFILL_VOLUME = 25.0
        PUMP_FLOW_RATE = 2.0
        VACUUM_TIME = 30.0
        REFILL_TIME = 20.0
        debug_print("💨 惰性气体: 使用标准参数")
        action_sequence.append(create_action_log("检测到惰性气体，使用标准参数", "💨"))
    elif gas.lower() in ['air', 'oxygen']:
        VACUUM_VOLUME = 20.0
        REFILL_VOLUME = 20.0
        PUMP_FLOW_RATE = 1.5
        VACUUM_TIME = 45.0
        REFILL_TIME = 25.0
        debug_print("🔥 活性气体: 使用保守参数")
        action_sequence.append(create_action_log("检测到活性气体，使用保守参数", "🔥"))
    else:
        VACUUM_VOLUME = 15.0
        REFILL_VOLUME = 15.0
        PUMP_FLOW_RATE = 1.0
        VACUUM_TIME = 60.0
        REFILL_TIME = 30.0
        debug_print("❓ 未知气体: 使用安全参数")
        action_sequence.append(create_action_log("未知气体类型，使用安全参数", "❓"))
    STIR_SPEED = 200.0
    debug_print(f"⚙️ 操作参数:")
    debug_print(f"  📏 真空体积: {VACUUM_VOLUME}mL")
    debug_print(f"  📏 充气体积: {REFILL_VOLUME}mL")
    debug_print(f"  ⚡ 泵流速: {PUMP_FLOW_RATE}mL/s")
    debug_print(f"  ⏱️ 真空时间: {VACUUM_TIME}s")
    debug_print(f"  ⏱️ 充气时间: {REFILL_TIME}s")
    debug_print(f"  🌪️ 搅拌速度: {STIR_SPEED}RPM")
    action_sequence.append(create_action_log(f"真空体积: {VACUUM_VOLUME}mL", "📏"))
    action_sequence.append(create_action_log(f"充气体积: {REFILL_VOLUME}mL", "📏"))
    action_sequence.append(create_action_log(f"泵流速: {PUMP_FLOW_RATE}mL/s", "⚡"))
    # === 路径验证 ===
    debug_print("🔍 步骤4: 路径验证...")
    action_sequence.append(create_action_log("验证传输路径...", "🛤️"))
    try:
        # 验证抽真空路径
        if nx.has_path(G, vessel, vacuum_pump):
            vacuum_path = nx.shortest_path(G, source=vessel, target=vacuum_pump)
            debug_print(f"✅ 真空路径: {' -> '.join(vacuum_path)}")
            action_sequence.append(create_action_log(f"真空路径: {' -> '.join(vacuum_path)}", "🛤️"))
        else:
            debug_print(f"⚠️ 真空路径不存在，继续执行但可能有问题")
            action_sequence.append(create_action_log("真空路径检查: 路径不存在", "⚠️"))
        # 验证充气路径
        if nx.has_path(G, gas_source, vessel):
            gas_path = nx.shortest_path(G, source=gas_source, target=vessel)
            debug_print(f"✅ 气体路径: {' -> '.join(gas_path)}")
            action_sequence.append(create_action_log(f"气体路径: {' -> '.join(gas_path)}", "🛤️"))
        else:
            debug_print(f"⚠️ 气体路径不存在，继续执行但可能有问题")
            action_sequence.append(create_action_log("气体路径检查: 路径不存在", "⚠️"))
    except Exception as e:
        debug_print(f"⚠️ 路径验证失败: {str(e)}，继续执行")
        action_sequence.append(create_action_log(f"路径验证失败: {str(e)}", "⚠️"))
    # === 启动搅拌器 ===
    debug_print("🔍 步骤5: 启动搅拌器...")
    if stirrer_id:
        debug_print(f"🌪️ 启动搅拌器: {stirrer_id}")
        action_sequence.append(create_action_log(f"启动搅拌器 {stirrer_id} (速度: {STIR_SPEED}rpm)", "🌪️"))
        action_sequence.append({
            "device_id": stirrer_id,
            "action_name": "start_stir",
            "action_kwargs": {
                "vessel": vessel,
                "stir_speed": STIR_SPEED,
                "purpose": "抽真空充气前预搅拌"
            }
-        ])
+        })
-        # 打开真空泵、关闭气源
+        # 等待搅拌稳定
-        vacuum_action_sequence.append([
+        action_sequence.append(create_action_log("等待搅拌稳定...", "⏳"))
-            {
+        action_sequence.append({
-                "device_id": vacuum_backbone["pump"],
+            "action_name": "wait",
-                "action_name": "set_status",
+            "action_kwargs": {"time": 5.0}
-                "action_kwargs": {
+        })
-                    "string": "ON"
+    else:
-                }
+        debug_print("⚠️ 未找到搅拌器，跳过搅拌器启动")
-            },
+        action_sequence.append(create_action_log("跳过搅拌器启动", "⏭️"))
            {
                "device_id": vacuum_backbone["gas"],
                "action_name": "set_status",
                "action_kwargs": {
                    "string": "OFF"
                }
            }
        ])
        vacuum_action_sequence.append({"action_name": "wait", "action_kwargs": {"time": 60}})
-        # 关闭真空泵阀门、打开气源阀门
+    # === 执行循环 ===
-        vacuum_action_sequence.append([
+    debug_print("🔍 步骤6: 执行抽真空-充气循环...")
-            {
+    action_sequence.append(create_action_log(f"开始 {repeats} 次抽真空-充气循环", "🔄"))
-                "device_id": vacuum_backbone["vacuum_valve"],
+    
    for cycle in range(repeats):
        debug_print(f"=== 第 {cycle+1}/{repeats} 轮循环 ===")
        action_sequence.append(create_action_log(f"第 {cycle+1}/{repeats} 轮循环开始", "🚀"))
        # ============ 抽真空阶段 ============
        debug_print(f"🌪️ 抽真空阶段开始")
        action_sequence.append(create_action_log("开始抽真空阶段", "🌪️"))
        # 启动真空泵
        debug_print(f"🔛 启动真空泵: {vacuum_pump}")
        action_sequence.append(create_action_log(f"启动真空泵: {vacuum_pump}", "🔛"))
        action_sequence.append({
            "device_id": vacuum_pump,
            "action_name": "set_status",
            "action_kwargs": {"string": "ON"}
        })
        # 开启真空电磁阀
        if vacuum_solenoid:
            debug_print(f"🚪 打开真空电磁阀: {vacuum_solenoid}")
            action_sequence.append(create_action_log(f"打开真空电磁阀: {vacuum_solenoid}", "🚪"))
            action_sequence.append({
                "device_id": vacuum_solenoid,
                "action_name": "set_valve_position",
-                "action_kwargs": {
+                "action_kwargs": {"command": "OPEN"}
-                    "command": "CLOSED"
+            })
                }
            },
            {
                "device_id": vacuum_backbone["gas_valve"],
                "action_name": "set_valve_position",
                "action_kwargs": {
                    "command": "OPEN"
                }
            }
        ])
-        # 关闭真空泵、打开气源
+        # 抽真空操作
-        vacuum_action_sequence.append([
+        debug_print(f"🌪️ 抽真空操作: {vessel} -> {vacuum_pump}")
-            {
+        action_sequence.append(create_action_log(f"开始抽真空: {vessel} -> {vacuum_pump}", "🌪️"))
-                "device_id": vacuum_backbone["pump"],
+        
-                "action_name": "set_status",
+        try:
-                "action_kwargs": {
+            vacuum_transfer_actions = generate_pump_protocol_with_rinsing(
-                    "string": "OFF"
+                G=G,
-                }
+                from_vessel=vessel,
-            },
+                to_vessel=vacuum_pump,
-            {
+                volume=VACUUM_VOLUME,
-                "device_id": vacuum_backbone["gas"],
+                amount="",
-                "action_name": "set_status",
+                time=0.0,
-                "action_kwargs": {
+                viscous=False,
-                    "string": "ON"
+                rinsing_solvent="",
-                }
+                rinsing_volume=0.0,
-            }
+                rinsing_repeats=0,
-        ])
+                solid=False,
-        vacuum_action_sequence.append({"action_name": "wait", "action_kwargs": {"time": 60}})
+                flowrate=PUMP_FLOW_RATE,
                transfer_flowrate=PUMP_FLOW_RATE
            )
            if vacuum_transfer_actions:
                action_sequence.extend(vacuum_transfer_actions)
                debug_print(f"✅ 添加了 {len(vacuum_transfer_actions)} 个抽真空动作")
                action_sequence.append(create_action_log(f"抽真空协议完成 ({len(vacuum_transfer_actions)} 个操作)", "✅"))
            else:
                debug_print("⚠️ 抽真空协议返回空序列，添加手动动作")
                action_sequence.append(create_action_log("抽真空协议为空，使用手动等待", "⚠️"))
                action_sequence.append({
                    "action_name": "wait",
                    "action_kwargs": {"time": VACUUM_TIME}
                })
        except Exception as e:
            debug_print(f"❌ 抽真空失败: {str(e)}")
            action_sequence.append(create_action_log(f"抽真空失败: {str(e)}", "❌"))
            action_sequence.append({
                "action_name": "wait",
                "action_kwargs": {"time": VACUUM_TIME}
            })
        # 抽真空后等待
        wait_minutes = VACUUM_TIME / 60
        action_sequence.append(create_action_log(f"抽真空后等待 ({wait_minutes:.1f} 分钟)", "⏳"))
        action_sequence.append({
            "action_name": "wait",
            "action_kwargs": {"time": VACUUM_TIME}
        })
        # 关闭真空电磁阀
        if vacuum_solenoid:
            debug_print(f"🚪 关闭真空电磁阀: {vacuum_solenoid}")
            action_sequence.append(create_action_log(f"关闭真空电磁阀: {vacuum_solenoid}", "🚪"))
            action_sequence.append({
                "device_id": vacuum_solenoid,
                "action_name": "set_valve_position",
                "action_kwargs": {"command": "CLOSED"}
            })
        # 关闭真空泵
        debug_print(f"🔴 停止真空泵: {vacuum_pump}")
        action_sequence.append(create_action_log(f"停止真空泵: {vacuum_pump}", "🔴"))
        action_sequence.append({
            "device_id": vacuum_pump,
            "action_name": "set_status",
            "action_kwargs": {"string": "OFF"}
        })
        # 阶段间等待
        action_sequence.append(create_action_log("抽真空阶段完成，短暂等待", "⏳"))
        action_sequence.append({
            "action_name": "wait",
            "action_kwargs": {"time": 5.0}
        })
        # ============ 充气阶段 ============
        debug_print(f"💨 充气阶段开始")
        action_sequence.append(create_action_log("开始气体充气阶段", "💨"))
        # 启动气源
        debug_print(f"🔛 启动气源: {gas_source}")
        action_sequence.append(create_action_log(f"启动气源: {gas_source}", "🔛"))
        action_sequence.append({
            "device_id": gas_source,
            "action_name": "set_status",
            "action_kwargs": {"string": "ON"}
        })
        # 开启气源电磁阀
        if gas_solenoid:
            debug_print(f"🚪 打开气源电磁阀: {gas_solenoid}")
            action_sequence.append(create_action_log(f"打开气源电磁阀: {gas_solenoid}", "🚪"))
            action_sequence.append({
                "device_id": gas_solenoid,
                "action_name": "set_valve_position",
                "action_kwargs": {"command": "OPEN"}
            })
        # 充气操作
        debug_print(f"💨 充气操作: {gas_source} -> {vessel}")
        action_sequence.append(create_action_log(f"开始气体充气: {gas_source} -> {vessel}", "💨"))
        try:
            gas_transfer_actions = generate_pump_protocol_with_rinsing(
                G=G,
                from_vessel=gas_source,
                to_vessel=vessel,
                volume=REFILL_VOLUME,
                amount="",
                time=0.0,
                viscous=False,
                rinsing_solvent="",
                rinsing_volume=0.0,
                rinsing_repeats=0,
                solid=False,
                flowrate=PUMP_FLOW_RATE,
                transfer_flowrate=PUMP_FLOW_RATE
            )
            if gas_transfer_actions:
                action_sequence.extend(gas_transfer_actions)
                debug_print(f"✅ 添加了 {len(gas_transfer_actions)} 个充气动作")
                action_sequence.append(create_action_log(f"气体充气协议完成 ({len(gas_transfer_actions)} 个操作)", "✅"))
            else:
                debug_print("⚠️ 充气协议返回空序列，添加手动动作")
                action_sequence.append(create_action_log("充气协议为空，使用手动等待", "⚠️"))
                action_sequence.append({
                    "action_name": "wait",
                    "action_kwargs": {"time": REFILL_TIME}
                })
        except Exception as e:
            debug_print(f"❌ 气体充气失败: {str(e)}")
            action_sequence.append(create_action_log(f"气体充气失败: {str(e)}", "❌"))
            action_sequence.append({
                "action_name": "wait",
                "action_kwargs": {"time": REFILL_TIME}
            })
        # 充气后等待
        refill_wait_minutes = REFILL_TIME / 60
        action_sequence.append(create_action_log(f"充气后等待 ({refill_wait_minutes:.1f} 分钟)", "⏳"))
        action_sequence.append({
            "action_name": "wait",
            "action_kwargs": {"time": REFILL_TIME}
        })
        # 关闭气源电磁阀
        if gas_solenoid:
            debug_print(f"🚪 关闭气源电磁阀: {gas_solenoid}")
            action_sequence.append(create_action_log(f"关闭气源电磁阀: {gas_solenoid}", "🚪"))
            action_sequence.append({
                "device_id": gas_solenoid,
                "action_name": "set_valve_position",
                "action_kwargs": {"command": "CLOSED"}
            })
        # 关闭气源
-        vacuum_action_sequence.append(
+        debug_print(f"🔴 停止气源: {gas_source}")
-            {
+        action_sequence.append(create_action_log(f"停止气源: {gas_source}", "🔴"))
-                "device_id": vacuum_backbone["gas"],
+        action_sequence.append({
-                "action_name": "set_status",
+            "device_id": gas_source,
-                "action_kwargs": {
+            "action_name": "set_status",
-                    "string": "OFF"
+            "action_kwargs": {"string": "OFF"}
-                }
+        })
            }
        )
-        # 关闭阀门
+        # 循环间等待
-        vacuum_action_sequence.append(
+        if cycle < repeats - 1:
-            {
+            debug_print(f"⏳ 等待下一个循环...")
-                "device_id": vacuum_backbone["gas_valve"],
+            action_sequence.append(create_action_log("等待下一个循环...", "⏳"))
-                "action_name": "set_valve_position",
+            action_sequence.append({
-                "action_kwargs": {
+                "action_name": "wait",
-                    "command": "CLOSED"
+                "action_kwargs": {"time": 10.0}
-                }
+            })
-            }
+        else:
-        )
+            action_sequence.append(create_action_log(f"第 {cycle+1}/{repeats} 轮循环完成", "✅"))
-    return vacuum_action_sequence
+    
    # === 停止搅拌器 ===
    debug_print("🔍 步骤7: 停止搅拌器...")
    if stirrer_id:
        debug_print(f"🛑 停止搅拌器: {stirrer_id}")
        action_sequence.append(create_action_log(f"停止搅拌器: {stirrer_id}", "🛑"))
        action_sequence.append({
            "device_id": stirrer_id,
            "action_name": "stop_stir",
            "action_kwargs": {"vessel": vessel}
        })
    else:
        action_sequence.append(create_action_log("跳过搅拌器停止", "⏭️"))
    # === 最终等待 ===
    action_sequence.append(create_action_log("最终稳定等待...", "⏳"))
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {"time": 10.0}
    })
    # === 总结 ===
    total_time = (VACUUM_TIME + REFILL_TIME + 25) * repeats + 20
    debug_print("=" * 60)
    debug_print(f"🎉 抽真空充气协议生成完成")
    debug_print(f"📊 协议统计:")
    debug_print(f"  📋 总动作数: {len(action_sequence)}")
    debug_print(f"  ⏱️ 预计总时间: {total_time:.0f}s ({total_time/60:.1f} 分钟)")
    debug_print(f"  🥼 处理容器: {vessel}")
    debug_print(f"  💨 使用气体: {gas}")
    debug_print(f"  🔄 重复次数: {repeats}")
    debug_print("=" * 60)
    # 添加完成日志
    summary_msg = f"抽真空充气协议完成: {vessel} (使用 {gas}，{repeats} 次循环)"
    action_sequence.append(create_action_log(summary_msg, "🎉"))
    return action_sequence
 # === 便捷函数 ===
 def generate_nitrogen_purge_protocol(G: nx.DiGraph, vessel: str, **kwargs) -> List[Dict[str, Any]]:
    """生成氮气置换协议"""
    debug_print(f"💨 生成氮气置换协议: {vessel}")
    return generate_evacuateandrefill_protocol(G, vessel, "nitrogen", **kwargs)
 def generate_argon_purge_protocol(G: nx.DiGraph, vessel: str, **kwargs) -> List[Dict[str, Any]]:
    """生成氩气置换协议"""
    debug_print(f"💨 生成氩气置换协议: {vessel}")
    return generate_evacuateandrefill_protocol(G, vessel, "argon", **kwargs)
 def generate_air_purge_protocol(G: nx.DiGraph, vessel: str, **kwargs) -> List[Dict[str, Any]]:
    """生成空气置换协议"""
    debug_print(f"💨 生成空气置换协议: {vessel}")
    return generate_evacuateandrefill_protocol(G, vessel, "air", **kwargs)
 def generate_inert_atmosphere_protocol(G: nx.DiGraph, vessel: str, gas: str = "nitrogen", **kwargs) -> List[Dict[str, Any]]:
    """生成惰性气氛协议"""
    debug_print(f"🛡️ 生成惰性气氛协议: {vessel} (使用 {gas})")
    return generate_evacuateandrefill_protocol(G, vessel, gas, **kwargs)
 # 测试函数
 def test_evacuateandrefill_protocol():
    """测试抽真空充气协议"""
    debug_print("=== 抽真空充气协议增强中文版测试 ===")
    debug_print("✅ 测试完成")
 if __name__ == "__main__":
    test_evacuateandrefill_protocol()
--- a/unilabos/compile/evacuateandrefill_protocol_old.py
+++ b/unilabos/compile/evacuateandrefill_protocol_old.py
@@ -0,0 +1,143 @@
 # import numpy as np
 # import networkx as nx
 # def generate_evacuateandrefill_protocol(
 #     G: nx.DiGraph, 
 #     vessel: str, 
 #     gas: str, 
 #     repeats: int = 1
 # ) -> list[dict]:
 #     """
 #     生成泵操作的动作序列。
 #     :param G: 有向图, 节点为容器和注射泵, 边为流体管道, A→B边的属性为管道接A端的阀门位置
 #     :param from_vessel: 容器A
 #     :param to_vessel: 容器B
 #     :param volume: 转移的体积
 #     :param flowrate: 最终注入容器B时的流速
 #     :param transfer_flowrate: 泵骨架中转移流速（若不指定，默认与注入流速相同）
 #     :return: 泵操作的动作序列
 #     """
 #     # 生成电磁阀、真空泵、气源操作的动作序列
 #     vacuum_action_sequence = []
 #     nodes = G.nodes(data=True)
 #     # 找到和 vessel 相连的电磁阀和真空泵、气源
 #     vacuum_backbone = {"vessel": vessel}
 #     for neighbor in G.neighbors(vessel):
 #         if nodes[neighbor]["class"].startswith("solenoid_valve"):
 #             for neighbor2 in G.neighbors(neighbor):
 #                 if neighbor2 == vessel:
 #                     continue
 #                 if nodes[neighbor2]["class"].startswith("vacuum_pump"):
 #                     vacuum_backbone.update({"vacuum_valve": neighbor, "pump": neighbor2})
 #                     break
 #                 elif nodes[neighbor2]["class"].startswith("gas_source"):
 #                     vacuum_backbone.update({"gas_valve": neighbor, "gas": neighbor2})
 #                     break
 #     # 判断是否设备齐全
 #     if len(vacuum_backbone) < 5:
 #         print(f"\n\n\n{vacuum_backbone}\n\n\n")
 #         raise ValueError("Not all devices are connected to the vessel.")
 #     # 生成操作的动作序列
 #     for i in range(repeats):
 #         # 打开真空泵阀门、关闭气源阀门
 #         vacuum_action_sequence.append([
 #             {
 #                 "device_id": vacuum_backbone["vacuum_valve"],
 #                 "action_name": "set_valve_position",
 #                 "action_kwargs": {
 #                     "command": "OPEN"
 #                 }
 #             },
 #             {
 #                 "device_id": vacuum_backbone["gas_valve"],
 #                 "action_name": "set_valve_position",
 #                 "action_kwargs": {
 #                     "command": "CLOSED"
 #                 }
 #             }
 #         ])
 #         # 打开真空泵、关闭气源
 #         vacuum_action_sequence.append([
 #             {
 #                 "device_id": vacuum_backbone["pump"],
 #                 "action_name": "set_status",
 #                 "action_kwargs": {
 #                     "string": "ON"
 #                 }
 #             },
 #             {
 #                 "device_id": vacuum_backbone["gas"],
 #                 "action_name": "set_status",
 #                 "action_kwargs": {
 #                     "string": "OFF"
 #                 }
 #             }
 #         ])
 #         vacuum_action_sequence.append({"action_name": "wait", "action_kwargs": {"time": 60}})
 #         # 关闭真空泵阀门、打开气源阀门
 #         vacuum_action_sequence.append([
 #             {
 #                 "device_id": vacuum_backbone["vacuum_valve"],
 #                 "action_name": "set_valve_position",
 #                 "action_kwargs": {
 #                     "command": "CLOSED"
 #                 }
 #             },
 #             {
 #                 "device_id": vacuum_backbone["gas_valve"],
 #                 "action_name": "set_valve_position",
 #                 "action_kwargs": {
 #                     "command": "OPEN"
 #                 }
 #             }
 #         ])
 #         # 关闭真空泵、打开气源
 #         vacuum_action_sequence.append([
 #             {
 #                 "device_id": vacuum_backbone["pump"],
 #                 "action_name": "set_status",
 #                 "action_kwargs": {
 #                     "string": "OFF"
 #                 }
 #             },
 #             {
 #                 "device_id": vacuum_backbone["gas"],
 #                 "action_name": "set_status",
 #                 "action_kwargs": {
 #                     "string": "ON"
 #                 }
 #             }
 #         ])
 #         vacuum_action_sequence.append({"action_name": "wait", "action_kwargs": {"time": 60}})
 #         # 关闭气源
 #         vacuum_action_sequence.append(
 #             {
 #                 "device_id": vacuum_backbone["gas"],
 #                 "action_name": "set_status",
 #                 "action_kwargs": {
 #                     "string": "OFF"
 #                 }
 #             }
 #         )
 #         # 关闭阀门
 #         vacuum_action_sequence.append(
 #             {
 #                 "device_id": vacuum_backbone["gas_valve"],
 #                 "action_name": "set_valve_position",
 #                 "action_kwargs": {
 #                     "command": "CLOSED"
 #                 }
 #             }
 #         )
 #     return vacuum_action_sequence
--- a/unilabos/compile/evaporate_protocol.py
+++ b/unilabos/compile/evaporate_protocol.py
@@ -1,81 +1,366 @@
-import numpy as np
+from typing import List, Dict, Any, Optional, Union
 import networkx as nx
 import logging
 import re
 logger = logging.getLogger(__name__)
 def debug_print(message):
    """调试输出"""
    print(f"🧪 [EVAPORATE] {message}", flush=True)
    logger.info(f"[EVAPORATE] {message}")
 def parse_time_input(time_input: Union[str, float]) -> float:
    """
    解析时间输入，支持带单位的字符串
    Args:
        time_input: 时间输入（如 "3 min", "180", "0.5 h" 等）
    Returns:
        float: 时间（秒）
    """
    if isinstance(time_input, (int, float)):
        debug_print(f"⏱️ 时间输入为数字: {time_input}s ✨")
        return float(time_input)
    if not time_input or not str(time_input).strip():
        debug_print(f"⚠️ 时间输入为空，使用默认值: 180s (3分钟) 🕐")
        return 180.0  # 默认3分钟
    time_str = str(time_input).lower().strip()
    debug_print(f"🔍 解析时间输入: '{time_str}' 📝")
    # 处理未知时间
    if time_str in ['?', 'unknown', 'tbd']:
        default_time = 180.0  # 默认3分钟
        debug_print(f"❓ 检测到未知时间，使用默认值: {default_time}s (3分钟) 🤷‍♀️")
        return default_time
    # 移除空格并提取数字和单位
    time_clean = re.sub(r'\s+', '', time_str)
    # 匹配数字和单位的正则表达式
    match = re.match(r'([0-9]*\.?[0-9]+)\s*(s|sec|second|min|minute|h|hr|hour|d|day)?', time_clean)
    if not match:
        # 如果无法解析，尝试直接转换为数字（默认秒）
        try:
            value = float(time_str)
            debug_print(f"✅ 时间解析成功: {time_str} → {value}s（无单位，默认秒）⏰")
            return value
        except ValueError:
            debug_print(f"❌ 无法解析时间: '{time_str}'，使用默认值180s (3分钟) 😅")
            return 180.0
    value = float(match.group(1))
    unit = match.group(2) or 's'  # 默认单位为秒
    # 转换为秒
    if unit in ['min', 'minute']:
        time_sec = value * 60.0  # min -> s
        debug_print(f"🕐 时间转换: {value} 分钟 → {time_sec}s ⏰")
    elif unit in ['h', 'hr', 'hour']:
        time_sec = value * 3600.0  # h -> s
        debug_print(f"🕐 时间转换: {value} 小时 → {time_sec}s ({time_sec/60:.1f}分钟) ⏰")
    elif unit in ['d', 'day']:
        time_sec = value * 86400.0  # d -> s
        debug_print(f"🕐 时间转换: {value} 天 → {time_sec}s ({time_sec/3600:.1f}小时) ⏰")
    else:  # s, sec, second 或默认
        time_sec = value  # 已经是s
        debug_print(f"🕐 时间转换: {value}s → {time_sec}s (已是秒) ⏰")
    return time_sec
 def find_rotavap_device(G: nx.DiGraph, vessel: str = None) -> Optional[str]:
    """
    在组态图中查找旋转蒸发仪设备
    Args:
        G: 设备图
        vessel: 指定的设备名称（可选）
    Returns:
        str: 找到的旋转蒸发仪设备ID，如果没找到返回None
    """
    debug_print("🔍 开始查找旋转蒸发仪设备... 🌪️")
    # 如果指定了vessel，先检查是否存在且是旋转蒸发仪
    if vessel:
        debug_print(f"🎯 检查指定设备: {vessel} 🔧")
        if vessel in G.nodes():
            node_data = G.nodes[vessel]
            node_class = node_data.get('class', '')
            node_type = node_data.get('type', '')
            debug_print(f"📋 设备信息 {vessel}: class={node_class}, type={node_type}")
            # 检查是否为旋转蒸发仪
            if any(keyword in str(node_class).lower() for keyword in ['rotavap', 'rotary', 'evaporat']):
                debug_print(f"🎉 找到指定的旋转蒸发仪: {vessel} ✨")
                return vessel
            elif node_type == 'device':
                debug_print(f"✅ 指定设备存在，尝试直接使用: {vessel} 🔧")
                return vessel
        else:
            debug_print(f"❌ 指定的设备 {vessel} 不存在 😞")
    # 在所有设备中查找旋转蒸发仪
    debug_print("🔎 在所有设备中搜索旋转蒸发仪... 🕵️‍♀️")
    rotavap_candidates = []
    for node_id, node_data in G.nodes(data=True):
        node_class = node_data.get('class', '')
        node_type = node_data.get('type', '')
        # 跳过非设备节点
        if node_type != 'device':
            continue
        # 检查设备类型
        if any(keyword in str(node_class).lower() for keyword in ['rotavap', 'rotary', 'evaporat']):
            rotavap_candidates.append(node_id)
            debug_print(f"🌟 找到旋转蒸发仪候选: {node_id} (class: {node_class}) 🌪️")
        elif any(keyword in str(node_id).lower() for keyword in ['rotavap', 'rotary', 'evaporat']):
            rotavap_candidates.append(node_id)
            debug_print(f"🌟 找到旋转蒸发仪候选 (按名称): {node_id} 🌪️")
    if rotavap_candidates:
        selected = rotavap_candidates[0]  # 选择第一个找到的
        debug_print(f"🎯 选择旋转蒸发仪: {selected} 🏆")
        return selected
    debug_print("😭 未找到旋转蒸发仪设备 💔")
    return None
 def find_connected_vessel(G: nx.DiGraph, rotavap_device: str) -> Optional[str]:
    """
    查找与旋转蒸发仪连接的容器
    Args:
        G: 设备图
        rotavap_device: 旋转蒸发仪设备ID
    Returns:
        str: 连接的容器ID，如果没找到返回None
    """
    debug_print(f"🔗 查找与 {rotavap_device} 连接的容器... 🥽")
    # 查看旋转蒸发仪的子设备
    rotavap_data = G.nodes[rotavap_device]
    children = rotavap_data.get('children', [])
    debug_print(f"👶 检查子设备: {children}")
    for child_id in children:
        if child_id in G.nodes():
            child_data = G.nodes[child_id]
            child_type = child_data.get('type', '')
            if child_type == 'container':
                debug_print(f"🎉 找到连接的容器: {child_id} 🥽✨")
                return child_id
    # 查看邻接的容器
    debug_print("🤝 检查邻接设备...")
    for neighbor in G.neighbors(rotavap_device):
        neighbor_data = G.nodes[neighbor]
        neighbor_type = neighbor_data.get('type', '')
        if neighbor_type == 'container':
            debug_print(f"🎉 找到邻接的容器: {neighbor} 🥽✨")
            return neighbor
    debug_print("😞 未找到连接的容器 💔")
    return None
 def generate_evaporate_protocol(
    G: nx.DiGraph,
    vessel: str,
-    pressure: float,
+    pressure: float = 0.1,
-    temp: float,
+    temp: float = 60.0,
-    time: float,
+    time: Union[str, float] = "180",     # 🔧 修改：支持字符串时间
-    stir_speed: float
+    stir_speed: float = 100.0,
-) -> list[dict]:
+    solvent: str = "",
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
-    Generate a protocol to evaporate a solution from a vessel.
+    生成蒸发操作的协议序列 - 支持单位
-    :param G: Directed graph. Nodes are containers and pumps, edges are fluidic connections.
+    Args:
-    :param vessel: Vessel to clean.
+        G: 设备图
-    :param solvent: Solvent to clean vessel with.
+        vessel: 容器名称或旋转蒸发仪名称
-    :param volume: Volume of solvent to clean vessel with.
+        pressure: 真空度 (bar)，默认0.1
-    :param temp: Temperature to heat vessel to while cleaning.
+        temp: 加热温度 (°C)，默认60
-    :param repeats: Number of cleaning cycles to perform.
+        time: 蒸发时间（支持 "3 min", "180", "0.5 h" 等）
-    :return: List of actions to clean vessel.
+        stir_speed: 旋转速度 (RPM)，默认100
        solvent: 溶剂名称（用于参数优化）
        **kwargs: 其他参数（兼容性）
    Returns:
        List[Dict[str, Any]]: 动作序列
    """
-    # 生成泵操作的动作序列
+    debug_print("🌟" * 20)
-    pump_action_sequence = []
+    debug_print("🌪️ 开始生成蒸发协议（支持单位）✨")
-    reactor_volume = 500.0
+    debug_print(f"📝 输入参数:")
-    transfer_flowrate = flowrate = 2.5
+    debug_print(f"  🥽 vessel: {vessel}")
    debug_print(f"  💨 pressure: {pressure} bar")
    debug_print(f"  🌡️ temp: {temp}°C")
    debug_print(f"  ⏰ time: {time} (类型: {type(time)})")
    debug_print(f"  🌪️ stir_speed: {stir_speed} RPM")
    debug_print(f"  🧪 solvent: '{solvent}'")
    debug_print("🌟" * 20)
-    # 开启冷凝器
+    # === 步骤1: 查找旋转蒸发仪设备 ===
-    pump_action_sequence.append({
+    debug_print("📍 步骤1: 查找旋转蒸发仪设备... 🔍")
-        "device_id": "rotavap_chiller",
+    
-        "action_name": "set_temperature",
+    # 验证vessel参数
-        "action_kwargs": {
+    if not vessel:
-            "command": "-40"
+        debug_print("❌ vessel 参数不能为空! 😱")
-        }
+        raise ValueError("vessel 参数不能为空")
-    })
+    
-    # TODO: 通过温度反馈改为 HeatChillToTemp，而非等待固定时间
+    # 查找旋转蒸发仪设备
-    pump_action_sequence.append({
+    rotavap_device = find_rotavap_device(G, vessel)
    if not rotavap_device:
        debug_print("💥 未找到旋转蒸发仪设备! 😭")
        raise ValueError(f"未找到旋转蒸发仪设备。请检查组态图中是否包含 class 包含 'rotavap'、'rotary' 或 'evaporat' 的设备")
    debug_print(f"🎉 成功找到旋转蒸发仪: {rotavap_device} ✨")
    # === 步骤2: 确定目标容器 ===
    debug_print("📍 步骤2: 确定目标容器... 🥽")
    target_vessel = vessel
    # 如果vessel就是旋转蒸发仪设备，查找连接的容器
    if vessel == rotavap_device:
        debug_print("🔄 vessel就是旋转蒸发仪，查找连接的容器...")
        connected_vessel = find_connected_vessel(G, rotavap_device)
        if connected_vessel:
            target_vessel = connected_vessel
            debug_print(f"✅ 使用连接的容器: {target_vessel} 🥽✨")
        else:
            debug_print(f"⚠️ 未找到连接的容器，使用设备本身: {rotavap_device} 🔧")
            target_vessel = rotavap_device
    elif vessel in G.nodes() and G.nodes[vessel].get('type') == 'container':
        debug_print(f"✅ 使用指定的容器: {vessel} 🥽✨")
        target_vessel = vessel
    else:
        debug_print(f"⚠️ 容器 '{vessel}' 不存在或类型不正确，使用旋转蒸发仪设备: {rotavap_device} 🔧")
        target_vessel = rotavap_device
    # === 🔧 新增：步骤3：单位解析处理 ===
    debug_print("📍 步骤3: 单位解析处理... ⚡")
    # 解析时间
    final_time = parse_time_input(time)
    debug_print(f"🎯 时间解析完成: {time} → {final_time}s ({final_time/60:.1f}分钟) ⏰✨")
    # === 步骤4: 参数验证和修正 ===
    debug_print("📍 步骤4: 参数验证和修正... 🔧")
    # 修正参数范围
    if pressure <= 0 or pressure > 1.0:
        debug_print(f"⚠️ 真空度 {pressure} bar 超出范围，修正为 0.1 bar 💨")
        pressure = 0.1
    else:
        debug_print(f"✅ 真空度 {pressure} bar 在正常范围内 💨")
    if temp < 10.0 or temp > 200.0:
        debug_print(f"⚠️ 温度 {temp}°C 超出范围，修正为 60°C 🌡️")
        temp = 60.0
    else:
        debug_print(f"✅ 温度 {temp}°C 在正常范围内 🌡️")
    if final_time <= 0:
        debug_print(f"⚠️ 时间 {final_time}s 无效，修正为 180s (3分钟) ⏰")
        final_time = 180.0
    else:
        debug_print(f"✅ 时间 {final_time}s ({final_time/60:.1f}分钟) 有效 ⏰")
    if stir_speed < 10.0 or stir_speed > 300.0:
        debug_print(f"⚠️ 旋转速度 {stir_speed} RPM 超出范围，修正为 100 RPM 🌪️")
        stir_speed = 100.0
    else:
        debug_print(f"✅ 旋转速度 {stir_speed} RPM 在正常范围内 🌪️")
    # 根据溶剂优化参数
    if solvent:
        debug_print(f"🧪 根据溶剂 '{solvent}' 优化参数... 🔬")
        solvent_lower = solvent.lower()
        if any(s in solvent_lower for s in ['water', 'aqueous', 'h2o']):
            temp = max(temp, 80.0)
            pressure = max(pressure, 0.2)
            debug_print("💧 水系溶剂：提高温度和真空度 🌡️💨")
        elif any(s in solvent_lower for s in ['ethanol', 'methanol', 'acetone']):
            temp = min(temp, 50.0)
            pressure = min(pressure, 0.05)
            debug_print("🍺 易挥发溶剂：降低温度和真空度 🌡️💨")
        elif any(s in solvent_lower for s in ['dmso', 'dmi', 'toluene']):
            temp = max(temp, 100.0)
            pressure = min(pressure, 0.01)
            debug_print("🔥 高沸点溶剂：提高温度，降低真空度 🌡️💨")
        else:
            debug_print("🧪 通用溶剂，使用标准参数 ✨")
    else:
        debug_print("🤷‍♀️ 未指定溶剂，使用默认参数 ✨")
    debug_print(f"🎯 最终参数: pressure={pressure} bar 💨, temp={temp}°C 🌡️, time={final_time}s ⏰, stir_speed={stir_speed} RPM 🌪️")
    # === 步骤5: 生成动作序列 ===
    debug_print("📍 步骤5: 生成动作序列... 🎬")
    action_sequence = []
    # 1. 等待稳定
    debug_print("  🔄 动作1: 添加初始等待稳定... ⏳")
    action_sequence.append({
        "action_name": "wait",
-        "action_kwargs": {
+        "action_kwargs": {"time": 10}
            "time": 1800
        }
    })
    debug_print("  ✅ 初始等待动作已添加 ⏳✨")
-    # 开启旋蒸真空泵、旋转，在液体转移后运行time时间
+    # 2. 执行蒸发
-    pump_action_sequence.append({
+    debug_print(f"  🌪️ 动作2: 执行蒸发操作...")
-        "device_id": "rotavap_controller",
+    debug_print(f"    🔧 设备: {rotavap_device}")
-        "action_name": "set_pump_time",
+    debug_print(f"    🥽 容器: {target_vessel}")
-        "action_kwargs": {
+    debug_print(f"    💨 真空度: {pressure} bar")
-            "command": str(time + reactor_volume / flowrate * 3)
+    debug_print(f"    🌡️ 温度: {temp}°C")
-        }
+    debug_print(f"    ⏰ 时间: {final_time}s ({final_time/60:.1f}分钟)")
-    })
+    debug_print(f"    🌪️ 旋转速度: {stir_speed} RPM")
    pump_action_sequence.append({
        "device_id": "rotavap_controller",
        "action_name": "set_pump_time",
        "action_kwargs": {
            "command": str(time + reactor_volume / flowrate * 3)
        }
    })
-    # 液体转入旋转蒸发器
+    evaporate_action = {
-    pump_action_sequence.append({
+        "device_id": rotavap_device,
-        "device_id": "", 
+        "action_name": "evaporate",
        "action_name": "PumpTransferProtocol",
        "action_kwargs": {
-            "from_vessel": vessel,
+            "vessel": target_vessel,
-            "to_vessel": "rotavap",
+            "pressure": pressure,
-            "volume": reactor_volume,
+            "temp": temp,
-            "time": reactor_volume / flowrate,
+            "time": final_time,
-            # "transfer_flowrate": transfer_flowrate,
+            "stir_speed": stir_speed,
            "solvent": solvent
        }
-    })
+    }
    action_sequence.append(evaporate_action)
    debug_print("  ✅ 蒸发动作已添加 🌪️✨")
-    pump_action_sequence.append({
+    # 3. 蒸发后等待
    debug_print("  🔄 动作3: 添加蒸发后等待... ⏳")
    action_sequence.append({
        "action_name": "wait",
-        "action_kwargs": {
+        "action_kwargs": {"time": 10}
            "time": time
        }
    })
-    return pump_action_sequence
+    debug_print("  ✅ 蒸发后等待动作已添加 ⏳✨")
    # === 总结 ===
    debug_print("🎊" * 20)
    debug_print(f"🎉 蒸发协议生成完成! ✨")
    debug_print(f"📊 总动作数: {len(action_sequence)} 个 📝")
    debug_print(f"🌪️ 旋转蒸发仪: {rotavap_device} 🔧")
    debug_print(f"🥽 目标容器: {target_vessel} 🧪")
    debug_print(f"⚙️ 蒸发参数: {pressure} bar 💨, {temp}°C 🌡️, {final_time}s ⏰, {stir_speed} RPM 🌪️")
    debug_print(f"⏱️ 预计总时间: {(final_time + 20)/60:.1f} 分钟 ⌛")
    debug_print("🎊" * 20)
    return action_sequence
--- a/unilabos/compile/filter_protocol.py
+++ b/unilabos/compile/filter_protocol.py
@@ -1,70 +1,236 @@
-from typing import List, Dict, Any
+from typing import List, Dict, Any, Optional
 import networkx as nx
 import logging
 from .pump_protocol import generate_pump_protocol_with_rinsing
 logger = logging.getLogger(__name__)
 def debug_print(message):
    """调试输出"""
    print(f"🧪 [FILTER] {message}", flush=True)
    logger.info(f"[FILTER] {message}")
 def find_filter_device(G: nx.DiGraph) -> str:
    """查找过滤器设备"""
    debug_print("🔍 查找过滤器设备... 🌊")
    # 查找过滤器设备
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if 'filter' in node_class.lower() or 'filter' in node.lower():
            debug_print(f"🎉 找到过滤器设备: {node} ✨")
            return node
    # 如果没找到，寻找可能的过滤器名称
    debug_print("🔎 在预定义名称中搜索过滤器... 📋")
    possible_names = ["filter", "filter_1", "virtual_filter", "filtration_unit"]
    for name in possible_names:
        if name in G.nodes():
            debug_print(f"🎉 找到过滤器设备: {name} ✨")
            return name
    debug_print("😭 未找到过滤器设备 💔")
    raise ValueError("未找到过滤器设备")
 def validate_vessel(G: nx.DiGraph, vessel: str, vessel_type: str = "容器") -> None:
    """验证容器是否存在"""
    debug_print(f"🔍 验证{vessel_type}: '{vessel}' 🧪")
    if not vessel:
        debug_print(f"❌ {vessel_type}不能为空! 😱")
        raise ValueError(f"{vessel_type}不能为空")
    if vessel not in G.nodes():
        debug_print(f"❌ {vessel_type} '{vessel}' 不存在于系统中! 😞")
        raise ValueError(f"{vessel_type} '{vessel}' 不存在于系统中")
    debug_print(f"✅ {vessel_type} '{vessel}' 验证通过 🎯")
 def generate_filter_protocol(
    G: nx.DiGraph,
    vessel: str,
    filtrate_vessel: str = "",
-    stir: bool = False,
+    **kwargs
    stir_speed: float = 300.0,
    temp: float = 25.0,
    continue_heatchill: bool = False,
    volume: float = 0.0
 ) -> List[Dict[str, Any]]:
    """
    生成过滤操作的协议序列
    Args:
-        G: 有向图，节点为设备和容器
+        G: 设备图
-        vessel: 过滤容器
+        vessel: 过滤容器名称（必需）- 包含需要过滤的混合物
-        filtrate_vessel: 滤液容器（可选）
+        filtrate_vessel: 滤液容器名称（可选）- 如果提供则收集滤液
-        stir: 是否搅拌
+        **kwargs: 其他参数（兼容性）
        stir_speed: 搅拌速度（可选）
        temp: 温度（可选，摄氏度）
        continue_heatchill: 是否继续加热冷却
        volume: 过滤体积（可选）
    Returns:
        List[Dict[str, Any]]: 过滤操作的动作序列
    Raises:
        ValueError: 当找不到过滤设备时抛出异常
    Examples:
        filter_protocol = generate_filter_protocol(G, "reactor", "filtrate_vessel", stir=True, volume=100.0)
    """
    debug_print("🌊" * 20)
    debug_print("🚀 开始生成过滤协议 ✨")
    debug_print(f"📝 输入参数:")
    debug_print(f"  🥽 vessel: {vessel}")
    debug_print(f"  🧪 filtrate_vessel: {filtrate_vessel}")
    debug_print(f"  ⚙️ 其他参数: {kwargs}")
    debug_print("🌊" * 20)
    action_sequence = []
-    # 查找过滤设备
+    # === 参数验证 ===
-    filter_nodes = [node for node in G.nodes() 
+    debug_print("📍 步骤1: 参数验证... 🔧")
                   if G.nodes[node].get('class') == 'virtual_filter']
-    if not filter_nodes:
+    # 验证必需参数
-        raise ValueError("没有找到可用的过滤设备")
+    debug_print("  🔍 验证必需参数...")
    validate_vessel(G, vessel, "过滤容器")
    debug_print("  ✅ 必需参数验证完成 🎯")
-    # 使用第一个可用的过滤器
+    # 验证可选参数
-    filter_id = filter_nodes[0]
+    debug_print("  🔍 验证可选参数...")
    if filtrate_vessel:
        validate_vessel(G, filtrate_vessel, "滤液容器")
        debug_print("  🌊 模式: 过滤并收集滤液 💧")
    else:
        debug_print("  🧱 模式: 过滤并收集固体 🔬")
    debug_print("  ✅ 可选参数验证完成 🎯")
-    # 验证容器是否存在
+    # === 查找设备 ===
-    if vessel not in G.nodes():
+    debug_print("📍 步骤2: 查找设备... 🔍")
        raise ValueError(f"过滤容器 {vessel} 不存在于图中")
-    if filtrate_vessel and filtrate_vessel not in G.nodes():
+    try:
-        raise ValueError(f"滤液容器 {filtrate_vessel} 不存在于图中")
+        debug_print("  🔎 搜索过滤器设备...")
        filter_device = find_filter_device(G)
        debug_print(f"  🎉 使用过滤器设备: {filter_device} 🌊✨")
-    # 执行过滤操作
+    except Exception as e:
        debug_print(f"  ❌ 设备查找失败: {str(e)} 😭")
        raise ValueError(f"设备查找失败: {str(e)}")
    # === 转移到过滤器（如果需要）===
    debug_print("📍 步骤3: 转移到过滤器... 🚚")
    if vessel != filter_device:
        debug_print(f"  🚛 需要转移: {vessel} → {filter_device} 📦")
        try:
            debug_print("  🔄 开始执行转移操作...")
            # 使用pump protocol转移液体到过滤器
            transfer_actions = generate_pump_protocol_with_rinsing(
                G=G,
                from_vessel=vessel,
                to_vessel=filter_device,
                volume=0.0,  # 转移所有液体
                amount="",
                time=0.0,
                viscous=False,
                rinsing_solvent="",
                rinsing_volume=0.0,
                rinsing_repeats=0,
                solid=False,
                flowrate=2.0,
                transfer_flowrate=2.0
            )
            if transfer_actions:
                action_sequence.extend(transfer_actions)
                debug_print(f"  ✅ 添加了 {len(transfer_actions)} 个转移动作 🚚✨")
            else:
                debug_print("  ⚠️ 转移协议返回空序列 🤔")
        except Exception as e:
            debug_print(f"  ❌ 转移失败: {str(e)} 😞")
            debug_print("  🔄 继续执行，可能是直接连接的过滤器 🤞")
    else:
        debug_print("  ✅ 过滤容器就是过滤器，无需转移 🎯")
    # === 执行过滤操作 ===
    debug_print("📍 步骤4: 执行过滤操作... 🌊")
    # 构建过滤动作参数
    debug_print("  ⚙️ 构建过滤参数...")
    filter_kwargs = {
        "vessel": filter_device,  # 过滤器设备
        "filtrate_vessel": filtrate_vessel,  # 滤液容器（可能为空）
        "stir": kwargs.get("stir", False),
        "stir_speed": kwargs.get("stir_speed", 0.0),
        "temp": kwargs.get("temp", 25.0),
        "continue_heatchill": kwargs.get("continue_heatchill", False),
        "volume": kwargs.get("volume", 0.0)  # 0表示过滤所有
    }
    debug_print(f"  📋 过滤参数: {filter_kwargs}")
    debug_print("  🌊 开始过滤操作...")
    # 过滤动作
    filter_action = {
        "device_id": filter_device,
        "action_name": "filter",
        "action_kwargs": filter_kwargs
    }
    action_sequence.append(filter_action)
    debug_print("  ✅ 过滤动作已添加 🌊✨")
    # 过滤后等待
    debug_print("  ⏳ 添加过滤后等待...")
    action_sequence.append({
-        "device_id": filter_id,
+        "action_name": "wait",
-        "action_name": "filter_sample",
+        "action_kwargs": {"time": 10.0}
        "action_kwargs": {
            "vessel": vessel,
            "filtrate_vessel": filtrate_vessel,
            "stir": stir,
            "stir_speed": stir_speed,
            "temp": temp,
            "continue_heatchill": continue_heatchill,
            "volume": volume
        }
    })
    debug_print("  ✅ 过滤后等待动作已添加 ⏰✨")
    # === 收集滤液（如果需要）===
    debug_print("📍 步骤5: 收集滤液... 💧")
    if filtrate_vessel:
        debug_print(f"  🧪 收集滤液: {filter_device} → {filtrate_vessel} 💧")
        try:
            debug_print("  🔄 开始执行收集操作...")
            # 使用pump protocol收集滤液
            collect_actions = generate_pump_protocol_with_rinsing(
                G=G,
                from_vessel=filter_device,
                to_vessel=filtrate_vessel,
                volume=0.0,  # 收集所有滤液
                amount="",
                time=0.0,
                viscous=False,
                rinsing_solvent="",
                rinsing_volume=0.0,
                rinsing_repeats=0,
                solid=False,
                flowrate=2.0,
                transfer_flowrate=2.0
            )
            if collect_actions:
                action_sequence.extend(collect_actions)
                debug_print(f"  ✅ 添加了 {len(collect_actions)} 个收集动作 🧪✨")
            else:
                debug_print("  ⚠️ 收集协议返回空序列 🤔")
        except Exception as e:
            debug_print(f"  ❌ 收集滤液失败: {str(e)} 😞")
            debug_print("  🔄 继续执行，可能滤液直接流入指定容器 🤞")
    else:
        debug_print("  🧱 未指定滤液容器，固体保留在过滤器中 🔬")
    # === 最终等待 ===
    debug_print("📍 步骤6: 最终等待... ⏰")
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {"time": 5.0}
    })
    debug_print("  ✅ 最终等待动作已添加 ⏰✨")
    # === 总结 ===
    debug_print("🎊" * 20)
    debug_print(f"🎉 过滤协议生成完成! ✨")
    debug_print(f"📊 总动作数: {len(action_sequence)} 个 📝")
    debug_print(f"🥽 过滤容器: {vessel} 🧪")
    debug_print(f"🌊 过滤器设备: {filter_device} 🔧")
    debug_print(f"💧 滤液容器: {filtrate_vessel or '无（保留固体）'} 🧱")
    debug_print(f"⏱️ 预计总时间: {(len(action_sequence) * 5):.0f} 秒 ⌛")
    debug_print("🎊" * 20)
    return action_sequence
--- a/unilabos/compile/filter_through_protocol.py
+++ b/unilabos/compile/filter_through_protocol.py
@@ -1,5 +1,72 @@
 from typing import List, Dict, Any
 import networkx as nx
 from .pump_protocol import generate_pump_protocol
 def get_vessel_liquid_volume(G: nx.DiGraph, vessel: str) -> float:
    """获取容器中的液体体积"""
    if vessel not in G.nodes():
        return 0.0
    vessel_data = G.nodes[vessel].get('data', {})
    liquids = vessel_data.get('liquid', [])
    total_volume = 0.0
    for liquid in liquids:
        if isinstance(liquid, dict) and 'liquid_volume' in liquid:
            total_volume += liquid['liquid_volume']
    return total_volume
 def find_filter_through_vessel(G: nx.DiGraph, filter_through: str) -> str:
    """查找过滤介质容器"""
    # 直接使用 filter_through 参数作为容器名称
    if filter_through in G.nodes():
        return filter_through
    # 尝试常见的过滤介质容器命名
    possible_names = [
        f"filter_{filter_through}",
        f"{filter_through}_filter",
        f"column_{filter_through}",
        f"{filter_through}_column",
        "filter_through_vessel",
        "column_vessel",
        "chromatography_column",
        "filter_column"
    ]
    for vessel_name in possible_names:
        if vessel_name in G.nodes():
            return vessel_name
    raise ValueError(f"未找到过滤介质容器 '{filter_through}'。尝试了以下名称: {[filter_through] + possible_names}")
 def find_eluting_solvent_vessel(G: nx.DiGraph, eluting_solvent: str) -> str:
    """查找洗脱溶剂容器"""
    if not eluting_solvent:
        return ""
    # 按照命名规则查找溶剂瓶
    solvent_vessel_id = f"flask_{eluting_solvent}"
    if solvent_vessel_id in G.nodes():
        return solvent_vessel_id
    # 如果直接匹配失败，尝试模糊匹配
    for node in G.nodes():
        if node.startswith('flask_') and eluting_solvent.lower() in node.lower():
            return node
    # 如果还是找不到，列出所有可用的溶剂瓶
    available_flasks = [node for node in G.nodes() 
                       if node.startswith('flask_') 
                       and G.nodes[node].get('type') == 'container']
    raise ValueError(f"找不到洗脱溶剂 '{eluting_solvent}' 对应的溶剂瓶。可用溶剂瓶: {available_flasks}")
 def generate_filter_through_protocol(
    G: nx.DiGraph,
@@ -12,10 +79,15 @@ def generate_filter_through_protocol(
    residence_time: float = 0.0
 ) -> List[Dict[str, Any]]:
    """
-    生成通过过滤介质过滤的协议序列
+    生成通过过滤介质过滤的协议序列，复用 pump_protocol 的成熟算法
    过滤流程：
    1. 液体转移：将样品从源容器转移到过滤介质
    2. 重力过滤：液体通过过滤介质自动流到目标容器
    3. 洗脱操作：将洗脱溶剂通过过滤介质洗脱目标物质
    Args:
-        G: 有向图，节点为设备和容器
+        G: 有向图，节点为设备和容器，边为流体管道
        from_vessel: 源容器的名称，即物质起始所在的容器
        to_vessel: 目标容器的名称，物质过滤后要到达的容器
        filter_through: 过滤时所通过的介质，如滤纸、柱子等
@@ -28,123 +100,288 @@ def generate_filter_through_protocol(
        List[Dict[str, Any]]: 过滤操作的动作序列
    Raises:
-        ValueError: 当找不到必要的设备时抛出异常
+        ValueError: 当找不到必要的设备或容器时
    Examples:
-        filter_through_protocol = generate_filter_through_protocol(
+        filter_through_actions = generate_filter_through_protocol(
-            G, "reactor", "collection_flask", "celite", "ethanol", 50.0, 2, 60.0
+            G, "reaction_mixture", "collection_bottle_1", "celite", "ethanol", 20.0, 2, 30.0
        )
    """
    action_sequence = []
-    # 验证容器是否存在
+    print(f"FILTER_THROUGH: 开始生成通过过滤协议")
    print(f"  - 源容器: {from_vessel}")
    print(f"  - 目标容器: {to_vessel}")
    print(f"  - 过滤介质: {filter_through}")
    print(f"  - 洗脱溶剂: {eluting_solvent}")
    print(f"  - 洗脱体积: {eluting_volume} mL" if eluting_volume > 0 else "  - 洗脱体积: 无")
    print(f"  - 洗脱重复次数: {eluting_repeats}")
    print(f"  - 停留时间: {residence_time}s" if residence_time > 0 else "  - 停留时间: 无")
    # 验证源容器和目标容器存在
    if from_vessel not in G.nodes():
-        raise ValueError(f"源容器 {from_vessel} 不存在于图中")
+        raise ValueError(f"源容器 '{from_vessel}' 不存在于系统中")
    if to_vessel not in G.nodes():
-        raise ValueError(f"目标容器 {to_vessel} 不存在于图中")
+        raise ValueError(f"目标容器 '{to_vessel}' 不存在于系统中")
-    # 查找转移泵设备（用于液体转移）
+    # 获取源容器中的液体体积
-    pump_nodes = [node for node in G.nodes() 
+    source_volume = get_vessel_liquid_volume(G, from_vessel)
-                  if G.nodes[node].get('class') == 'virtual_transfer_pump']
+    print(f"FILTER_THROUGH: 源容器 {from_vessel} 中有 {source_volume} mL 液体")
-    if not pump_nodes:
+    # 查找过滤介质容器
-        raise ValueError("没有找到可用的转移泵设备")
+    try:
        filter_through_vessel = find_filter_through_vessel(G, filter_through)
        print(f"FILTER_THROUGH: 找到过滤介质容器: {filter_through_vessel}")
    except ValueError as e:
        raise ValueError(f"无法找到过滤介质容器: {str(e)}")
-    pump_id = pump_nodes[0]
+    # 查找洗脱溶剂容器（如果需要）
    eluting_vessel = ""
    if eluting_solvent and eluting_volume > 0 and eluting_repeats > 0:
        try:
            eluting_vessel = find_eluting_solvent_vessel(G, eluting_solvent)
            print(f"FILTER_THROUGH: 找到洗脱溶剂容器: {eluting_vessel}")
        except ValueError as e:
            raise ValueError(f"无法找到洗脱溶剂容器: {str(e)}")
-    # 查找过滤设备（可选，如果有专门的过滤设备）
+    # === 第一步：将样品从源容器转移到过滤介质 ===
-    filter_nodes = [node for node in G.nodes() 
+    transfer_volume = source_volume if source_volume > 0 else 100.0  # 默认100mL
-                   if G.nodes[node].get('class') == 'virtual_filter']
+    print(f"FILTER_THROUGH: 将 {transfer_volume} mL 样品从 {from_vessel} 转移到 {filter_through_vessel}")
-    filter_id = filter_nodes[0] if filter_nodes else None
+    try:
        # 使用成熟的 pump_protocol 算法进行液体转移
        sample_transfer_actions = generate_pump_protocol(
            G=G,
            from_vessel=from_vessel,
            to_vessel=filter_through_vessel,
            volume=transfer_volume,
            flowrate=0.8,  # 较慢的流速，避免冲击过滤介质
            transfer_flowrate=1.2
        )
        action_sequence.extend(sample_transfer_actions)
    except Exception as e:
        raise ValueError(f"无法将样品转移到过滤介质: {str(e)}")
-    # 查找洗脱溶剂容器（如果需要洗脱）
+    # === 第二步：等待样品通过过滤介质（停留时间） ===
-    eluting_vessel = None
+    if residence_time > 0:
-    if eluting_solvent and eluting_volume > 0:
+        print(f"FILTER_THROUGH: 等待样品在过滤介质中停留 {residence_time}s")
        eluting_vessel = f"flask_{eluting_solvent}"
        if eluting_vessel not in G.nodes():
            # 查找可用的溶剂容器
            available_vessels = [node for node in G.nodes() 
                               if node.startswith('flask_') and 
                               G.nodes[node].get('type') == 'container']
            if available_vessels:
                eluting_vessel = available_vessels[0]
            else:
                raise ValueError(f"没有找到洗脱溶剂容器 {eluting_solvent}")
    # 步骤1：将样品从源容器转移到过滤装置（模拟通过过滤介质）
    # 这里我们将过滤过程分解为多个转移步骤来模拟通过介质的过程
    # 首先转移样品（模拟样品通过过滤介质）
    action_sequence.append({
        "device_id": pump_id,
        "action_name": "transfer",
        "action_kwargs": {
            "from_vessel": from_vessel,
            "to_vessel": to_vessel,
            "volume": 0.0,  # 转移所有液体，体积由系统确定
            "amount": f"通过 {filter_through} 过滤",
            "time": residence_time if residence_time > 0 else 0.0,
            "viscous": False,
            "rinsing_solvent": "",
            "rinsing_volume": 0.0,
            "rinsing_repeats": 0,
            "solid": True  # 通过过滤介质可能涉及固体分离
        }
    })
    # 步骤2：如果有专门的过滤设备，使用过滤设备处理
    if filter_id:
        action_sequence.append({
-            "device_id": filter_id,
+            "action_name": "wait",
-            "action_name": "filter_sample",
+            "action_kwargs": {"time": residence_time}
-            "action_kwargs": {
+        })
-                "vessel": to_vessel,
+    else:
-                "filtrate_vessel": to_vessel,
+        # 即使没有指定停留时间，也等待一段时间让液体通过
-                "stir": False,
+        default_wait_time = max(10, transfer_volume / 10)  # 根据体积估算等待时间
-                "stir_speed": 0.0,
+        print(f"FILTER_THROUGH: 等待样品通过过滤介质 {default_wait_time}s")
-                "temp": 25.0,
+        action_sequence.append({
-                "continue_heatchill": False,
+            "action_name": "wait",
-                "volume": 0.0
+            "action_kwargs": {"time": default_wait_time}
            }
        })
-    # 步骤3：洗脱操作（如果指定了洗脱溶剂和重复次数）
+    # === 第三步：洗脱操作（如果指定了洗脱参数） ===
    if eluting_solvent and eluting_volume > 0 and eluting_repeats > 0 and eluting_vessel:
-        for repeat in range(eluting_repeats):
+        print(f"FILTER_THROUGH: 开始洗脱操作 - {eluting_repeats} 次，每次 {eluting_volume} mL {eluting_solvent}")
-            # 添加洗脱溶剂
+        
        for repeat_idx in range(eluting_repeats):
            print(f"FILTER_THROUGH: 第 {repeat_idx + 1}/{eluting_repeats} 次洗脱")
            try:
                # 将洗脱溶剂转移到过滤介质
                eluting_transfer_actions = generate_pump_protocol(
                    G=G,
                    from_vessel=eluting_vessel,
                    to_vessel=filter_through_vessel,
                    volume=eluting_volume,
                    flowrate=0.6,  # 洗脱用更慢的流速
                    transfer_flowrate=1.0
                )
                action_sequence.extend(eluting_transfer_actions)
            except Exception as e:
                raise ValueError(f"第 {repeat_idx + 1} 次洗脱转移失败: {str(e)}")
            # 等待洗脱溶剂通过过滤介质
            eluting_wait_time = max(30, eluting_volume / 5)  # 根据洗脱体积估算等待时间
            print(f"FILTER_THROUGH: 等待第 {repeat_idx + 1} 次洗脱液通过 {eluting_wait_time}s")
            action_sequence.append({
-                "device_id": pump_id,
+                "action_name": "wait",
-                "action_name": "transfer",
+                "action_kwargs": {"time": eluting_wait_time}
                "action_kwargs": {
                    "from_vessel": eluting_vessel,
                    "to_vessel": to_vessel,
                    "volume": eluting_volume,
                    "amount": f"洗脱溶剂 {eluting_solvent} - 第 {repeat + 1} 次",
                    "time": 0.0,
                    "viscous": False,
                    "rinsing_solvent": "",
                    "rinsing_volume": 0.0,
                    "rinsing_repeats": 0,
                    "solid": False
                }
            })
-            # 如果有过滤设备，再次过滤洗脱液
+            # 洗脱间隔等待
-            if filter_id:
+            if repeat_idx < eluting_repeats - 1:  # 不是最后一次洗脱
                action_sequence.append({
-                    "device_id": filter_id,
+                    "action_name": "wait",
-                    "action_name": "filter_sample",
+                    "action_kwargs": {"time": 10}
                    "action_kwargs": {
                        "vessel": to_vessel,
                        "filtrate_vessel": to_vessel,
                        "stir": False,
                        "stir_speed": 0.0,
                        "temp": 25.0,
                        "continue_heatchill": False,
                        "volume": eluting_volume
                    }
                })
    # === 第四步：最终等待，确保所有液体完全通过 ===
    print(f"FILTER_THROUGH: 最终等待，确保所有液体完全通过过滤介质")
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {"time": 20}
    })
    print(f"FILTER_THROUGH: 生成了 {len(action_sequence)} 个动作")
    print(f"FILTER_THROUGH: 通过过滤协议生成完成")
    print(f"FILTER_THROUGH: 样品从 {from_vessel} 通过 {filter_through} 到达 {to_vessel}")
    if eluting_repeats > 0:
        total_eluting_volume = eluting_volume * eluting_repeats
        print(f"FILTER_THROUGH: 总洗脱体积: {total_eluting_volume} mL {eluting_solvent}")
    return action_sequence
 # 便捷函数：常用过滤方案
 def generate_gravity_column_protocol(
    G: nx.DiGraph,
    from_vessel: str,
    to_vessel: str,
    column_material: str = "silica_gel"
 ) -> List[Dict[str, Any]]:
    """重力柱层析：简单重力过滤，无洗脱"""
    return generate_filter_through_protocol(G, from_vessel, to_vessel, column_material, "", 0.0, 0, 0.0)
 def generate_celite_filter_protocol(
    G: nx.DiGraph,
    from_vessel: str,
    to_vessel: str,
    wash_solvent: str = "ethanol",
    wash_volume: float = 20.0
 ) -> List[Dict[str, Any]]:
    """硅藻土过滤：用于去除固体杂质"""
    return generate_filter_through_protocol(G, from_vessel, to_vessel, "celite", wash_solvent, wash_volume, 1, 30.0)
 def generate_column_chromatography_protocol(
    G: nx.DiGraph,
    from_vessel: str,
    to_vessel: str,
    column_material: str = "silica_gel",
    eluting_solvent: str = "ethyl_acetate",
    eluting_volume: float = 30.0,
    eluting_repeats: int = 3
 ) -> List[Dict[str, Any]]:
    """柱层析：多次洗脱分离"""
    return generate_filter_through_protocol(
        G, from_vessel, to_vessel, column_material, eluting_solvent, eluting_volume, eluting_repeats, 60.0
    )
 def generate_solid_phase_extraction_protocol(
    G: nx.DiGraph,
    from_vessel: str,
    to_vessel: str,
    spe_cartridge: str = "C18",
    eluting_solvent: str = "methanol",
    eluting_volume: float = 15.0,
    eluting_repeats: int = 2
 ) -> List[Dict[str, Any]]:
    """固相萃取：C18柱或其他SPE柱"""
    return generate_filter_through_protocol(
        G, from_vessel, to_vessel, spe_cartridge, eluting_solvent, eluting_volume, eluting_repeats, 120.0
    )
 def generate_resin_filter_protocol(
    G: nx.DiGraph,
    from_vessel: str,
    to_vessel: str,
    resin_type: str = "ion_exchange",
    regeneration_solvent: str = "NaCl_solution",
    regeneration_volume: float = 25.0
 ) -> List[Dict[str, Any]]:
    """树脂过滤：离子交换树脂或其他功能树脂"""
    return generate_filter_through_protocol(
        G, from_vessel, to_vessel, resin_type, regeneration_solvent, regeneration_volume, 1, 180.0
    )
 def generate_multi_step_purification_protocol(
    G: nx.DiGraph,
    from_vessel: str,
    to_vessel: str,
    filter_steps: List[Dict[str, Any]]
 ) -> List[Dict[str, Any]]:
    """
    多步骤纯化：连续多个过滤介质
    Args:
        G: 网络图
        from_vessel: 源容器
        to_vessel: 最终目标容器
        filter_steps: 过滤步骤列表，每个元素包含过滤参数
    Returns:
        List[Dict[str, Any]]: 完整的动作序列
    Example:
        filter_steps = [
            {
                "to_vessel": "intermediate_vessel_1",
                "filter_through": "celite",
                "eluting_solvent": "",
                "eluting_volume": 0.0,
                "eluting_repeats": 0,
                "residence_time": 30.0
            },
            {
                "from_vessel": "intermediate_vessel_1",
                "to_vessel": "final_vessel",
                "filter_through": "silica_gel",
                "eluting_solvent": "ethyl_acetate",
                "eluting_volume": 20.0,
                "eluting_repeats": 2,
                "residence_time": 60.0
            }
        ]
    """
    action_sequence = []
    current_from_vessel = from_vessel
    for i, step in enumerate(filter_steps):
        print(f"FILTER_THROUGH: 处理第 {i+1}/{len(filter_steps)} 个过滤步骤")
        # 使用步骤中指定的参数，或使用默认值
        step_from_vessel = step.get('from_vessel', current_from_vessel)
        step_to_vessel = step.get('to_vessel', to_vessel if i == len(filter_steps) - 1 else f"intermediate_vessel_{i+1}")
        # 生成单个过滤步骤的协议
        step_actions = generate_filter_through_protocol(
            G=G,
            from_vessel=step_from_vessel,
            to_vessel=step_to_vessel,
            filter_through=step.get('filter_through', 'silica_gel'),
            eluting_solvent=step.get('eluting_solvent', ''),
            eluting_volume=step.get('eluting_volume', 0.0),
            eluting_repeats=step.get('eluting_repeats', 0),
            residence_time=step.get('residence_time', 0.0)
        )
        action_sequence.extend(step_actions)
        # 更新下一步的源容器
        current_from_vessel = step_to_vessel
        # 在步骤之间加入等待时间
        if i < len(filter_steps) - 1:  # 不是最后一个步骤
            action_sequence.append({
                "action_name": "wait",
                "action_kwargs": {"time": 15}
            })
    print(f"FILTER_THROUGH: 多步骤纯化协议生成完成，共 {len(action_sequence)} 个动作")
    return action_sequence
 # 测试函数
 def test_filter_through_protocol():
    """测试通过过滤协议的示例"""
    print("=== FILTER THROUGH PROTOCOL 测试 ===")
    print("测试完成")
 if __name__ == "__main__":
    test_filter_through_protocol()
--- a/unilabos/compile/heatchill_protocol.py
+++ b/unilabos/compile/heatchill_protocol.py
@@ -1,117 +1,376 @@
-from typing import List, Dict, Any
+from typing import List, Dict, Any, Union
 import networkx as nx
 import logging
 import re
 logger = logging.getLogger(__name__)
 def debug_print(message):
    """调试输出"""
    print(f"🌡️ [HEATCHILL] {message}", flush=True)
    logger.info(f"[HEATCHILL] {message}")
 def parse_time_input(time_input: Union[str, float, int]) -> float:
    """
    解析时间输入（统一函数）
    Args:
        time_input: 时间输入（如 "30 min", "1 h", "300", "?", 60.0）
    Returns:
        float: 时间（秒）
    """
    if not time_input:
        return 300.0
    # 🔢 处理数值输入
    if isinstance(time_input, (int, float)):
        result = float(time_input)
        debug_print(f"⏰ 数值时间: {time_input} → {result}s")
        return result
    # 📝 处理字符串输入
    time_str = str(time_input).lower().strip()
    debug_print(f"🔍 解析时间: '{time_str}'")
    # ❓ 特殊值处理
    special_times = {
        '?': 300.0, 'unknown': 300.0, 'tbd': 300.0,
        'overnight': 43200.0, 'several hours': 10800.0, 
        'few hours': 7200.0, 'long time': 3600.0, 'short time': 300.0
    }
    if time_str in special_times:
        result = special_times[time_str]
        debug_print(f"🎯 特殊时间: '{time_str}' → {result}s ({result/60:.1f}分钟)")
        return result
    # 🔢 纯数字处理
    try:
        result = float(time_str)
        debug_print(f"⏰ 纯数字: {time_str} → {result}s")
        return result
    except ValueError:
        pass
    # 📐 正则表达式解析
    pattern = r'(\d+\.?\d*)\s*([a-z]*)'
    match = re.match(pattern, time_str)
    if not match:
        debug_print(f"⚠️ 无法解析时间: '{time_str}'，使用默认值: 300s")
        return 300.0
    value = float(match.group(1))
    unit = match.group(2) or 's'
    # 📏 单位转换
    unit_multipliers = {
        's': 1.0, 'sec': 1.0, 'second': 1.0, 'seconds': 1.0,
        'm': 60.0, 'min': 60.0, 'mins': 60.0, 'minute': 60.0, 'minutes': 60.0,
        'h': 3600.0, 'hr': 3600.0, 'hrs': 3600.0, 'hour': 3600.0, 'hours': 3600.0,
        'd': 86400.0, 'day': 86400.0, 'days': 86400.0
    }
    multiplier = unit_multipliers.get(unit, 1.0)
    result = value * multiplier
    debug_print(f"✅ 时间解析: '{time_str}' → {value} {unit} → {result}s ({result/60:.1f}分钟)")
    return result
 def parse_temp_input(temp_input: Union[str, float], default_temp: float = 25.0) -> float:
    """
    解析温度输入（统一函数）
    Args:
        temp_input: 温度输入
        default_temp: 默认温度
    Returns:
        float: 温度（°C）
    """
    if not temp_input:
        return default_temp
    # 🔢 数值输入
    if isinstance(temp_input, (int, float)):
        result = float(temp_input)
        debug_print(f"🌡️ 数值温度: {temp_input} → {result}°C")
        return result
    # 📝 字符串输入
    temp_str = str(temp_input).lower().strip()
    debug_print(f"🔍 解析温度: '{temp_str}'")
    # 🎯 特殊温度
    special_temps = {
        "room temperature": 25.0, "reflux": 78.0, "ice bath": 0.0,
        "boiling": 100.0, "hot": 60.0, "warm": 40.0, "cold": 10.0
    }
    if temp_str in special_temps:
        result = special_temps[temp_str]
        debug_print(f"🎯 特殊温度: '{temp_str}' → {result}°C")
        return result
    # 📐 正则解析（如 "256 °C"）
    temp_pattern = r'(\d+(?:\.\d+)?)\s*°?[cf]?'
    match = re.search(temp_pattern, temp_str)
    if match:
        result = float(match.group(1))
        debug_print(f"✅ 温度解析: '{temp_str}' → {result}°C")
        return result
    debug_print(f"⚠️ 无法解析温度: '{temp_str}'，使用默认值: {default_temp}°C")
    return default_temp
 def find_connected_heatchill(G: nx.DiGraph, vessel: str) -> str:
    """查找与指定容器相连的加热/冷却设备"""
    debug_print(f"🔍 查找加热设备，目标容器: {vessel}")
    # 🔧 查找所有加热设备
    heatchill_nodes = []
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if 'heatchill' in node_class.lower() or 'virtual_heatchill' in node_class:
            heatchill_nodes.append(node)
            debug_print(f"🎉 找到加热设备: {node}")
    # 🔗 检查连接
    if vessel and heatchill_nodes:
        for heatchill in heatchill_nodes:
            if G.has_edge(heatchill, vessel) or G.has_edge(vessel, heatchill):
                debug_print(f"✅ 加热设备 '{heatchill}' 与容器 '{vessel}' 相连")
                return heatchill
    # 🎯 使用第一个可用设备
    if heatchill_nodes:
        selected = heatchill_nodes[0]
        debug_print(f"🔧 使用第一个加热设备: {selected}")
        return selected
    # 🆘 默认设备
    debug_print("⚠️ 未找到加热设备，使用默认设备")
    return "heatchill_1"
 def validate_and_fix_params(temp: float, time: float, stir_speed: float) -> tuple:
    """验证和修正参数"""
    # 🌡️ 温度范围验证
    if temp < -50.0 or temp > 300.0:
        debug_print(f"⚠️ 温度 {temp}°C 超出范围，修正为 25°C")
        temp = 25.0
    else:
        debug_print(f"✅ 温度 {temp}°C 在正常范围内")
    # ⏰ 时间验证
    if time < 0:
        debug_print(f"⚠️ 时间 {time}s 无效，修正为 300s")
        time = 300.0
    else:
        debug_print(f"✅ 时间 {time}s ({time/60:.1f}分钟) 有效")
    # 🌪️ 搅拌速度验证
    if stir_speed < 0 or stir_speed > 1500.0:
        debug_print(f"⚠️ 搅拌速度 {stir_speed} RPM 超出范围，修正为 300 RPM")
        stir_speed = 300.0
    else:
        debug_print(f"✅ 搅拌速度 {stir_speed} RPM 在正常范围内")
    return temp, time, stir_speed
 def generate_heat_chill_protocol(
    G: nx.DiGraph,
    vessel: str,
-    temp: float,
+    temp: float = 25.0,
-    time: float,
+    time: Union[str, float] = "300",
-    stir: bool,
+    temp_spec: str = "",
-    stir_speed: float,
+    time_spec: str = "",
-    purpose: str
+    pressure: str = "",
    reflux_solvent: str = "",
    stir: bool = False,
    stir_speed: float = 300.0,
    purpose: str = "",
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
-    生成加热/冷却操作的协议序列 - 严格按照 HeatChill.action
+    生成加热/冷却操作的协议序列
    """
    action_sequence = []
-    # 查找加热/冷却设备
+    debug_print("🌡️" * 20)
-    heatchill_nodes = [node for node in G.nodes() 
+    debug_print("🚀 开始生成加热冷却协议 ✨")
-                      if G.nodes[node].get('class') == 'virtual_heatchill']
+    debug_print(f"📝 输入参数:")
    debug_print(f"  🥽 vessel: {vessel}")
    debug_print(f"  🌡️ temp: {temp}°C")
    debug_print(f"  ⏰ time: {time}")
    debug_print(f"  🎯 temp_spec: {temp_spec}")
    debug_print(f"  ⏱️ time_spec: {time_spec}")
    debug_print(f"  🌪️ stir: {stir} ({stir_speed} RPM)")
    debug_print("🌡️" * 20)
-    if not heatchill_nodes:
+    # 📋 参数验证
-        raise ValueError("没有找到可用的加热/冷却设备")
+    debug_print("📍 步骤1: 参数验证... 🔧")
-    
+    if not vessel:
-    heatchill_id = heatchill_nodes[0]
+        debug_print("❌ vessel 参数不能为空! 😱")
        raise ValueError("vessel 参数不能为空")
    if vessel not in G.nodes():
-        raise ValueError(f"容器 {vessel} 不存在于图中")
+        debug_print(f"❌ 容器 '{vessel}' 不存在于系统中! 😞")
        raise ValueError(f"容器 '{vessel}' 不存在于系统中")
-    action_sequence.append({
+    debug_print("✅ 基础参数验证通过 🎯")
    # 🔄 参数解析
    debug_print("📍 步骤2: 参数解析... ⚡")
    #温度解析：优先使用 temp_spec
    final_temp = parse_temp_input(temp_spec, temp) if temp_spec else temp
    # 时间解析：优先使用 time_spec
    final_time = parse_time_input(time_spec) if time_spec else parse_time_input(time)
    # 参数修正
    final_temp, final_time, stir_speed = validate_and_fix_params(final_temp, final_time, stir_speed)
    debug_print(f"🎯 最终参数: temp={final_temp}°C, time={final_time}s, stir_speed={stir_speed} RPM")
    # 🔍 查找设备
    debug_print("📍 步骤3: 查找加热设备... 🔍")
    try:
        heatchill_id = find_connected_heatchill(G, vessel)
        debug_print(f"🎉 使用加热设备: {heatchill_id} ✨")
    except Exception as e:
        debug_print(f"❌ 设备查找失败: {str(e)} 😭")
        raise ValueError(f"无法找到加热设备: {str(e)}")
    # 🚀 生成动作
    debug_print("📍 步骤4: 生成加热动作... 🔥")
    # 🕐 模拟运行时间优化
    debug_print("  ⏱️ 检查模拟运行时间限制...")
    original_time = final_time
    simulation_time_limit = 100.0  # 模拟运行时间限制：100秒
    if final_time > simulation_time_limit:
        final_time = simulation_time_limit
        debug_print(f"  🎮 模拟运行优化: {original_time}s → {final_time}s (限制为{simulation_time_limit}s) ⚡")
        debug_print(f"  📊 时间缩短: {original_time/60:.1f}分钟 → {final_time/60:.1f}分钟 🚀")
    else:
        debug_print(f"  ✅ 时间在限制内: {final_time}s ({final_time/60:.1f}分钟) 保持不变 🎯")
    action_sequence = []
    heatchill_action = {
        "device_id": heatchill_id,
        "action_name": "heat_chill",
        "action_kwargs": {
            "vessel": vessel,
-            "temp": temp,
+            "temp": float(final_temp),
-            "time": time,
+            "time": float(final_time),
-            "stir": stir,
+            "stir": bool(stir),
-            "stir_speed": stir_speed,
+            "stir_speed": float(stir_speed),
-            "purpose": purpose
+            "purpose": str(purpose or f"加热到 {final_temp}°C") + (f" (模拟时间: {final_time}s)" if original_time != final_time else "")
        }
-    })
+    }
    action_sequence.append(heatchill_action)
    debug_print("✅ 加热动作已添加 🔥✨")
    # 显示时间调整信息
    if original_time != final_time:
        debug_print(f"  🎭 模拟优化说明: 原计划 {original_time/60:.1f}分钟，实际模拟 {final_time/60:.1f}分钟 ⚡")
    # 🎊 总结
    debug_print("🎊" * 20)
    debug_print(f"🎉 加热冷却协议生成完成! ✨")
    debug_print(f"📊 总动作数: {len(action_sequence)} 个")
    debug_print(f"🥽 加热容器: {vessel}")
    debug_print(f"🌡️ 目标温度: {final_temp}°C")
    debug_print(f"⏰ 加热时间: {final_time}s ({final_time/60:.1f}分钟)")
    debug_print("🎊" * 20)
    return action_sequence
 def generate_heat_chill_to_temp_protocol(
    G: nx.DiGraph,
    vessel: str,
    temp: float = 25.0,
    time: Union[str, float] = 100.0,
    **kwargs
 ) -> List[Dict[str, Any]]:
    """生成加热到指定温度的协议（简化版）"""
    debug_print(f"🌡️ 生成加热到温度协议: {vessel} → {temp}°C")
    return generate_heat_chill_protocol(G, vessel, temp, time, **kwargs)
 def generate_heat_chill_start_protocol(
    G: nx.DiGraph,
    vessel: str,
-    temp: float,
+    temp: float = 25.0,
-    purpose: str
+    purpose: str = "",
    **kwargs
 ) -> List[Dict[str, Any]]:
-    """
+    """生成开始加热操作的协议序列"""
    生成开始加热/冷却操作的协议序列 - 严格按照 HeatChillStart.action
    """
    action_sequence = []
-    heatchill_nodes = [node for node in G.nodes() 
+    debug_print("🔥 开始生成启动加热协议 ✨")
-                      if G.nodes[node].get('class') == 'virtual_heatchill']
+    debug_print(f"🥽 vessel: {vessel}, 🌡️ temp: {temp}°C")
-    if not heatchill_nodes:
+    # 基础验证
-        raise ValueError("没有找到可用的加热/冷却设备")
+    if not vessel or vessel not in G.nodes():
        debug_print("❌ 容器验证失败!")
        raise ValueError("vessel 参数无效")
-    heatchill_id = heatchill_nodes[0]
+    # 查找设备
    heatchill_id = find_connected_heatchill(G, vessel)
-    if vessel not in G.nodes():
+    # 生成动作
-        raise ValueError(f"容器 {vessel} 不存在于图中")
+    action_sequence = [{
    action_sequence.append({
        "device_id": heatchill_id,
        "action_name": "heat_chill_start",
        "action_kwargs": {
            "vessel": vessel,
            "temp": temp,
-            "purpose": purpose
+            "purpose": purpose or f"开始加热到 {temp}°C"
        }
-    })
+    }]
    debug_print(f"✅ 启动加热协议生成完成 🎯")
    return action_sequence
 def generate_heat_chill_stop_protocol(
    G: nx.DiGraph,
-    vessel: str
+    vessel: str,
    **kwargs
 ) -> List[Dict[str, Any]]:
-    """
+    """生成停止加热操作的协议序列"""
    生成停止加热/冷却操作的协议序列
-    Args:
+    debug_print("🛑 开始生成停止加热协议 ✨")
-        G: 有向图，节点为设备和容器
+    debug_print(f"🥽 vessel: {vessel}")
        vessel: 容器名称
-    Returns:
+    # 基础验证
-        List[Dict[str, Any]]: 停止加热/冷却操作的动作序列
+    if not vessel or vessel not in G.nodes():
-    """
+        debug_print("❌ 容器验证失败!")
-    action_sequence = []
+        raise ValueError("vessel 参数无效")
-    # 查找加热/冷却设备
+    # 查找设备
-    heatchill_nodes = [node for node in G.nodes() 
+    heatchill_id = find_connected_heatchill(G, vessel)
                      if G.nodes[node].get('class') == 'virtual_heatchill']
-    if not heatchill_nodes:
+    # 生成动作
-        raise ValueError("没有找到可用的加热/冷却设备")
+    action_sequence = [{
    heatchill_id = heatchill_nodes[0]
    if vessel not in G.nodes():
        raise ValueError(f"容器 {vessel} 不存在于图中")
    action_sequence.append({
        "device_id": heatchill_id,
        "action_name": "heat_chill_stop",
        "action_kwargs": {
            "vessel": vessel
        }
-    })
+    }]
    debug_print(f"✅ 停止加热协议生成完成 🎯")
    return action_sequence
 # 测试函数
 def test_heatchill_protocol():
    """测试加热协议"""
    debug_print("🧪 === HEATCHILL PROTOCOL 测试 === ✨")
    debug_print("✅ 测试完成 🎉")
 if __name__ == "__main__":
    test_heatchill_protocol()
--- a/unilabos/compile/hydrogenate_protocol.py
+++ b/unilabos/compile/hydrogenate_protocol.py
@@ -0,0 +1,400 @@
 import networkx as nx
 from typing import List, Dict, Any, Optional
 def parse_temperature(temp_str: str) -> float:
    """
    解析温度字符串，支持多种格式
    Args:
        temp_str: 温度字符串（如 "45 °C", "45°C", "45"）
    Returns:
        float: 温度值（摄氏度）
    """
    try:
        # 移除常见的温度单位和符号
        temp_clean = temp_str.replace("°C", "").replace("°", "").replace("C", "").strip()
        return float(temp_clean)
    except ValueError:
        print(f"HYDROGENATE: 无法解析温度 '{temp_str}'，使用默认温度 25°C")
        return 25.0
 def parse_time(time_str: str) -> float:
    """
    解析时间字符串，支持多种格式
    Args:
        time_str: 时间字符串（如 "2 h", "120 min", "7200 s"）
    Returns:
        float: 时间值（秒）
    """
    try:
        time_clean = time_str.lower().strip()
        # 处理小时
        if "h" in time_clean:
            hours = float(time_clean.replace("h", "").strip())
            return hours * 3600.0
        # 处理分钟
        if "min" in time_clean:
            minutes = float(time_clean.replace("min", "").strip())
            return minutes * 60.0
        # 处理秒
        if "s" in time_clean:
            seconds = float(time_clean.replace("s", "").strip())
            return seconds
        # 默认按小时处理
        return float(time_clean) * 3600.0
    except ValueError:
        print(f"HYDROGENATE: 无法解析时间 '{time_str}'，使用默认时间 2小时")
        return 7200.0  # 2小时
 def find_associated_solenoid_valve(G: nx.DiGraph, device_id: str) -> Optional[str]:
    """查找与指定设备相关联的电磁阀"""
    solenoid_valves = [
        node for node in G.nodes() 
        if ('solenoid' in (G.nodes[node].get('class') or '').lower()
            or 'solenoid_valve' in node)
    ]
    # 通过网络连接查找直接相连的电磁阀
    for solenoid in solenoid_valves:
        if G.has_edge(device_id, solenoid) or G.has_edge(solenoid, device_id):
            return solenoid
    # 通过命名规则查找关联的电磁阀
    device_type = ""
    if 'gas' in device_id.lower():
        device_type = "gas"
    elif 'h2' in device_id.lower() or 'hydrogen' in device_id.lower():
        device_type = "gas"
    if device_type:
        for solenoid in solenoid_valves:
            if device_type in solenoid.lower():
                return solenoid
    return None
 def find_connected_device(G: nx.DiGraph, vessel: str, device_type: str) -> str:
    """
    查找与容器相连的指定类型设备
    Args:
        G: 网络图
        vessel: 容器名称
        device_type: 设备类型 ('heater', 'stirrer', 'gas_source')
    Returns:
        str: 设备ID，如果没有则返回None
    """
    print(f"HYDROGENATE: 正在查找与容器 '{vessel}' 相连的 {device_type}...")
    # 根据设备类型定义搜索关键词
    if device_type == 'heater':
        keywords = ['heater', 'heat', 'heatchill']
        device_class = 'virtual_heatchill'
    elif device_type == 'stirrer':
        keywords = ['stirrer', 'stir']
        device_class = 'virtual_stirrer'
    elif device_type == 'gas_source':
        keywords = ['gas', 'h2', 'hydrogen']
        device_class = 'virtual_gas_source'
    else:
        return None
    # 查找设备节点
    device_nodes = []
    for node in G.nodes():
        node_data = G.nodes[node]
        node_name = node.lower()
        node_class = node_data.get('class', '').lower()
        # 通过名称匹配
        if any(keyword in node_name for keyword in keywords):
            device_nodes.append(node)
        # 通过类型匹配
        elif device_class in node_class:
            device_nodes.append(node)
    print(f"HYDROGENATE: 找到的{device_type}节点: {device_nodes}")
    # 检查是否有设备与目标容器相连
    for device in device_nodes:
        if G.has_edge(device, vessel) or G.has_edge(vessel, device):
            print(f"HYDROGENATE: 找到与容器 '{vessel}' 相连的{device_type}: {device}")
            return device
    # 如果没有直接连接，查找距离最近的设备
    for device in device_nodes:
        try:
            path = nx.shortest_path(G, source=device, target=vessel)
            if len(path) <= 3:  # 最多2个中间节点
                print(f"HYDROGENATE: 找到距离较近的{device_type}: {device}")
                return device
        except nx.NetworkXNoPath:
            continue
    print(f"HYDROGENATE: 未找到与容器 '{vessel}' 相连的{device_type}")
    return None
 def generate_hydrogenate_protocol(
    G: nx.DiGraph,
    temp: str,
    time: str,
    vessel: str,
    **kwargs  # 接收其他可能的参数但不使用
 ) -> List[Dict[str, Any]]:
    """
    生成氢化反应协议序列
    Args:
        G: 有向图，节点为容器和设备
        temp: 反应温度（如 "45 °C"）
        time: 反应时间（如 "2 h"）
        vessel: 反应容器
        **kwargs: 其他可选参数，但不使用
    Returns:
        List[Dict[str, Any]]: 动作序列
    """
    action_sequence = []
    # 解析参数
    temperature = parse_temperature(temp)
    reaction_time = parse_time(time)
    print(f"HYDROGENATE: 开始生成氢化反应协议")
    print(f"  - 反应温度: {temperature}°C")
    print(f"  - 反应时间: {reaction_time/3600:.1f} 小时")
    print(f"  - 反应容器: {vessel}")
    # 1. 验证目标容器存在
    if vessel not in G.nodes():
        print(f"HYDROGENATE: 警告 - 容器 '{vessel}' 不存在于系统中，跳过氢化反应")
        return action_sequence
    # 2. 查找相连的设备
    heater_id = find_connected_device(G, vessel, 'heater')
    stirrer_id = find_connected_device(G, vessel, 'stirrer')
    gas_source_id = find_connected_device(G, vessel, 'gas_source')
    # 3. 启动搅拌器
    if stirrer_id:
        print(f"HYDROGENATE: 启动搅拌器 {stirrer_id}")
        action_sequence.append({
            "device_id": stirrer_id,
            "action_name": "start_stir",
            "action_kwargs": {
                "vessel": vessel,
                "stir_speed": 300.0,
                "purpose": "氢化反应: 开始搅拌"
            }
        })
    else:
        print(f"HYDROGENATE: 警告 - 未找到搅拌器，继续执行")
    # 4. 启动气源（氢气）- 修复版本
    if gas_source_id:
        print(f"HYDROGENATE: 启动气源 {gas_source_id} (氢气)")
        action_sequence.append({
            "device_id": gas_source_id,
            "action_name": "set_status",  # 修改为 set_status
            "action_kwargs": {
                "string": "ON"  # 修改参数格式
            }
        })
        # 查找相关的电磁阀
        gas_solenoid = find_associated_solenoid_valve(G, gas_source_id)
        if gas_solenoid:
            print(f"HYDROGENATE: 开启气源电磁阀 {gas_solenoid}")
            action_sequence.append({
                "device_id": gas_solenoid,
                "action_name": "set_valve_position",
                "action_kwargs": {
                    "command": "OPEN"
                }
            })
    else:
        print(f"HYDROGENATE: 警告 - 未找到气源，继续执行")
    # 5. 等待气体稳定
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": 30.0,
            "description": "等待氢气环境稳定"
        }
    })
    # 6. 启动加热器
    if heater_id:
        print(f"HYDROGENATE: 启动加热器 {heater_id} 到 {temperature}°C")
        action_sequence.append({
            "device_id": heater_id,
            "action_name": "heat_chill_start",
            "action_kwargs": {
                "vessel": vessel,
                "temp": temperature,
                "purpose": f"氢化反应: 加热到 {temperature}°C"
            }
        })
        # 等待温度稳定
        action_sequence.append({
            "action_name": "wait",
            "action_kwargs": {
                "time": 20.0,
                "description": f"等待温度稳定到 {temperature}°C"
            }
        })
        # 🕐 模拟运行时间优化
        print("HYDROGENATE: 检查模拟运行时间限制...")
        original_reaction_time = reaction_time
        simulation_time_limit = 60.0  # 模拟运行时间限制：60秒
        if reaction_time > simulation_time_limit:
            reaction_time = simulation_time_limit
            print(f"HYDROGENATE: 模拟运行优化: {original_reaction_time}s → {reaction_time}s (限制为{simulation_time_limit}s)")
            print(f"HYDROGENATE: 时间缩短: {original_reaction_time/3600:.2f}小时 → {reaction_time/60:.1f}分钟")
        else:
            print(f"HYDROGENATE: 时间在限制内: {reaction_time}s ({reaction_time/60:.1f}分钟) 保持不变")
        # 保持反应温度
        action_sequence.append({
            "device_id": heater_id,
            "action_name": "heat_chill",
            "action_kwargs": {
                "vessel": vessel,
                "temp": temperature,
                "time": reaction_time,
                "purpose": f"氢化反应: 保持 {temperature}°C，反应 {reaction_time/60:.1f}分钟" + (f" (模拟时间)" if original_reaction_time != reaction_time else "")
            }
        })
        # 显示时间调整信息
        if original_reaction_time != reaction_time:
            print(f"HYDROGENATE: 模拟优化说明: 原计划 {original_reaction_time/3600:.2f}小时，实际模拟 {reaction_time/60:.1f}分钟")
    else:
        print(f"HYDROGENATE: 警告 - 未找到加热器，使用室温反应")
        # 🕐 室温反应也需要时间优化
        print("HYDROGENATE: 检查室温反应模拟时间限制...")
        original_reaction_time = reaction_time
        simulation_time_limit = 60.0  # 模拟运行时间限制：60秒
        if reaction_time > simulation_time_limit:
            reaction_time = simulation_time_limit
            print(f"HYDROGENATE: 室温反应时间优化: {original_reaction_time}s → {reaction_time}s")
            print(f"HYDROGENATE: 时间缩短: {original_reaction_time/3600:.2f}小时 → {reaction_time/60:.1f}分钟")
        else:
            print(f"HYDROGENATE: 室温反应时间在限制内: {reaction_time}s 保持不变")
        # 室温反应，只等待时间
        action_sequence.append({
            "action_name": "wait",
            "action_kwargs": {
                "time": reaction_time,
                "description": f"室温氢化反应 {reaction_time/60:.1f}分钟" + (f" (模拟时间)" if original_reaction_time != reaction_time else "")
            }
        })
        # 显示时间调整信息
        if original_reaction_time != reaction_time:
            print(f"HYDROGENATE: 室温反应优化说明: 原计划 {original_reaction_time/3600:.2f}小时，实际模拟 {reaction_time/60:.1f}分钟")
    # 7. 停止加热
    if heater_id:
        action_sequence.append({
            "device_id": heater_id,
            "action_name": "heat_chill_stop",
            "action_kwargs": {
                "vessel": vessel,
                "purpose": "氢化反应完成，停止加热"
            }
        })
    # 8. 等待冷却
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": 300.0,
            "description": "等待反应混合物冷却"
        }
    })
    # 9. 停止气源 - 修复版本
    if gas_source_id:
        # 先关闭电磁阀
        gas_solenoid = find_associated_solenoid_valve(G, gas_source_id)
        if gas_solenoid:
            print(f"HYDROGENATE: 关闭气源电磁阀 {gas_solenoid}")
            action_sequence.append({
                "device_id": gas_solenoid,
                "action_name": "set_valve_position",
                "action_kwargs": {
                    "command": "CLOSED"
                }
            })
        # 再关闭气源
        action_sequence.append({
            "device_id": gas_source_id,
            "action_name": "set_status",  # 修改为 set_status
            "action_kwargs": {
                "string": "OFF"  # 修改参数格式
            }
        })
    # 10. 停止搅拌
    if stirrer_id:
        action_sequence.append({
            "device_id": stirrer_id,
            "action_name": "stop_stir",
            "action_kwargs": {
                "vessel": vessel,
                "purpose": "氢化反应完成，停止搅拌"
            }
        })
    print(f"HYDROGENATE: 协议生成完成，共 {len(action_sequence)} 个动作")
    print(f"HYDROGENATE: 预计总时间: {(reaction_time + 450)/3600:.1f} 小时")
    return action_sequence
 # 测试函数
 def test_hydrogenate_protocol():
    """测试氢化反应协议"""
    print("=== HYDROGENATE PROTOCOL 测试 ===")
    # 测试温度解析
    test_temps = ["45 °C", "45°C", "45", "25 C", "invalid"]
    for temp in test_temps:
        parsed = parse_temperature(temp)
        print(f"温度 '{temp}' -> {parsed}°C")
    # 测试时间解析
    test_times = ["2 h", "120 min", "7200 s", "2", "invalid"]
    for time in test_times:
        parsed = parse_time(time)
        print(f"时间 '{time}' -> {parsed/3600:.1f} 小时")
    print("测试完成")
 if __name__ == "__main__":
    test_hydrogenate_protocol()
--- a/unilabos/compile/pump_protocol.py
+++ b/unilabos/compile/pump_protocol.py
--- a/unilabos/compile/recrystallize_protocol.py
+++ b/unilabos/compile/recrystallize_protocol.py
@@ -0,0 +1,435 @@
 import networkx as nx
 import re
 from typing import List, Dict, Any, Tuple, Union
 from .pump_protocol import generate_pump_protocol_with_rinsing
 def debug_print(message):
    """调试输出"""
    print(f"💎 [RECRYSTALLIZE] {message}", flush=True)
 def parse_volume_with_units(volume_input: Union[str, float, int], default_unit: str = "mL") -> float:
    """
    解析带单位的体积输入
    Args:
        volume_input: 体积输入（如 "100 mL", "2.5 L", "500", "?", 100.0）
        default_unit: 默认单位（默认为毫升）
    Returns:
        float: 体积（毫升）
    """
    if not volume_input:
        debug_print("⚠️ 体积输入为空，返回 0.0mL 📦")
        return 0.0
    # 处理数值输入
    if isinstance(volume_input, (int, float)):
        result = float(volume_input)
        debug_print(f"🔢 数值体积输入: {volume_input} → {result}mL（默认单位）💧")
        return result
    # 处理字符串输入
    volume_str = str(volume_input).lower().strip()
    debug_print(f"🔍 解析体积字符串: '{volume_str}' 📝")
    # 处理特殊值
    if volume_str in ['?', 'unknown', 'tbd', 'to be determined']:
        default_volume = 50.0  # 50mL默认值
        debug_print(f"❓ 检测到未知体积，使用默认值: {default_volume}mL 🎯")
        return default_volume
    # 如果是纯数字，使用默认单位
    try:
        value = float(volume_str)
        if default_unit.lower() in ["ml", "milliliter"]:
            result = value
        elif default_unit.lower() in ["l", "liter"]:
            result = value * 1000.0
        elif default_unit.lower() in ["μl", "ul", "microliter"]:
            result = value / 1000.0
        else:
            result = value  # 默认mL
        debug_print(f"🔢 纯数字输入: {volume_str} → {result}mL（单位: {default_unit}）📏")
        return result
    except ValueError:
        pass
    # 移除空格并提取数字和单位
    volume_clean = re.sub(r'\s+', '', volume_str)
    # 匹配数字和单位的正则表达式
    match = re.match(r'([0-9]*\.?[0-9]+)\s*(ml|l|μl|ul|microliter|milliliter|liter)?', volume_clean)
    if not match:
        debug_print(f"⚠️ 无法解析体积: '{volume_str}'，使用默认值: 50mL 🎯")
        return 50.0
    value = float(match.group(1))
    unit = match.group(2) or default_unit.lower()
    # 转换为毫升
    if unit in ['l', 'liter']:
        volume = value * 1000.0  # L -> mL
        debug_print(f"📏 升转毫升: {value}L → {volume}mL 💧")
    elif unit in ['μl', 'ul', 'microliter']:
        volume = value / 1000.0  # μL -> mL
        debug_print(f"📏 微升转毫升: {value}μL → {volume}mL 💧")
    else:  # ml, milliliter 或默认
        volume = value  # 已经是mL
        debug_print(f"📏 毫升单位: {value}mL → {volume}mL 💧")
    debug_print(f"✅ 体积解析完成: '{volume_str}' → {volume}mL ✨")
    return volume
 def parse_ratio(ratio_str: str) -> Tuple[float, float]:
    """
    解析比例字符串，支持多种格式
    Args:
        ratio_str: 比例字符串（如 "1:1", "3:7", "50:50"）
    Returns:
        Tuple[float, float]: 比例元组 (ratio1, ratio2)
    """
    debug_print(f"⚖️ 开始解析比例: '{ratio_str}' 📊")
    try:
        # 处理 "1:1", "3:7", "50:50" 等格式
        if ":" in ratio_str:
            parts = ratio_str.split(":")
            if len(parts) == 2:
                ratio1 = float(parts[0])
                ratio2 = float(parts[1])
                debug_print(f"✅ 冒号格式解析成功: {ratio1}:{ratio2} 🎯")
                return ratio1, ratio2
        # 处理 "1-1", "3-7" 等格式
        if "-" in ratio_str:
            parts = ratio_str.split("-")
            if len(parts) == 2:
                ratio1 = float(parts[0])
                ratio2 = float(parts[1])
                debug_print(f"✅ 横线格式解析成功: {ratio1}:{ratio2} 🎯")
                return ratio1, ratio2
        # 处理 "1,1", "3,7" 等格式
        if "," in ratio_str:
            parts = ratio_str.split(",")
            if len(parts) == 2:
                ratio1 = float(parts[0])
                ratio2 = float(parts[1])
                debug_print(f"✅ 逗号格式解析成功: {ratio1}:{ratio2} 🎯")
                return ratio1, ratio2
        # 默认 1:1
        debug_print(f"⚠️ 无法解析比例 '{ratio_str}'，使用默认比例 1:1 🎭")
        return 1.0, 1.0
    except ValueError:
        debug_print(f"❌ 比例解析错误 '{ratio_str}'，使用默认比例 1:1 🎭")
        return 1.0, 1.0
 def find_solvent_vessel(G: nx.DiGraph, solvent: str) -> str:
    """
    查找溶剂容器
    Args:
        G: 网络图
        solvent: 溶剂名称
    Returns:
        str: 溶剂容器ID
    """
    debug_print(f"🔍 正在查找溶剂 '{solvent}' 的容器... 🧪")
    # 构建可能的容器名称
    possible_names = [
        f"flask_{solvent}",
        f"bottle_{solvent}",
        f"reagent_{solvent}",
        f"reagent_bottle_{solvent}",
        f"{solvent}_flask",
        f"{solvent}_bottle",
        f"{solvent}",
        f"vessel_{solvent}",
    ]
    debug_print(f"📋 候选容器名称: {possible_names[:3]}... (共{len(possible_names)}个) 📝")
    # 第一步：通过容器名称匹配
    debug_print("  🎯 步骤1: 精确名称匹配...")
    for vessel_name in possible_names:
        if vessel_name in G.nodes():
            debug_print(f"  🎉 通过名称匹配找到容器: {vessel_name} ✨")
            return vessel_name
    # 第二步：通过模糊匹配
    debug_print("  🔍 步骤2: 模糊名称匹配...")
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            node_name = G.nodes[node_id].get('name', '').lower()
            if solvent.lower() in node_id.lower() or solvent.lower() in node_name:
                debug_print(f"  🎉 通过模糊匹配找到容器: {node_id} ✨")
                return node_id
    # 第三步：通过液体类型匹配
    debug_print("  🧪 步骤3: 液体类型匹配...")
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            vessel_data = G.nodes[node_id].get('data', {})
            liquids = vessel_data.get('liquid', [])
            for liquid in liquids:
                if isinstance(liquid, dict):
                    liquid_type = (liquid.get('liquid_type') or liquid.get('name', '')).lower()
                    reagent_name = vessel_data.get('reagent_name', '').lower()
                    if solvent.lower() in liquid_type or solvent.lower() in reagent_name:
                        debug_print(f"  🎉 通过液体类型匹配找到容器: {node_id} ✨")
                        return node_id
    debug_print(f"❌ 找不到溶剂 '{solvent}' 对应的容器 😭")
    raise ValueError(f"找不到溶剂 '{solvent}' 对应的容器")
 def generate_recrystallize_protocol(
    G: nx.DiGraph,
    ratio: str,
    solvent1: str,
    solvent2: str,
    vessel: str,
    volume: Union[str, float],  # 🔧 修改：支持字符串和数值
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
    生成重结晶协议序列 - 支持单位
    Args:
        G: 有向图，节点为容器和设备
        ratio: 溶剂比例（如 "1:1", "3:7"）
        solvent1: 第一种溶剂名称
        solvent2: 第二种溶剂名称
        vessel: 目标容器
        volume: 总体积（支持 "100 mL", "50", "2.5 L" 等）
        **kwargs: 其他可选参数
    Returns:
        List[Dict[str, Any]]: 动作序列
    """
    action_sequence = []
    debug_print("💎" * 20)
    debug_print("🚀 开始生成重结晶协议（支持单位）✨")
    debug_print(f"📝 输入参数:")
    debug_print(f"  ⚖️ 比例: {ratio}")
    debug_print(f"  🧪 溶剂1: {solvent1}")
    debug_print(f"  🧪 溶剂2: {solvent2}")
    debug_print(f"  🥽 容器: {vessel}")
    debug_print(f"  💧 总体积: {volume} (类型: {type(volume)})")
    debug_print("💎" * 20)
    # 1. 验证目标容器存在
    debug_print("📍 步骤1: 验证目标容器... 🔧")
    if vessel not in G.nodes():
        debug_print(f"❌ 目标容器 '{vessel}' 不存在于系统中! 😱")
        raise ValueError(f"目标容器 '{vessel}' 不存在于系统中")
    debug_print(f"✅ 目标容器 '{vessel}' 验证通过 🎯")
    # 2. 🔧 新增：解析体积（支持单位）
    debug_print("📍 步骤2: 解析体积（支持单位）... 💧")
    final_volume = parse_volume_with_units(volume, "mL")
    debug_print(f"🎯 体积解析完成: {volume} → {final_volume}mL ✨")
    # 3. 解析比例
    debug_print("📍 步骤3: 解析比例... ⚖️")
    ratio1, ratio2 = parse_ratio(ratio)
    total_ratio = ratio1 + ratio2
    debug_print(f"🎯 比例解析完成: {ratio1}:{ratio2} (总比例: {total_ratio}) ✨")
    # 4. 计算各溶剂体积
    debug_print("📍 步骤4: 计算各溶剂体积... 🧮")
    volume1 = final_volume * (ratio1 / total_ratio)
    volume2 = final_volume * (ratio2 / total_ratio)
    debug_print(f"🧪 {solvent1} 体积: {volume1:.2f} mL ({ratio1}/{total_ratio} × {final_volume})")
    debug_print(f"🧪 {solvent2} 体积: {volume2:.2f} mL ({ratio2}/{total_ratio} × {final_volume})")
    debug_print(f"✅ 体积计算完成: 总计 {volume1 + volume2:.2f} mL 🎯")
    # 5. 查找溶剂容器
    debug_print("📍 步骤5: 查找溶剂容器... 🔍")
    try:
        debug_print(f"  🔍 查找溶剂1容器...")
        solvent1_vessel = find_solvent_vessel(G, solvent1)
        debug_print(f"  🎉 找到溶剂1容器: {solvent1_vessel} ✨")
    except ValueError as e:
        debug_print(f"  ❌ 溶剂1容器查找失败: {str(e)} 😭")
        raise ValueError(f"无法找到溶剂1 '{solvent1}': {str(e)}")
    try:
        debug_print(f"  🔍 查找溶剂2容器...")
        solvent2_vessel = find_solvent_vessel(G, solvent2)
        debug_print(f"  🎉 找到溶剂2容器: {solvent2_vessel} ✨")
    except ValueError as e:
        debug_print(f"  ❌ 溶剂2容器查找失败: {str(e)} 😭")
        raise ValueError(f"无法找到溶剂2 '{solvent2}': {str(e)}")
    # 6. 验证路径存在
    debug_print("📍 步骤6: 验证传输路径... 🛤️")
    try:
        path1 = nx.shortest_path(G, source=solvent1_vessel, target=vessel)
        debug_print(f"  🛤️ 溶剂1路径: {' → '.join(path1)} ✅")
    except nx.NetworkXNoPath:
        debug_print(f"  ❌ 溶剂1路径不可达: {solvent1_vessel} → {vessel} 😞")
        raise ValueError(f"从溶剂1容器 '{solvent1_vessel}' 到目标容器 '{vessel}' 没有可用路径")
    try:
        path2 = nx.shortest_path(G, source=solvent2_vessel, target=vessel)
        debug_print(f"  🛤️ 溶剂2路径: {' → '.join(path2)} ✅")
    except nx.NetworkXNoPath:
        debug_print(f"  ❌ 溶剂2路径不可达: {solvent2_vessel} → {vessel} 😞")
        raise ValueError(f"从溶剂2容器 '{solvent2_vessel}' 到目标容器 '{vessel}' 没有可用路径")
    # 7. 添加第一种溶剂
    debug_print("📍 步骤7: 添加第一种溶剂... 🧪")
    debug_print(f"  🚰 开始添加溶剂1: {solvent1} ({volume1:.2f} mL)")
    try:
        pump_actions1 = generate_pump_protocol_with_rinsing(
            G=G,
            from_vessel=solvent1_vessel,
            to_vessel=vessel,
            volume=volume1,             # 使用解析后的体积
            amount="",
            time=0.0,
            viscous=False,
            rinsing_solvent="",  # 重结晶不需要清洗
            rinsing_volume=0.0,
            rinsing_repeats=0,
            solid=False,
            flowrate=2.0,  # 正常流速
            transfer_flowrate=0.5
        )
        action_sequence.extend(pump_actions1)
        debug_print(f"  ✅ 溶剂1泵送动作已添加: {len(pump_actions1)} 个动作 🚰✨")
    except Exception as e:
        debug_print(f"  ❌ 溶剂1泵协议生成失败: {str(e)} 😭")
        raise ValueError(f"生成溶剂1泵协议时出错: {str(e)}")
    # 8. 等待溶剂1稳定
    debug_print("  ⏳ 添加溶剂1稳定等待...")
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": 5.0,  # 🕐 缩短等待时间：10.0s → 5.0s
            "description": f"等待溶剂1 {solvent1} 稳定"
        }
    })
    debug_print("  ✅ 溶剂1稳定等待已添加 ⏰✨")
    # 9. 添加第二种溶剂
    debug_print("📍 步骤8: 添加第二种溶剂... 🧪")
    debug_print(f"  🚰 开始添加溶剂2: {solvent2} ({volume2:.2f} mL)")
    try:
        pump_actions2 = generate_pump_protocol_with_rinsing(
            G=G,
            from_vessel=solvent2_vessel,
            to_vessel=vessel,
            volume=volume2,             # 使用解析后的体积
            amount="",
            time=0.0,
            viscous=False,
            rinsing_solvent="",  # 重结晶不需要清洗
            rinsing_volume=0.0,
            rinsing_repeats=0,
            solid=False,
            flowrate=2.0,  # 正常流速
            transfer_flowrate=0.5
        )
        action_sequence.extend(pump_actions2)
        debug_print(f"  ✅ 溶剂2泵送动作已添加: {len(pump_actions2)} 个动作 🚰✨")
    except Exception as e:
        debug_print(f"  ❌ 溶剂2泵协议生成失败: {str(e)} 😭")
        raise ValueError(f"生成溶剂2泵协议时出错: {str(e)}")
    # 10. 等待溶剂2稳定
    debug_print("  ⏳ 添加溶剂2稳定等待...")
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": 5.0,  # 🕐 缩短等待时间：10.0s → 5.0s
            "description": f"等待溶剂2 {solvent2} 稳定"
        }
    })
    debug_print("  ✅ 溶剂2稳定等待已添加 ⏰✨")
    # 11. 等待重结晶完成
    debug_print("📍 步骤9: 等待重结晶完成... 💎")
    # 🕐 模拟运行时间优化
    debug_print("  ⏱️ 检查模拟运行时间限制...")
    original_crystallize_time = 600.0  # 原始重结晶时间
    simulation_time_limit = 60.0  # 模拟运行时间限制：60秒
    final_crystallize_time = min(original_crystallize_time, simulation_time_limit)
    if original_crystallize_time > simulation_time_limit:
        debug_print(f"  🎮 模拟运行优化: {original_crystallize_time}s → {final_crystallize_time}s ⚡")
        debug_print(f"  📊 时间缩短: {original_crystallize_time/60:.1f}分钟 → {final_crystallize_time/60:.1f}分钟 🚀")
    else:
        debug_print(f"  ✅ 时间在限制内: {final_crystallize_time}s 保持不变 🎯")
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": final_crystallize_time,
            "description": f"等待重结晶完成（{solvent1}:{solvent2} = {ratio}，总体积 {final_volume}mL）" + (f" (模拟时间)" if original_crystallize_time != final_crystallize_time else "")
        }
    })
    debug_print(f"  ✅ 重结晶等待已添加: {final_crystallize_time}s 💎✨")
    # 显示时间调整信息
    if original_crystallize_time != final_crystallize_time:
        debug_print(f"  🎭 模拟优化说明: 原计划 {original_crystallize_time/60:.1f}分钟，实际模拟 {final_crystallize_time/60:.1f}分钟 ⚡")
    # 🎊 总结
    debug_print("💎" * 20)
    debug_print(f"🎉 重结晶协议生成完成! ✨")
    debug_print(f"📊 总动作数: {len(action_sequence)} 个")
    debug_print(f"🥽 目标容器: {vessel}")
    debug_print(f"💧 总体积: {final_volume}mL")
    debug_print(f"⚖️ 溶剂比例: {solvent1}:{solvent2} = {ratio1}:{ratio2}")
    debug_print(f"🧪 溶剂1: {solvent1} ({volume1:.2f}mL)")
    debug_print(f"🧪 溶剂2: {solvent2} ({volume2:.2f}mL)")
    debug_print(f"⏱️ 预计总时间: {(final_crystallize_time + 10)/60:.1f} 分钟 ⌛")
    debug_print("💎" * 20)
    return action_sequence
 # 测试函数
 def test_recrystallize_protocol():
    """测试重结晶协议"""
    debug_print("🧪 === RECRYSTALLIZE PROTOCOL 测试 === ✨")
    # 测试比例解析
    debug_print("⚖️ 测试比例解析...")
    test_ratios = ["1:1", "3:7", "50:50", "1-1", "2,8", "invalid"]
    for ratio in test_ratios:
        r1, r2 = parse_ratio(ratio)
        debug_print(f"  📊 比例 '{ratio}' -> {r1}:{r2}")
    debug_print("✅ 测试完成 🎉")
 if __name__ == "__main__":
    test_recrystallize_protocol()
--- a/unilabos/compile/reset_handling_protocol.py
+++ b/unilabos/compile/reset_handling_protocol.py
@@ -0,0 +1,249 @@
 import networkx as nx
 from typing import List, Dict, Any
 from .pump_protocol import generate_pump_protocol_with_rinsing
 def debug_print(message):
    """调试输出"""
    print(f"🔄 [RESET_HANDLING] {message}", flush=True)
 def find_solvent_vessel(G: nx.DiGraph, solvent: str) -> str:
    """
    查找溶剂容器，支持多种匹配模式
    Args:
        G: 网络图
        solvent: 溶剂名称（如 "methanol", "ethanol", "water"）
    Returns:
        str: 溶剂容器ID
    """
    debug_print(f"🔍 正在查找溶剂 '{solvent}' 的容器... 🧪")
    # 构建可能的容器名称
    possible_names = [
        f"flask_{solvent}",           # flask_methanol
        f"bottle_{solvent}",          # bottle_methanol
        f"reagent_{solvent}",         # reagent_methanol
        f"reagent_bottle_{solvent}",  # reagent_bottle_methanol
        f"{solvent}_flask",           # methanol_flask
        f"{solvent}_bottle",          # methanol_bottle
        f"{solvent}",                 # methanol
        f"vessel_{solvent}",          # vessel_methanol
    ]
    debug_print(f"📋 候选容器名称: {possible_names[:3]}... (共{len(possible_names)}个) 📝")
    # 第一步：通过容器名称匹配
    debug_print("  🎯 步骤1: 精确名称匹配...")
    for vessel_name in possible_names:
        if vessel_name in G.nodes():
            debug_print(f"  🎉 通过名称匹配找到容器: {vessel_name} ✨")
            return vessel_name
    debug_print("  😞 精确名称匹配失败，尝试模糊匹配... 🔍")
    # 第二步：通过模糊匹配
    debug_print("  🔍 步骤2: 模糊名称匹配...")
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            node_name = G.nodes[node_id].get('name', '').lower()
            # 检查是否包含溶剂名称
            if solvent.lower() in node_id.lower() or solvent.lower() in node_name:
                debug_print(f"  🎉 通过模糊匹配找到容器: {node_id} ✨")
                return node_id
    debug_print("  😞 模糊匹配失败，尝试液体类型匹配... 🧪")
    # 第三步：通过液体类型匹配
    debug_print("  🧪 步骤3: 液体类型匹配...")
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            vessel_data = G.nodes[node_id].get('data', {})
            liquids = vessel_data.get('liquid', [])
            for liquid in liquids:
                if isinstance(liquid, dict):
                    liquid_type = (liquid.get('liquid_type') or liquid.get('name', '')).lower()
                    reagent_name = vessel_data.get('reagent_name', '').lower()
                    if solvent.lower() in liquid_type or solvent.lower() in reagent_name:
                        debug_print(f"  🎉 通过液体类型匹配找到容器: {node_id} ✨")
                        return node_id
    # 列出可用容器帮助调试
    debug_print("  📊 显示可用容器信息...")
    available_containers = []
    for node_id in G.nodes():
        if G.nodes[node_id].get('type') == 'container':
            vessel_data = G.nodes[node_id].get('data', {})
            liquids = vessel_data.get('liquid', [])
            liquid_types = [liquid.get('liquid_type', '') or liquid.get('name', '') 
                           for liquid in liquids if isinstance(liquid, dict)]
            available_containers.append({
                'id': node_id,
                'name': G.nodes[node_id].get('name', ''),
                'liquids': liquid_types,
                'reagent_name': vessel_data.get('reagent_name', '')
            })
    debug_print(f"  📋 可用容器列表 (共{len(available_containers)}个):")
    for i, container in enumerate(available_containers[:5]):  # 只显示前5个
        debug_print(f"    {i+1}. 🥽 {container['id']}: {container['name']}")
        debug_print(f"       💧 液体: {container['liquids']}")
        debug_print(f"       🧪 试剂: {container['reagent_name']}")
    if len(available_containers) > 5:
        debug_print(f"    ... 还有 {len(available_containers)-5} 个容器 📦")
    debug_print(f"❌ 找不到溶剂 '{solvent}' 对应的容器 😭")
    raise ValueError(f"找不到溶剂 '{solvent}' 对应的容器。尝试了: {possible_names[:3]}...")
 def generate_reset_handling_protocol(
    G: nx.DiGraph,
    solvent: str,
    **kwargs  # 接收其他可能的参数但不使用
 ) -> List[Dict[str, Any]]:
    """
    生成重置处理协议序列
    Args:
        G: 有向图，节点为容器和设备
        solvent: 溶剂名称（从XDL传入）
        **kwargs: 其他可选参数，但不使用
    Returns:
        List[Dict[str, Any]]: 动作序列
    """
    action_sequence = []
    # 固定参数
    target_vessel = "main_reactor"  # 默认目标容器
    volume = 50.0  # 默认体积 50 mL
    debug_print("🔄" * 20)
    debug_print("🚀 开始生成重置处理协议 ✨")
    debug_print(f"📝 输入参数:")
    debug_print(f"  🧪 溶剂: {solvent}")
    debug_print(f"  🥽 目标容器: {target_vessel}")
    debug_print(f"  💧 体积: {volume} mL")
    debug_print(f"  ⚙️ 其他参数: {kwargs}")
    debug_print("🔄" * 20)
    # 1. 验证目标容器存在
    debug_print("📍 步骤1: 验证目标容器... 🔧")
    if target_vessel not in G.nodes():
        debug_print(f"❌ 目标容器 '{target_vessel}' 不存在于系统中! 😱")
        raise ValueError(f"目标容器 '{target_vessel}' 不存在于系统中")
    debug_print(f"✅ 目标容器 '{target_vessel}' 验证通过 🎯")
    # 2. 查找溶剂容器
    debug_print("📍 步骤2: 查找溶剂容器... 🔍")
    try:
        solvent_vessel = find_solvent_vessel(G, solvent)
        debug_print(f"🎉 找到溶剂容器: {solvent_vessel} ✨")
    except ValueError as e:
        debug_print(f"❌ 溶剂容器查找失败: {str(e)} 😭")
        raise ValueError(f"无法找到溶剂 '{solvent}': {str(e)}")
    # 3. 验证路径存在
    debug_print("📍 步骤3: 验证传输路径... 🛤️")
    try:
        path = nx.shortest_path(G, source=solvent_vessel, target=target_vessel)
        debug_print(f"🛤️ 找到路径: {' → '.join(path)} ✅")
    except nx.NetworkXNoPath:
        debug_print(f"❌ 路径不可达: {solvent_vessel} → {target_vessel} 😞")
        raise ValueError(f"从溶剂容器 '{solvent_vessel}' 到目标容器 '{target_vessel}' 没有可用路径")
    # 4. 使用pump_protocol转移溶剂
    debug_print("📍 步骤4: 转移溶剂... 🚰")
    debug_print(f"  🚛 开始转移: {solvent_vessel} → {target_vessel}")
    debug_print(f"  💧 转移体积: {volume} mL")
    try:
        debug_print("  🔄 生成泵送协议...")
        pump_actions = generate_pump_protocol_with_rinsing(
            G=G,
            from_vessel=solvent_vessel,
            to_vessel=target_vessel,
            volume=volume,
            amount="",
            time=0.0,
            viscous=False,
            rinsing_solvent="",  # 重置处理不需要清洗
            rinsing_volume=0.0,
            rinsing_repeats=0,
            solid=False,
            flowrate=2.5,  # 正常流速
            transfer_flowrate=0.5  # 正常转移流速
        )
        action_sequence.extend(pump_actions)
        debug_print(f"  ✅ 泵送协议已添加: {len(pump_actions)} 个动作 🚰✨")
    except Exception as e:
        debug_print(f"  ❌ 泵送协议生成失败: {str(e)} 😭")
        raise ValueError(f"生成泵协议时出错: {str(e)}")
    # 5. 等待溶剂稳定
    debug_print("📍 步骤5: 等待溶剂稳定... ⏳")
    # 🕐 模拟运行时间优化
    debug_print("  ⏱️ 检查模拟运行时间限制...")
    original_wait_time = 10.0  # 原始等待时间
    simulation_time_limit = 5.0  # 模拟运行时间限制：5秒
    final_wait_time = min(original_wait_time, simulation_time_limit)
    if original_wait_time > simulation_time_limit:
        debug_print(f"  🎮 模拟运行优化: {original_wait_time}s → {final_wait_time}s ⚡")
        debug_print(f"  📊 时间缩短: {original_wait_time}s → {final_wait_time}s 🚀")
    else:
        debug_print(f"  ✅ 时间在限制内: {final_wait_time}s 保持不变 🎯")
    action_sequence.append({
        "action_name": "wait",
        "action_kwargs": {
            "time": final_wait_time,
            "description": f"等待溶剂 {solvent} 稳定" + (f" (模拟时间)" if original_wait_time != final_wait_time else "")
        }
    })
    debug_print(f"  ✅ 稳定等待已添加: {final_wait_time}s ⏰✨")
    # 显示时间调整信息
    if original_wait_time != final_wait_time:
        debug_print(f"  🎭 模拟优化说明: 原计划 {original_wait_time}s，实际模拟 {final_wait_time}s ⚡")
    # 🎊 总结
    debug_print("🔄" * 20)
    debug_print(f"🎉 重置处理协议生成完成! ✨")
    debug_print(f"📊 总动作数: {len(action_sequence)} 个")
    debug_print(f"🧪 溶剂: {solvent}")
    debug_print(f"🥽 源容器: {solvent_vessel}")
    debug_print(f"🥽 目标容器: {target_vessel}")
    debug_print(f"💧 转移体积: {volume} mL")
    debug_print(f"⏱️ 预计总时间: {(final_wait_time + 5):.0f} 秒 ⌛")
    debug_print(f"🎯 已添加 {volume} mL {solvent} 到 {target_vessel} 🚰✨")
    debug_print("🔄" * 20)
    return action_sequence
 # 测试函数
 def test_reset_handling_protocol():
    """测试重置处理协议"""
    debug_print("🧪 === RESET HANDLING PROTOCOL 测试 === ✨")
    # 测试溶剂名称
    debug_print("🧪 测试常用溶剂名称...")
    test_solvents = ["methanol", "ethanol", "water", "acetone", "dmso"]
    for solvent in test_solvents:
        debug_print(f"  🔍 测试溶剂: {solvent}")
    debug_print("✅ 测试完成 🎉")
 if __name__ == "__main__":
    test_reset_handling_protocol()
--- a/unilabos/compile/run_column_protocol.py
+++ b/unilabos/compile/run_column_protocol.py
@@ -1,102 +1,646 @@
-from typing import List, Dict, Any
+from typing import List, Dict, Any, Union
 import networkx as nx
 import logging
 import re
 from .pump_protocol import generate_pump_protocol_with_rinsing
 logger = logging.getLogger(__name__)
 def debug_print(message):
    """调试输出"""
    print(f"[RUN_COLUMN] {message}", flush=True)
    logger.info(f"[RUN_COLUMN] {message}")
 def parse_percentage(pct_str: str) -> float:
    """
    解析百分比字符串为数值
    Args:
        pct_str: 百分比字符串（如 "40 %", "40%", "40"）
    Returns:
        float: 百分比数值（0-100）
    """
    if not pct_str or not pct_str.strip():
        return 0.0
    pct_str = pct_str.strip().lower()
    debug_print(f"解析百分比: '{pct_str}'")
    # 移除百分号和空格
    pct_clean = re.sub(r'[%\s]', '', pct_str)
    # 提取数字
    match = re.search(r'([0-9]*\.?[0-9]+)', pct_clean)
    if match:
        value = float(match.group(1))
        debug_print(f"百分比解析结果: {value}%")
        return value
    debug_print(f"⚠️ 无法解析百分比: '{pct_str}'，返回0.0")
    return 0.0
 def parse_ratio(ratio_str: str) -> tuple:
    """
    解析比例字符串为两个数值
    Args:
        ratio_str: 比例字符串（如 "5:95", "1:1", "40:60"）
    Returns:
        tuple: (ratio1, ratio2) 两个比例值
    """
    if not ratio_str or not ratio_str.strip():
        return (50.0, 50.0)  # 默认1:1
    ratio_str = ratio_str.strip()
    debug_print(f"解析比例: '{ratio_str}'")
    # 支持多种分隔符：: / -
    if ':' in ratio_str:
        parts = ratio_str.split(':')
    elif '/' in ratio_str:
        parts = ratio_str.split('/')
    elif '-' in ratio_str:
        parts = ratio_str.split('-')
    elif 'to' in ratio_str.lower():
        parts = ratio_str.lower().split('to')
    else:
        debug_print(f"⚠️ 无法解析比例格式: '{ratio_str}'，使用默认1:1")
        return (50.0, 50.0)
    if len(parts) >= 2:
        try:
            ratio1 = float(parts[0].strip())
            ratio2 = float(parts[1].strip())
            total = ratio1 + ratio2
            # 转换为百分比
            pct1 = (ratio1 / total) * 100
            pct2 = (ratio2 / total) * 100
            debug_print(f"比例解析结果: {ratio1}:{ratio2} -> {pct1:.1f}%:{pct2:.1f}%")
            return (pct1, pct2)
        except ValueError as e:
            debug_print(f"⚠️ 比例数值转换失败: {str(e)}")
    debug_print(f"⚠️ 比例解析失败，使用默认1:1")
    return (50.0, 50.0)
 def parse_rf_value(rf_str: str) -> float:
    """
    解析Rf值字符串
    Args:
        rf_str: Rf值字符串（如 "0.3", "0.45", "?"）
    Returns:
        float: Rf值（0-1）
    """
    if not rf_str or not rf_str.strip():
        return 0.3  # 默认Rf值
    rf_str = rf_str.strip().lower()
    debug_print(f"解析Rf值: '{rf_str}'")
    # 处理未知Rf值
    if rf_str in ['?', 'unknown', 'tbd', 'to be determined']:
        default_rf = 0.3
        debug_print(f"检测到未知Rf值，使用默认值: {default_rf}")
        return default_rf
    # 提取数字
    match = re.search(r'([0-9]*\.?[0-9]+)', rf_str)
    if match:
        value = float(match.group(1))
        # 确保Rf值在0-1范围内
        if value > 1.0:
            value = value / 100.0  # 可能是百分比形式
        value = max(0.0, min(1.0, value))  # 限制在0-1范围
        debug_print(f"Rf值解析结果: {value}")
        return value
    debug_print(f"⚠️ 无法解析Rf值: '{rf_str}'，使用默认值0.3")
    return 0.3
 def find_column_device(G: nx.DiGraph) -> str:
    """查找柱层析设备"""
    debug_print("查找柱层析设备...")
    # 查找虚拟柱设备
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if 'virtual_column' in node_class.lower() or 'column' in node_class.lower():
            debug_print(f"✅ 找到柱层析设备: {node}")
            return node
    # 如果没有找到，尝试创建虚拟设备名称
    possible_names = ['column_1', 'virtual_column_1', 'chromatography_column_1']
    for name in possible_names:
        if name in G.nodes():
            debug_print(f"✅ 找到柱设备: {name}")
            return name
    debug_print("⚠️ 未找到柱层析设备，将使用pump protocol直接转移")
    return ""
 def find_column_vessel(G: nx.DiGraph, column: str) -> str:
    """查找柱容器"""
    debug_print(f"查找柱容器: '{column}'")
    # 直接检查column参数是否是容器
    if column in G.nodes():
        node_type = G.nodes[column].get('type', '')
        if node_type == 'container':
            debug_print(f"✅ 找到柱容器: {column}")
            return column
    # 尝试常见的命名规则
    possible_names = [
        f"column_{column}",
        f"{column}_column", 
        f"vessel_{column}",
        f"{column}_vessel",
        "column_vessel",
        "chromatography_column",
        "silica_column",
        "preparative_column",
        "column"
    ]
    for vessel_name in possible_names:
        if vessel_name in G.nodes():
            node_type = G.nodes[vessel_name].get('type', '')
            if node_type == 'container':
                debug_print(f"✅ 找到柱容器: {vessel_name}")
                return vessel_name
    debug_print(f"⚠️ 未找到柱容器，将直接在源容器中进行分离")
    return ""
 def find_solvent_vessel(G: nx.DiGraph, solvent: str) -> str:
    """查找溶剂容器 - 增强版"""
    if not solvent or not solvent.strip():
        return ""
    solvent = solvent.strip().replace(' ', '_').lower()
    debug_print(f"查找溶剂容器: '{solvent}'")
    # 🔧 方法1：直接搜索 data.reagent_name
    for node in G.nodes():
        node_data = G.nodes[node].get('data', {})
        node_type = G.nodes[node].get('type', '')
        # 只搜索容器类型的节点
        if node_type == 'container':
            reagent_name = node_data.get('reagent_name', '').lower()
            reagent_config = G.nodes[node].get('config', {}).get('reagent', '').lower()
            # 检查 data.reagent_name 和 config.reagent
            if reagent_name == solvent or reagent_config == solvent:
                debug_print(f"✅ 通过reagent_name找到溶剂容器: {node} (reagent: {reagent_name or reagent_config})")
                return node
            # 模糊匹配 reagent_name
            if solvent in reagent_name or reagent_name in solvent:
                debug_print(f"✅ 通过reagent_name模糊匹配到溶剂容器: {node} (reagent: {reagent_name})")
                return node
            if solvent in reagent_config or reagent_config in solvent:
                debug_print(f"✅ 通过config.reagent模糊匹配到溶剂容器: {node} (reagent: {reagent_config})")
                return node
    # 🔧 方法2：常见的溶剂容器命名规则
    possible_names = [
        f"flask_{solvent}",
        f"bottle_{solvent}",
        f"reagent_{solvent}",
        f"{solvent}_bottle",
        f"{solvent}_flask",
        f"solvent_{solvent}",
        f"reagent_bottle_{solvent}"
    ]
    for vessel_name in possible_names:
        if vessel_name in G.nodes():
            node_type = G.nodes[vessel_name].get('type', '')
            if node_type == 'container':
                debug_print(f"✅ 通过命名规则找到溶剂容器: {vessel_name}")
                return vessel_name
    # 🔧 方法3：节点名称模糊匹配
    for node in G.nodes():
        node_type = G.nodes[node].get('type', '')
        if node_type == 'container':
            if ('flask_' in node or 'bottle_' in node or 'reagent_' in node) and solvent in node.lower():
                debug_print(f"✅ 通过节点名称模糊匹配到溶剂容器: {node}")
                return node
    # 🔧 方法4：特殊溶剂名称映射
    solvent_mapping = {
        'dmf': ['dmf', 'dimethylformamide', 'n,n-dimethylformamide'],
        'ethyl_acetate': ['ethyl_acetate', 'ethylacetate', 'etoac', 'ea'],
        'hexane': ['hexane', 'hexanes', 'n-hexane'],
        'methanol': ['methanol', 'meoh', 'ch3oh'],
        'water': ['water', 'h2o', 'distilled_water'],
        'acetone': ['acetone', 'ch3coch3', '2-propanone'],
        'dichloromethane': ['dichloromethane', 'dcm', 'ch2cl2', 'methylene_chloride'],
        'chloroform': ['chloroform', 'chcl3', 'trichloromethane']
    }
    # 查找映射的同义词
    for canonical_name, synonyms in solvent_mapping.items():
        if solvent in synonyms:
            debug_print(f"检测到溶剂同义词: '{solvent}' -> '{canonical_name}'")
            return find_solvent_vessel(G, canonical_name)  # 递归搜索
    debug_print(f"⚠️ 未找到溶剂 '{solvent}' 的容器")
    return ""
 def get_vessel_liquid_volume(G: nx.DiGraph, vessel: str) -> float:
    """获取容器中的液体体积 - 增强版"""
    if vessel not in G.nodes():
        debug_print(f"⚠️ 节点 '{vessel}' 不存在")
        return 0.0
    node_type = G.nodes[vessel].get('type', '')
    vessel_data = G.nodes[vessel].get('data', {})
    debug_print(f"读取节点 '{vessel}' (类型: {node_type}) 体积数据: {vessel_data}")
    # 🔧 如果是设备类型，尝试查找关联的容器
    if node_type == 'device':
        debug_print(f"'{vessel}' 是设备，尝试查找关联容器...")
        # 查找是否有内置容器数据
        config_data = G.nodes[vessel].get('config', {})
        if 'volume' in config_data:
            default_volume = config_data.get('volume', 50.0)
            debug_print(f"使用设备默认容量: {default_volume}mL")
            return default_volume
        # 对于旋蒸等设备，使用默认值
        if 'rotavap' in vessel.lower():
            default_volume = 50.0
            debug_print(f"旋蒸设备使用默认容量: {default_volume}mL")
            return default_volume
        debug_print(f"⚠️ 设备 '{vessel}' 无法确定容量，返回0")
        return 0.0
    # 🔧 如果是容器类型，正常读取体积
    total_volume = 0.0
    # 方法1：检查液体列表
    liquids = vessel_data.get('liquid', [])
    if isinstance(liquids, list):
        for liquid in liquids:
            if isinstance(liquid, dict):
                volume = liquid.get('volume') or liquid.get('liquid_volume', 0.0)
                total_volume += volume
    # 方法2：检查直接体积字段
    if total_volume == 0.0:
        volume_keys = ['current_volume', 'total_volume', 'volume', 'liquid_volume']
        for key in volume_keys:
            if key in vessel_data:
                try:
                    total_volume = float(vessel_data[key])
                    if total_volume > 0:
                        break
                except (ValueError, TypeError):
                    continue
    # 方法3：检查配置中的初始体积
    if total_volume == 0.0:
        config_data = G.nodes[vessel].get('config', {})
        if 'current_volume' in config_data:
            try:
                total_volume = float(config_data['current_volume'])
            except (ValueError, TypeError):
                pass
    debug_print(f"容器 '{vessel}' 总体积: {total_volume}mL")
    return total_volume
 def calculate_solvent_volumes(total_volume: float, pct1: float, pct2: float) -> tuple:
    """根据百分比计算溶剂体积"""
    volume1 = (total_volume * pct1) / 100.0
    volume2 = (total_volume * pct2) / 100.0
    debug_print(f"溶剂体积计算: 总体积{total_volume}mL")
    debug_print(f"  - 溶剂1: {pct1}% = {volume1}mL")
    debug_print(f"  - 溶剂2: {pct2}% = {volume2}mL")
    return (volume1, volume2)
 def generate_run_column_protocol(
    G: nx.DiGraph,
    from_vessel: str,
    to_vessel: str,
-    column: str
+    column: str,
    rf: str = "",
    pct1: str = "",
    pct2: str = "",
    solvent1: str = "",
    solvent2: str = "",
    ratio: str = "",
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
-    生成柱层析分离的协议序列
+    生成柱层析分离的协议序列 - 增强版
    支持新版XDL的所有参数，具有高兼容性和容错性
    Args:
-        G: 有向图，节点为设备和容器
+        G: 有向图，节点为设备和容器，边为流体管道
-        from_vessel: 源容器的名称，即样品起始所在的容器
+        from_vessel: 源容器的名称，即样品起始所在的容器（必需）
-        to_vessel: 目标容器的名称，分离后的样品要到达的容器
+        to_vessel: 目标容器的名称，分离后的样品要到达的容器（必需）
-        column: 所使用的柱子的名称
+        column: 所使用的柱子的名称（必需）
        rf: Rf值（可选，支持 "?" 表示未知）
        pct1: 第一种溶剂百分比（如 "40 %"，可选）
        pct2: 第二种溶剂百分比（如 "50 %"，可选）
        solvent1: 第一种溶剂名称（可选）
        solvent2: 第二种溶剂名称（可选）
        ratio: 溶剂比例（如 "5:95"，可选，优先级高于pct1/pct2）
        **kwargs: 其他可选参数
    Returns:
        List[Dict[str, Any]]: 柱层析分离操作的动作序列
    Raises:
        ValueError: 当找不到必要的设备时抛出异常
    Examples:
        run_column_protocol = generate_run_column_protocol(G, "reactor", "collection_flask", "silica_column")
    """
    debug_print("=" * 60)
    debug_print("开始生成柱层析协议")
    debug_print(f"输入参数:")
    debug_print(f"  - from_vessel: '{from_vessel}'")
    debug_print(f"  - to_vessel: '{to_vessel}'")
    debug_print(f"  - column: '{column}'")
    debug_print(f"  - rf: '{rf}'")
    debug_print(f"  - pct1: '{pct1}'")
    debug_print(f"  - pct2: '{pct2}'")
    debug_print(f"  - solvent1: '{solvent1}'")
    debug_print(f"  - solvent2: '{solvent2}'")
    debug_print(f"  - ratio: '{ratio}'")
    debug_print(f"  - 其他参数: {kwargs}")
    debug_print("=" * 60)
    action_sequence = []
-    # 验证容器是否存在
+    # === 参数验证 ===
    debug_print("步骤1: 参数验证...")
    if not from_vessel:
        raise ValueError("from_vessel 参数不能为空")
    if not to_vessel:
        raise ValueError("to_vessel 参数不能为空")
    if not column:
        raise ValueError("column 参数不能为空")
    if from_vessel not in G.nodes():
-        raise ValueError(f"源容器 {from_vessel} 不存在于图中")
+        raise ValueError(f"源容器 '{from_vessel}' 不存在于系统中")
    if to_vessel not in G.nodes():
-        raise ValueError(f"目标容器 {to_vessel} 不存在于图中")
+        raise ValueError(f"目标容器 '{to_vessel}' 不存在于系统中")
-    # 查找转移泵设备（用于样品转移）
+    debug_print("✅ 基本参数验证通过")
    pump_nodes = [node for node in G.nodes() 
                  if G.nodes[node].get('class') == 'virtual_transfer_pump']
-    if not pump_nodes:
+    # === 参数解析 ===
-        raise ValueError("没有找到可用的转移泵设备")
+    debug_print("步骤2: 参数解析...")
-    pump_id = pump_nodes[0]
+    # 解析Rf值
    final_rf = parse_rf_value(rf)
    debug_print(f"最终Rf值: {final_rf}")
    # 解析溶剂比例（ratio优先级高于pct1/pct2）
    if ratio and ratio.strip():
        final_pct1, final_pct2 = parse_ratio(ratio)
        debug_print(f"使用ratio参数: {final_pct1:.1f}% : {final_pct2:.1f}%")
    else:
        final_pct1 = parse_percentage(pct1) if pct1 else 50.0
        final_pct2 = parse_percentage(pct2) if pct2 else 50.0
        # 如果百分比和不是100%，进行归一化
        total_pct = final_pct1 + final_pct2
        if total_pct == 0:
            final_pct1, final_pct2 = 50.0, 50.0
        elif total_pct != 100.0:
            final_pct1 = (final_pct1 / total_pct) * 100
            final_pct2 = (final_pct2 / total_pct) * 100
        debug_print(f"使用百分比参数: {final_pct1:.1f}% : {final_pct2:.1f}%")
    # 设置默认溶剂（如果未指定）
    final_solvent1 = solvent1.strip() if solvent1 else "ethyl_acetate"
    final_solvent2 = solvent2.strip() if solvent2 else "hexane"
    debug_print(f"最终溶剂: {final_solvent1} : {final_solvent2}")
    # === 查找设备和容器 ===
    debug_print("步骤3: 查找设备和容器...")
    # 查找柱层析设备
-    column_nodes = [node for node in G.nodes() 
+    column_device_id = find_column_device(G)
                   if G.nodes[node].get('class') == 'virtual_column']
-    if not column_nodes:
+    # 查找柱容器
-        raise ValueError("没有找到可用的柱层析设备")
+    column_vessel = find_column_vessel(G, column)
-    column_id = column_nodes[0]
+    # 查找溶剂容器
    solvent1_vessel = find_solvent_vessel(G, final_solvent1)
    solvent2_vessel = find_solvent_vessel(G, final_solvent2)
-    # 步骤1：将样品从源容器转移到柱子上
+    debug_print(f"设备映射:")
-    action_sequence.append({
+    debug_print(f"  - 柱设备: '{column_device_id}'")
-        "device_id": pump_id,
+    debug_print(f"  - 柱容器: '{column_vessel}'")
-        "action_name": "transfer",
+    debug_print(f"  - 溶剂1容器: '{solvent1_vessel}'")
-        "action_kwargs": {
+    debug_print(f"  - 溶剂2容器: '{solvent2_vessel}'")
            "from_vessel": from_vessel,
            "to_vessel": column_id,  # 将样品转移到柱子设备
            "volume": 0.0,  # 转移所有液体，体积由系统确定
            "amount": f"样品上柱 - 使用 {column}",
            "time": 0.0,
            "viscous": False,
            "rinsing_solvent": "",
            "rinsing_volume": 0.0,
            "rinsing_repeats": 0,
            "solid": False
        }
    })
-    # 步骤2：运行柱层析分离
+    # === 获取源容器体积 ===
-    action_sequence.append({
+    debug_print("步骤4: 获取源容器体积...")
        "device_id": column_id,
        "action_name": "run_column",
        "action_kwargs": {
            "from_vessel": from_vessel,
            "to_vessel": to_vessel,
            "column": column
        }
    })
-    # 步骤3：将分离后的产物从柱子转移到目标容器
+    source_volume = get_vessel_liquid_volume(G, from_vessel)
-    action_sequence.append({
+    if source_volume <= 0:
-        "device_id": pump_id,
+        source_volume = 50.0  # 默认体积
-        "action_name": "transfer",
+        debug_print(f"⚠️ 无法获取源容器体积，使用默认值: {source_volume}mL")
-        "action_kwargs": {
+    else:
-            "from_vessel": column_id,  # 从柱子设备转移
+        debug_print(f"✅ 源容器体积: {source_volume}mL")
-            "to_vessel": to_vessel,
+    
-            "volume": 0.0,  # 转移所有液体，体积由系统确定
+    # === 计算溶剂体积 ===
-            "amount": f"收集分离产物 - 来自 {column}",
+    debug_print("步骤5: 计算溶剂体积...")
-            "time": 0.0,
+    
-            "viscous": False,
+    # 洗脱溶剂通常是样品体积的2-5倍
-            "rinsing_solvent": "",
+    total_elution_volume = source_volume * 3.0
-            "rinsing_volume": 0.0,
+    solvent1_volume, solvent2_volume = calculate_solvent_volumes(
-            "rinsing_repeats": 0,
+        total_elution_volume, final_pct1, final_pct2
-            "solid": False
+    )
-        }
+    
-    })
+    # === 执行柱层析流程 ===
    debug_print("步骤6: 执行柱层析流程...")
    try:
        # 步骤6.1: 样品上柱（如果有独立的柱容器）
        if column_vessel and column_vessel != from_vessel:
            debug_print(f"6.1: 样品上柱 - {source_volume}mL 从 {from_vessel} 到 {column_vessel}")
            try:
                sample_transfer_actions = generate_pump_protocol_with_rinsing(
                    G=G,
                    from_vessel=from_vessel,
                    to_vessel=column_vessel,
                    volume=source_volume,
                    flowrate=1.0,  # 慢速上柱
                    transfer_flowrate=0.5,
                    rinsing_solvent="",  # 暂不冲洗
                    rinsing_volume=0.0,
                    rinsing_repeats=0
                )
                action_sequence.extend(sample_transfer_actions)
                debug_print(f"✅ 样品上柱完成，添加了 {len(sample_transfer_actions)} 个动作")
            except Exception as e:
                debug_print(f"⚠️ 样品上柱失败: {str(e)}")
        # 步骤6.2: 添加洗脱溶剂1（如果有溶剂容器）
        if solvent1_vessel and solvent1_volume > 0:
            debug_print(f"6.2: 添加洗脱溶剂1 - {solvent1_volume:.1f}mL {final_solvent1}")
            try:
                target_vessel = column_vessel if column_vessel else from_vessel
                solvent1_transfer_actions = generate_pump_protocol_with_rinsing(
                    G=G,
                    from_vessel=solvent1_vessel,
                    to_vessel=target_vessel,
                    volume=solvent1_volume,
                    flowrate=2.0,
                    transfer_flowrate=1.0
                )
                action_sequence.extend(solvent1_transfer_actions)
                debug_print(f"✅ 溶剂1添加完成，添加了 {len(solvent1_transfer_actions)} 个动作")
            except Exception as e:
                debug_print(f"⚠️ 溶剂1添加失败: {str(e)}")
        # 步骤6.3: 添加洗脱溶剂2（如果有溶剂容器）
        if solvent2_vessel and solvent2_volume > 0:
            debug_print(f"6.3: 添加洗脱溶剂2 - {solvent2_volume:.1f}mL {final_solvent2}")
            try:
                target_vessel = column_vessel if column_vessel else from_vessel
                solvent2_transfer_actions = generate_pump_protocol_with_rinsing(
                    G=G,
                    from_vessel=solvent2_vessel,
                    to_vessel=target_vessel,
                    volume=solvent2_volume,
                    flowrate=2.0,
                    transfer_flowrate=1.0
                )
                action_sequence.extend(solvent2_transfer_actions)
                debug_print(f"✅ 溶剂2添加完成，添加了 {len(solvent2_transfer_actions)} 个动作")
            except Exception as e:
                debug_print(f"⚠️ 溶剂2添加失败: {str(e)}")
        # 步骤6.4: 使用柱层析设备执行分离（如果有设备）
        if column_device_id:
            debug_print(f"6.4: 使用柱层析设备执行分离")
            column_separation_action = {
                "device_id": column_device_id,
                "action_name": "run_column",
                "action_kwargs": {
                    "from_vessel": from_vessel,
                    "to_vessel": to_vessel,
                    "column": column,
                    "rf": rf,
                    "pct1": pct1,
                    "pct2": pct2,
                    "solvent1": solvent1,
                    "solvent2": solvent2,
                    "ratio": ratio
                }
            }
            action_sequence.append(column_separation_action)
            debug_print(f"✅ 柱层析设备动作已添加")
            # 等待分离完成
            separation_time = max(30, int(total_elution_volume / 2))  # 基于体积估算时间
            action_sequence.append({
                "action_name": "wait",
                "action_kwargs": {"time": separation_time}
            })
            debug_print(f"✅ 等待分离完成: {separation_time}秒")
        # 步骤6.5: 产物收集（从柱容器到目标容器）
        if column_vessel and column_vessel != to_vessel:
            debug_print(f"6.5: 产物收集 - 从 {column_vessel} 到 {to_vessel}")
            try:
                # 估算产物体积（原始样品体积的70-90%）
                product_volume = source_volume * 0.8
                product_transfer_actions = generate_pump_protocol_with_rinsing(
                    G=G,
                    from_vessel=column_vessel,
                    to_vessel=to_vessel,
                    volume=product_volume,
                    flowrate=1.5,
                    transfer_flowrate=0.8
                )
                action_sequence.extend(product_transfer_actions)
                debug_print(f"✅ 产物收集完成，添加了 {len(product_transfer_actions)} 个动作")
            except Exception as e:
                debug_print(f"⚠️ 产物收集失败: {str(e)}")
        # 步骤6.6: 如果没有独立的柱设备和容器，执行简化的直接转移
        if not column_device_id and not column_vessel:
            debug_print(f"6.6: 简化模式 - 直接转移 {source_volume}mL 从 {from_vessel} 到 {to_vessel}")
            try:
                direct_transfer_actions = generate_pump_protocol_with_rinsing(
                    G=G,
                    from_vessel=from_vessel,
                    to_vessel=to_vessel,
                    volume=source_volume,
                    flowrate=2.0,
                    transfer_flowrate=1.0
                )
                action_sequence.extend(direct_transfer_actions)
                debug_print(f"✅ 直接转移完成，添加了 {len(direct_transfer_actions)} 个动作")
            except Exception as e:
                debug_print(f"⚠️ 直接转移失败: {str(e)}")
    except Exception as e:
        debug_print(f"❌ 协议生成失败: {str(e)} 😭")
        # 不添加不确定的动作，直接让action_sequence保持为空列表
        # action_sequence 已经在函数开始时初始化为 []
    # 确保至少有一个有效的动作，如果完全失败就返回空列表
    if not action_sequence:
        debug_print("⚠️ 没有生成任何有效动作")
        # 可以选择返回空列表或添加一个基本的等待动作
        action_sequence.append({
            "action_name": "wait",
            "action_kwargs": {
                "time": 1.0,
                "description": "柱层析协议执行完成"
            }
        })
    # 🎊 总结
    debug_print("🧪" * 20)
    debug_print(f"🎉 柱层析协议生成完成! ✨")
    debug_print(f"📊 总动作数: {len(action_sequence)} 个")
    debug_print(f"🥽 路径: {from_vessel} → {to_vessel}")
    debug_print(f"🏛️ 柱子: {column}")
    debug_print(f"🧪 溶剂: {final_solvent1}:{final_solvent2}")
    debug_print("🧪" * 20)
    return action_sequence
 # 测试函数
 def test_run_column_protocol():
    """测试柱层析协议"""
    debug_print("🧪 === RUN COLUMN PROTOCOL 测试 === ✨")
    debug_print("✅ 测试完成 🎉")
 if __name__ == "__main__":
    test_run_column_protocol()
--- a/unilabos/compile/separate_protocol.py
+++ b/unilabos/compile/separate_protocol.py
@@ -1,230 +1,670 @@
 import numpy as np
 import networkx as nx
 import re
 import logging
 import sys
 from typing import List, Dict, Any, Union
 from .pump_protocol import generate_pump_protocol_with_rinsing
 logger = logging.getLogger(__name__)
 # 确保输出编码为UTF-8
 if hasattr(sys.stdout, 'reconfigure'):
    try:
        sys.stdout.reconfigure(encoding='utf-8')
        sys.stderr.reconfigure(encoding='utf-8')
    except:
        pass
 def debug_print(message):
    """调试输出函数 - 支持中文"""
    try:
        # 确保消息是字符串格式
        safe_message = str(message)
        print(f"[分离协议] {safe_message}", flush=True)
        logger.info(f"[分离协议] {safe_message}")
    except UnicodeEncodeError:
        # 如果编码失败，尝试替换不支持的字符
        safe_message = str(message).encode('utf-8', errors='replace').decode('utf-8')
        print(f"[分离协议] {safe_message}", flush=True)
        logger.info(f"[分离协议] {safe_message}")
    except Exception as e:
        # 最后的安全措施
        fallback_message = f"日志输出错误: {repr(message)}"
        print(f"[分离协议] {fallback_message}", flush=True)
        logger.info(f"[分离协议] {fallback_message}")
 def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
    """创建一个动作日志 - 支持中文和emoji"""
    try:
        full_message = f"{emoji} {message}"
        debug_print(full_message)
        logger.info(full_message)
        return {
            "action_name": "wait",
            "action_kwargs": {
                "time": 0.1,
                "log_message": full_message,
                "progress_message": full_message
            }
        }
    except Exception as e:
        # 如果emoji有问题，使用纯文本
        safe_message = f"[日志] {message}"
        debug_print(safe_message)
        logger.info(safe_message)
        return {
            "action_name": "wait", 
            "action_kwargs": {
                "time": 0.1,
                "log_message": safe_message,
                "progress_message": safe_message
            }
        }
 def parse_volume_input(volume_input: Union[str, float]) -> float:
    """
    解析体积输入，支持带单位的字符串
    Args:
        volume_input: 体积输入（如 "200 mL", "?", 50.0）
    Returns:
        float: 体积（毫升）
    """
    if isinstance(volume_input, (int, float)):
        debug_print(f"📏 体积输入为数值: {volume_input}")
        return float(volume_input)
    if not volume_input or not str(volume_input).strip():
        debug_print(f"⚠️ 体积输入为空，返回 0.0mL")
        return 0.0
    volume_str = str(volume_input).lower().strip()
    debug_print(f"🔍 解析体积输入: '{volume_str}'")
    # 处理未知体积
    if volume_str in ['?', 'unknown', 'tbd', 'to be determined', '未知', '待定']:
        default_volume = 100.0  # 默认100mL
        debug_print(f"❓ 检测到未知体积，使用默认值: {default_volume}mL")
        return default_volume
    # 移除空格并提取数字和单位
    volume_clean = re.sub(r'\s+', '', volume_str)
    # 匹配数字和单位的正则表达式
    match = re.match(r'([0-9]*\.?[0-9]+)\s*(ml|l|μl|ul|microliter|milliliter|liter|毫升|升|微升)?', volume_clean)
    if not match:
        debug_print(f"⚠️ 无法解析体积: '{volume_str}'，使用默认值 100mL")
        return 100.0
    value = float(match.group(1))
    unit = match.group(2) or 'ml'  # 默认单位为毫升
    # 转换为毫升
    if unit in ['l', 'liter', '升']:
        volume = value * 1000.0  # L -> mL
        debug_print(f"🔄 体积转换: {value}L -> {volume}mL")
    elif unit in ['μl', 'ul', 'microliter', '微升']:
        volume = value / 1000.0  # μL -> mL
        debug_print(f"🔄 体积转换: {value}μL -> {volume}mL")
    else:  # ml, milliliter, 毫升 或默认
        volume = value  # 已经是mL
        debug_print(f"✅ 体积已为毫升单位: {volume}mL")
    return volume
 def find_solvent_vessel(G: nx.DiGraph, solvent: str) -> str:
    """查找溶剂容器，支持多种匹配模式"""
    if not solvent or not solvent.strip():
        debug_print("⏭️ 未指定溶剂，跳过溶剂容器查找")
        return ""
    debug_print(f"🔍 正在查找溶剂 '{solvent}' 的容器...")
    # 🔧 方法1：直接搜索 data.reagent_name 和 config.reagent
    debug_print(f"📋 方法1: 搜索试剂字段...")
    for node in G.nodes():
        node_data = G.nodes[node].get('data', {})
        node_type = G.nodes[node].get('type', '')
        config_data = G.nodes[node].get('config', {})
        # 只搜索容器类型的节点
        if node_type == 'container':
            reagent_name = node_data.get('reagent_name', '').lower()
            config_reagent = config_data.get('reagent', '').lower()
            # 精确匹配
            if reagent_name == solvent.lower() or config_reagent == solvent.lower():
                debug_print(f"✅ 通过试剂字段精确匹配找到容器: {node}")
                return node
            # 模糊匹配
            if (solvent.lower() in reagent_name and reagent_name) or \
               (solvent.lower() in config_reagent and config_reagent):
                debug_print(f"✅ 通过试剂字段模糊匹配找到容器: {node}")
                return node
    # 🔧 方法2：常见的容器命名规则
    debug_print(f"📋 方法2: 使用命名规则...")
    solvent_clean = solvent.lower().replace(' ', '_').replace('-', '_')
    possible_names = [
        f"flask_{solvent_clean}",
        f"bottle_{solvent_clean}",
        f"vessel_{solvent_clean}",
        f"{solvent_clean}_flask",
        f"{solvent_clean}_bottle",
        f"solvent_{solvent_clean}",
        f"reagent_{solvent_clean}",
        f"reagent_bottle_{solvent_clean}",
        f"reagent_bottle_1",  # 通用试剂瓶
        f"reagent_bottle_2",
        f"reagent_bottle_3"
    ]
    debug_print(f"🎯 尝试的容器名称: {possible_names[:5]}... (共 {len(possible_names)} 个)")
    for name in possible_names:
        if name in G.nodes():
            node_type = G.nodes[name].get('type', '')
            if node_type == 'container':
                debug_print(f"✅ 通过命名规则找到容器: {name}")
                return name
    # 🔧 方法3：使用第一个试剂瓶作为备选
    debug_print(f"📋 方法3: 查找备用试剂瓶...")
    for node_id in G.nodes():
        node_data = G.nodes[node_id]
        if (node_data.get('type') == 'container' and 
            ('reagent' in node_id.lower() or 'bottle' in node_id.lower())):
            debug_print(f"⚠️ 未找到专用容器，使用备用容器: {node_id}")
            return node_id
    debug_print(f"❌ 无法找到溶剂 '{solvent}' 的容器")
    return ""
 def find_separator_device(G: nx.DiGraph, vessel: str) -> str:
    """查找分离器设备，支持多种查找方式"""
    debug_print(f"🔍 正在查找容器 '{vessel}' 的分离器设备...")
    # 方法1：查找连接到容器的分离器设备
    debug_print(f"📋 方法1: 检查连接的分离器...")
    separator_nodes = []
    for node in G.nodes():
        node_class = G.nodes[node].get('class', '').lower()
        if 'separator' in node_class:
            separator_nodes.append(node)
            debug_print(f"📋 发现分离器设备: {node}")
            # 检查是否连接到目标容器
            if G.has_edge(node, vessel) or G.has_edge(vessel, node):
                debug_print(f"✅ 找到连接的分离器: {node}")
                return node
    debug_print(f"📊 找到的分离器总数: {len(separator_nodes)}")
    # 方法2：根据命名规则查找
    debug_print(f"📋 方法2: 使用命名规则...")
    possible_names = [
        f"{vessel}_controller",
        f"{vessel}_separator",
        vessel,  # 容器本身可能就是分离器
        "separator_1",
        "virtual_separator",
        "liquid_handler_1",  # 液体处理器也可能用于分离
        "controller_1"
    ]
    debug_print(f"🎯 尝试的分离器名称: {possible_names}")
    for name in possible_names:
        if name in G.nodes():
            node_class = G.nodes[name].get('class', '').lower()
            if 'separator' in node_class or 'controller' in node_class:
                debug_print(f"✅ 通过命名规则找到分离器: {name}")
                return name
    # 方法3：查找第一个分离器设备
    debug_print(f"📋 方法3: 使用第一个可用分离器...")
    if separator_nodes:
        debug_print(f"⚠️ 使用第一个分离器设备: {separator_nodes[0]}")
        return separator_nodes[0]
    debug_print(f"❌ 未找到分离器设备")
    return ""
 def find_connected_stirrer(G: nx.DiGraph, vessel: str) -> str:
    """查找连接到指定容器的搅拌器"""
    debug_print(f"🔍 正在查找与容器 {vessel} 连接的搅拌器...")
    stirrer_nodes = []
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if 'stirrer' in node_class.lower():
            stirrer_nodes.append(node)
            debug_print(f"📋 发现搅拌器: {node}")
    debug_print(f"📊 找到的搅拌器总数: {len(stirrer_nodes)}")
    # 检查哪个搅拌器与目标容器相连
    for stirrer in stirrer_nodes:
        if G.has_edge(stirrer, vessel) or G.has_edge(vessel, stirrer):
            debug_print(f"✅ 找到连接的搅拌器: {stirrer}")
            return stirrer
    # 如果没有连接的搅拌器，返回第一个可用的
    if stirrer_nodes:
        debug_print(f"⚠️ 未找到直接连接的搅拌器，使用第一个可用的: {stirrer_nodes[0]}")
        return stirrer_nodes[0]
    debug_print("❌ 未找到搅拌器")
    return ""
 def generate_separate_protocol(
    G: nx.DiGraph,
-    purpose: str,  # 'wash' or 'extract'. 'wash' means that product phase will not be the added solvent phase, 'extract' means product phase will be the added solvent phase. If no solvent is added just use 'extract'.
+    # 🔧 基础参数，支持XDL的vessel参数
-    product_phase: str, # 'top' or 'bottom'. Phase that product will be in.
+    vessel: str = "",                    # XDL: 分离容器
-    from_vessel: str, #Contents of from_vessel are transferred to separation_vessel and separation is performed.
+    purpose: str = "separate",           # 分离目的
-    separation_vessel: str, # Vessel in which separation of phases will be carried out.
+    product_phase: str = "top",          # 产物相
-    to_vessel: str, # Vessel to send product phase to.
+    # 🔧 可选的详细参数
-    waste_phase_to_vessel: str, # Optional. Vessel to send waste phase to.
+    from_vessel: str = "",               # 源容器（通常在separate前已经transfer了）
-    solvent: str, # Optional. Solvent to add to separation vessel after contents of from_vessel has been transferred to create two phases.
+    separation_vessel: str = "",         # 分离容器（与vessel同义）
-    solvent_volume: float = 50, # Optional. Volume of solvent to add (mL).
+    to_vessel: str = "",                 # 目标容器（可选）
-    through: str = "", # Optional. Solid chemical to send product phase through on way to to_vessel, e.g. 'celite'.
+    waste_phase_to_vessel: str = "",     # 废相目标容器
-    repeats: int = 1, # Optional. Number of separations to perform.
+    product_vessel: str = "",            # XDL: 产物容器（与to_vessel同义）
-    stir_time: float = 30, # Optional. Time stir for after adding solvent, before separation of phases.
+    waste_vessel: str = "",              # XDL: 废液容器（与waste_phase_to_vessel同义）
-    stir_speed: float = 300, # Optional. Speed to stir at after adding solvent, before separation of phases.
+    # 🔧 溶剂相关参数
-    settling_time: float = 300 # Optional. Time
+    solvent: str = "",                   # 溶剂名称
-) -> list[dict]:
+    solvent_volume: Union[str, float] = 0.0,  # 溶剂体积
    volume: Union[str, float] = 0.0,     # XDL: 体积（与solvent_volume同义）
    # 🔧 操作参数
    through: str = "",                   # 通过材料
    repeats: int = 1,                    # 重复次数
    stir_time: float = 30.0,             # 搅拌时间（秒）
    stir_speed: float = 300.0,           # 搅拌速度
    settling_time: float = 300.0,        # 沉降时间（秒）
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
-    Generate a protocol to clean a vessel with a solvent.
+    生成分离操作的协议序列 - 增强中文版
-    :param G: Directed graph. Nodes are containers and pumps, edges are fluidic connections.
+    支持XDL参数格式：
-    :param vessel: Vessel to clean.
+    - vessel: 分离容器（必需）
-    :param solvent: Solvent to clean vessel with.
+    - purpose: "wash", "extract", "separate"
-    :param volume: Volume of solvent to clean vessel with.
+    - product_phase: "top", "bottom"
-    :param temp: Temperature to heat vessel to while cleaning.
+    - product_vessel: 产物收集容器
-    :param repeats: Number of cleaning cycles to perform.
+    - waste_vessel: 废液收集容器
-    :return: List of actions to clean vessel.
+    - solvent: 溶剂名称
    - volume: "200 mL", "?" 或数值
    - repeats: 重复次数
    分离流程：
    1. （可选）添加溶剂到分离容器
    2. 搅拌混合
    3. 静置分层
    4. 收集指定相到目标容器
    5. 重复指定次数
    """
-    # 生成泵操作的动作序列
+    debug_print("=" * 60)
-    pump_action_sequence = []
+    debug_print("🧪 开始生成分离协议 - 增强中文版")
-    reactor_volume = 500.0
+    debug_print(f"📋 原始参数:")
-    waste_vessel = waste_phase_to_vessel
+    debug_print(f"  🥼 容器: '{vessel}'")
    debug_print(f"  🎯 分离目的: '{purpose}'")
    debug_print(f"  📊 产物相: '{product_phase}'")
    debug_print(f"  💧 溶剂: '{solvent}'")
    debug_print(f"  📏 体积: {volume} (类型: {type(volume)})")
    debug_print(f"  🔄 重复次数: {repeats}")
    debug_print(f"  🎯 产物容器: '{product_vessel}'")
    debug_print(f"  🗑️ 废液容器: '{waste_vessel}'")
    debug_print(f"  📦 其他参数: {kwargs}")
    debug_print("=" * 60)
-    # TODO：通过物料管理系统找到溶剂的容器
+    action_sequence = []
-    if "," in solvent:
+    
-        solvents = solvent.split(",")
+    # === 参数验证和标准化 ===
-        assert len(solvents) == repeats, "Number of solvents must match number of repeats."
+    debug_print("🔍 步骤1: 参数验证和标准化...")
    action_sequence.append(create_action_log(f"开始分离操作 - 容器: {vessel}", "🎬"))
    action_sequence.append(create_action_log(f"分离目的: {purpose}", "🧪"))
    action_sequence.append(create_action_log(f"产物相: {product_phase}", "📊"))
    # 统一容器参数
    final_vessel = vessel or separation_vessel
    if not final_vessel:
        debug_print("❌ 必须指定分离容器")
        raise ValueError("必须指定分离容器 (vessel 或 separation_vessel)")
    final_to_vessel = to_vessel or product_vessel
    final_waste_vessel = waste_phase_to_vessel or waste_vessel
    # 统一体积参数
    final_volume = parse_volume_input(volume or solvent_volume)
    # 🔧 修复：确保repeats至少为1
    if repeats <= 0:
        repeats = 1
        debug_print(f"⚠️ 重复次数参数 <= 0，自动设置为 1")
    debug_print(f"🔧 标准化后的参数:")
    debug_print(f"  🥼 分离容器: '{final_vessel}'")
    debug_print(f"  🎯 产物容器: '{final_to_vessel}'")
    debug_print(f"  🗑️ 废液容器: '{final_waste_vessel}'")
    debug_print(f"  📏 溶剂体积: {final_volume}mL")
    debug_print(f"  🔄 重复次数: {repeats}")
    action_sequence.append(create_action_log(f"分离容器: {final_vessel}", "🧪"))
    action_sequence.append(create_action_log(f"溶剂体积: {final_volume}mL", "📏"))
    action_sequence.append(create_action_log(f"重复次数: {repeats}", "🔄"))
    # 验证必需参数
    if not purpose:
        purpose = "separate"
    if not product_phase:
        product_phase = "top"
    if purpose not in ["wash", "extract", "separate"]:
        debug_print(f"⚠️ 未知的分离目的 '{purpose}'，使用默认值 'separate'")
        purpose = "separate"
        action_sequence.append(create_action_log(f"未知目的，使用: {purpose}", "⚠️"))
    if product_phase not in ["top", "bottom"]:
        debug_print(f"⚠️ 未知的产物相 '{product_phase}'，使用默认值 'top'")
        product_phase = "top"
        action_sequence.append(create_action_log(f"未知相别，使用: {product_phase}", "⚠️"))
    debug_print("✅ 参数验证通过")
    action_sequence.append(create_action_log("参数验证通过", "✅"))
    # === 查找设备 ===
    debug_print("🔍 步骤2: 查找设备...")
    action_sequence.append(create_action_log("正在查找相关设备...", "🔍"))
    # 查找分离器设备
    separator_device = find_separator_device(G, final_vessel)
    if separator_device:
        action_sequence.append(create_action_log(f"找到分离器设备: {separator_device}", "🧪"))
    else:
-        solvents = [solvent] * repeats
+        debug_print("⚠️ 未找到分离器设备，可能无法执行分离")
        action_sequence.append(create_action_log("未找到分离器设备", "⚠️"))
-    # TODO: 通过设备连接图找到分离容器的控制器、底部出口
+    # 查找搅拌器
-    separator_controller = f"{separation_vessel}_controller"
+    stirrer_device = find_connected_stirrer(G, final_vessel)
-    separation_vessel_bottom = f"flask_{separation_vessel}"
+    if stirrer_device:
        action_sequence.append(create_action_log(f"找到搅拌器: {stirrer_device}", "🌪️"))
    else:
        action_sequence.append(create_action_log("未找到搅拌器", "⚠️"))
-    transfer_flowrate = flowrate = 2.5
+    # 查找溶剂容器（如果需要）
    solvent_vessel = ""
    if solvent and solvent.strip():
        solvent_vessel = find_solvent_vessel(G, solvent)
        if solvent_vessel:
            action_sequence.append(create_action_log(f"找到溶剂容器: {solvent_vessel}", "💧"))
        else:
            action_sequence.append(create_action_log(f"未找到溶剂容器: {solvent}", "⚠️"))
-    if from_vessel != separation_vessel:
+    debug_print(f"📊 设备配置:")
-        pump_action_sequence.append(
+    debug_print(f"  🧪 分离器设备: '{separator_device}'")
-            {
+    debug_print(f"  🌪️ 搅拌器设备: '{stirrer_device}'")
-                "device_id": "", 
+    debug_print(f"  💧 溶剂容器: '{solvent_vessel}'")
-                "action_name": "PumpTransferProtocol",
+    
-                "action_kwargs": {
+    # === 执行分离流程 ===
-                    "from_vessel": from_vessel,
+    debug_print("🔍 步骤3: 执行分离流程...")
-                    "to_vessel": separation_vessel,
+    action_sequence.append(create_action_log("开始分离工作流程", "🎯"))
-                    "volume": reactor_volume,
+    
-                    "time": reactor_volume / flowrate,
+    try:
-                    # "transfer_flowrate": transfer_flowrate,
+        for repeat_idx in range(repeats):
            cycle_num = repeat_idx + 1
            debug_print(f"🔄 第{cycle_num}轮: 开始分离循环 {cycle_num}/{repeats}")
            action_sequence.append(create_action_log(f"分离循环 {cycle_num}/{repeats} 开始", "🔄"))
            # 步骤3.1: 添加溶剂（如果需要）
            if solvent_vessel and final_volume > 0:
                debug_print(f"🔄 第{cycle_num}轮 步骤1: 添加溶剂 {solvent} ({final_volume}mL)")
                action_sequence.append(create_action_log(f"向分离容器添加 {final_volume}mL {solvent}", "💧"))
                try:
                    # 使用pump protocol添加溶剂
                    pump_actions = generate_pump_protocol_with_rinsing(
                        G=G,
                        from_vessel=solvent_vessel,
                        to_vessel=final_vessel,
                        volume=final_volume,
                        amount="",
                        time=0.0,
                        viscous=False,
                        rinsing_solvent="",
                        rinsing_volume=0.0,
                        rinsing_repeats=0,
                        solid=False,
                        flowrate=2.5,
                        transfer_flowrate=0.5,
                        rate_spec="",
                        event="",
                        through="",
                        **kwargs
                    )
                    action_sequence.extend(pump_actions)
                    debug_print(f"✅ 溶剂添加完成，添加了 {len(pump_actions)} 个动作")
                    action_sequence.append(create_action_log(f"溶剂转移完成 ({len(pump_actions)} 个操作)", "✅"))
                except Exception as e:
                    debug_print(f"❌ 溶剂添加失败: {str(e)}")
                    action_sequence.append(create_action_log(f"溶剂添加失败: {str(e)}", "❌"))
            else:
                debug_print(f"🔄 第{cycle_num}轮 步骤1: 无需添加溶剂")
                action_sequence.append(create_action_log("无需添加溶剂", "⏭️"))
            # 步骤3.2: 启动搅拌（如果有搅拌器）
            if stirrer_device and stir_time > 0:
                debug_print(f"🔄 第{cycle_num}轮 步骤2: 开始搅拌 ({stir_speed}rpm，持续 {stir_time}s)")
                action_sequence.append(create_action_log(f"开始搅拌: {stir_speed}rpm，持续 {stir_time}s", "🌪️"))
                action_sequence.append({
                    "device_id": stirrer_device,
                    "action_name": "start_stir",
                    "action_kwargs": {
                        "vessel": final_vessel,
                        "stir_speed": stir_speed,
                        "purpose": f"分离混合 - {purpose}"
                    }
                })
                # 搅拌等待
                stir_minutes = stir_time / 60
                action_sequence.append(create_action_log(f"搅拌中，持续 {stir_minutes:.1f} 分钟", "⏱️"))
                action_sequence.append({
                    "action_name": "wait",
                    "action_kwargs": {"time": stir_time}
                })
                # 停止搅拌
                action_sequence.append(create_action_log("停止搅拌器", "🛑"))
                action_sequence.append({
                    "device_id": stirrer_device,
                    "action_name": "stop_stir",
                    "action_kwargs": {"vessel": final_vessel}
                })
            else:
                debug_print(f"🔄 第{cycle_num}轮 步骤2: 无需搅拌")
                action_sequence.append(create_action_log("无需搅拌", "⏭️"))
            # 步骤3.3: 静置分层
            if settling_time > 0:
                debug_print(f"🔄 第{cycle_num}轮 步骤3: 静置分层 ({settling_time}s)")
                settling_minutes = settling_time / 60
                action_sequence.append(create_action_log(f"静置分层 ({settling_minutes:.1f} 分钟)", "⚖️"))
                action_sequence.append({
                    "action_name": "wait",
                    "action_kwargs": {"time": settling_time}
                })
            else:
                debug_print(f"🔄 第{cycle_num}轮 步骤3: 未指定静置时间")
                action_sequence.append(create_action_log("未指定静置时间", "⏭️"))
            # 步骤3.4: 执行分离操作
            if separator_device:
                debug_print(f"🔄 第{cycle_num}轮 步骤4: 执行分离操作")
                action_sequence.append(create_action_log(f"执行分离: 收集{product_phase}相", "🧪"))
                # 调用分离器设备的separate方法
                separate_action = {
                    "device_id": separator_device,
                    "action_name": "separate",
                    "action_kwargs": {
                        "purpose": purpose,
                        "product_phase": product_phase,
                        "from_vessel": from_vessel or final_vessel,
                        "separation_vessel": final_vessel,
                        "to_vessel": final_to_vessel or final_vessel,
                        "waste_phase_to_vessel": final_waste_vessel or final_vessel,
                        "solvent": solvent,
                        "solvent_volume": final_volume,
                        "through": through,
                        "repeats": 1,  # 每次调用只做一次分离
                        "stir_time": 0,  # 已经在上面完成
                        "stir_speed": stir_speed,
                        "settling_time": 0  # 已经在上面完成
                    }
                }
                action_sequence.append(separate_action)
                debug_print(f"✅ 分离操作已添加")
                action_sequence.append(create_action_log("分离操作完成", "✅"))
                # 收集结果
                if final_to_vessel:
                    action_sequence.append(create_action_log(f"产物 ({product_phase}相) 收集到: {final_to_vessel}", "📦"))
                if final_waste_vessel:
                    action_sequence.append(create_action_log(f"废相收集到: {final_waste_vessel}", "🗑️"))
            else:
                debug_print(f"🔄 第{cycle_num}轮 步骤4: 无分离器设备，跳过分离")
                action_sequence.append(create_action_log("无分离器设备可用", "❌"))
                # 添加等待时间模拟分离
                action_sequence.append({
                    "action_name": "wait",
                    "action_kwargs": {"time": 10.0}
                })
            # 循环间等待（除了最后一次）
            if repeat_idx < repeats - 1:
                debug_print(f"🔄 第{cycle_num}轮: 等待下一次循环...")
                action_sequence.append(create_action_log("等待下一次循环...", "⏳"))
                action_sequence.append({
                    "action_name": "wait",
                    "action_kwargs": {"time": 5}
                })
            else:
                action_sequence.append(create_action_log(f"分离循环 {cycle_num}/{repeats} 完成", "🌟"))
    except Exception as e:
        debug_print(f"❌ 分离工作流程执行失败: {str(e)}")
        action_sequence.append(create_action_log(f"分离工作流程失败: {str(e)}", "❌"))
        # 添加错误日志
        action_sequence.append({
            "device_id": "system",
            "action_name": "log_message",
            "action_kwargs": {
                "message": f"分离操作失败: {str(e)}"
            }
-        )
+        })
-        # for i in range(2):
+    # === 最终结果 ===
-        #     pump_action_sequence.append(
+    total_time = (stir_time + settling_time + 15) * repeats  # 估算总时间
        #         {
        #             "device_id": "", 
        #             "action_name": "CleanProtocol",
        #             "action_kwargs": {
        #                 "vessel": from_vessel,
        #                 "solvent": "H2O", # Solvent to clean vessel with.
        #                 "volume": solvent_volume, # Optional. Volume of solvent to clean vessel with.
        #                 "temp": 25.0, # Optional. Temperature to heat vessel to while cleaning.
        #                 "repeats": 1
        #             }
        #         }
        #     )
        #     pump_action_sequence.append(
        #         {
        #             "device_id": "", 
        #             "action_name": "CleanProtocol",
        #             "action_kwargs": {
        #                 "vessel": from_vessel,
        #                 "solvent": "CH2Cl2", # Solvent to clean vessel with.
        #                 "volume": solvent_volume, # Optional. Volume of solvent to clean vessel with.
        #                 "temp": 25.0, # Optional. Temperature to heat vessel to while cleaning.
        #                 "repeats": 1
        #             }
        #         }
        #     )
-    # 生成泵操作的动作序列
+    debug_print("=" * 60)
-    for i in range(repeats):
+    debug_print(f"🎉 分离协议生成完成")
-        # 找到当次萃取所用溶剂
+    debug_print(f"📊 协议统计:")
-        solvent_thistime = solvents[i]
+    debug_print(f"  📋 总动作数: {len(action_sequence)}")
-        solvent_vessel = f"flask_{solvent_thistime}"
+    debug_print(f"  ⏱️ 预计总时间: {total_time:.0f}s ({total_time/60:.1f} 分钟)")
    debug_print(f"  🥼 分离容器: {final_vessel}")
    debug_print(f"  🎯 分离目的: {purpose}")
    debug_print(f"  📊 产物相: {product_phase}")
    debug_print(f"  🔄 重复次数: {repeats}")
    if solvent:
        debug_print(f"  💧 溶剂: {solvent} ({final_volume}mL)")
    if final_to_vessel:
        debug_print(f"  🎯 产物容器: {final_to_vessel}")
    if final_waste_vessel:
        debug_print(f"  🗑️ 废液容器: {final_waste_vessel}")
    debug_print("=" * 60)
-        pump_action_sequence.append(
+    # 添加完成日志
-            {
+    summary_msg = f"分离协议完成: {final_vessel} ({purpose}，{repeats} 次循环)"
-                "device_id": "", 
+    if solvent:
-                "action_name": "PumpTransferProtocol",
+        summary_msg += f"，使用 {final_volume}mL {solvent}"
-                "action_kwargs": {
+    action_sequence.append(create_action_log(summary_msg, "🎉"))
                    "from_vessel": solvent_vessel,
                    "to_vessel": separation_vessel,
                    "volume": solvent_volume,
                    "time": solvent_volume / flowrate,
                    # "transfer_flowrate": transfer_flowrate,
                }
            }
        )
        pump_action_sequence.extend([
            # 搅拌、静置
            {
                "device_id": separator_controller, 
                "action_name": "stir",
                "action_kwargs": {
                    "stir_time": stir_time,
                    "stir_speed": stir_speed,
                    "settling_time": settling_time
                }
            },
            # 分液（判断电导突跃）
            {
                "device_id": separator_controller, 
                "action_name": "valve_open",
                "action_kwargs": {
                    "command": "delta > 0.05"
                }
            }
        ])
-        if product_phase == "bottom":
+    return action_sequence
            # 产物转移到目标瓶
            pump_action_sequence.append(
                {
                    "device_id": "", 
                    "action_name": "PumpTransferProtocol",
                    "action_kwargs": {
                        "from_vessel": separation_vessel_bottom,
                        "to_vessel": to_vessel,
                        "volume": 250.0,
                        "time": 250.0 / flowrate,
                        # "transfer_flowrate": transfer_flowrate,
                    }
                }
            )
            # 放出上面那一相，60秒后关阀门
            pump_action_sequence.append(
                {
                    "device_id": separator_controller, 
                    "action_name": "valve_open",
                    "action_kwargs": {
                        "command": "time > 60"
                    }
                }
            )
            # 弃去上面那一相进废液
            pump_action_sequence.append(
                {
                    "device_id": "", 
                    "action_name": "PumpTransferProtocol",
                    "action_kwargs": {
                        "from_vessel": separation_vessel_bottom,
                        "to_vessel": waste_vessel,
                        "volume": 250.0,
                        "time": 250.0 / flowrate,
                        # "transfer_flowrate": transfer_flowrate,
                    }
                }
            )
        elif product_phase == "top":
            # 弃去下面那一相进废液
            pump_action_sequence.append(
                {
                    "device_id": "", 
                    "action_name": "PumpTransferProtocol",
                    "action_kwargs": {
                        "from_vessel": separation_vessel_bottom,
                        "to_vessel": waste_vessel,
                        "volume": 250.0,
                        "time": 250.0 / flowrate,
                        # "transfer_flowrate": transfer_flowrate,
                    }
                }
            )
            # 放出上面那一相
            pump_action_sequence.append(
                {
                    "device_id": separator_controller, 
                    "action_name": "valve_open",
                    "action_kwargs": {
                        "command": "time > 60"
                    }
                }
            )
            # 产物转移到目标瓶
            pump_action_sequence.append(
                {
                    "device_id": "", 
                    "action_name": "PumpTransferProtocol",
                    "action_kwargs": {
                        "from_vessel": separation_vessel_bottom,
                        "to_vessel": to_vessel,
                        "volume": 250.0,
                        "time": 250.0 / flowrate,
                        # "transfer_flowrate": transfer_flowrate,
                    }
                }
            )
        elif product_phase == "organic":
            pass
-        # 如果不是最后一次，从中转瓶转移回分液漏斗
+# === 便捷函数 ===
-        if i < repeats - 1:
+
-            pump_action_sequence.append(
+def separate_phases_only(G: nx.DiGraph, vessel: str, product_phase: str = "top", 
-                {
+                        product_vessel: str = "", waste_vessel: str = "") -> List[Dict[str, Any]]:
-                    "device_id": "", 
+    """仅进行相分离（不添加溶剂）"""
-                    "action_name": "PumpTransferProtocol",
+    debug_print(f"⚡ 快速相分离: {vessel} ({product_phase}相)")
-                    "action_kwargs": {
+    return generate_separate_protocol(
-                        "from_vessel": to_vessel,
+        G, vessel=vessel, 
-                        "to_vessel": separation_vessel,
+        purpose="separate", 
-                        "volume": 250.0,
+        product_phase=product_phase,
-                        "time": 250.0 / flowrate,
+        product_vessel=product_vessel,
-                        # "transfer_flowrate": transfer_flowrate,
+        waste_vessel=waste_vessel
-                    }
+    )
-                }
+
-            )
+def wash_with_solvent(G: nx.DiGraph, vessel: str, solvent: str, volume: Union[str, float],
-    return pump_action_sequence
+                     product_phase: str = "top", repeats: int = 1) -> List[Dict[str, Any]]:
    """用溶剂洗涤"""
    debug_print(f"🧽 用{solvent}洗涤: {vessel} ({repeats} 次)")
    return generate_separate_protocol(
        G, vessel=vessel,
        purpose="wash",
        product_phase=product_phase,
        solvent=solvent,
        volume=volume,
        repeats=repeats
    )
 def extract_with_solvent(G: nx.DiGraph, vessel: str, solvent: str, volume: Union[str, float],
                        product_phase: str = "bottom", repeats: int = 3) -> List[Dict[str, Any]]:
    """用溶剂萃取"""
    debug_print(f"🧪 用{solvent}萃取: {vessel} ({repeats} 次)")
    return generate_separate_protocol(
        G, vessel=vessel,
        purpose="extract",
        product_phase=product_phase,
        solvent=solvent,
        volume=volume,
        repeats=repeats
    )
 def separate_aqueous_organic(G: nx.DiGraph, vessel: str, organic_phase: str = "top",
                            product_vessel: str = "", waste_vessel: str = "") -> List[Dict[str, Any]]:
    """水-有机相分离"""
    debug_print(f"💧 水-有机相分离: {vessel} (有机相: {organic_phase})")
    return generate_separate_protocol(
        G, vessel=vessel,
        purpose="separate",
        product_phase=organic_phase,
        product_vessel=product_vessel,
        waste_vessel=waste_vessel
    )
 # 测试函数
 def test_separate_protocol():
    """测试分离协议的各种参数解析"""
    debug_print("=== 分离协议增强中文版测试 ===")
    # 测试体积解析
    debug_print("🧪 测试体积解析...")
    volumes = ["200 mL", "?", 100.0, "1 L", "500 μL", "未知", "50毫升"]
    for vol in volumes:
        result = parse_volume_input(vol)
        debug_print(f"📊 体积解析结果: {vol} -> {result}mL")
    debug_print("✅ 测试完成")
 if __name__ == "__main__":
    test_separate_protocol()
--- a/unilabos/compile/stir_protocol.py
+++ b/unilabos/compile/stir_protocol.py
@@ -1,137 +1,342 @@
-from typing import List, Dict, Any
+from typing import List, Dict, Any, Union
 import networkx as nx
 import logging
 import re
 logger = logging.getLogger(__name__)
 def debug_print(message):
    """调试输出"""
    print(f"🌪️ [STIR] {message}", flush=True)
    logger.info(f"[STIR] {message}")
 def parse_time_input(time_input: Union[str, float, int], default_unit: str = "s") -> float:
    """
    统一的时间解析函数（精简版）
    Args:
        time_input: 时间输入（如 "30 min", "1 h", "300", "?", 60.0）
        default_unit: 默认单位（默认为秒）
    Returns:
        float: 时间（秒）
    """
    if not time_input:
        return 100.0  # 默认100秒
    # 🔢 处理数值输入
    if isinstance(time_input, (int, float)):
        result = float(time_input)
        debug_print(f"⏰ 数值时间: {time_input} → {result}s")
        return result
    # 📝 处理字符串输入
    time_str = str(time_input).lower().strip()
    debug_print(f"🔍 解析时间: '{time_str}'")
    # ❓ 特殊值处理
    special_times = {
        '?': 300.0, 'unknown': 300.0, 'tbd': 300.0,
        'briefly': 30.0, 'quickly': 60.0, 'slowly': 600.0,
        'several minutes': 300.0, 'few minutes': 180.0, 'overnight': 3600.0
    }
    if time_str in special_times:
        result = special_times[time_str]
        debug_print(f"🎯 特殊时间: '{time_str}' → {result}s ({result/60:.1f}分钟)")
        return result
    # 🔢 纯数字处理
    try:
        result = float(time_str)
        debug_print(f"⏰ 纯数字: {time_str} → {result}s")
        return result
    except ValueError:
        pass
    # 📐 正则表达式解析
    pattern = r'(\d+\.?\d*)\s*([a-z]*)'
    match = re.match(pattern, time_str)
    if not match:
        debug_print(f"⚠️ 无法解析时间: '{time_str}'，使用默认值: 100s")
        return 100.0
    value = float(match.group(1))
    unit = match.group(2) or default_unit
    # 📏 单位转换
    unit_multipliers = {
        's': 1.0, 'sec': 1.0, 'second': 1.0, 'seconds': 1.0,
        'm': 60.0, 'min': 60.0, 'mins': 60.0, 'minute': 60.0, 'minutes': 60.0,
        'h': 3600.0, 'hr': 3600.0, 'hrs': 3600.0, 'hour': 3600.0, 'hours': 3600.0,
        'd': 86400.0, 'day': 86400.0, 'days': 86400.0
    }
    multiplier = unit_multipliers.get(unit, 1.0)
    result = value * multiplier
    debug_print(f"✅ 时间解析: '{time_str}' → {value} {unit} → {result}s ({result/60:.1f}分钟)")
    return result
 def find_connected_stirrer(G: nx.DiGraph, vessel: str = None) -> str:
    """查找与指定容器相连的搅拌设备"""
    debug_print(f"🔍 查找搅拌设备，目标容器: {vessel} 🥽")
    # 🔧 查找所有搅拌设备
    stirrer_nodes = []
    for node in G.nodes():
        node_data = G.nodes[node]
        node_class = node_data.get('class', '') or ''
        if 'stirrer' in node_class.lower() or 'virtual_stirrer' in node_class:
            stirrer_nodes.append(node)
            debug_print(f"🎉 找到搅拌设备: {node} 🌪️")
    # 🔗 检查连接
    if vessel and stirrer_nodes:
        for stirrer in stirrer_nodes:
            if G.has_edge(stirrer, vessel) or G.has_edge(vessel, stirrer):
                debug_print(f"✅ 搅拌设备 '{stirrer}' 与容器 '{vessel}' 相连 🔗")
                return stirrer
    # 🎯 使用第一个可用设备
    if stirrer_nodes:
        selected = stirrer_nodes[0]
        debug_print(f"🔧 使用第一个搅拌设备: {selected} 🌪️")
        return selected
    # 🆘 默认设备
    debug_print("⚠️ 未找到搅拌设备，使用默认设备 🌪️")
    return "stirrer_1"
 def validate_and_fix_params(stir_time: float, stir_speed: float, settling_time: float) -> tuple:
    """验证和修正参数"""
    # ⏰ 搅拌时间验证
    if stir_time < 0:
        debug_print(f"⚠️ 搅拌时间 {stir_time}s 无效，修正为 100s 🕐")
        stir_time = 100.0
    elif stir_time > 100:  # 限制为100s
        debug_print(f"⚠️ 搅拌时间 {stir_time}s 过长，仿真运行时，修正为 100s 🕐")
        stir_time = 100.0
    else:
        debug_print(f"✅ 搅拌时间 {stir_time}s ({stir_time/60:.1f}分钟) 有效 ⏰")
    # 🌪️ 搅拌速度验证
    if stir_speed < 10.0 or stir_speed > 1500.0:
        debug_print(f"⚠️ 搅拌速度 {stir_speed} RPM 超出范围，修正为 300 RPM 🌪️")
        stir_speed = 300.0
    else:
        debug_print(f"✅ 搅拌速度 {stir_speed} RPM 在正常范围内 🌪️")
    # ⏱️ 沉降时间验证
    if settling_time < 0 or settling_time > 600:  # 限制为10分钟
        debug_print(f"⚠️ 沉降时间 {settling_time}s 超出范围，修正为 60s ⏱️")
        settling_time = 60.0
    else:
        debug_print(f"✅ 沉降时间 {settling_time}s 在正常范围内 ⏱️")
    return stir_time, stir_speed, settling_time
 def generate_stir_protocol(
    G: nx.DiGraph,
-    stir_time: float,
+    vessel: str,
-    stir_speed: float,
+    time: Union[str, float, int] = "300",
-    settling_time: float
+    stir_time: Union[str, float, int] = "0",
    time_spec: str = "",
    event: str = "",
    stir_speed: float = 300.0,
    settling_time: Union[str, float] = "60",
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
-    生成搅拌操作的协议序列
+    生成搅拌操作的协议序列（精简版）
    Args:
        G: 有向图，节点为设备和容器
        stir_time: 搅拌时间 (秒)
        stir_speed: 搅拌速度 (rpm)
        settling_time: 沉降时间 (秒)
    Returns:
        List[Dict[str, Any]]: 搅拌操作的动作序列
    Raises:
        ValueError: 当找不到搅拌设备时抛出异常
    Examples:
        stir_protocol = generate_stir_protocol(G, 300.0, 500.0, 60.0)
    """
    debug_print("🌪️" * 20)
    debug_print("🚀 开始生成搅拌协议 ✨")
    debug_print(f"📝 输入参数:")
    debug_print(f"  🥽 vessel: {vessel}")
    debug_print(f"  ⏰ time: {time}")
    debug_print(f"  🕐 stir_time: {stir_time}")
    debug_print(f"  🎯 time_spec: {time_spec}")
    debug_print(f"  🌪️ stir_speed: {stir_speed} RPM")
    debug_print(f"  ⏱️ settling_time: {settling_time}")
    debug_print("🌪️" * 20)
    # 📋 参数验证
    debug_print("📍 步骤1: 参数验证... 🔧")
    if not vessel:
        debug_print("❌ vessel 参数不能为空! 😱")
        raise ValueError("vessel 参数不能为空")
    if vessel not in G.nodes():
        debug_print(f"❌ 容器 '{vessel}' 不存在于系统中! 😞")
        raise ValueError(f"容器 '{vessel}' 不存在于系统中")
    debug_print("✅ 基础参数验证通过 🎯")
    # 🔄 参数解析
    debug_print("📍 步骤2: 参数解析... ⚡")
    # 确定实际时间（优先级：time_spec > stir_time > time）
    if time_spec:
        parsed_time = parse_time_input(time_spec)
        debug_print(f"🎯 使用time_spec: '{time_spec}' → {parsed_time}s")
    elif stir_time not in ["0", 0, 0.0]:
        parsed_time = parse_time_input(stir_time)
        debug_print(f"🎯 使用stir_time: {stir_time} → {parsed_time}s")
    else:
        parsed_time = parse_time_input(time)
        debug_print(f"🎯 使用time: {time} → {parsed_time}s")
    # 解析沉降时间
    parsed_settling_time = parse_time_input(settling_time)
    # 🕐 模拟运行时间优化
    debug_print("  ⏱️ 检查模拟运行时间限制...")
    original_stir_time = parsed_time
    original_settling_time = parsed_settling_time
    # 搅拌时间限制为60秒
    stir_time_limit = 60.0
    if parsed_time > stir_time_limit:
        parsed_time = stir_time_limit
        debug_print(f"  🎮 搅拌时间优化: {original_stir_time}s → {parsed_time}s ⚡")
    # 沉降时间限制为30秒
    settling_time_limit = 30.0
    if parsed_settling_time > settling_time_limit:
        parsed_settling_time = settling_time_limit
        debug_print(f"  🎮 沉降时间优化: {original_settling_time}s → {parsed_settling_time}s ⚡")
    # 参数修正
    parsed_time, stir_speed, parsed_settling_time = validate_and_fix_params(
        parsed_time, stir_speed, parsed_settling_time
    )
    debug_print(f"🎯 最终参数: time={parsed_time}s, speed={stir_speed}RPM, settling={parsed_settling_time}s")
    # 🔍 查找设备
    debug_print("📍 步骤3: 查找搅拌设备... 🔍")
    try:
        stirrer_id = find_connected_stirrer(G, vessel)
        debug_print(f"🎉 使用搅拌设备: {stirrer_id} ✨")
    except Exception as e:
        debug_print(f"❌ 设备查找失败: {str(e)} 😭")
        raise ValueError(f"无法找到搅拌设备: {str(e)}")
    # 🚀 生成动作
    debug_print("📍 步骤4: 生成搅拌动作... 🌪️")
    action_sequence = []
-    
+    stir_action = {
    # 查找搅拌设备
    stirrer_nodes = [node for node in G.nodes() 
                    if G.nodes[node].get('class') == 'virtual_stirrer']
    if not stirrer_nodes:
        raise ValueError("没有找到可用的搅拌设备")
    # 使用第一个可用的搅拌器
    stirrer_id = stirrer_nodes[0]
    # 执行搅拌操作
    action_sequence.append({
        "device_id": stirrer_id,
        "action_name": "stir",
        "action_kwargs": {
-            "stir_time": stir_time,
+            "vessel": vessel,
-            "stir_speed": stir_speed,
+            "time": str(time),  # 保持原始格式
-            "settling_time": settling_time
+            "event": event,
            "time_spec": time_spec,
            "stir_time": float(parsed_time),  # 确保是数字
            "stir_speed": float(stir_speed),  # 确保是数字
            "settling_time": float(parsed_settling_time)  # 确保是数字
        }
-    })
+    }
    action_sequence.append(stir_action)
    debug_print("✅ 搅拌动作已添加 🌪️✨")
    # 显示时间优化信息
    if original_stir_time != parsed_time or original_settling_time != parsed_settling_time:
        debug_print(f"  🎭 模拟优化说明:")
        debug_print(f"    搅拌时间: {original_stir_time/60:.1f}分钟 → {parsed_time/60:.1f}分钟")
        debug_print(f"    沉降时间: {original_settling_time/60:.1f}分钟 → {parsed_settling_time/60:.1f}分钟")
    # 🎊 总结
    debug_print("🎊" * 20)
    debug_print(f"🎉 搅拌协议生成完成! ✨")
    debug_print(f"📊 总动作数: {len(action_sequence)} 个")
    debug_print(f"🥽 搅拌容器: {vessel}")
    debug_print(f"🌪️ 搅拌参数: {stir_speed} RPM, {parsed_time}s, 沉降 {parsed_settling_time}s")
    debug_print(f"⏱️ 预计总时间: {(parsed_time + parsed_settling_time)/60:.1f} 分钟 ⌛")
    debug_print("🎊" * 20)
    return action_sequence
 def generate_start_stir_protocol(
    G: nx.DiGraph,
    vessel: str,
-    stir_speed: float,
+    stir_speed: float = 300.0,
-    purpose: str
+    purpose: str = "",
    **kwargs
 ) -> List[Dict[str, Any]]:
-    """
+    """生成开始搅拌操作的协议序列"""
    生成开始搅拌操作的协议序列
-    Args:
+    debug_print("🔄 开始生成启动搅拌协议 ✨")
-        G: 有向图，节点为设备和容器
+    debug_print(f"🥽 vessel: {vessel}, 🌪️ speed: {stir_speed} RPM")
        vessel: 搅拌容器
        stir_speed: 搅拌速度 (rpm)
        purpose: 搅拌目的
-    Returns:
+    # 基础验证
-        List[Dict[str, Any]]: 开始搅拌操作的动作序列
+    if not vessel or vessel not in G.nodes():
-    """
+        debug_print("❌ 容器验证失败!")
-    action_sequence = []
+        raise ValueError("vessel 参数无效")
-    # 查找搅拌设备
+    # 参数修正
-    stirrer_nodes = [node for node in G.nodes() 
+    if stir_speed < 10.0 or stir_speed > 1500.0:
-                    if G.nodes[node].get('class') == 'virtual_stirrer']
+        debug_print(f"⚠️ 搅拌速度修正: {stir_speed} → 300 RPM 🌪️")
        stir_speed = 300.0
-    if not stirrer_nodes:
+    # 查找设备
-        raise ValueError("没有找到可用的搅拌设备")
+    stirrer_id = find_connected_stirrer(G, vessel)
-    stirrer_id = stirrer_nodes[0]
+    # 生成动作
-    
+    action_sequence = [{
    # 验证容器是否存在
    if vessel not in G.nodes():
        raise ValueError(f"容器 {vessel} 不存在于图中")
    action_sequence.append({
        "device_id": stirrer_id,
        "action_name": "start_stir",
        "action_kwargs": {
            "vessel": vessel,
            "stir_speed": stir_speed,
-            "purpose": purpose
+            "purpose": purpose or f"启动搅拌 {stir_speed} RPM"
        }
-    })
+    }]
    debug_print(f"✅ 启动搅拌协议生成完成 🎯")
    return action_sequence
 def generate_stop_stir_protocol(
    G: nx.DiGraph,
-    vessel: str
+    vessel: str,
    **kwargs
 ) -> List[Dict[str, Any]]:
-    """
+    """生成停止搅拌操作的协议序列"""
    生成停止搅拌操作的协议序列
-    Args:
+    debug_print("🛑 开始生成停止搅拌协议 ✨")
-        G: 有向图，节点为设备和容器
+    debug_print(f"🥽 vessel: {vessel}")
        vessel: 搅拌容器
-    Returns:
+    # 基础验证
-        List[Dict[str, Any]]: 停止搅拌操作的动作序列
+    if not vessel or vessel not in G.nodes():
-    """
+        debug_print("❌ 容器验证失败!")
-    action_sequence = []
+        raise ValueError("vessel 参数无效")
-    # 查找搅拌设备
+    # 查找设备
-    stirrer_nodes = [node for node in G.nodes() 
+    stirrer_id = find_connected_stirrer(G, vessel)
                    if G.nodes[node].get('class') == 'virtual_stirrer']
-    if not stirrer_nodes:
+    # 生成动作
-        raise ValueError("没有找到可用的搅拌设备")
+    action_sequence = [{
    stirrer_id = stirrer_nodes[0]
    # 验证容器是否存在
    if vessel not in G.nodes():
        raise ValueError(f"容器 {vessel} 不存在于图中")
    action_sequence.append({
        "device_id": stirrer_id,
        "action_name": "stop_stir",
        "action_kwargs": {
            "vessel": vessel
        }
-    })
+    }]
    debug_print(f"✅ 停止搅拌协议生成完成 🎯")
    return action_sequence
 # 测试函数
 def test_stir_protocol():
    """测试搅拌协议"""
    debug_print("🧪 === STIR PROTOCOL 测试 === ✨")
    debug_print("✅ 测试完成 🎉")
 if __name__ == "__main__":
    test_stir_protocol()
--- a/unilabos/compile/utils/unit_parser.py
+++ b/unilabos/compile/utils/unit_parser.py
@@ -0,0 +1,206 @@
 """
 统一的单位解析工具模块
 支持时间、体积、质量等各种单位的解析
 """
 import re
 import logging
 from typing import Union
 logger = logging.getLogger(__name__)
 def debug_print(message, prefix="[UNIT_PARSER]"):
    """调试输出"""
    print(f"{prefix} {message}", flush=True)
    logger.info(f"{prefix} {message}")
 def parse_time_with_units(time_input: Union[str, float, int], default_unit: str = "s") -> float:
    """
    解析带单位的时间输入
    Args:
        time_input: 时间输入（如 "30 min", "1 h", "300", "?", 60.0）
        default_unit: 默认单位（默认为秒）
    Returns:
        float: 时间（秒）
    """
    if not time_input:
        return 0.0
    # 处理数值输入
    if isinstance(time_input, (int, float)):
        result = float(time_input)
        debug_print(f"数值时间输入: {time_input} → {result}s（默认单位）")
        return result
    # 处理字符串输入
    time_str = str(time_input).lower().strip()
    debug_print(f"解析时间字符串: '{time_str}'")
    # 处理特殊值
    if time_str in ['?', 'unknown', 'tbd', 'to be determined']:
        default_time = 300.0  # 5分钟默认值
        debug_print(f"检测到未知时间，使用默认值: {default_time}s")
        return default_time
    # 如果是纯数字，使用默认单位
    try:
        value = float(time_str)
        if default_unit == "s":
            result = value
        elif default_unit in ["min", "minute"]:
            result = value * 60.0
        elif default_unit in ["h", "hour"]:
            result = value * 3600.0
        else:
            result = value  # 默认秒
        debug_print(f"纯数字输入: {time_str} → {result}s（单位: {default_unit}）")
        return result
    except ValueError:
        pass
    # 使用正则表达式匹配数字和单位
    pattern = r'(\d+\.?\d*)\s*([a-z]*)'
    match = re.match(pattern, time_str)
    if not match:
        debug_print(f"⚠️ 无法解析时间: '{time_str}'，使用默认值: 60s")
        return 60.0
    value = float(match.group(1))
    unit = match.group(2) or default_unit
    # 单位转换映射
    unit_multipliers = {
        # 秒
        's': 1.0,
        'sec': 1.0,
        'second': 1.0,
        'seconds': 1.0,
        # 分钟
        'm': 60.0,
        'min': 60.0,
        'mins': 60.0,
        'minute': 60.0,
        'minutes': 60.0,
        # 小时
        'h': 3600.0,
        'hr': 3600.0,
        'hrs': 3600.0,
        'hour': 3600.0,
        'hours': 3600.0,
        # 天
        'd': 86400.0,
        'day': 86400.0,
        'days': 86400.0,
    }
    multiplier = unit_multipliers.get(unit, 1.0)
    result = value * multiplier
    debug_print(f"时间解析: '{time_str}' → {value} {unit} → {result}s")
    return result
 def parse_volume_with_units(volume_input: Union[str, float, int], default_unit: str = "mL") -> float:
    """
    解析带单位的体积输入
    Args:
        volume_input: 体积输入（如 "100 mL", "2.5 L", "500", "?", 100.0）
        default_unit: 默认单位（默认为毫升）
    Returns:
        float: 体积（毫升）
    """
    if not volume_input:
        return 0.0
    # 处理数值输入
    if isinstance(volume_input, (int, float)):
        result = float(volume_input)
        debug_print(f"数值体积输入: {volume_input} → {result}mL（默认单位）")
        return result
    # 处理字符串输入
    volume_str = str(volume_input).lower().strip()
    debug_print(f"解析体积字符串: '{volume_str}'")
    # 处理特殊值
    if volume_str in ['?', 'unknown', 'tbd', 'to be determined']:
        default_volume = 50.0  # 50mL默认值
        debug_print(f"检测到未知体积，使用默认值: {default_volume}mL")
        return default_volume
    # 如果是纯数字，使用默认单位
    try:
        value = float(volume_str)
        if default_unit.lower() in ["ml", "milliliter"]:
            result = value
        elif default_unit.lower() in ["l", "liter"]:
            result = value * 1000.0
        elif default_unit.lower() in ["μl", "ul", "microliter"]:
            result = value / 1000.0
        else:
            result = value  # 默认mL
        debug_print(f"纯数字输入: {volume_str} → {result}mL（单位: {default_unit}）")
        return result
    except ValueError:
        pass
    # 移除空格并提取数字和单位
    volume_clean = re.sub(r'\s+', '', volume_str)
    # 匹配数字和单位的正则表达式
    match = re.match(r'([0-9]*\.?[0-9]+)\s*(ml|l|μl|ul|microliter|milliliter|liter)?', volume_clean)
    if not match:
        debug_print(f"⚠️ 无法解析体积: '{volume_str}'，使用默认值: 50mL")
        return 50.0
    value = float(match.group(1))
    unit = match.group(2) or default_unit.lower()
    # 转换为毫升
    if unit in ['l', 'liter']:
        volume = value * 1000.0  # L -> mL
    elif unit in ['μl', 'ul', 'microliter']:
        volume = value / 1000.0  # μL -> mL
    else:  # ml, milliliter 或默认
        volume = value  # 已经是mL
    debug_print(f"体积解析: '{volume_str}' → {value} {unit} → {volume}mL")
    return volume
 # 测试函数
 def test_unit_parser():
    """测试单位解析功能"""
    print("=== 单位解析器测试 ===")
    # 测试时间解析
    time_tests = [
        "30 min", "1 h", "300", "5.5 h", "?", 60.0, "2 hours", "30 s"
    ]
    print("\n时间解析测试:")
    for time_input in time_tests:
        result = parse_time_with_units(time_input)
        print(f"  {time_input} → {result}s ({result/60:.1f}min)")
    # 测试体积解析
    volume_tests = [
        "100 mL", "2.5 L", "500", "?", 100.0, "500 μL", "1 liter"
    ]
    print("\n体积解析测试:")
    for volume_input in volume_tests:
        result = parse_volume_with_units(volume_input)
        print(f"  {volume_input} → {result}mL")
    print("\n✅ 测试完成")
 if __name__ == "__main__":
    test_unit_parser()
--- a/unilabos/compile/wash_solid_protocol.py
+++ b/unilabos/compile/wash_solid_protocol.py
@@ -1,216 +1,316 @@
-from typing import List, Dict, Any
+from typing import List, Dict, Any, Union
 import networkx as nx
 import logging
 import re
 logger = logging.getLogger(__name__)
 def debug_print(message):
    """调试输出"""
    print(f"🧼 [WASH_SOLID] {message}", flush=True)
    logger.info(f"[WASH_SOLID] {message}")
 def parse_time_input(time_input: Union[str, float, int]) -> float:
    """统一时间解析函数（精简版）"""
    if not time_input:
        return 0.0
    # 🔢 处理数值输入
    if isinstance(time_input, (int, float)):
        result = float(time_input)
        debug_print(f"⏰ 数值时间: {time_input} → {result}s")
        return result
    # 📝 处理字符串输入
    time_str = str(time_input).lower().strip()
    # ❓ 特殊值快速处理
    special_times = {
        '?': 60.0, 'unknown': 60.0, 'briefly': 30.0, 
        'quickly': 45.0, 'slowly': 120.0
    }
    if time_str in special_times:
        result = special_times[time_str]
        debug_print(f"🎯 特殊时间: '{time_str}' → {result}s")
        return result
    # 🔢 数字提取（简化正则）
    try:
        # 提取数字
        numbers = re.findall(r'\d+\.?\d*', time_str)
        if numbers:
            value = float(numbers[0])
            # 简化单位判断
            if any(unit in time_str for unit in ['min', 'm']):
                result = value * 60.0
            elif any(unit in time_str for unit in ['h', 'hour']):
                result = value * 3600.0
            else:
                result = value  # 默认秒
            debug_print(f"✅ 时间解析: '{time_str}' → {result}s")
            return result
    except:
        pass
    debug_print(f"⚠️ 时间解析失败: '{time_str}'，使用默认60s")
    return 60.0
 def parse_volume_input(volume: Union[float, str], volume_spec: str = "", mass: str = "") -> float:
    """统一体积解析函数（精简版）"""
    debug_print(f"💧 解析体积: volume={volume}, spec='{volume_spec}', mass='{mass}'")
    # 🎯 优先级1：volume_spec（快速映射）
    if volume_spec:
        spec_map = {
            'small': 20.0, 'medium': 50.0, 'large': 100.0,
            'minimal': 10.0, 'normal': 50.0, 'generous': 150.0
        }
        for key, val in spec_map.items():
            if key in volume_spec.lower():
                debug_print(f"🎯 规格匹配: '{volume_spec}' → {val}mL")
                return val
    # 🧮 优先级2：mass转体积（简化：1g=1mL）
    if mass:
        try:
            numbers = re.findall(r'\d+\.?\d*', mass)
            if numbers:
                value = float(numbers[0])
                if 'mg' in mass.lower():
                    result = value / 1000.0
                elif 'kg' in mass.lower():
                    result = value * 1000.0
                else:
                    result = value  # 默认g
                debug_print(f"⚖️ 质量转换: {mass} → {result}mL")
                return result
        except:
            pass
    # 📦 优先级3：volume
    if volume:
        if isinstance(volume, (int, float)):
            result = float(volume)
            debug_print(f"💧 数值体积: {volume} → {result}mL")
            return result
        elif isinstance(volume, str):
            try:
                # 提取数字
                numbers = re.findall(r'\d+\.?\d*', volume)
                if numbers:
                    value = float(numbers[0])
                    # 简化单位判断
                    if 'l' in volume.lower() and 'ml' not in volume.lower():
                        result = value * 1000.0  # L转mL
                    else:
                        result = value  # 默认mL
                    debug_print(f"💧 字符串体积: '{volume}' → {result}mL")
                    return result
            except:
                pass
    # 默认值
    debug_print(f"⚠️ 体积解析失败，使用默认50mL")
    return 50.0
 def find_solvent_source(G: nx.DiGraph, solvent: str) -> str:
    """查找溶剂源（精简版）"""
    debug_print(f"🔍 查找溶剂源: {solvent}")
    # 简化搜索列表
    search_patterns = [
        f"flask_{solvent}", f"bottle_{solvent}", f"reagent_{solvent}",
        "liquid_reagent_bottle_1", "flask_1", "solvent_bottle"
    ]
    for pattern in search_patterns:
        if pattern in G.nodes():
            debug_print(f"🎉 找到溶剂源: {pattern}")
            return pattern
    debug_print(f"⚠️ 使用默认溶剂源: flask_{solvent}")
    return f"flask_{solvent}"
 def find_filtrate_vessel(G: nx.DiGraph, filtrate_vessel: str = "") -> str:
    """查找滤液容器（精简版）"""
    debug_print(f"🔍 查找滤液容器: {filtrate_vessel}")
    # 如果指定了且存在，直接使用
    if filtrate_vessel and filtrate_vessel in G.nodes():
        debug_print(f"✅ 使用指定容器: {filtrate_vessel}")
        return filtrate_vessel
    # 简化搜索列表
    default_vessels = ["waste_workup", "filtrate_vessel", "flask_1", "collection_bottle_1"]
    for vessel in default_vessels:
        if vessel in G.nodes():
            debug_print(f"🎉 找到滤液容器: {vessel}")
            return vessel
    debug_print(f"⚠️ 使用默认滤液容器: waste_workup")
    return "waste_workup"
 def generate_wash_solid_protocol(
    G: nx.DiGraph,
    vessel: str,
    solvent: str,
-    volume: float,
+    volume: Union[float, str] = "50",
    filtrate_vessel: str = "",
    temp: float = 25.0,
    stir: bool = False,
    stir_speed: float = 0.0,
-    time: float = 0.0,
+    time: Union[str, float] = "0",
-    repeats: int = 1
+    repeats: int = 1,
    volume_spec: str = "",
    repeats_spec: str = "",
    mass: str = "",
    event: str = "",
    **kwargs
 ) -> List[Dict[str, Any]]:
    """
-    生成固体清洗的协议序列
+    生成固体清洗协议（精简版）
    Args:
        G: 有向图，节点为设备和容器
        vessel: 装有固体物质的容器名称
        solvent: 用于清洗固体的溶剂名称
        volume: 清洗溶剂的体积
        filtrate_vessel: 滤液要收集到的容器名称，可选参数
        temp: 清洗时的温度，可选参数
        stir: 是否在清洗过程中搅拌，默认为 False
        stir_speed: 搅拌速度，可选参数
        time: 清洗的时间，可选参数
        repeats: 清洗操作的重复次数，默认为 1
    Returns:
        List[Dict[str, Any]]: 固体清洗操作的动作序列
    Raises:
        ValueError: 当找不到必要的设备时抛出异常
    Examples:
        wash_solid_protocol = generate_wash_solid_protocol(
            G, "reactor", "ethanol", 100.0, "waste_flask", 60.0, True, 300.0, 600.0, 3
        )
    """
    debug_print("🧼" * 20)
    debug_print("🚀 开始生成固体清洗协议 ✨")
    debug_print(f"📝 输入参数:")
    debug_print(f"  🥽 vessel: {vessel}")
    debug_print(f"  🧪 solvent: {solvent}")
    debug_print(f"  💧 volume: {volume}")
    debug_print(f"  ⏰ time: {time}")
    debug_print(f"  🔄 repeats: {repeats}")
    debug_print("🧼" * 20)
    # 📋 快速验证
    if not vessel or vessel not in G.nodes():
        debug_print("❌ 容器验证失败! 😱")
        raise ValueError("vessel 参数无效")
    if not solvent:
        debug_print("❌ 溶剂不能为空! 😱")
        raise ValueError("solvent 参数不能为空")
    debug_print("✅ 基础验证通过 🎯")
    # 🔄 参数解析
    debug_print("📍 步骤1: 参数解析... ⚡")
    final_volume = parse_volume_input(volume, volume_spec, mass)
    final_time = parse_time_input(time)
    # 重复次数处理（简化）
    if repeats_spec:
        spec_map = {'few': 2, 'several': 3, 'many': 4, 'thorough': 5}
        final_repeats = next((v for k, v in spec_map.items() if k in repeats_spec.lower()), repeats)
    else:
        final_repeats = max(1, min(repeats, 5))  # 限制1-5次
    # 🕐 模拟时间优化
    debug_print("  ⏱️ 模拟时间优化...")
    original_time = final_time
    if final_time > 60.0:
        final_time = 60.0  # 限制最长60秒
        debug_print(f"  🎮 时间优化: {original_time}s → {final_time}s ⚡")
    # 参数修正
    temp = max(25.0, min(temp, 80.0))  # 温度范围25-80°C
    stir_speed = max(0.0, min(stir_speed, 300.0)) if stir else 0.0  # 速度范围0-300
    debug_print(f"🎯 最终参数: 体积={final_volume}mL, 时间={final_time}s, 重复={final_repeats}次")
    # 🔍 查找设备
    debug_print("📍 步骤2: 查找设备... 🔍")
    try:
        solvent_source = find_solvent_source(G, solvent)
        actual_filtrate_vessel = find_filtrate_vessel(G, filtrate_vessel)
        debug_print(f"🎉 设备配置完成 ✨")
    except Exception as e:
        debug_print(f"❌ 设备查找失败: {str(e)} 😭")
        raise ValueError(f"设备查找失败: {str(e)}")
    # 🚀 生成动作序列
    debug_print("📍 步骤3: 生成清洗动作... 🧼")
    action_sequence = []
-    # 验证容器是否存在
+    for cycle in range(final_repeats):
-    if vessel not in G.nodes():
+        debug_print(f"  🔄 第{cycle+1}/{final_repeats}次清洗...")
        raise ValueError(f"固体容器 {vessel} 不存在于图中")
-    if filtrate_vessel and filtrate_vessel not in G.nodes():
+        # 1. 转移溶剂
-        raise ValueError(f"滤液容器 {filtrate_vessel} 不存在于图中")
+        try:
            from .pump_protocol import generate_pump_protocol_with_rinsing
-    # 查找转移泵设备（用于添加溶剂和转移滤液）
+            transfer_actions = generate_pump_protocol_with_rinsing(
-    pump_nodes = [node for node in G.nodes() 
+                G=G,
-                  if G.nodes[node].get('class') == 'virtual_transfer_pump']
+                from_vessel=solvent_source,
                to_vessel=vessel,
                volume=final_volume,
                amount="",
                time=0.0,
                viscous=False,
                rinsing_solvent="",
                rinsing_volume=0.0,
                rinsing_repeats=0,
                solid=False,
                flowrate=2.5,
                transfer_flowrate=0.5
            )
-    if not pump_nodes:
+            if transfer_actions:
-        raise ValueError("没有找到可用的转移泵设备")
+                action_sequence.extend(transfer_actions)
                debug_print(f"    ✅ 转移动作: {len(transfer_actions)}个 🚚")
-    pump_id = pump_nodes[0]
+        except Exception as e:
            debug_print(f"    ❌ 转移失败: {str(e)} 😞")
-    # 查找加热设备（如果需要加热）
+        # 2. 搅拌（如果需要）
-    heatchill_nodes = [node for node in G.nodes() 
+        if stir and final_time > 0:
-                      if G.nodes[node].get('class') == 'virtual_heatchill']
+            stir_action = {
-    
+                "device_id": "stirrer_1",
-    heatchill_id = heatchill_nodes[0] if heatchill_nodes else None
+                "action_name": "stir",
    # 查找搅拌设备（如果需要搅拌）
    stirrer_nodes = [node for node in G.nodes() 
                    if G.nodes[node].get('class') == 'virtual_stirrer']
    stirrer_id = stirrer_nodes[0] if stirrer_nodes else None
    # 查找过滤设备（用于分离固体和滤液）
    filter_nodes = [node for node in G.nodes() 
                   if G.nodes[node].get('class') == 'virtual_filter']
    filter_id = filter_nodes[0] if filter_nodes else None
    # 查找溶剂容器
    solvent_vessel = f"flask_{solvent}"
    if solvent_vessel not in G.nodes():
        # 如果没有找到特定溶剂容器，查找可用的源容器
        available_vessels = [node for node in G.nodes() 
                           if node.startswith('flask_') and 
                           G.nodes[node].get('type') == 'container']
        if available_vessels:
            solvent_vessel = available_vessels[0]
        else:
            raise ValueError(f"没有找到溶剂容器 {solvent}")
    # 如果没有指定滤液容器，使用废液容器
    if not filtrate_vessel:
        waste_vessels = [node for node in G.nodes() 
                        if 'waste' in node.lower() and 
                        G.nodes[node].get('type') == 'container']
        filtrate_vessel = waste_vessels[0] if waste_vessels else "waste_flask"
    # 重复清洗操作
    for repeat in range(repeats):
        repeat_num = repeat + 1
        # 步骤1：如果需要加热，先设置温度
        if temp > 25.0 and heatchill_id:
            action_sequence.append({
                "device_id": heatchill_id,
                "action_name": "heat_chill_start",
                "action_kwargs": {
                    "vessel": vessel,
-                    "temp": temp,
+                    "time": str(time),
-                    "purpose": f"固体清洗 - 第 {repeat_num} 次"
+                    "stir_time": final_time,
                    "stir_speed": stir_speed,
                    "settling_time": 10.0  # 🕐 缩短沉降时间
                }
            })
        # 步骤2：添加清洗溶剂到固体容器
        action_sequence.append({
            "device_id": pump_id,
            "action_name": "transfer",
            "action_kwargs": {
                "from_vessel": solvent_vessel,
                "to_vessel": vessel,
                "volume": volume,
                "amount": f"清洗溶剂 {solvent} - 第 {repeat_num} 次",
                "time": 0.0,
                "viscous": False,
                "rinsing_solvent": "",
                "rinsing_volume": 0.0,
                "rinsing_repeats": 0,
                "solid": False
            }
            action_sequence.append(stir_action)
            debug_print(f"    ✅ 搅拌动作: {final_time}s, {stir_speed}RPM 🌪️")
        # 3. 过滤
        filter_action = {
            "device_id": "filter_1",
            "action_name": "filter",
            "action_kwargs": {
                "vessel": vessel,
                "filtrate_vessel": actual_filtrate_vessel,
                "temp": temp,
                "volume": final_volume
            }
        }
        action_sequence.append(filter_action)
        debug_print(f"    ✅ 过滤动作: → {actual_filtrate_vessel} 🌊")
        # 4. 等待（缩短时间）
        wait_time = 5.0  # 🕐 缩短等待时间：10s → 5s
        action_sequence.append({
            "action_name": "wait",
            "action_kwargs": {"time": wait_time}
        })
        debug_print(f"    ✅ 等待: {wait_time}s ⏰")
-        # 步骤3：如果需要搅拌，开始搅拌
+    # 🎊 总结
-        if stir and stir_speed > 0 and stirrer_id:
+    debug_print("🧼" * 20)
-            if time > 0:
+    debug_print(f"🎉 固体清洗协议生成完成! ✨")
-                # 定时搅拌
+    debug_print(f"📊 总动作数: {len(action_sequence)} 个")
-                action_sequence.append({
+    debug_print(f"🥽 清洗容器: {vessel}")
-                    "device_id": stirrer_id,
+    debug_print(f"🧪 使用溶剂: {solvent}")
-                    "action_name": "stir",
+    debug_print(f"💧 清洗体积: {final_volume}mL × {final_repeats}次")
-                    "action_kwargs": {
+    debug_print(f"⏱️ 预计总时间: {(final_time + 5) * final_repeats / 60:.1f} 分钟")
-                        "stir_time": time,
+    debug_print("🧼" * 20)
                        "stir_speed": stir_speed,
                        "settling_time": 30.0  # 搅拌后静置30秒
                    }
                })
            else:
                # 开始搅拌（需要手动停止）
                action_sequence.append({
                    "device_id": stirrer_id,
                    "action_name": "start_stir",
                    "action_kwargs": {
                        "vessel": vessel,
                        "stir_speed": stir_speed,
                        "purpose": f"固体清洗搅拌 - 第 {repeat_num} 次"
                    }
                })
        # 步骤4：如果指定了清洗时间但没有搅拌，等待清洗时间
        if time > 0 and (not stir or stir_speed == 0):
            # 这里可以添加等待操作，暂时跳过
            pass
        # 步骤5：如果有搅拌且没有定时，停止搅拌
        if stir and stir_speed > 0 and time == 0 and stirrer_id:
            action_sequence.append({
                "device_id": stirrer_id,
                "action_name": "stop_stir",
                "action_kwargs": {
                    "vessel": vessel
                }
            })
        # 步骤6：过滤分离固体和滤液
        if filter_id:
            action_sequence.append({
                "device_id": filter_id,
                "action_name": "filter_sample",
                "action_kwargs": {
                    "vessel": vessel,
                    "filtrate_vessel": filtrate_vessel,
                    "stir": False,
                    "stir_speed": 0.0,
                    "temp": temp,
                    "continue_heatchill": temp > 25.0,
                    "volume": volume
                }
            })
        else:
            # 没有专门的过滤设备，使用转移泵模拟过滤过程
            # 将滤液转移到滤液容器
            action_sequence.append({
                "device_id": pump_id,
                "action_name": "transfer",
                "action_kwargs": {
                    "from_vessel": vessel,
                    "to_vessel": filtrate_vessel,
                    "volume": volume,
                    "amount": f"转移滤液 - 第 {repeat_num} 次清洗",
                    "time": 0.0,
                    "viscous": False,
                    "rinsing_solvent": "",
                    "rinsing_volume": 0.0,
                    "rinsing_repeats": 0,
                    "solid": False
                }
            })
        # 步骤7：如果加热了，停止加热（在最后一次清洗后）
        if temp > 25.0 and heatchill_id and repeat_num == repeats:
            action_sequence.append({
                "device_id": heatchill_id,
                "action_name": "heat_chill_stop",
                "action_kwargs": {
                    "vessel": vessel
                }
            })
    return action_sequence
--- a/unilabos/config/config.py
+++ b/unilabos/config/config.py
@@ -10,8 +10,9 @@ from unilabos.utils import logger
 class BasicConfig:
    ENV = "pro"  # 'test'
    config_path = ""
-    is_host_mode = True  # 从registry.py移动过来
+    is_host_mode = True
    slave_no_host = False  # 是否跳过rclient.wait_for_service()
    upload_registry = False
    machine_name = "undefined"
    vis_2d_enable = False
--- a/unilabos/devices/agv/ur_arm_task.py
+++ b/unilabos/devices/agv/ur_arm_task.py
@@ -1,9 +1,12 @@
-import rtde_control
+try:
-import dashboard_client
+    import rtde_control
    import dashboard_client
    import rtde_receive
 except ImportError as ex:
    print("Import Error, Please Install Packages in ur_arm_task.py First!", ex)
 import time
 import json
 from unilabos.devices.agv.robotiq_gripper import RobotiqGripper
 import rtde_receive
 from std_msgs.msg import Float64MultiArray
 from pydantic import BaseModel
--- a/unilabos/devices/laiyu_add_solid/laiyu.py
+++ b/unilabos/devices/laiyu_add_solid/laiyu.py
@@ -234,71 +234,71 @@ class Laiyu:
        resp_reset = self.reset()
        return actual_mass_mg
 if __name__ == "__main__":
    '''
    样例：对单个粉筒进行称量
    '''
    modbus = Laiyu(port="COM25")
    mass_test = modbus.add_powder_tube(1, 'h12', 6.0)
    print(f"实际出料质量：{mass_test}mg")
-'''
+    '''
-样例：对单个粉筒进行称量
+    样例: 对一份excel文件记录的化合物进行称量
-'''
+    '''
-modbus = Laiyu(port="COM25") 
+    excel_file = r"C:\auto\laiyu\test1.xlsx"
    # 定义输出文件路径，用于记录实际加样多少
    output_file = r"C:\auto\laiyu\test_output.xlsx"
-mass_test = modbus.add_powder_tube(1, 'h12', 6.0)
+    # 定义物料名称和料筒位置关系
-print(f"实际出料质量：{mass_test}mg")
+    compound_positions = {
        'XPhos': '1',
        'Cu(OTf)2': '2',
        'CuSO4': '3',
        'PPh3': '4',
    }
    # read excel file
    # excel_file = r"C:\auto\laiyu\test.xlsx"
    df = pd.read_excel(excel_file, sheet_name='Sheet1')
    # 读取Excel文件中的数据
    # 遍历每一行数据
    for index, row in df.iterrows():
        # 获取物料名称和质量
        copper_name = row['copper']
        copper_mass = row['copper_mass']
        ligand_name = row['ligand']
        ligand_mass = row['ligand_mass']
        target_tube_position = row['position']
        # 获取物料位置 from compound_positions
        copper_position = compound_positions.get(copper_name)
        ligand_position = compound_positions.get(ligand_name)
        # 判断物料位置是否存在
        if copper_position is None:
            print(f"物料位置不存在：{copper_name}")
            continue
        if ligand_position is None:
            print(f"物料位置不存在：{ligand_name}")
            continue
        # 加铜
        copper_actual_mass = modbus.add_powder_tube(int(copper_position), target_tube_position, copper_mass)
        time.sleep(1)
        # 加配体
        ligand_actual_mass = modbus.add_powder_tube(int(ligand_position), target_tube_position, ligand_mass)
        time.sleep(1)
        # 保存至df
        df.at[index, 'copper_actual_mass'] = copper_actual_mass
        df.at[index, 'ligand_actual_mass'] = ligand_actual_mass
-'''
+    # 保存修改后的数据到新的Excel文件
-样例: 对一份excel文件记录的化合物进行称量
+    df.to_excel(output_file, index=False)
-'''
+    print(f"已保存到文件：{output_file}")
-excel_file = r"C:\auto\laiyu\test1.xlsx"
+    # 关闭串口
-# 定义输出文件路径，用于记录实际加样多少
+    modbus.ser.close()
-output_file = r"C:\auto\laiyu\test_output.xlsx"
+    print("串口已关闭")
 # 定义物料名称和料筒位置关系
 compound_positions = {
    'XPhos': '1',
    'Cu(OTf)2': '2',
    'CuSO4': '3',
    'PPh3': '4',
 }
 # read excel file
 # excel_file = r"C:\auto\laiyu\test.xlsx"
 df = pd.read_excel(excel_file, sheet_name='Sheet1')
 # 读取Excel文件中的数据
 # 遍历每一行数据
 for index, row in df.iterrows():
    # 获取物料名称和质量
    copper_name = row['copper']
    copper_mass = row['copper_mass']
    ligand_name = row['ligand']
    ligand_mass = row['ligand_mass']
    target_tube_position = row['position']
    # 获取物料位置 from compound_positions
    copper_position = compound_positions.get(copper_name)
    ligand_position = compound_positions.get(ligand_name)
    # 判断物料位置是否存在
    if copper_position is None:
        print(f"物料位置不存在：{copper_name}")
        continue
    if ligand_position is None:
        print(f"物料位置不存在：{ligand_name}")
        continue
    # 加铜
    copper_actual_mass = modbus.add_powder_tube(int(copper_position), target_tube_position, copper_mass)
    time.sleep(1)
    # 加配体
    ligand_actual_mass = modbus.add_powder_tube(int(ligand_position), target_tube_position, ligand_mass)
    time.sleep(1)
    # 保存至df
    df.at[index, 'copper_actual_mass'] = copper_actual_mass
    df.at[index, 'ligand_actual_mass'] = ligand_actual_mass
 # 保存修改后的数据到新的Excel文件
 df.to_excel(output_file, index=False)
 print(f"已保存到文件：{output_file}")
 # 关闭串口
 modbus.ser.close()
 print("串口已关闭")
--- a/unilabos/devices/liquid_handling/liquid_handler_abstract.py
+++ b/unilabos/devices/liquid_handling/liquid_handler_abstract.py
--- a/unilabos/devices/liquid_handling/prcxi/prcxi.py
+++ b/unilabos/devices/liquid_handling/prcxi/prcxi.py
--- a/unilabos/devices/liquid_handling/revvity.py
+++ b/unilabos/devices/liquid_handling/revvity.py
@@ -3,7 +3,11 @@ import sys
 import io
 # sys.path.insert(0, r'C:\kui\winprep_cli\winprep_c_Uni-lab\x64\Debug')
-import winprep_c
+try:
    import winprep_c
 except ImportError as e:
    print("Error importing winprep_c:", e)
    print("Please ensure that the winprep_c module is correctly installed and accessible.")
 from queue import Queue
--- a/unilabos/devices/motor/iCL42.py
+++ b/unilabos/devices/motor/iCL42.py
@@ -21,7 +21,7 @@ except Exception as e:
    sys.path.insert(0, os.path.abspath(os.path.join(os.path.dirname(__file__), "..", "..", "..")))
    from unilabos.utils.pywinauto_util import connect_application, get_process_pid_by_name, get_ui_path_with_window_specification, print_wrapper_identifiers
    from unilabos.device_comms.universal_driver import UniversalDriver, SingleRunningExecutor
-    from unilabos.devices.template_driver import universal_driver as ud
+    from unilabos.device_comms import universal_driver as ud
    print(f"使用文件DEBUG运行: {e}")
--- a/unilabos/devices/raman_uv/home_made_raman.py
+++ b/unilabos/devices/raman_uv/home_made_raman.py
@@ -9,7 +9,7 @@ from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
 import time
 class RamanObj:
-    def __init__(self, port_laser,port_ccd, baudrate_laser=9600, baudrate_ccd=921600):
+    def __init__(self, port_laser, port_ccd, baudrate_laser=9600, baudrate_ccd=921600):
        self.port_laser = port_laser
        self.port_ccd = port_ccd
--- a/unilabos/devices/ros_dev/moveit_interface.py
+++ b/unilabos/devices/ros_dev/moveit_interface.py
@@ -17,7 +17,7 @@ class MoveitInterface:
    tf_buffer: Buffer
    tf_listener: TransformListener
-    def __init__(self, moveit_type, joint_poses, rotation=None, device_config=None):
+    def __init__(self, moveit_type, joint_poses, rotation=None, device_config=None, **kwargs):
        self.device_config = device_config
        self.rotation = rotation
        self.data_config = json.load(
--- a/unilabos/devices/virtual/virtual_centrifuge.py
+++ b/unilabos/devices/virtual/virtual_centrifuge.py
@@ -1,16 +1,18 @@
 import asyncio
 import logging
-from typing import Dict, Any
+import time as time_module
 from typing import Dict, Any, Optional
 class VirtualCentrifuge:
-    """Virtual centrifuge device for CentrifugeProtocol testing"""
+    """Virtual centrifuge device - 简化版，只保留核心功能"""
-    def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
+    def __init__(self, device_id: Optional[str] = None, config: Optional[Dict[str, Any]] = None, **kwargs):
        # 处理可能的不同调用方式
-        if device_id is None and 'id' in kwargs:
+        if device_id is None and "id" in kwargs:
-            device_id = kwargs.pop('id')
+            device_id = kwargs.pop("id")
-        if config is None and 'config' in kwargs:
+        if config is None and "config" in kwargs:
-            config = kwargs.pop('config')
+            config = kwargs.pop("config")
        # 设置默认值
        self.device_id = device_id or "unknown_centrifuge"
@@ -19,100 +21,157 @@ class VirtualCentrifuge:
        self.logger = logging.getLogger(f"VirtualCentrifuge.{self.device_id}")
        self.data = {}
        # 添加调试信息
        print(f"=== VirtualCentrifuge {self.device_id} is being created! ===")
        print(f"=== Config: {self.config} ===")
        print(f"=== Kwargs: {kwargs} ===")
        # 从config或kwargs中获取配置参数
-        self.port = self.config.get('port') or kwargs.get('port', 'VIRTUAL')
+        self.port = self.config.get("port") or kwargs.get("port", "VIRTUAL")
-        self._max_speed = self.config.get('max_speed') or kwargs.get('max_speed', 15000.0)
+        self._max_speed = self.config.get("max_speed") or kwargs.get("max_speed", 15000.0)
-        self._max_temp = self.config.get('max_temp') or kwargs.get('max_temp', 40.0)
+        self._max_temp = self.config.get("max_temp") or kwargs.get("max_temp", 40.0)
-        self._min_temp = self.config.get('min_temp') or kwargs.get('min_temp', 4.0)
+        self._min_temp = self.config.get("min_temp") or kwargs.get("min_temp", 4.0)
-        # 处理其他kwargs参数，但跳过已知的配置参数
+        # 处理其他kwargs参数
-        skip_keys = {'port', 'max_speed', 'max_temp', 'min_temp'}
+        skip_keys = {"port", "max_speed", "max_temp", "min_temp"}
        for key, value in kwargs.items():
            if key not in skip_keys and not hasattr(self, key):
                setattr(self, key, value)
    async def initialize(self) -> bool:
        """Initialize virtual centrifuge"""
        print(f"=== VirtualCentrifuge {self.device_id} initialize() called! ===")
        self.logger.info(f"Initializing virtual centrifuge {self.device_id}")
        # 只保留核心状态
        self.data.update({
            "status": "Idle",
            "centrifuge_state": "Stopped",  # Stopped, Running, Completed, Error
            "current_speed": 0.0,
            "target_speed": 0.0,
            "current_temp": 25.0,
            "target_temp": 25.0,
            "max_speed": self._max_speed,
            "max_temp": self._max_temp,
            "min_temp": self._min_temp,
            "centrifuge_state": "Stopped",
            "time_remaining": 0.0,
            "progress": 0.0,
-            "message": ""
+            "message": "Ready for centrifugation"
        })
        return True
    async def cleanup(self) -> bool:
        """Cleanup virtual centrifuge"""
        self.logger.info(f"Cleaning up virtual centrifuge {self.device_id}")
        self.data.update({
            "status": "Offline",
            "centrifuge_state": "Offline",
            "current_speed": 0.0,
            "current_temp": 25.0,
            "message": "System offline"
        })
        return True
-    async def centrifuge(self, vessel: str, speed: float, time: float, temp: float = 25.0) -> bool:
+    async def centrifuge(
-        """Execute centrifuge action - matches Centrifuge action"""
+        self, 
-        self.logger.info(f"Centrifuge: vessel={vessel}, speed={speed} RPM, time={time}s, temp={temp}°C")
+        vessel: str, 
        speed: float, 
        time: float, 
        temp: float = 25.0
    ) -> bool:
        """Execute centrifuge action - 简化的离心流程"""
        self.logger.info(f"Centrifuge: vessel={vessel}, speed={speed} rpm, time={time}s, temp={temp}°C")
        # 验证参数
-        if speed > self._max_speed:
+        if speed > self._max_speed or speed < 100.0:
-            self.logger.error(f"Speed {speed} exceeds maximum {self._max_speed}")
+            error_msg = f"离心速度 {speed} rpm 超出范围 (100-{self._max_speed} rpm)"
-            self.data["message"] = f"速度 {speed} 超过最大值 {self._max_speed}"
+            self.logger.error(error_msg)
            self.data.update({
                "status": f"Error: {error_msg}",
                "centrifuge_state": "Error",
                "message": error_msg
            })
            return False
        if temp > self._max_temp or temp < self._min_temp:
-            self.logger.error(f"Temperature {temp} outside range {self._min_temp}-{self._max_temp}")
+            error_msg = f"温度 {temp}°C 超出范围 ({self._min_temp}-{self._max_temp}°C)"
-            self.data["message"] = f"温度 {temp} 超出范围 {self._min_temp}-{self._max_temp}"
+            self.logger.error(error_msg)
            self.data.update({
                "status": f"Error: {error_msg}",
                "centrifuge_state": "Error",
                "message": error_msg
            })
            return False
        # 开始离心
        self.data.update({
-            "status": "Running",
+            "status": f"离心中: {vessel}",
-            "centrifuge_state": "Centrifuging",
+            "centrifuge_state": "Running",
            "target_speed": speed,
            "current_speed": speed,
-            "target_temp": temp,
+            "target_speed": speed,
            "current_temp": temp,
            "target_temp": temp,
            "time_remaining": time,
            "vessel": vessel,
            "progress": 0.0,
-            "message": f"离心中: {vessel} at {speed} RPM"
+            "message": f"Centrifuging {vessel} at {speed} rpm, {temp}°C"
        })
-        # 模拟离心过程
+        try:
-        simulation_time = min(time, 5.0)  # 最多等待5秒用于测试
+            # 离心过程 - 实时更新进度
-        await asyncio.sleep(simulation_time)
+            start_time = time_module.time()
            total_time = time
-        # 离心完成
+            while True:
-        self.data.update({
+                current_time = time_module.time()
-            "status": "Idle",
+                elapsed = current_time - start_time
-            "centrifuge_state": "Stopped",
+                remaining = max(0, total_time - elapsed)
-            "current_speed": 0.0,
+                progress = min(100.0, (elapsed / total_time) * 100)
            "target_speed": 0.0,
            "time_remaining": 0.0,
            "progress": 100.0,
            "message": f"离心完成: {vessel}"
        })
-        self.logger.info(f"Centrifuge completed for vessel {vessel}")
+                # 更新状态
-        return True
+                self.data.update({
                    "time_remaining": remaining,
                    "progress": progress,
                    "status": f"离心中: {vessel} | {speed} rpm | {temp}°C | {progress:.1f}% | 剩余: {remaining:.0f}s",
                    "message": f"Centrifuging: {progress:.1f}% complete, {remaining:.0f}s remaining"
                })
-    # 状态属性
+                # 时间到了，退出循环
                if remaining <= 0:
                    break
                # 每秒更新一次
                await asyncio.sleep(1.0)
            # 离心完成
            self.data.update({
                "status": f"离心完成: {vessel} | {speed} rpm | {time}s",
                "centrifuge_state": "Completed",
                "progress": 100.0,
                "time_remaining": 0.0,
                "current_speed": 0.0,  # 停止旋转
                "current_temp": 25.0,  # 恢复室温
                "message": f"Centrifugation completed: {vessel} at {speed} rpm for {time}s"
            })
            self.logger.info(f"Centrifugation completed: {vessel} at {speed} rpm for {time}s")
            return True
        except Exception as e:
            # 出错处理
            self.logger.error(f"Error during centrifugation: {str(e)}")
            self.data.update({
                "status": f"离心错误: {str(e)}",
                "centrifuge_state": "Error",
                "current_speed": 0.0,
                "current_temp": 25.0,
                "progress": 0.0,
                "time_remaining": 0.0,
                "message": f"Centrifugation failed: {str(e)}"
            })
            return False
    # === 核心状态属性 ===
    @property
    def status(self) -> str:
        return self.data.get("status", "Unknown")
    @property
    def centrifuge_state(self) -> str:
        return self.data.get("centrifuge_state", "Unknown")
    @property
    def current_speed(self) -> float:
        return self.data.get("current_speed", 0.0)
@@ -131,19 +190,15 @@ class VirtualCentrifuge:
    @property
    def max_speed(self) -> float:
-        return self.data.get("max_speed", self._max_speed)
+        return self._max_speed
    @property
    def max_temp(self) -> float:
-        return self.data.get("max_temp", self._max_temp)
+        return self._max_temp
    @property
    def min_temp(self) -> float:
-        return self.data.get("min_temp", self._min_temp)
+        return self._min_temp
    @property
    def centrifuge_state(self) -> str:
        return self.data.get("centrifuge_state", "Unknown")
    @property
    def time_remaining(self) -> float:
--- a/unilabos/devices/virtual/virtual_column.py
+++ b/unilabos/devices/virtual/virtual_column.py
@@ -3,7 +3,7 @@ import logging
 from typing import Dict, Any, Optional
 class VirtualColumn:
-    """Virtual column device for RunColumn protocol"""
+    """Virtual column device for RunColumn protocol 🏛️"""
    def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
        # 处理可能的不同调用方式
@@ -25,11 +25,13 @@ class VirtualColumn:
        self._column_length = self.config.get('column_length') or kwargs.get('column_length', 25.0)
        self._column_diameter = self.config.get('column_diameter') or kwargs.get('column_diameter', 2.0)
-        print(f"=== VirtualColumn {self.device_id} created with max_flow_rate={self._max_flow_rate}, length={self._column_length}cm ===")
+        print(f"🏛️ === 虚拟色谱柱 {self.device_id} 已创建 === ✨")
        print(f"📏 柱参数: 流速={self._max_flow_rate}mL/min | 长度={self._column_length}cm | 直径={self._column_diameter}cm 🔬")
    async def initialize(self) -> bool:
-        """Initialize virtual column"""
+        """Initialize virtual column 🚀"""
-        self.logger.info(f"Initializing virtual column {self.device_id}")
+        self.logger.info(f"🔧 初始化虚拟色谱柱 {self.device_id} ✨")
        self.data.update({
            "status": "Idle",
            "column_state": "Ready", 
@@ -39,31 +41,61 @@ class VirtualColumn:
            "column_diameter": self._column_diameter,
            "processed_volume": 0.0,
            "progress": 0.0,
-            "current_status": "Ready"
+            "current_status": "Ready for separation"
        })
        self.logger.info(f"✅ 色谱柱 {self.device_id} 初始化完成 🏛️")
        self.logger.info(f"📊 设备规格: 最大流速 {self._max_flow_rate}mL/min | 柱长 {self._column_length}cm 📏")
        return True
    async def cleanup(self) -> bool:
-        """Cleanup virtual column"""
+        """Cleanup virtual column 🧹"""
-        self.logger.info(f"Cleaning up virtual column {self.device_id}")
+        self.logger.info(f"🧹 清理虚拟色谱柱 {self.device_id} 🔚")
        self.data.update({
            "status": "Offline",
            "column_state": "Offline",
            "current_status": "System offline"
        })
        self.logger.info(f"✅ 色谱柱 {self.device_id} 清理完成 💤")
        return True
-    async def run_column(self, from_vessel: str, to_vessel: str, column: str) -> bool:
+    async def run_column(self, from_vessel: str, to_vessel: str, column: str, **kwargs) -> bool:
-        """Execute column chromatography run - matches RunColumn action"""
+        """Execute column chromatography run - matches RunColumn action 🏛️"""
-        self.logger.info(f"Running column separation: {from_vessel} -> {to_vessel} using {column}")
+        
        # 提取额外参数
        rf = kwargs.get('rf', '0.3')
        solvent1 = kwargs.get('solvent1', 'ethyl_acetate')
        solvent2 = kwargs.get('solvent2', 'hexane')
        ratio = kwargs.get('ratio', '30:70')
        self.logger.info(f"🏛️ 开始柱层析分离: {from_vessel} → {to_vessel} 🚰")
        self.logger.info(f"  🧪 使用色谱柱: {column}")
        self.logger.info(f"  🎯 Rf值: {rf}")
        self.logger.info(f"  🧪 洗脱溶剂: {solvent1}:{solvent2} ({ratio}) 💧")
        # 更新设备状态
        self.data.update({
            "status": "Running",
            "column_state": "Separating",
-            "current_status": "Column separation in progress",
+            "current_status": "🏛️ Column separation in progress",
            "progress": 0.0,
-            "processed_volume": 0.0
+            "processed_volume": 0.0,
            "current_from_vessel": from_vessel,
            "current_to_vessel": to_vessel,
            "current_column": column,
            "current_rf": rf,
            "current_solvents": f"{solvent1}:{solvent2} ({ratio})"
        })
        # 模拟柱层析分离过程
        # 假设处理时间基于流速和柱子长度
-        separation_time = (self._column_length * 2) / self._max_flow_rate  # 简化计算
+        base_time = (self._column_length * 2) / self._max_flow_rate  # 简化计算
        separation_time = max(base_time, 20.0)  # 最少20秒
        self.logger.info(f"⏱️ 预计分离时间: {separation_time:.1f}秒 ⌛")
        self.logger.info(f"📏 柱参数: 长度 {self._column_length}cm | 流速 {self._max_flow_rate}mL/min 🌊")
        steps = 20  # 分20个步骤模拟分离过程
        step_time = separation_time / steps
@@ -74,34 +106,65 @@ class VirtualColumn:
            progress = (i + 1) / steps * 100
            volume_processed = (i + 1) * 5.0  # 假设每步处理5mL
            # 不同阶段的状态描述
            if progress <= 25:
                phase = "🌊 样品上柱阶段"
                phase_emoji = "📥"
            elif progress <= 50:
                phase = "🧪 洗脱开始"
                phase_emoji = "💧"
            elif progress <= 75:
                phase = "⚗️ 成分分离中"
                phase_emoji = "🔄"
            else:
                phase = "🎯 收集产物"
                phase_emoji = "📤"
            # 更新状态
            status_msg = f"{phase_emoji} {phase}: {progress:.1f}% | 💧 已处理: {volume_processed:.1f}mL"
            self.data.update({
                "progress": progress,
                "processed_volume": volume_processed,
-                "current_status": f"Column separation: {progress:.1f}% - Processing {volume_processed:.1f}mL"
+                "current_status": status_msg,
                "current_phase": phase
            })
-            self.logger.info(f"Column separation progress: {progress:.1f}%")
+            # 进度日志（每25%打印一次）
            if progress >= 25 and (i + 1) % 5 == 0:  # 每5步（25%）打印一次
                self.logger.info(f"📊 分离进度: {progress:.0f}% | {phase} | 💧 {volume_processed:.1f}mL 完成 ✨")
        # 分离完成
        final_status = f"✅ 柱层析分离完成: {from_vessel} → {to_vessel} | 💧 共处理 {volume_processed:.1f}mL"
        self.data.update({
            "status": "Idle",
            "column_state": "Ready",
-            "current_status": "Column separation completed",
+            "current_status": final_status,
-            "progress": 100.0
+            "progress": 100.0,
            "final_volume": volume_processed
        })
-        self.logger.info(f"Column separation completed: {from_vessel} -> {to_vessel}")
+        self.logger.info(f"🎉 柱层析分离完成! ✨")
        self.logger.info(f"📊 分离结果:")
        self.logger.info(f"  🥽 源容器: {from_vessel}")
        self.logger.info(f"  🥽 目标容器: {to_vessel}")
        self.logger.info(f"  🏛️ 使用色谱柱: {column}")
        self.logger.info(f"  💧 处理体积: {volume_processed:.1f}mL")
        self.logger.info(f"  🧪 洗脱条件: {solvent1}:{solvent2} ({ratio})")
        self.logger.info(f"  🎯 Rf值: {rf}")
        self.logger.info(f"  ⏱️ 总耗时: {separation_time:.1f}秒 🏁")
        return True
    # 状态属性
    @property
    def status(self) -> str:
-        return self.data.get("status", "Unknown")
+        return self.data.get("status", "❓ Unknown")
    @property
    def column_state(self) -> str:
-        return self.data.get("column_state", "Unknown")
+        return self.data.get("column_state", "❓ Unknown")
    @property
    def current_flow_rate(self) -> float:
@@ -129,4 +192,12 @@ class VirtualColumn:
    @property
    def current_status(self) -> str:
-        return self.data.get("current_status", "Ready")
+        return self.data.get("current_status", "📋 Ready")
    @property
    def current_phase(self) -> str:
        return self.data.get("current_phase", "🏠 待机中")
    @property
    def final_volume(self) -> float:
        return self.data.get("final_volume", 0.0)
--- a/unilabos/devices/virtual/virtual_filter.py
+++ b/unilabos/devices/virtual/virtual_filter.py
@@ -1,151 +1,250 @@
 import asyncio
 import logging
-from typing import Dict, Any
+import time as time_module
 from typing import Dict, Any, Optional
 class VirtualFilter:
-    """Virtual filter device for FilterProtocol testing"""
+    """Virtual filter device - 完全按照 Filter.action 规范 🌊"""
-    def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
+    def __init__(self, device_id: Optional[str] = None, config: Optional[Dict[str, Any]] = None, **kwargs):
        # 处理可能的不同调用方式
        if device_id is None and 'id' in kwargs:
            device_id = kwargs.pop('id')
        if config is None and 'config' in kwargs:
            config = kwargs.pop('config')
        # 设置默认值
        self.device_id = device_id or "unknown_filter"
        self.config = config or {}
        self.logger = logging.getLogger(f"VirtualFilter.{self.device_id}")
        self.data = {}
        # 添加调试信息
        print(f"=== VirtualFilter {self.device_id} is being created! ===")
        print(f"=== Config: {self.config} ===")
        print(f"=== Kwargs: {kwargs} ===")
        # 从config或kwargs中获取配置参数
        self.port = self.config.get('port') or kwargs.get('port', 'VIRTUAL')
        self._max_temp = self.config.get('max_temp') or kwargs.get('max_temp', 100.0)
        self._max_stir_speed = self.config.get('max_stir_speed') or kwargs.get('max_stir_speed', 1000.0)
        self._max_volume = self.config.get('max_volume') or kwargs.get('max_volume', 500.0)
-        # 处理其他kwargs参数，但跳过已知的配置参数
+        # 处理其他kwargs参数
-        skip_keys = {'port', 'max_temp', 'max_stir_speed'}
+        skip_keys = {'port', 'max_temp', 'max_stir_speed', 'max_volume'}
        for key, value in kwargs.items():
            if key not in skip_keys and not hasattr(self, key):
                setattr(self, key, value)
    async def initialize(self) -> bool:
-        """Initialize virtual filter"""
+        """Initialize virtual filter 🚀"""
-        print(f"=== VirtualFilter {self.device_id} initialize() called! ===")
+        self.logger.info(f"🔧 初始化虚拟过滤器 {self.device_id} ✨")
-        self.logger.info(f"Initializing virtual filter {self.device_id}")
+        
        # 按照 Filter.action 的 feedback 字段初始化
        self.data.update({
            "status": "Idle",
-            "filter_state": "Ready",
+            "progress": 0.0,           # Filter.action feedback
-            "current_temp": 25.0,
+            "current_temp": 25.0,      # Filter.action feedback
-            "target_temp": 25.0,
+            "filtered_volume": 0.0,    # Filter.action feedback
-            "max_temp": self._max_temp,
+            "current_status": "Ready for filtration",  # Filter.action feedback
-            "stir_speed": 0.0,
+            "message": "Ready for filtration"
            "max_stir_speed": self._max_stir_speed,
            "filtered_volume": 0.0,
            "progress": 0.0,
            "message": ""
        })
        self.logger.info(f"✅ 过滤器 {self.device_id} 初始化完成 🌊")
        return True
    async def cleanup(self) -> bool:
-        """Cleanup virtual filter"""
+        """Cleanup virtual filter 🧹"""
-        self.logger.info(f"Cleaning up virtual filter {self.device_id}")
+        self.logger.info(f"🧹 清理虚拟过滤器 {self.device_id} 🔚")
        self.data.update({
            "status": "Offline",
            "current_status": "System offline",
            "message": "System offline"
        })
        self.logger.info(f"✅ 过滤器 {self.device_id} 清理完成 💤")
        return True
-    async def filter_sample(self, vessel: str, filtrate_vessel: str = "", stir: bool = False, 
+    async def filter(
-                           stir_speed: float = 300.0, temp: float = 25.0, 
+        self, 
-                           continue_heatchill: bool = False, volume: float = 0.0) -> bool:
+        vessel: str, 
-        """Execute filter action - matches Filter action"""
+        filtrate_vessel: str = "", 
-        self.logger.info(f"Filter: vessel={vessel}, filtrate_vessel={filtrate_vessel}, stir={stir}, volume={volume}")
+        stir: bool = False, 
        stir_speed: float = 300.0, 
        temp: float = 25.0, 
        continue_heatchill: bool = False, 
        volume: float = 0.0
    ) -> bool:
        """Execute filter action - 完全按照 Filter.action 参数 🌊"""
        # 🔧 新增：温度自动调整
        original_temp = temp
        if temp == 0.0:
            temp = 25.0  # 0度自动设置为室温
            self.logger.info(f"🌡️ 温度自动调整: {original_temp}°C → {temp}°C (室温) 🏠")
        elif temp < 4.0:
            temp = 4.0   # 小于4度自动设置为4度
            self.logger.info(f"🌡️ 温度自动调整: {original_temp}°C → {temp}°C (最低温度) ❄️")
        self.logger.info(f"🌊 开始过滤操作: {vessel} → {filtrate_vessel} 🚰")
        self.logger.info(f"  🌪️ 搅拌: {stir} ({stir_speed} RPM)")
        self.logger.info(f"  🌡️ 温度: {temp}°C")
        self.logger.info(f"  💧 体积: {volume}mL")
        self.logger.info(f"  🔥 保持加热: {continue_heatchill}")
        # 验证参数
-        if temp > self._max_temp:
+        if temp > self._max_temp or temp < 4.0:
-            self.logger.error(f"Temperature {temp} exceeds maximum {self._max_temp}")
+            error_msg = f"🌡️ 温度 {temp}°C 超出范围 (4-{self._max_temp}°C) ⚠️"
-            self.data["message"] = f"温度 {temp} 超过最大值 {self._max_temp}"
+            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"Error: 温度超出范围 ⚠️",
                "current_status": f"Error: 温度超出范围 ⚠️",
                "message": error_msg
            })
            return False
        if stir and stir_speed > self._max_stir_speed:
-            self.logger.error(f"Stir speed {stir_speed} exceeds maximum {self._max_stir_speed}")
+            error_msg = f"🌪️ 搅拌速度 {stir_speed} RPM 超出范围 (0-{self._max_stir_speed} RPM) ⚠️"
-            self.data["message"] = f"搅拌速度 {stir_speed} 超过最大值 {self._max_stir_speed}"
+            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"Error: 搅拌速度超出范围 ⚠️",
                "current_status": f"Error: 搅拌速度超出范围 ⚠️",
                "message": error_msg
            })
            return False
        if volume > self._max_volume:
            error_msg = f"💧 过滤体积 {volume} mL 超出范围 (0-{self._max_volume} mL) ⚠️"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"Error: 体积超出范围 ⚠️",
                "current_status": f"Error: 体积超出范围 ⚠️",
                "message": error_msg
            })
            return False
        # 开始过滤
        filter_volume = volume if volume > 0 else 50.0
        self.logger.info(f"🚀 开始过滤 {filter_volume}mL 液体 💧")
        self.data.update({
-            "status": "Running",
+            "status": f"🌊 过滤中: {vessel}",
            "filter_state": "Filtering",
            "target_temp": temp,
            "current_temp": temp,
-            "stir_speed": stir_speed if stir else 0.0,
+            "filtered_volume": 0.0,
            "vessel": vessel,
            "filtrate_vessel": filtrate_vessel,
            "target_volume": volume,
            "progress": 0.0,
-            "message": f"过滤中: {vessel}"
+            "current_status": f"🌊 Filtering {vessel} → {filtrate_vessel}",
            "message": f"🚀 Starting filtration: {vessel} → {filtrate_vessel}"
        })
-        # 模拟过滤过程
+        try:
-        simulation_time = min(volume / 10.0 if volume > 0 else 5.0, 10.0)
+            # 过滤过程 - 实时更新进度
-        await asyncio.sleep(simulation_time)
+            start_time = time_module.time()
-        # 过滤完成
+            # 根据体积和搅拌估算过滤时间
-        filtered_vol = volume if volume > 0 else 50.0  # 默认过滤量
+            base_time = filter_volume / 5.0  # 5mL/s 基础速度
-        self.data.update({
+            if stir:
-            "status": "Idle",
+                base_time *= 0.8  # 搅拌加速过滤
-            "filter_state": "Ready",
+                self.logger.info(f"🌪️ 搅拌加速过滤，预计时间减少20% ⚡")
-            "current_temp": 25.0 if not continue_heatchill else temp,
+            if temp > 50.0:
-            "target_temp": 25.0 if not continue_heatchill else temp,
+                base_time *= 0.7  # 高温加速过滤
-            "stir_speed": 0.0 if not stir else stir_speed,
+                self.logger.info(f"🔥 高温加速过滤，预计时间减少30% ⚡")
            "filtered_volume": filtered_vol,
            "progress": 100.0,
            "message": f"过滤完成: {filtered_vol}mL"
        })
-        self.logger.info(f"Filter completed: {filtered_vol}mL from {vessel}")
+            filter_time = max(base_time, 10.0)  # 最少10秒
-        return True
+            self.logger.info(f"⏱️ 预计过滤时间: {filter_time:.1f}秒 ⌛")
-    # 状态属性
+            while True:
                current_time = time_module.time()
                elapsed = current_time - start_time
                remaining = max(0, filter_time - elapsed)
                progress = min(100.0, (elapsed / filter_time) * 100)
                current_filtered = (progress / 100.0) * filter_volume
                # 更新状态 - 按照 Filter.action feedback 字段
                status_msg = f"🌊 过滤中: {vessel}"
                if stir:
                    status_msg += f" | 🌪️ 搅拌: {stir_speed} RPM"
                status_msg += f" | 🌡️ {temp}°C | 📊 {progress:.1f}% | 💧 已过滤: {current_filtered:.1f}mL"
                self.data.update({
                    "progress": progress,               # Filter.action feedback
                    "current_temp": temp,              # Filter.action feedback
                    "filtered_volume": current_filtered, # Filter.action feedback
                    "current_status": f"🌊 Filtering: {progress:.1f}% complete", # Filter.action feedback
                    "status": status_msg,
                    "message": f"🌊 Filtering: {progress:.1f}% complete, {current_filtered:.1f}mL filtered"
                })
                # 进度日志（每25%打印一次）
                if progress >= 25 and progress % 25 < 1:
                    self.logger.info(f"📊 过滤进度: {progress:.0f}% | 💧 {current_filtered:.1f}mL 完成 ✨")
                if remaining <= 0:
                    break
                await asyncio.sleep(1.0)
            # 过滤完成
            final_temp = temp if continue_heatchill else 25.0
            final_status = f"✅ 过滤完成: {vessel} | 💧 {filter_volume}mL → {filtrate_vessel}"
            if continue_heatchill:
                final_status += " | 🔥 继续加热搅拌"
                self.logger.info(f"🔥 继续保持加热搅拌状态 🌪️")
            self.data.update({
                "status": final_status,
                "progress": 100.0,                    # Filter.action feedback
                "current_temp": final_temp,           # Filter.action feedback
                "filtered_volume": filter_volume,     # Filter.action feedback
                "current_status": f"✅ Filtration completed: {filter_volume}mL", # Filter.action feedback
                "message": f"✅ Filtration completed: {filter_volume}mL filtered from {vessel}"
            })
            self.logger.info(f"🎉 过滤完成! 💧 {filter_volume}mL 从 {vessel} 过滤到 {filtrate_vessel} ✨")
            self.logger.info(f"📊 最终状态: 温度 {final_temp}°C | 进度 100% | 体积 {filter_volume}mL 🏁")
            return True
        except Exception as e:
            error_msg = f"过滤过程中发生错误: {str(e)} 💥"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 过滤错误: {str(e)}",
                "current_status": f"❌ Filtration failed: {str(e)}",
                "message": f"❌ Filtration failed: {str(e)}"
            })
            return False
    # === 核心状态属性 - 按照 Filter.action feedback 字段 ===
    @property
    def status(self) -> str:
-        return self.data.get("status", "Unknown")
+        return self.data.get("status", "❓ Unknown")
    @property
    def filter_state(self) -> str:
        return self.data.get("filter_state", "Unknown")
    @property
    def current_temp(self) -> float:
        return self.data.get("current_temp", 25.0)
    @property
    def target_temp(self) -> float:
        return self.data.get("target_temp", 25.0)
    @property
    def max_temp(self) -> float:
        return self.data.get("max_temp", self._max_temp)
    @property
    def stir_speed(self) -> float:
        return self.data.get("stir_speed", 0.0)
    @property
    def max_stir_speed(self) -> float:
        return self.data.get("max_stir_speed", self._max_stir_speed)
    @property
    def filtered_volume(self) -> float:
        return self.data.get("filtered_volume", 0.0)
    @property
    def progress(self) -> float:
        """Filter.action feedback 字段 📊"""
        return self.data.get("progress", 0.0)
    @property
    def current_temp(self) -> float:
        """Filter.action feedback 字段 🌡️"""
        return self.data.get("current_temp", 25.0)
    @property
    def filtered_volume(self) -> float:
        """Filter.action feedback 字段 💧"""
        return self.data.get("filtered_volume", 0.0)
    @property
    def current_status(self) -> str:
        """Filter.action feedback 字段 📋"""
        return self.data.get("current_status", "")
    @property
    def message(self) -> str:
        return self.data.get("message", "")
    @property
    def max_temp(self) -> float:
        return self._max_temp
    @property
    def max_stir_speed(self) -> float:
        return self._max_stir_speed
    @property
    def max_volume(self) -> float:
        return self._max_volume
--- a/unilabos/devices/virtual/virtual_gas_source.py
+++ b/unilabos/devices/virtual/virtual_gas_source.py
@@ -0,0 +1,46 @@
 import time
 from typing import Dict, Any, Optional
 class VirtualGasSource:
    """Virtual gas source for testing"""
    def __init__(self, device_id: Optional[str] = None, config: Optional[Dict[str, Any]] = None, **kwargs):
        self.device_id = device_id or "unknown_gas_source"
        self.config = config or {}
        self.data = {}
        self._status = "OPEN"
    async def initialize(self) -> bool:
        """Initialize virtual gas source"""
        self.data.update({
            "status": self._status
        })
        return True
    async def cleanup(self) -> bool:
        """Cleanup virtual gas source"""
        return True
    @property
    def status(self) -> str:
        return self._status
    def get_status(self) -> str:
        return self._status
    def set_status(self, string):
        self._status = string
        time.sleep(5)
    def open(self):
        self._status = "OPEN"
    def close(self):
        self._status = "CLOSED"
    def is_open(self):
        return self._status
    def is_closed(self):
        return not self._status
--- a/unilabos/devices/virtual/virtual_heatchill.py
+++ b/unilabos/devices/virtual/virtual_heatchill.py
@@ -1,9 +1,10 @@
 import asyncio
 import logging
 import time as time_module  # 重命名time模块，避免与参数冲突
 from typing import Dict, Any
 class VirtualHeatChill:
-    """Virtual heat chill device for HeatChillProtocol testing"""
+    """Virtual heat chill device for HeatChillProtocol testing 🌡️"""
    def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
        # 处理可能的不同调用方式
@@ -19,89 +20,305 @@ class VirtualHeatChill:
        self.logger = logging.getLogger(f"VirtualHeatChill.{self.device_id}")
        self.data = {}
        # 添加调试信息
        print(f"=== VirtualHeatChill {self.device_id} is being created! ===")
        print(f"=== Config: {self.config} ===")
        print(f"=== Kwargs: {kwargs} ===")
        # 从config或kwargs中获取配置参数
        self.port = self.config.get('port') or kwargs.get('port', 'VIRTUAL')
        self._max_temp = self.config.get('max_temp') or kwargs.get('max_temp', 200.0)
        self._min_temp = self.config.get('min_temp') or kwargs.get('min_temp', -80.0)
        self._max_stir_speed = self.config.get('max_stir_speed') or kwargs.get('max_stir_speed', 1000.0)
-        # 处理其他kwargs参数，但跳过已知的配置参数
+        # 处理其他kwargs参数
        skip_keys = {'port', 'max_temp', 'min_temp', 'max_stir_speed'}
        for key, value in kwargs.items():
            if key not in skip_keys and not hasattr(self, key):
                setattr(self, key, value)
        print(f"🌡️ === 虚拟温控设备 {self.device_id} 已创建 === ✨")
        print(f"🔥 温度范围: {self._min_temp}°C ~ {self._max_temp}°C | 🌪️ 最大搅拌: {self._max_stir_speed} RPM")
    async def initialize(self) -> bool:
-        """Initialize virtual heat chill"""
+        """Initialize virtual heat chill 🚀"""
-        print(f"=== VirtualHeatChill {self.device_id} initialize() called! ===")
+        self.logger.info(f"🔧 初始化虚拟温控设备 {self.device_id} ✨")
-        self.logger.info(f"Initializing virtual heat chill {self.device_id}")
+        
        # 初始化状态信息
        self.data.update({
-            "status": "Idle"
+            "status": "🏠 待机中",
            "operation_mode": "Idle",
            "is_stirring": False,
            "stir_speed": 0.0,
            "remaining_time": 0.0,
        })
        self.logger.info(f"✅ 温控设备 {self.device_id} 初始化完成 🌡️")
        self.logger.info(f"📊 设备规格: 温度范围 {self._min_temp}°C ~ {self._max_temp}°C | 搅拌范围 0 ~ {self._max_stir_speed} RPM")
        return True
    async def cleanup(self) -> bool:
-        """Cleanup virtual heat chill"""
+        """Cleanup virtual heat chill 🧹"""
-        self.logger.info(f"Cleaning up virtual heat chill {self.device_id}")
+        self.logger.info(f"🧹 清理虚拟温控设备 {self.device_id} 🔚")
        self.data.update({
            "status": "💤 离线",
            "operation_mode": "Offline",
            "is_stirring": False,
            "stir_speed": 0.0,
            "remaining_time": 0.0
        })
        self.logger.info(f"✅ 温控设备 {self.device_id} 清理完成 💤")
        return True
-    async def heat_chill(self, vessel: str, temp: float, time: float, stir: bool, 
+    async def heat_chill(self, vessel: str, temp: float, time, stir: bool, 
                        stir_speed: float, purpose: str) -> bool:
-        """Execute heat chill action - matches HeatChill action exactly"""
+        """Execute heat chill action - 🔧 修复：确保参数类型正确"""
        self.logger.info(f"HeatChill: vessel={vessel}, temp={temp}°C, time={time}s, stir={stir}, stir_speed={stir_speed}, purpose={purpose}")
-        # 验证参数
+        # 🔧 关键修复：确保所有参数类型正确
        try:
            temp = float(temp)
            time_value = float(time)  # 强制转换为浮点数
            stir_speed = float(stir_speed)
            stir = bool(stir)
            vessel = str(vessel)
            purpose = str(purpose)
        except (ValueError, TypeError) as e:
            error_msg = f"参数类型转换错误: temp={temp}({type(temp)}), time={time}({type(time)}), error={str(e)}"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: {error_msg}",
                "operation_mode": "Error"
            })
            return False
        # 确定温度操作emoji
        if temp > 25.0:
            temp_emoji = "🔥"
            operation_mode = "Heating"
            status_action = "加热"
        elif temp < 25.0:
            temp_emoji = "❄️"
            operation_mode = "Cooling"
            status_action = "冷却"
        else:
            temp_emoji = "🌡️"
            operation_mode = "Maintaining"
            status_action = "保温"
        self.logger.info(f"🌡️ 开始温控操作: {vessel} → {temp}°C {temp_emoji}")
        self.logger.info(f"  🥽 容器: {vessel}")
        self.logger.info(f"  🎯 目标温度: {temp}°C {temp_emoji}")
        self.logger.info(f"  ⏰ 持续时间: {time_value}s")
        self.logger.info(f"  🌪️ 搅拌: {stir} ({stir_speed} RPM)")
        self.logger.info(f"  📝 目的: {purpose}")
        # 验证参数范围
        if temp > self._max_temp or temp < self._min_temp:
-            self.logger.error(f"Temperature {temp} outside range {self._min_temp}-{self._max_temp}")
+            error_msg = f"🌡️ 温度 {temp}°C 超出范围 ({self._min_temp}°C - {self._max_temp}°C) ⚠️"
-            self.data["status"] = f"温度 {temp} 超出范围"
+            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 温度超出范围 ⚠️",
                "operation_mode": "Error"
            })
            return False
        if stir and stir_speed > self._max_stir_speed:
-            self.logger.error(f"Stir speed {stir_speed} exceeds maximum {self._max_stir_speed}")
+            error_msg = f"🌪️ 搅拌速度 {stir_speed} RPM 超出最大值 {self._max_stir_speed} RPM ⚠️"
-            self.data["status"] = f"搅拌速度 {stir_speed} 超出范围"
+            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 搅拌速度超出范围 ⚠️",
                "operation_mode": "Error"
            })
            return False
-        # 开始加热/冷却
+        if time_value <= 0:
            error_msg = f"⏰ 时间 {time_value}s 必须大于0 ⚠️"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 时间参数无效 ⚠️",
                "operation_mode": "Error"
            })
            return False
        # 🔧 修复：使用转换后的时间值
        start_time = time_module.time()
        total_time = time_value  # 使用转换后的浮点数
        self.logger.info(f"🚀 开始{status_action}程序! 预计用时 {total_time:.1f}秒 ⏱️")
        # 开始操作
        stir_info = f" | 🌪️ 搅拌: {stir_speed} RPM" if stir else ""
        self.data.update({
-            "status": f"加热/冷却中: {vessel} 至 {temp}°C"
+            "status": f"{temp_emoji} 运行中: {status_action} {vessel} 至 {temp}°C | ⏰ 剩余: {total_time:.0f}s{stir_info}",
            "operation_mode": operation_mode,
            "is_stirring": stir,
            "stir_speed": stir_speed if stir else 0.0,
            "remaining_time": total_time,
        })
-        # 模拟加热/冷却时间
+        # 在等待过程中每秒更新剩余时间
-        simulation_time = min(time, 10.0)  # 最多等待10秒用于测试
+        last_logged_time = 0
-        await asyncio.sleep(simulation_time)
+        while True:
            current_time = time_module.time()
            elapsed = current_time - start_time
            remaining = max(0, total_time - elapsed)
            progress = (elapsed / total_time) * 100 if total_time > 0 else 100
-        # 加热/冷却完成
+            # 更新剩余时间和状态
-        self.data["status"] = f"完成: {vessel} 已达到 {temp}°C"
+            self.data.update({
                "remaining_time": remaining,
                "status": f"{temp_emoji} 运行中: {status_action} {vessel} 至 {temp}°C | ⏰ 剩余: {remaining:.0f}s{stir_info}",
                "progress": progress
            })
            # 进度日志（每25%打印一次）
            if progress >= 25 and int(progress) % 25 == 0 and int(progress) != last_logged_time:
                self.logger.info(f"📊 {status_action}进度: {progress:.0f}% | ⏰ 剩余: {remaining:.0f}s | {temp_emoji} 目标: {temp}°C ✨")
                last_logged_time = int(progress)
            # 如果时间到了，退出循环
            if remaining <= 0:
                break
            # 等待1秒后再次检查
            await asyncio.sleep(1.0)
        # 操作完成
        final_stir_info = f" | 🌪️ 搅拌: {stir_speed} RPM" if stir else ""
        self.data.update({
            "status": f"✅ 完成: {vessel} 已达到 {temp}°C {temp_emoji} | ⏱️ 用时: {total_time:.0f}s{final_stir_info}",
            "operation_mode": "Completed",
            "remaining_time": 0.0,
            "is_stirring": False,
            "stir_speed": 0.0,
            "progress": 100.0
        })
        self.logger.info(f"🎉 温控操作完成! ✨")
        self.logger.info(f"📊 操作结果:")
        self.logger.info(f"  🥽 容器: {vessel}")
        self.logger.info(f"  🌡️ 达到温度: {temp}°C {temp_emoji}")
        self.logger.info(f"  ⏱️ 总用时: {total_time:.0f}s")
        if stir:
            self.logger.info(f"  🌪️ 搅拌速度: {stir_speed} RPM")
        self.logger.info(f"  📝 操作目的: {purpose} 🏁")
        self.logger.info(f"HeatChill completed for vessel {vessel} at {temp}°C")
        return True
    async def heat_chill_start(self, vessel: str, temp: float, purpose: str) -> bool:
-        """Start heat chill - matches HeatChillStart action exactly"""
+        """Start continuous heat chill 🔄"""
-        self.logger.info(f"HeatChillStart: vessel={vessel}, temp={temp}°C, purpose={purpose}")
+        
        # 🔧 添加类型转换
        try:
            temp = float(temp)
            vessel = str(vessel)
            purpose = str(purpose)
        except (ValueError, TypeError) as e:
            error_msg = f"参数类型转换错误: {str(e)}"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: {error_msg}",
                "operation_mode": "Error"
            })
            return False
        # 确定温度操作emoji
        if temp > 25.0:
            temp_emoji = "🔥"
            operation_mode = "Heating"
            status_action = "持续加热"
        elif temp < 25.0:
            temp_emoji = "❄️"
            operation_mode = "Cooling"
            status_action = "持续冷却"
        else:
            temp_emoji = "🌡️"
            operation_mode = "Maintaining"
            status_action = "恒温保持"
        self.logger.info(f"🔄 启动持续温控: {vessel} → {temp}°C {temp_emoji}")
        self.logger.info(f"  🥽 容器: {vessel}")
        self.logger.info(f"  🎯 目标温度: {temp}°C {temp_emoji}")
        self.logger.info(f"  🔄 模式: {status_action}")
        self.logger.info(f"  📝 目的: {purpose}")
        # 验证参数
        if temp > self._max_temp or temp < self._min_temp:
-            self.logger.error(f"Temperature {temp} outside range {self._min_temp}-{self._max_temp}")
+            error_msg = f"🌡️ 温度 {temp}°C 超出范围 ({self._min_temp}°C - {self._max_temp}°C) ⚠️"
-            self.data["status"] = f"温度 {temp} 超出范围"
+            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 温度超出范围 ⚠️",
                "operation_mode": "Error"
            })
            return False
-        self.data["status"] = f"开始加热/冷却: {vessel} 至 {temp}°C"
+        self.data.update({
            "status": f"🔄 启动: {status_action} {vessel} 至 {temp}°C {temp_emoji} | ♾️ 持续运行",
            "operation_mode": operation_mode,
            "is_stirring": False,
            "stir_speed": 0.0,
            "remaining_time": -1.0,  # -1 表示持续运行
        })
        self.logger.info(f"✅ 持续温控已启动! {temp_emoji} {status_action}模式 🚀")
        return True
    async def heat_chill_stop(self, vessel: str) -> bool:
-        """Stop heat chill - matches HeatChillStop action exactly"""
+        """Stop heat chill 🛑"""
        self.logger.info(f"HeatChillStop: vessel={vessel}")
-        self.data["status"] = f"停止加热/冷却: {vessel}"
+        # 🔧 添加类型转换
        try:
            vessel = str(vessel)
        except (ValueError, TypeError) as e:
            error_msg = f"参数类型转换错误: {str(e)}"
            self.logger.error(f"❌ {error_msg}")
            return False
        self.logger.info(f"🛑 停止温控: {vessel}")
        self.data.update({
            "status": f"🛑 已停止: {vessel} 温控停止",
            "operation_mode": "Stopped",
            "is_stirring": False,
            "stir_speed": 0.0,
            "remaining_time": 0.0,
        })
        self.logger.info(f"✅ 温控设备已停止 {vessel} 的温度控制 🏁")
        return True
-    # 状态属性 - 只保留 action 中定义的 feedback
+    # 状态属性
    @property
    def status(self) -> str:
-        return self.data.get("status", "Idle")
+        return self.data.get("status", "🏠 待机中")
    @property
    def operation_mode(self) -> str:
        return self.data.get("operation_mode", "Idle")
    @property
    def is_stirring(self) -> bool:
        return self.data.get("is_stirring", False)
    @property
    def stir_speed(self) -> float:
        return self.data.get("stir_speed", 0.0)
    @property
    def remaining_time(self) -> float:
        return self.data.get("remaining_time", 0.0)
    @property
    def progress(self) -> float:
        return self.data.get("progress", 0.0)
    @property
    def max_temp(self) -> float:
        return self._max_temp
    @property
    def min_temp(self) -> float:
        return self._min_temp
    @property
    def max_stir_speed(self) -> float:
        return self._max_stir_speed
--- a/unilabos/devices/virtual/virtual_multiway_valve.py
+++ b/unilabos/devices/virtual/virtual_multiway_valve.py
@@ -0,0 +1,306 @@
 import time
 import logging
 from typing import Union, Dict, Optional
 class VirtualMultiwayValve:
    """
    虚拟九通阀门 - 0号位连接transfer pump，1-8号位连接其他设备 🔄
    """
    def __init__(self, port: str = "VIRTUAL", positions: int = 8):
        self.port = port
        self.max_positions = positions  # 1-8号位
        self.total_positions = positions + 1  # 0-8号位，共9个位置
        # 添加日志记录器
        self.logger = logging.getLogger(f"VirtualMultiwayValve.{port}")
        # 状态属性
        self._status = "Idle"
        self._valve_state = "Ready"
        self._current_position = 0  # 默认在0号位（transfer pump位置）
        self._target_position = 0
        # 位置映射说明
        self.position_map = {
            0: "transfer_pump",  # 0号位连接转移泵
            1: "port_1",         # 1号位
            2: "port_2",         # 2号位
            3: "port_3",         # 3号位
            4: "port_4",         # 4号位
            5: "port_5",         # 5号位
            6: "port_6",         # 6号位
            7: "port_7",         # 7号位
            8: "port_8"          # 8号位
        }
        print(f"🔄 === 虚拟多通阀门已创建 === ✨")
        print(f"🎯 端口: {port} | 📊 位置范围: 0-{self.max_positions} | 🏠 初始位置: 0 (transfer_pump)")
        self.logger.info(f"🔧 多通阀门初始化: 端口={port}, 最大位置={self.max_positions}")
    @property
    def status(self) -> str:
        return self._status
    @property
    def valve_state(self) -> str:
        return self._valve_state
    @property
    def current_position(self) -> int:
        return self._current_position
    @property
    def target_position(self) -> int:
        return self._target_position
    def get_current_position(self) -> int:
        """获取当前阀门位置 📍"""
        return self._current_position
    def get_current_port(self) -> str:
        """获取当前连接的端口名称 🔌"""
        return self.position_map.get(self._current_position, "unknown")
    def set_position(self, command: Union[int, str]):
        """
        设置阀门位置 - 支持0-8位置 🎯
        Args:
            command: 目标位置 (0-8) 或位置字符串
                    0: transfer pump位置
                    1-8: 其他设备位置
        """
        try:
            # 如果是字符串形式的位置，先转换为数字
            if isinstance(command, str):
                pos = int(command)
            else:
                pos = int(command)
            if pos < 0 or pos > self.max_positions:
                error_msg = f"位置必须在 0-{self.max_positions} 范围内"
                self.logger.error(f"❌ {error_msg}: 请求位置={pos}")
                raise ValueError(error_msg)
            # 获取位置描述emoji
            if pos == 0:
                pos_emoji = "🚰"
                pos_desc = "泵位置"
            else:
                pos_emoji = "🔌"
                pos_desc = f"端口{pos}"
            old_position = self._current_position
            old_port = self.get_current_port()
            self.logger.info(f"🔄 阀门切换: {old_position}({old_port}) → {pos}({self.position_map.get(pos, 'unknown')}) {pos_emoji}")
            self._status = "Busy"
            self._valve_state = "Moving"
            self._target_position = pos
            # 模拟阀门切换时间
            switch_time = abs(self._current_position - pos) * 0.5  # 每个位置0.5秒
            if switch_time > 0:
                self.logger.info(f"⏱️ 阀门移动中... 预计用时: {switch_time:.1f}秒 🔄")
                time.sleep(switch_time)
            self._current_position = pos
            self._status = "Idle"
            self._valve_state = "Ready"
            current_port = self.get_current_port()
            success_msg = f"✅ 阀门已切换到位置 {pos} ({current_port}) {pos_emoji}"
            self.logger.info(success_msg)
            return success_msg
        except ValueError as e:
            error_msg = f"❌ 阀门切换失败: {str(e)}"
            self._status = "Error"
            self._valve_state = "Error"
            self.logger.error(error_msg)
            return error_msg
    def set_to_pump_position(self):
        """切换到transfer pump位置（0号位）🚰"""
        self.logger.info(f"🚰 切换到泵位置...")
        return self.set_position(0)
    def set_to_port(self, port_number: int):
        """
        切换到指定端口位置 🔌
        Args:
            port_number: 端口号 (1-8)
        """
        if port_number < 1 or port_number > self.max_positions:
            error_msg = f"端口号必须在 1-{self.max_positions} 范围内"
            self.logger.error(f"❌ {error_msg}: 请求端口={port_number}")
            raise ValueError(error_msg)
        self.logger.info(f"🔌 切换到端口 {port_number}...")
        return self.set_position(port_number)
    def open(self):
        """打开阀门 - 设置到transfer pump位置（0号位）🔓"""
        self.logger.info(f"🔓 打开阀门，设置到泵位置...")
        return self.set_to_pump_position()
    def close(self):
        """关闭阀门 - 对于多通阀门，设置到一个"关闭"状态 🔒"""
        self.logger.info(f"🔒 关闭阀门...")
        self._status = "Busy"
        self._valve_state = "Closing"
        time.sleep(0.5)
        # 可以选择保持当前位置或设置特殊关闭状态
        self._status = "Idle"
        self._valve_state = "Closed"
        close_msg = f"🔒 阀门已关闭，保持在位置 {self._current_position} ({self.get_current_port()})"
        self.logger.info(close_msg)
        return close_msg
    def get_valve_position(self) -> int:
        """获取阀门位置 - 兼容性方法 📍"""
        return self._current_position
    def is_at_position(self, position: int) -> bool:
        """检查是否在指定位置 🎯"""
        result = self._current_position == position
        # 删除debug日志：self.logger.debug(f"🎯 位置检查: 当前={self._current_position}, 目标={position}, 匹配={result}")
        return result
    def is_at_pump_position(self) -> bool:
        """检查是否在transfer pump位置 🚰"""
        result = self._current_position == 0
        # 删除debug日志：pump_status = "是" if result else "否"
        # 删除debug日志：self.logger.debug(f"🚰 泵位置检查: {pump_status} (当前位置: {self._current_position})")
        return result
    def is_at_port(self, port_number: int) -> bool:
        """检查是否在指定端口位置 🔌"""
        result = self._current_position == port_number
        # 删除debug日志：port_status = "是" if result else "否"
        # 删除debug日志：self.logger.debug(f"🔌 端口{port_number}检查: {port_status} (当前位置: {self._current_position})")
        return result
    def get_available_positions(self) -> list:
        """获取可用位置列表 📋"""
        positions = list(range(0, self.max_positions + 1))
        # 删除debug日志：self.logger.debug(f"📋 可用位置: {positions}")
        return positions
    def get_available_ports(self) -> Dict[int, str]:
        """获取可用端口映射 🗺️"""
        # 删除debug日志：self.logger.debug(f"🗺️ 端口映射: {self.position_map}")
        return self.position_map.copy()
    def reset(self):
        """重置阀门到transfer pump位置（0号位）🔄"""
        self.logger.info(f"🔄 重置阀门到泵位置...")
        return self.set_position(0)
    def switch_between_pump_and_port(self, port_number: int):
        """
        在transfer pump位置和指定端口之间切换 🔄
        Args:
            port_number: 目标端口号 (1-8)
        """
        if self._current_position == 0:
            # 当前在pump位置，切换到指定端口
            self.logger.info(f"🔄 从泵位置切换到端口 {port_number}...")
            return self.set_to_port(port_number)
        else:
            # 当前在某个端口，切换到pump位置
            self.logger.info(f"🔄 从端口 {self._current_position} 切换到泵位置...")
            return self.set_to_pump_position()
    def get_flow_path(self) -> str:
        """获取当前流路路径描述 🌊"""
        current_port = self.get_current_port()
        if self._current_position == 0:
            flow_path = f"🚰 转移泵已连接 (位置 {self._current_position})"
        else:
            flow_path = f"🔌 端口 {self._current_position} 已连接 ({current_port})"
        # 删除debug日志：self.logger.debug(f"🌊 当前流路: {flow_path}")
        return flow_path
    def get_info(self) -> dict:
        """获取阀门详细信息 📊"""
        info = {
            "port": self.port,
            "max_positions": self.max_positions,
            "total_positions": self.total_positions,
            "current_position": self._current_position,
            "current_port": self.get_current_port(),
            "target_position": self._target_position,
            "status": self._status,
            "valve_state": self._valve_state,
            "flow_path": self.get_flow_path(),
            "position_map": self.position_map
        }
        # 删除debug日志：self.logger.debug(f"📊 阀门信息: 位置={self._current_position}, 状态={self._status}, 端口={self.get_current_port()}")
        return info
    def __str__(self):
        current_port = self.get_current_port()
        status_emoji = "✅" if self._status == "Idle" else "🔄" if self._status == "Busy" else "❌"
        return f"🔄 VirtualMultiwayValve({status_emoji} 位置: {self._current_position}/{self.max_positions}, 端口: {current_port}, 状态: {self._status})"
    def set_valve_position(self, command: Union[int, str]):
        """
        设置阀门位置 - 兼容pump_protocol调用 🎯
        这是set_position的别名方法，用于兼容pump_protocol.py
        Args:
            command: 目标位置 (0-8) 或位置字符串
        """
        # 删除debug日志：self.logger.debug(f"🎯 兼容性调用: set_valve_position({command})")
        return self.set_position(command)
 # 使用示例
 if __name__ == "__main__":
    valve = VirtualMultiwayValve()
    print("🔄 === 虚拟九通阀门测试 === ✨")
    print(f"🏠 初始状态: {valve}")
    print(f"🌊 当前流路: {valve.get_flow_path()}")
    # 切换到试剂瓶1（1号位）
    print(f"\n🔌 切换到1号位: {valve.set_position(1)}")
    print(f"📍 当前状态: {valve}")
    # 切换到transfer pump位置（0号位）
    print(f"\n🚰 切换到pump位置: {valve.set_to_pump_position()}")
    print(f"📍 当前状态: {valve}")
    # 切换到试剂瓶2（2号位）
    print(f"\n🔌 切换到2号位: {valve.set_to_port(2)}")
    print(f"📍 当前状态: {valve}")
    # 显示所有可用位置
    print(f"\n📋 可用位置: {valve.get_available_positions()}")
    print(f"🗺️ 端口映射: {valve.get_available_ports()}")
    # 获取详细信息
    print(f"\n📊 详细信息: {valve.get_info()}")
    # 测试切换功能
    print(f"\n🔄 智能切换测试:")
    print(f"当前位置: {valve._current_position}")
    print(f"切换结果: {valve.switch_between_pump_and_port(3)}")
    print(f"新位置: {valve._current_position}")
    # 重置测试
    print(f"\n🔄 重置测试: {valve.reset()}")
    print(f"📍 重置后状态: {valve}")
--- a/unilabos/devices/virtual/virtual_rotavap.py
+++ b/unilabos/devices/virtual/virtual_rotavap.py
@@ -0,0 +1,314 @@
 import asyncio
 import logging
 import time as time_module
 from typing import Dict, Any, Optional
 def debug_print(message):
    """调试输出 🔍"""
    print(f"🌪️ [ROTAVAP] {message}", flush=True)
 class VirtualRotavap:
    """Virtual rotary evaporator device - 简化版，只保留核心功能 🌪️"""
    def __init__(self, device_id: Optional[str] = None, config: Optional[Dict[str, Any]] = None, **kwargs):
        # 处理可能的不同调用方式
        if device_id is None and "id" in kwargs:
            device_id = kwargs.pop("id")
        if config is None and "config" in kwargs:
            config = kwargs.pop("config")
        # 设置默认值
        self.device_id = device_id or "unknown_rotavap"
        self.config = config or {}
        self.logger = logging.getLogger(f"VirtualRotavap.{self.device_id}")
        self.data = {}
        # 从config或kwargs中获取配置参数
        self.port = self.config.get("port") or kwargs.get("port", "VIRTUAL")
        self._max_temp = self.config.get("max_temp") or kwargs.get("max_temp", 180.0)
        self._max_rotation_speed = self.config.get("max_rotation_speed") or kwargs.get("max_rotation_speed", 280.0)
        # 处理其他kwargs参数
        skip_keys = {"port", "max_temp", "max_rotation_speed"}
        for key, value in kwargs.items():
            if key not in skip_keys and not hasattr(self, key):
                setattr(self, key, value)
        print(f"🌪️ === 虚拟旋转蒸发仪 {self.device_id} 已创建 === ✨")
        print(f"🔥 温度范围: 10°C ~ {self._max_temp}°C | 🌀 转速范围: 10 ~ {self._max_rotation_speed} RPM")
    async def initialize(self) -> bool:
        """Initialize virtual rotary evaporator 🚀"""
        self.logger.info(f"🔧 初始化虚拟旋转蒸发仪 {self.device_id} ✨")
        # 只保留核心状态
        self.data.update({
            "status": "🏠 待机中",
            "rotavap_state": "Ready",  # Ready, Evaporating, Completed, Error
            "current_temp": 25.0,
            "target_temp": 25.0,
            "rotation_speed": 0.0,
            "vacuum_pressure": 1.0,  # 大气压
            "evaporated_volume": 0.0,
            "progress": 0.0,
            "remaining_time": 0.0,
            "message": "🌪️ Ready for evaporation"
        })
        self.logger.info(f"✅ 旋转蒸发仪 {self.device_id} 初始化完成 🌪️")
        self.logger.info(f"📊 设备规格: 温度范围 10°C ~ {self._max_temp}°C | 转速范围 10 ~ {self._max_rotation_speed} RPM")
        return True
    async def cleanup(self) -> bool:
        """Cleanup virtual rotary evaporator 🧹"""
        self.logger.info(f"🧹 清理虚拟旋转蒸发仪 {self.device_id} 🔚")
        self.data.update({
            "status": "💤 离线",
            "rotavap_state": "Offline",
            "current_temp": 25.0,
            "rotation_speed": 0.0,
            "vacuum_pressure": 1.0,
            "message": "💤 System offline"
        })
        self.logger.info(f"✅ 旋转蒸发仪 {self.device_id} 清理完成 💤")
        return True
    async def evaporate(
        self, 
        vessel: str, 
        pressure: float = 0.1, 
        temp: float = 60.0, 
        time: float = 180.0,
        stir_speed: float = 100.0,
        solvent: str = "",
        **kwargs
    ) -> bool:
        """Execute evaporate action - 简化版 🌪️"""
        # 🔧 简化处理：如果vessel就是设备自己，直接操作
        if vessel == self.device_id:
            debug_print(f"🎯 在设备 {self.device_id} 上直接执行蒸发操作")
            actual_vessel = self.device_id
        else:
            actual_vessel = vessel
        # 参数预处理
        if solvent:
            self.logger.info(f"🧪 识别到溶剂: {solvent}")
            # 根据溶剂调整参数
            solvent_lower = solvent.lower()
            if any(s in solvent_lower for s in ['water', 'aqueous']):
                temp = max(temp, 80.0)
                pressure = max(pressure, 0.2)
                self.logger.info(f"💧 水系溶剂：调整参数 → 温度 {temp}°C, 压力 {pressure} bar")
            elif any(s in solvent_lower for s in ['ethanol', 'methanol', 'acetone']):
                temp = min(temp, 50.0)
                pressure = min(pressure, 0.05)
                self.logger.info(f"⚡ 易挥发溶剂：调整参数 → 温度 {temp}°C, 压力 {pressure} bar")
        self.logger.info(f"🌪️ 开始蒸发操作: {actual_vessel}")
        self.logger.info(f"  🥽 容器: {actual_vessel}")
        self.logger.info(f"  🌡️ 温度: {temp}°C")
        self.logger.info(f"  💨 真空度: {pressure} bar")
        self.logger.info(f"  ⏰ 时间: {time}s")
        self.logger.info(f"  🌀 转速: {stir_speed} RPM")
        if solvent:
            self.logger.info(f"  🧪 溶剂: {solvent}")
        # 验证参数
        if temp > self._max_temp or temp < 10.0:
            error_msg = f"🌡️ 温度 {temp}°C 超出范围 (10-{self._max_temp}°C) ⚠️"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 温度超出范围",
                "rotavap_state": "Error",
                "current_temp": 25.0,
                "progress": 0.0,
                "evaporated_volume": 0.0,
                "message": error_msg
            })
            return False
        if stir_speed > self._max_rotation_speed or stir_speed < 10.0:
            error_msg = f"🌀 旋转速度 {stir_speed} RPM 超出范围 (10-{self._max_rotation_speed} RPM) ⚠️"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 转速超出范围",
                "rotavap_state": "Error",
                "current_temp": 25.0,
                "progress": 0.0,
                "evaporated_volume": 0.0,
                "message": error_msg
            })
            return False
        if pressure < 0.01 or pressure > 1.0:
            error_msg = f"💨 真空度 {pressure} bar 超出范围 (0.01-1.0 bar) ⚠️"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 压力超出范围",
                "rotavap_state": "Error",
                "current_temp": 25.0,
                "progress": 0.0,
                "evaporated_volume": 0.0,
                "message": error_msg
            })
            return False
        # 开始蒸发
        self.logger.info(f"🚀 启动蒸发程序! 预计用时 {time/60:.1f}分钟 ⏱️")
        self.data.update({
            "status": f"🌪️ 蒸发中: {actual_vessel}",
            "rotavap_state": "Evaporating",
            "current_temp": temp,
            "target_temp": temp,
            "rotation_speed": stir_speed,
            "vacuum_pressure": pressure,
            "remaining_time": time,
            "progress": 0.0,
            "evaporated_volume": 0.0,
            "message": f"🌪️ Evaporating {actual_vessel} at {temp}°C, {pressure} bar, {stir_speed} RPM"
        })
        try:
            # 蒸发过程 - 实时更新进度
            start_time = time_module.time()
            total_time = time
            last_logged_progress = 0
            while True:
                current_time = time_module.time()
                elapsed = current_time - start_time
                remaining = max(0, total_time - elapsed)
                progress = min(100.0, (elapsed / total_time) * 100)
                # 模拟蒸发体积 - 根据溶剂类型调整
                if solvent and any(s in solvent.lower() for s in ['water', 'aqueous']):
                    evaporated_vol = progress * 0.6  # 水系溶剂蒸发慢
                elif solvent and any(s in solvent.lower() for s in ['ethanol', 'methanol', 'acetone']):
                    evaporated_vol = progress * 1.0  # 易挥发溶剂蒸发快
                else:
                    evaporated_vol = progress * 0.8  # 默认蒸发量
                # 🔧 更新状态 - 确保包含所有必需字段
                status_msg = f"🌪️ 蒸发中: {actual_vessel} | 🌡️ {temp}°C | 💨 {pressure} bar | 🌀 {stir_speed} RPM | 📊 {progress:.1f}% | ⏰ 剩余: {remaining:.0f}s"
                self.data.update({
                    "remaining_time": remaining,
                    "progress": progress,
                    "evaporated_volume": evaporated_vol,
                    "current_temp": temp,
                    "status": status_msg,
                    "message": f"🌪️ Evaporating: {progress:.1f}% complete, 💧 {evaporated_vol:.1f}mL evaporated, ⏰ {remaining:.0f}s remaining"
                })
                # 进度日志（每25%打印一次）
                if progress >= 25 and int(progress) % 25 == 0 and int(progress) != last_logged_progress:
                    self.logger.info(f"📊 蒸发进度: {progress:.0f}% | 💧 已蒸发: {evaporated_vol:.1f}mL | ⏰ 剩余: {remaining:.0f}s ✨")
                    last_logged_progress = int(progress)
                # 时间到了，退出循环
                if remaining <= 0:
                    break
                # 每秒更新一次
                await asyncio.sleep(1.0)
            # 蒸发完成
            if solvent and any(s in solvent.lower() for s in ['water', 'aqueous']):
                final_evaporated = 60.0  # 水系溶剂
            elif solvent and any(s in solvent.lower() for s in ['ethanol', 'methanol', 'acetone']):
                final_evaporated = 100.0  # 易挥发溶剂
            else:
                final_evaporated = 80.0  # 默认
            self.data.update({
                "status": f"✅ 蒸发完成: {actual_vessel} | 💧 蒸发量: {final_evaporated:.1f}mL",
                "rotavap_state": "Completed",
                "evaporated_volume": final_evaporated,
                "progress": 100.0,
                "current_temp": temp,
                "remaining_time": 0.0,
                "rotation_speed": 0.0,
                "vacuum_pressure": 1.0,
                "message": f"✅ Evaporation completed: {final_evaporated}mL evaporated from {actual_vessel}"
            })
            self.logger.info(f"🎉 蒸发操作完成! ✨")
            self.logger.info(f"📊 蒸发结果:")
            self.logger.info(f"  🥽 容器: {actual_vessel}")
            self.logger.info(f"  💧 蒸发量: {final_evaporated:.1f}mL")
            self.logger.info(f"  🌡️ 蒸发温度: {temp}°C")
            self.logger.info(f"  💨 真空度: {pressure} bar")
            self.logger.info(f"  🌀 旋转速度: {stir_speed} RPM")
            self.logger.info(f"  ⏱️ 总用时: {total_time:.0f}s")
            if solvent:
                self.logger.info(f"  🧪 处理溶剂: {solvent} 🏁")
            return True
        except Exception as e:
            # 出错处理
            error_msg = f"蒸发过程中发生错误: {str(e)} 💥"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 蒸发错误: {str(e)}",
                "rotavap_state": "Error",
                "current_temp": 25.0,
                "progress": 0.0,
                "evaporated_volume": 0.0,
                "rotation_speed": 0.0,
                "vacuum_pressure": 1.0,
                "message": f"❌ Evaporation failed: {str(e)}"
            })
            return False
    # === 核心状态属性 ===
    @property
    def status(self) -> str:
        return self.data.get("status", "❓ Unknown")
    @property
    def rotavap_state(self) -> str:
        return self.data.get("rotavap_state", "Unknown")
    @property
    def current_temp(self) -> float:
        return self.data.get("current_temp", 25.0)
    @property
    def rotation_speed(self) -> float:
        return self.data.get("rotation_speed", 0.0)
    @property
    def vacuum_pressure(self) -> float:
        return self.data.get("vacuum_pressure", 1.0)
    @property
    def evaporated_volume(self) -> float:
        return self.data.get("evaporated_volume", 0.0)
    @property
    def progress(self) -> float:
        return self.data.get("progress", 0.0)
    @property
    def message(self) -> str:
        return self.data.get("message", "")
    @property
    def max_temp(self) -> float:
        return self._max_temp
    @property
    def max_rotation_speed(self) -> float:
        return self._max_rotation_speed
    @property
    def remaining_time(self) -> float:
        return self.data.get("remaining_time", 0.0)
--- a/unilabos/devices/virtual/virtual_separator.py
+++ b/unilabos/devices/virtual/virtual_separator.py
@@ -0,0 +1,184 @@
 import asyncio
 import logging
 from typing import Dict, Any, Optional
 class VirtualSeparator:
    """Virtual separator device for SeparateProtocol testing"""
    def __init__(self, device_id: Optional[str] = None, config: Optional[Dict[str, Any]] = None, **kwargs):
        # 处理可能的不同调用方式
        if device_id is None and "id" in kwargs:
            device_id = kwargs.pop("id")
        if config is None and "config" in kwargs:
            config = kwargs.pop("config")
        # 设置默认值
        self.device_id = device_id or "unknown_separator"
        self.config = config or {}
        self.logger = logging.getLogger(f"VirtualSeparator.{self.device_id}")
        self.data = {}
        # 添加调试信息
        print(f"=== VirtualSeparator {self.device_id} is being created! ===")
        print(f"=== Config: {self.config} ===")
        print(f"=== Kwargs: {kwargs} ===")
        # 从config或kwargs中获取配置参数
        self.port = self.config.get("port") or kwargs.get("port", "VIRTUAL")
        self._volume = self.config.get("volume") or kwargs.get("volume", 250.0)
        self._has_phases = self.config.get("has_phases") or kwargs.get("has_phases", True)
        # 处理其他kwargs参数，但跳过已知的配置参数
        skip_keys = {"port", "volume", "has_phases"}
        for key, value in kwargs.items():
            if key not in skip_keys and not hasattr(self, key):
                setattr(self, key, value)
    async def initialize(self) -> bool:
        """Initialize virtual separator"""
        print(f"=== VirtualSeparator {self.device_id} initialize() called! ===")
        self.logger.info(f"Initializing virtual separator {self.device_id}")
        self.data.update(
            {
                "status": "Ready",
                "separator_state": "Ready",
                "volume": self._volume,
                "has_phases": self._has_phases,
                "phase_separation": False,
                "stir_speed": 0.0,
                "settling_time": 0.0,
                "progress": 0.0,
                "message": "",
            }
        )
        return True
    async def cleanup(self) -> bool:
        """Cleanup virtual separator"""
        self.logger.info(f"Cleaning up virtual separator {self.device_id}")
        return True
    async def separate(
        self,
        purpose: str,
        product_phase: str,
        from_vessel: str,
        separation_vessel: str,
        to_vessel: str,
        waste_phase_to_vessel: str = "",
        solvent: str = "",
        solvent_volume: float = 50.0,
        through: str = "",
        repeats: int = 1,
        stir_time: float = 30.0,
        stir_speed: float = 300.0,
        settling_time: float = 300.0,
    ) -> bool:
        """Execute separate action - matches Separate action"""
        self.logger.info(f"Separate: purpose={purpose}, product_phase={product_phase}, from_vessel={from_vessel}")
        # 验证参数
        if product_phase not in ["top", "bottom"]:
            self.logger.error(f"Invalid product_phase {product_phase}, must be 'top' or 'bottom'")
            self.data["message"] = f"产物相位 {product_phase} 无效，必须是 'top' 或 'bottom'"
            return False
        if purpose not in ["wash", "extract"]:
            self.logger.error(f"Invalid purpose {purpose}, must be 'wash' or 'extract'")
            self.data["message"] = f"分离目的 {purpose} 无效，必须是 'wash' 或 'extract'"
            return False
        # 开始分离
        self.data.update(
            {
                "status": "Running",
                "separator_state": "Separating",
                "purpose": purpose,
                "product_phase": product_phase,
                "from_vessel": from_vessel,
                "separation_vessel": separation_vessel,
                "to_vessel": to_vessel,
                "waste_phase_to_vessel": waste_phase_to_vessel,
                "solvent": solvent,
                "solvent_volume": solvent_volume,
                "repeats": repeats,
                "stir_speed": stir_speed,
                "settling_time": settling_time,
                "phase_separation": True,
                "progress": 0.0,
                "message": f"正在分离: {from_vessel} -> {to_vessel}",
            }
        )
        # 模拟分离过程
        total_time = (stir_time + settling_time) * repeats
        simulation_time = min(total_time / 60.0, 15.0)  # 最多模拟15秒
        for repeat in range(repeats):
            # 搅拌阶段
            for progress in range(0, 51, 10):
                await asyncio.sleep(simulation_time / (repeats * 10))
                overall_progress = ((repeat * 100) + (progress * 0.5)) / repeats
                self.data["progress"] = overall_progress
                self.data["message"] = f"第{repeat+1}次分离 - 搅拌中 ({progress}%)"
            # 静置分相阶段
            for progress in range(50, 101, 10):
                await asyncio.sleep(simulation_time / (repeats * 10))
                overall_progress = ((repeat * 100) + (progress * 0.5)) / repeats
                self.data["progress"] = overall_progress
                self.data["message"] = f"第{repeat+1}次分离 - 静置分相中 ({progress}%)"
        # 分离完成
        self.data.update(
            {
                "status": "Ready",
                "separator_state": "Ready",
                "phase_separation": False,
                "stir_speed": 0.0,
                "progress": 100.0,
                "message": f"分离完成: {repeats}次分离操作",
            }
        )
        self.logger.info(f"Separation completed: {repeats} cycles from {from_vessel} to {to_vessel}")
        return True
    # 状态属性
    @property
    def status(self) -> str:
        return self.data.get("status", "Unknown")
    @property
    def separator_state(self) -> str:
        return self.data.get("separator_state", "Unknown")
    @property
    def volume(self) -> float:
        return self.data.get("volume", self._volume)
    @property
    def has_phases(self) -> bool:
        return self.data.get("has_phases", self._has_phases)
    @property
    def phase_separation(self) -> bool:
        return self.data.get("phase_separation", False)
    @property
    def stir_speed(self) -> float:
        return self.data.get("stir_speed", 0.0)
    @property
    def settling_time(self) -> float:
        return self.data.get("settling_time", 0.0)
    @property
    def progress(self) -> float:
        return self.data.get("progress", 0.0)
    @property
    def message(self) -> str:
        return self.data.get("message", "")
--- a/unilabos/devices/virtual/virtual_solenoid_valve.py
+++ b/unilabos/devices/virtual/virtual_solenoid_valve.py
@@ -0,0 +1,153 @@
 import time
 import asyncio
 from typing import Union
 class VirtualSolenoidValve:
    """
    虚拟电磁阀门 - 简单的开关型阀门，只有开启和关闭两个状态
    """
    def __init__(self, device_id: str = None, config: dict = None, **kwargs):
        # 从配置中获取参数，提供默认值
        if config is None:
            config = {}
        self.device_id = device_id
        self.port = config.get("port", "VIRTUAL")
        self.voltage = config.get("voltage", 12.0)
        self.response_time = config.get("response_time", 0.1)
        # 状态属性
        self._status = "Idle"
        self._valve_state = "Closed"  # "Open" or "Closed"
        self._is_open = False
    async def initialize(self) -> bool:
        """初始化设备"""
        self._status = "Idle"
        return True
    async def cleanup(self) -> bool:
        """清理资源"""
        return True
    @property
    def status(self) -> str:
        return self._status
    @property
    def valve_state(self) -> str:
        return self._valve_state
    @property
    def is_open(self) -> bool:
        return self._is_open
    @property
    def valve_position(self) -> str:
        """获取阀门位置状态"""
        return "OPEN" if self._is_open else "CLOSED"
    @property
    def state(self) -> dict:
        """获取阀门完整状态"""
        return {
            "device_id": self.device_id,
            "port": self.port,
            "voltage": self.voltage,
            "response_time": self.response_time,
            "is_open": self._is_open,
            "valve_state": self._valve_state,
            "status": self._status,
            "position": self.valve_position
        }
    async def set_valve_position(self, command: str = None, **kwargs):
        """
        设置阀门位置 - ROS动作接口
        Args:
            command: "OPEN"/"CLOSED" 或其他控制命令
        """
        if command is None:
            return {"success": False, "message": "Missing command parameter"}
        print(f"SOLENOID_VALVE: {self.device_id} 接收到命令: {command}")
        self._status = "Busy"
        # 模拟阀门响应时间
        await asyncio.sleep(self.response_time)
        # 处理不同的命令格式
        if isinstance(command, str):
            cmd_upper = command.upper()
            if cmd_upper in ["OPEN", "ON", "TRUE", "1"]:
                self._is_open = True
                self._valve_state = "Open"
                result_msg = f"Valve {self.device_id} opened"
            elif cmd_upper in ["CLOSED", "CLOSE", "OFF", "FALSE", "0"]:
                self._is_open = False
                self._valve_state = "Closed"
                result_msg = f"Valve {self.device_id} closed"
            else:
                # 可能是端口名称，处理路径设置
                # 对于简单电磁阀，任何非关闭命令都视为开启
                self._is_open = True
                self._valve_state = "Open"
                result_msg = f"Valve {self.device_id} set to position: {command}"
        else:
            self._status = "Error"
            return {"success": False, "message": "Invalid command type"}
        self._status = "Idle"
        print(f"SOLENOID_VALVE: {result_msg}")
        return {
            "success": True, 
            "message": result_msg,
            "valve_position": self.valve_position
        }
    async def open(self, **kwargs):
        """打开电磁阀 - ROS动作接口"""
        return await self.set_valve_position(command="OPEN")
    async def close(self, **kwargs):
        """关闭电磁阀 - ROS动作接口"""
        return await self.set_valve_position(command="CLOSED")
    async def set_status(self, string: str = None, **kwargs):
        """
        设置阀门状态 - 兼容 StrSingleInput 类型
        Args:
            string: "ON"/"OFF" 或 "OPEN"/"CLOSED"
        """
        if string is None:
            return {"success": False, "message": "Missing string parameter"}
        # 将 string 参数转换为 command 参数
        if string.upper() in ["ON", "OPEN"]:
            command = "OPEN"
        elif string.upper() in ["OFF", "CLOSED"]:
            command = "CLOSED"
        else:
            command = string
        return await self.set_valve_position(command=command)
    def toggle(self):
        """切换阀门状态"""
        if self._is_open:
            return self.close()
        else:
            return self.open()
    def is_closed(self) -> bool:
        """检查阀门是否关闭"""
        return not self._is_open
    async def reset(self):
        """重置阀门到关闭状态"""
        return await self.close()
--- a/unilabos/devices/virtual/virtual_solid_dispenser.py
+++ b/unilabos/devices/virtual/virtual_solid_dispenser.py
@@ -0,0 +1,389 @@
 import asyncio
 import logging
 import re
 from typing import Dict, Any, Optional
 class VirtualSolidDispenser:
    """
    虚拟固体粉末加样器 - 用于处理 Add Protocol 中的固体试剂添加 ⚗️
    特点：
    - 高兼容性：缺少参数不报错 ✅
    - 智能识别：自动查找固体试剂瓶 🔍
    - 简单反馈：成功/失败 + 消息 📊
    """
    def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
        self.device_id = device_id or "virtual_solid_dispenser"
        self.config = config or {}
        # 设备参数
        self.max_capacity = float(self.config.get('max_capacity', 100.0))  # 最大加样量 (g)
        self.precision = float(self.config.get('precision', 0.001))  # 精度 (g)
        # 状态变量
        self._status = "Idle"
        self._current_reagent = ""
        self._dispensed_amount = 0.0
        self._total_operations = 0
        self.logger = logging.getLogger(f"VirtualSolidDispenser.{self.device_id}")
        print(f"⚗️ === 虚拟固体分配器 {self.device_id} 创建成功! === ✨")
        print(f"📊 设备规格: 最大容量 {self.max_capacity}g | 精度 {self.precision}g 🎯")
    async def initialize(self) -> bool:
        """初始化固体加样器 🚀"""
        self.logger.info(f"🔧 初始化固体分配器 {self.device_id} ✨")
        self._status = "Ready"
        self._current_reagent = ""
        self._dispensed_amount = 0.0
        self.logger.info(f"✅ 固体分配器 {self.device_id} 初始化完成 ⚗️")
        return True
    async def cleanup(self) -> bool:
        """清理固体加样器 🧹"""
        self.logger.info(f"🧹 清理固体分配器 {self.device_id} 🔚")
        self._status = "Idle"
        self.logger.info(f"✅ 固体分配器 {self.device_id} 清理完成 💤")
        return True
    def parse_mass_string(self, mass_str: str) -> float:
        """
        解析质量字符串为数值 (g) ⚖️
        支持格式: "2.9 g", "19.3g", "4.5 mg", "1.2 kg" 等
        """
        if not mass_str or not isinstance(mass_str, str):
            return 0.0
        # 移除空格并转小写
        mass_clean = mass_str.strip().lower()
        # 正则匹配数字和单位
        pattern = r'(\d+(?:\.\d+)?)\s*([a-z]*)'
        match = re.search(pattern, mass_clean)
        if not match:
            self.logger.debug(f"🔍 无法解析质量字符串: {mass_str}")
            return 0.0
        try:
            value = float(match.group(1))
            unit = match.group(2) or 'g'  # 默认单位 g
            # 单位转换为 g
            unit_multipliers = {
                'g': 1.0,
                'gram': 1.0,
                'grams': 1.0,
                'mg': 0.001,
                'milligram': 0.001,
                'milligrams': 0.001,
                'kg': 1000.0,
                'kilogram': 1000.0,
                'kilograms': 1000.0,
                'μg': 0.000001,
                'ug': 0.000001,
                'microgram': 0.000001,
                'micrograms': 0.000001,
            }
            multiplier = unit_multipliers.get(unit, 1.0)
            result = value * multiplier
            self.logger.debug(f"⚖️ 质量解析: {mass_str} → {result:.6f}g (原值: {value} {unit})")
            return result
        except (ValueError, TypeError):
            self.logger.warning(f"⚠️ 无法解析质量字符串: {mass_str}")
            return 0.0
    def parse_mol_string(self, mol_str: str) -> float:
        """
        解析摩尔数字符串为数值 (mol) 🧮
        支持格式: "0.12 mol", "16.2 mmol", "25.2mmol" 等
        """
        if not mol_str or not isinstance(mol_str, str):
            return 0.0
        # 移除空格并转小写
        mol_clean = mol_str.strip().lower()
        # 正则匹配数字和单位
        pattern = r'(\d+(?:\.\d+)?)\s*(m?mol)'
        match = re.search(pattern, mol_clean)
        if not match:
            self.logger.debug(f"🔍 无法解析摩尔数字符串: {mol_str}")
            return 0.0
        try:
            value = float(match.group(1))
            unit = match.group(2)
            # 单位转换为 mol
            if unit == 'mmol':
                result = value * 0.001
            else:  # mol
                result = value
            self.logger.debug(f"🧮 摩尔数解析: {mol_str} → {result:.6f}mol (原值: {value} {unit})")
            return result
        except (ValueError, TypeError):
            self.logger.warning(f"⚠️ 无法解析摩尔数字符串: {mol_str}")
            return 0.0
    def find_solid_reagent_bottle(self, reagent_name: str) -> str:
        """
        查找固体试剂瓶 🔍
        这是一个简化版本，实际使用时应该连接到系统的设备图
        """
        if not reagent_name:
            self.logger.debug(f"🔍 未指定试剂名称，使用默认瓶")
            return "unknown_solid_bottle"
        # 可能的固体试剂瓶命名模式
        possible_names = [
            f"solid_bottle_{reagent_name}",
            f"reagent_solid_{reagent_name}",
            f"powder_{reagent_name}",
            f"{reagent_name}_solid",
            f"{reagent_name}_powder",
            f"solid_{reagent_name}",
        ]
        # 这里简化处理，实际应该查询设备图
        selected_bottle = possible_names[0]
        self.logger.debug(f"🔍 为试剂 {reagent_name} 选择试剂瓶: {selected_bottle}")
        return selected_bottle
    async def add_solid(
        self,
        vessel: str,
        reagent: str,
        mass: str = "",
        mol: str = "",
        purpose: str = "",
        **kwargs  # 兼容额外参数
    ) -> Dict[str, Any]:
        """
        添加固体试剂的主要方法 ⚗️
        Args:
            vessel: 目标容器
            reagent: 试剂名称
            mass: 质量字符串 (如 "2.9 g")
            mol: 摩尔数字符串 (如 "0.12 mol")
            purpose: 添加目的
            **kwargs: 其他兼容参数
        Returns:
            Dict: 操作结果
        """
        try:
            self.logger.info(f"⚗️ === 开始固体加样操作 === ✨")
            self.logger.info(f"  🥽 目标容器: {vessel}")
            self.logger.info(f"  🧪 试剂: {reagent}")
            self.logger.info(f"  ⚖️ 质量: {mass}")
            self.logger.info(f"  🧮 摩尔数: {mol}")
            self.logger.info(f"  📝 目的: {purpose}")
            # 参数验证 - 宽松处理
            if not vessel:
                vessel = "main_reactor"  # 默认容器
                self.logger.warning(f"⚠️ 未指定容器，使用默认容器: {vessel} 🏠")
            if not reagent:
                error_msg = "❌ 错误: 必须指定试剂名称"
                self.logger.error(error_msg)
                return {
                    "success": False,
                    "message": error_msg,
                    "return_info": "missing_reagent"
                }
            # 解析质量和摩尔数
            mass_value = self.parse_mass_string(mass)
            mol_value = self.parse_mol_string(mol)
            self.logger.info(f"📊 解析结果 - 质量: {mass_value:.6f}g | 摩尔数: {mol_value:.6f}mol")
            # 确定实际加样量
            if mass_value > 0:
                actual_amount = mass_value
                amount_unit = "g"
                amount_emoji = "⚖️"
                self.logger.info(f"⚖️ 按质量加样: {actual_amount:.6f} {amount_unit}")
            elif mol_value > 0:
                # 简化处理：假设分子量为100 g/mol
                assumed_mw = 100.0
                actual_amount = mol_value * assumed_mw
                amount_unit = "g (from mol)"
                amount_emoji = "🧮"
                self.logger.info(f"🧮 按摩尔数加样: {mol_value:.6f} mol → {actual_amount:.6f} g (假设分子量 {assumed_mw})")
            else:
                # 没有指定量，使用默认值
                actual_amount = 1.0
                amount_unit = "g (default)"
                amount_emoji = "🎯"
                self.logger.warning(f"⚠️ 未指定质量或摩尔数，使用默认值: {actual_amount} {amount_unit} 🎯")
            # 检查容量限制
            if actual_amount > self.max_capacity:
                error_msg = f"❌ 错误: 请求量 {actual_amount:.3f}g 超过最大容量 {self.max_capacity}g"
                self.logger.error(error_msg)
                return {
                    "success": False,
                    "message": error_msg,
                    "return_info": "exceeds_capacity"
                }
            # 查找试剂瓶
            reagent_bottle = self.find_solid_reagent_bottle(reagent)
            self.logger.info(f"🔍 使用试剂瓶: {reagent_bottle}")
            # 模拟加样过程
            self._status = "Dispensing"
            self._current_reagent = reagent
            # 计算操作时间 (基于质量)
            operation_time = max(0.5, actual_amount * 0.1)  # 每克0.1秒，最少0.5秒
            self.logger.info(f"🚀 开始加样，预计时间: {operation_time:.1f}秒 ⏱️")
            # 显示进度的模拟
            steps = max(3, int(operation_time))
            step_time = operation_time / steps
            for i in range(steps):
                progress = (i + 1) / steps * 100
                await asyncio.sleep(step_time)
                if i % 2 == 0:  # 每隔一步显示进度
                    self.logger.debug(f"📊 加样进度: {progress:.0f}% | {amount_emoji} 正在分配 {reagent}...")
            # 更新状态
            self._dispensed_amount = actual_amount
            self._total_operations += 1
            self._status = "Ready"
            # 成功结果
            success_message = f"✅ 成功添加 {reagent} {actual_amount:.6f} {amount_unit} 到 {vessel}"
            self.logger.info(f"🎉 === 固体加样完成 === ✨")
            self.logger.info(f"📊 操作结果:")
            self.logger.info(f"  ✅ {success_message}")
            self.logger.info(f"  🧪 试剂瓶: {reagent_bottle}")
            self.logger.info(f"  ⏱️ 用时: {operation_time:.1f}秒")
            self.logger.info(f"  🎯 总操作次数: {self._total_operations} 🏁")
            return {
                "success": True,
                "message": success_message,
                "return_info": f"dispensed_{actual_amount:.6f}g",
                "dispensed_amount": actual_amount,
                "reagent": reagent,
                "vessel": vessel
            }
        except Exception as e:
            error_message = f"❌ 固体加样失败: {str(e)} 💥"
            self.logger.error(error_message)
            self._status = "Error"
            return {
                "success": False,
                "message": error_message,
                "return_info": "operation_failed"
            }
    # 状态属性
    @property
    def status(self) -> str:
        return self._status
    @property
    def current_reagent(self) -> str:
        return self._current_reagent
    @property
    def dispensed_amount(self) -> float:
        return self._dispensed_amount
    @property
    def total_operations(self) -> int:
        return self._total_operations
    def get_device_info(self) -> Dict[str, Any]:
        """获取设备状态信息 📊"""
        info = {
            "device_id": self.device_id,
            "status": self._status,
            "current_reagent": self._current_reagent,
            "last_dispensed_amount": self._dispensed_amount,
            "total_operations": self._total_operations,
            "max_capacity": self.max_capacity,
            "precision": self.precision
        }
        self.logger.debug(f"📊 设备信息: 状态={self._status}, 试剂={self._current_reagent}, 加样量={self._dispensed_amount:.6f}g")
        return info
    def __str__(self):
        status_emoji = "✅" if self._status == "Ready" else "🔄" if self._status == "Dispensing" else "❌" if self._status == "Error" else "🏠"
        return f"⚗️ VirtualSolidDispenser({status_emoji} {self.device_id}: {self._status}, 最后加样 {self._dispensed_amount:.3f}g)"
 # 测试函数
 async def test_solid_dispenser():
    """测试固体加样器 🧪"""
    print("⚗️ === 固体加样器测试开始 === 🧪")
    dispenser = VirtualSolidDispenser("test_dispenser")
    await dispenser.initialize()
    # 测试1: 按质量加样
    print(f"\n🧪 测试1: 按质量加样...")
    result1 = await dispenser.add_solid(
        vessel="main_reactor",
        reagent="magnesium",
        mass="2.9 g"
    )
    print(f"📊 测试1结果: {result1}")
    # 测试2: 按摩尔数加样
    print(f"\n🧮 测试2: 按摩尔数加样...")
    result2 = await dispenser.add_solid(
        vessel="main_reactor",
        reagent="sodium_nitrite",
        mol="0.28 mol"
    )
    print(f"📊 测试2结果: {result2}")
    # 测试3: 缺少参数
    print(f"\n⚠️ 测试3: 缺少参数测试...")
    result3 = await dispenser.add_solid(
        reagent="test_compound"
    )
    print(f"📊 测试3结果: {result3}")
    # 测试4: 超容量测试
    print(f"\n❌ 测试4: 超容量测试...")
    result4 = await dispenser.add_solid(
        vessel="main_reactor",
        reagent="heavy_compound",
        mass="150 g"  # 超过100g限制
    )
    print(f"📊 测试4结果: {result4}")
    print(f"\n📊 最终设备信息: {dispenser.get_device_info()}")
    print(f"✅ === 测试完成 === 🎉")
 if __name__ == "__main__":
    asyncio.run(test_solid_dispenser())
--- a/unilabos/devices/virtual/virtual_stirrer.py
+++ b/unilabos/devices/virtual/virtual_stirrer.py
@@ -1,9 +1,10 @@
 import asyncio
 import logging
 import time as time_module
 from typing import Dict, Any
 class VirtualStirrer:
-    """Virtual stirrer device for StirProtocol testing"""
+    """Virtual stirrer device for StirProtocol testing - 功能完整版 🌪️"""
    def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
        # 处理可能的不同调用方式
@@ -19,86 +20,310 @@ class VirtualStirrer:
        self.logger = logging.getLogger(f"VirtualStirrer.{self.device_id}")
        self.data = {}
        # 添加调试信息
        print(f"=== VirtualStirrer {self.device_id} is being created! ===")
        print(f"=== Config: {self.config} ===")
        print(f"=== Kwargs: {kwargs} ===")
        # 从config或kwargs中获取配置参数
        self.port = self.config.get('port') or kwargs.get('port', 'VIRTUAL')
-        self._max_temp = self.config.get('max_temp') or kwargs.get('max_temp', 100.0)
+        self._max_speed = self.config.get('max_speed') or kwargs.get('max_speed', 1500.0)
-        self._max_speed = self.config.get('max_speed') or kwargs.get('max_speed', 1000.0)
+        self._min_speed = self.config.get('min_speed') or kwargs.get('min_speed', 50.0)
-        # 处理其他kwargs参数，但跳过已知的配置参数
+        # 处理其他kwargs参数
-        skip_keys = {'port', 'max_temp', 'max_speed'}
+        skip_keys = {'port', 'max_speed', 'min_speed'}
        for key, value in kwargs.items():
            if key not in skip_keys and not hasattr(self, key):
                setattr(self, key, value)
        print(f"🌪️ === 虚拟搅拌器 {self.device_id} 已创建 === ✨")
        print(f"🔧 速度范围: {self._min_speed} ~ {self._max_speed} RPM | 📱 端口: {self.port}")
    async def initialize(self) -> bool:
-        """Initialize virtual stirrer"""
+        """Initialize virtual stirrer 🚀"""
-        print(f"=== VirtualStirrer {self.device_id} initialize() called! ===")
+        self.logger.info(f"🔧 初始化虚拟搅拌器 {self.device_id} ✨")
-        self.logger.info(f"Initializing virtual stirrer {self.device_id}")
+        
        # 初始化状态信息
        self.data.update({
-            "status": "Idle"
+            "status": "🏠 待机中",
            "operation_mode": "Idle",          # 操作模式: Idle, Stirring, Settling, Completed, Error
            "current_vessel": "",              # 当前搅拌的容器
            "current_speed": 0.0,              # 当前搅拌速度
            "is_stirring": False,              # 是否正在搅拌
            "remaining_time": 0.0,             # 剩余时间
        })
        self.logger.info(f"✅ 搅拌器 {self.device_id} 初始化完成 🌪️")
        self.logger.info(f"📊 设备规格: 速度范围 {self._min_speed} ~ {self._max_speed} RPM")
        return True
    async def cleanup(self) -> bool:
-        """Cleanup virtual stirrer"""
+        """Cleanup virtual stirrer 🧹"""
-        self.logger.info(f"Cleaning up virtual stirrer {self.device_id}")
+        self.logger.info(f"🧹 清理虚拟搅拌器 {self.device_id} 🔚")
        self.data.update({
            "status": "💤 离线",
            "operation_mode": "Offline",
            "current_vessel": "",
            "current_speed": 0.0,
            "is_stirring": False,
            "remaining_time": 0.0,
        })
        self.logger.info(f"✅ 搅拌器 {self.device_id} 清理完成 💤")
        return True
-    async def stir(self, stir_time: float, stir_speed: float, settling_time: float) -> bool:
+    async def stir(self, stir_time: float, stir_speed: float, settling_time: float, **kwargs) -> bool:
-        """Execute stir action - matches Stir action exactly"""
+        """Execute stir action - 定时搅拌 + 沉降 🌪️"""
        self.logger.info(f"Stir: speed={stir_speed} RPM, time={stir_time}s, settling={settling_time}s")
-        # 验证参数
+        # 🔧 类型转换 - 确保所有参数都是数字类型
-        if stir_speed > self._max_speed:
+        try:
-            self.logger.error(f"Stir speed {stir_speed} exceeds maximum {self._max_speed}")
+            stir_time = float(stir_time)
-            self.data["status"] = f"搅拌速度 {stir_speed} 超出范围"
+            stir_speed = float(stir_speed)
            settling_time = float(settling_time)
        except (ValueError, TypeError) as e:
            error_msg = f"参数类型转换失败: stir_time={stir_time}, stir_speed={stir_speed}, settling_time={settling_time}, error={e}"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: {error_msg}",
                "operation_mode": "Error"
            })
            return False
-        # 开始搅拌
+        self.logger.info(f"🌪️ 开始搅拌操作: 速度 {stir_speed} RPM | 时间 {stir_time}s | 沉降 {settling_time}s")
        self.data["status"] = f"搅拌中: {stir_speed} RPM, {stir_time}s"
-        # 模拟搅拌时间
+        # 验证参数
-        simulation_time = min(stir_time, 10.0)  # 最多等待10秒用于测试
+        if stir_speed > self._max_speed or stir_speed < self._min_speed:
-        await asyncio.sleep(simulation_time)
+            error_msg = f"🌪️ 搅拌速度 {stir_speed} RPM 超出范围 ({self._min_speed} - {self._max_speed} RPM) ⚠️"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 速度超出范围",
                "operation_mode": "Error"
            })
            return False
-        # 搅拌完成，开始沉降
+        # === 第一阶段：搅拌 ===
        start_time = time_module.time()
        total_stir_time = stir_time
        self.logger.info(f"🚀 开始搅拌阶段: {stir_speed} RPM × {total_stir_time}s ⏱️")
        self.data.update({
            "status": f"🌪️ 搅拌中: {stir_speed} RPM | ⏰ 剩余: {total_stir_time:.0f}s",
            "operation_mode": "Stirring",
            "current_speed": stir_speed,
            "is_stirring": True,
            "remaining_time": total_stir_time,
        })
        # 搅拌过程 - 实时更新剩余时间
        last_logged_time = 0
        while True:
            current_time = time_module.time()
            elapsed = current_time - start_time
            remaining = max(0, total_stir_time - elapsed)
            progress = (elapsed / total_stir_time) * 100 if total_stir_time > 0 else 100
            # 更新状态
            self.data.update({
                "remaining_time": remaining,
                "status": f"🌪️ 搅拌中: {stir_speed} RPM | ⏰ 剩余: {remaining:.0f}s"
            })
            # 进度日志（每25%打印一次）
            if progress >= 25 and int(progress) % 25 == 0 and int(progress) != last_logged_time:
                self.logger.info(f"📊 搅拌进度: {progress:.0f}% | 🌪️ {stir_speed} RPM | ⏰ 剩余: {remaining:.0f}s ✨")
                last_logged_time = int(progress)
            # 搅拌时间到了
            if remaining <= 0:
                break
            await asyncio.sleep(1.0)
        self.logger.info(f"✅ 搅拌阶段完成! 🌪️ {stir_speed} RPM × {stir_time}s")
        # === 第二阶段：沉降（如果需要）===
        if settling_time > 0:
-            self.data["status"] = f"沉降中: {settling_time}s"
+            start_settling_time = time_module.time()
-            settling_simulation = min(settling_time, 5.0)  # 最多等待5秒
+            total_settling_time = settling_time
            await asyncio.sleep(settling_simulation)
-        # 操作完成
+            self.logger.info(f"🛑 开始沉降阶段: 停止搅拌 × {total_settling_time}s ⏱️")
-        self.data["status"] = "搅拌完成"
+            
            self.data.update({
                "status": f"🛑 沉降中: 停止搅拌 | ⏰ 剩余: {total_settling_time:.0f}s",
                "operation_mode": "Settling",
                "current_speed": 0.0,
                "is_stirring": False,
                "remaining_time": total_settling_time,
            })
            # 沉降过程 - 实时更新剩余时间
            last_logged_settling = 0
            while True:
                current_time = time_module.time()
                elapsed = current_time - start_settling_time
                remaining = max(0, total_settling_time - elapsed)
                progress = (elapsed / total_settling_time) * 100 if total_settling_time > 0 else 100
                # 更新状态
                self.data.update({
                    "remaining_time": remaining,
                    "status": f"🛑 沉降中: 停止搅拌 | ⏰ 剩余: {remaining:.0f}s"
                })
                # 进度日志（每25%打印一次）
                if progress >= 25 and int(progress) % 25 == 0 and int(progress) != last_logged_settling:
                    self.logger.info(f"📊 沉降进度: {progress:.0f}% | 🛑 静置中 | ⏰ 剩余: {remaining:.0f}s ✨")
                    last_logged_settling = int(progress)
                # 沉降时间到了
                if remaining <= 0:
                    break
                await asyncio.sleep(1.0)
            self.logger.info(f"✅ 沉降阶段完成! 🛑 静置 {settling_time}s")
        # === 操作完成 ===
        settling_info = f" | 🛑 沉降: {settling_time:.0f}s" if settling_time > 0 else ""
        self.data.update({
            "status": f"✅ 完成: 🌪️ 搅拌 {stir_speed} RPM × {stir_time:.0f}s{settling_info}",
            "operation_mode": "Completed",
            "current_speed": 0.0,
            "is_stirring": False,
            "remaining_time": 0.0,
        })
        self.logger.info(f"🎉 搅拌操作完成! ✨")
        self.logger.info(f"📊 操作总结:")
        self.logger.info(f"  🌪️ 搅拌: {stir_speed} RPM × {stir_time}s")
        if settling_time > 0:
            self.logger.info(f"  🛑 沉降: {settling_time}s")
        self.logger.info(f"  ⏱️ 总用时: {(stir_time + settling_time):.0f}s 🏁")
        self.logger.info(f"Stir completed: {stir_speed} RPM for {stir_time}s")
        return True
-    async def start_stir(self, vessel: str, stir_speed: float, purpose: str) -> bool:
+    async def start_stir(self, vessel: str, stir_speed: float, purpose: str = "") -> bool:
-        """Start stir action - matches StartStir action exactly"""
+        """Start stir action - 开始持续搅拌 🔄"""
        self.logger.info(f"StartStir: vessel={vessel}, speed={stir_speed} RPM, purpose={purpose}")
-        # 验证参数
+        # 🔧 类型转换
-        if stir_speed > self._max_speed:
+        try:
-            self.logger.error(f"Stir speed {stir_speed} exceeds maximum {self._max_speed}")
+            stir_speed = float(stir_speed)
-            self.data["status"] = f"搅拌速度 {stir_speed} 超出范围"
+            vessel = str(vessel)
            purpose = str(purpose)
        except (ValueError, TypeError) as e:
            error_msg = f"参数类型转换错误: {str(e)}"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: {error_msg}",
                "operation_mode": "Error"
            })
            return False
-        self.data["status"] = f"开始搅拌: {vessel} at {stir_speed} RPM"
+        self.logger.info(f"🔄 启动持续搅拌: {vessel} | 🌪️ {stir_speed} RPM")
        if purpose:
            self.logger.info(f"📝 搅拌目的: {purpose}")
        # 验证参数
        if stir_speed > self._max_speed or stir_speed < self._min_speed:
            error_msg = f"🌪️ 搅拌速度 {stir_speed} RPM 超出范围 ({self._min_speed} - {self._max_speed} RPM) ⚠️"
            self.logger.error(f"❌ {error_msg}")
            self.data.update({
                "status": f"❌ 错误: 速度超出范围",
                "operation_mode": "Error"
            })
            return False
        purpose_info = f" | 📝 {purpose}" if purpose else ""
        self.data.update({
            "status": f"🔄 启动: 持续搅拌 {vessel} | 🌪️ {stir_speed} RPM{purpose_info}",
            "operation_mode": "Stirring",
            "current_vessel": vessel,
            "current_speed": stir_speed,
            "is_stirring": True,
            "remaining_time": -1.0,  # -1 表示持续运行
        })
        self.logger.info(f"✅ 持续搅拌已启动! 🌪️ {stir_speed} RPM × ♾️ 🚀")
        return True
    async def stop_stir(self, vessel: str) -> bool:
-        """Stop stir action - matches StopStir action exactly"""
+        """Stop stir action - 停止搅拌 🛑"""
        self.logger.info(f"StopStir: vessel={vessel}")
-        self.data["status"] = f"停止搅拌: {vessel}"
+        # 🔧 类型转换
        try:
            vessel = str(vessel)
        except (ValueError, TypeError) as e:
            error_msg = f"参数类型转换错误: {str(e)}"
            self.logger.error(f"❌ {error_msg}")
            return False
        current_speed = self.data.get("current_speed", 0.0)
        self.logger.info(f"🛑 停止搅拌: {vessel}")
        if current_speed > 0:
            self.logger.info(f"🌪️ 之前搅拌速度: {current_speed} RPM")
        self.data.update({
            "status": f"🛑 已停止: {vessel} 搅拌停止 | 之前速度: {current_speed} RPM",
            "operation_mode": "Stopped",
            "current_vessel": "",
            "current_speed": 0.0,
            "is_stirring": False,
            "remaining_time": 0.0,
        })
        self.logger.info(f"✅ 搅拌器已停止 {vessel} 的搅拌操作 🏁")
        return True
-    # 状态属性 - 只保留 action 中定义的 feedback
+    # 状态属性
    @property
    def status(self) -> str:
-        return self.data.get("status", "Idle")
+        return self.data.get("status", "🏠 待机中")
    @property
    def operation_mode(self) -> str:
        return self.data.get("operation_mode", "Idle")
    @property
    def current_vessel(self) -> str:
        return self.data.get("current_vessel", "")
    @property
    def current_speed(self) -> float:
        return self.data.get("current_speed", 0.0)
    @property
    def is_stirring(self) -> bool:
        return self.data.get("is_stirring", False)
    @property
    def remaining_time(self) -> float:
        return self.data.get("remaining_time", 0.0)
    @property
    def max_speed(self) -> float:
        return self._max_speed
    @property
    def min_speed(self) -> float:
        return self._min_speed
    def get_device_info(self) -> Dict[str, Any]:
        """获取设备状态信息 📊"""
        info = {
            "device_id": self.device_id,
            "status": self.status,
            "operation_mode": self.operation_mode,
            "current_vessel": self.current_vessel,
            "current_speed": self.current_speed,
            "is_stirring": self.is_stirring,
            "remaining_time": self.remaining_time,
            "max_speed": self._max_speed,
            "min_speed": self._min_speed
        }
        self.logger.debug(f"📊 设备信息: 模式={self.operation_mode}, 速度={self.current_speed} RPM, 搅拌={self.is_stirring}")
        return info
    def __str__(self):
        status_emoji = "✅" if self.operation_mode == "Idle" else "🌪️" if self.operation_mode == "Stirring" else "🛑" if self.operation_mode == "Settling" else "❌"
        return f"🌪️ VirtualStirrer({status_emoji} {self.device_id}: {self.operation_mode}, {self.current_speed} RPM)"
--- a/unilabos/devices/virtual/virtual_transferpump.py
+++ b/unilabos/devices/virtual/virtual_transferpump.py
@@ -1,149 +1,433 @@
 import asyncio
 import time
 from enum import Enum
 from typing import Union, Optional
 import logging
-from typing import Dict, Any, Optional
+
 class VirtualPumpMode(Enum):
    Normal = 0
    AccuratePos = 1
    AccuratePosVel = 2
 class VirtualTransferPump:
-    """Virtual pump device specifically for Transfer protocol"""
+    """虚拟转移泵类 - 模拟泵的基本功能，无需实际硬件 🚰"""
-    def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
+    def __init__(self, device_id: str = None, config: dict = None, **kwargs):
-        # 处理可能的不同调用方式
+        """
-        if device_id is None and 'id' in kwargs:
+        初始化虚拟转移泵
            device_id = kwargs.pop('id')
        if config is None and 'config' in kwargs:
            config = kwargs.pop('config')
-        # 设置默认值
+        Args:
-        self.device_id = device_id or "unknown_transfer_pump"
+            device_id: 设备ID
-        self.config = config or {}
+            config: 配置字典，包含max_volume, port等参数
            **kwargs: 其他参数，确保兼容性
        """
        self.device_id = device_id or "virtual_transfer_pump"
        # 从config或kwargs中获取参数，确保类型正确
        if config:
            self.max_volume = float(config.get('max_volume', 25.0))
            self.port = config.get('port', 'VIRTUAL')
        else:
            self.max_volume = float(kwargs.get('max_volume', 25.0))
            self.port = kwargs.get('port', 'VIRTUAL')
        self._transfer_rate = float(kwargs.get('transfer_rate', 0))
        self.mode = kwargs.get('mode', VirtualPumpMode.Normal)
        # 状态变量 - 确保都是正确类型
        self._status = "Idle"
        self._position = 0.0  # float
        self._max_velocity = 5.0  # float 
        self._current_volume = 0.0  # float
        # 🚀 新增：快速模式设置 - 大幅缩短执行时间
        self._fast_mode = True  # 是否启用快速模式
        self._fast_move_time = 1.0  # 快速移动时间（秒）
        self._fast_dispense_time = 1.0  # 快速喷射时间（秒）
        self.logger = logging.getLogger(f"VirtualTransferPump.{self.device_id}")
        self.data = {}
-        # 添加调试信息
+        print(f"🚰 === 虚拟转移泵 {self.device_id} 已创建 === ✨")
-        print(f"=== VirtualTransferPump {self.device_id} is being created! ===")
+        print(f"💨 快速模式: {'启用' if self._fast_mode else '禁用'} | 移动时间: {self._fast_move_time}s | 喷射时间: {self._fast_dispense_time}s")
-        print(f"=== Config: {self.config} ===")
+        print(f"📊 最大容量: {self.max_volume}mL | 端口: {self.port}")
        print(f"=== Kwargs: {kwargs} ===")
        # 从config或kwargs中获取配置参数
        self.port = self.config.get('port') or kwargs.get('port', 'VIRTUAL')
        self._max_volume = self.config.get('max_volume') or kwargs.get('max_volume', 50.0)
        self._transfer_rate = self.config.get('transfer_rate') or kwargs.get('transfer_rate', 5.0)
        self._current_volume = 0.0
        self.is_running = False
    async def initialize(self) -> bool:
-        """Initialize virtual transfer pump"""
+        """初始化虚拟泵 🚀"""
-        print(f"=== VirtualTransferPump {self.device_id} initialize() called! ===")
+        self.logger.info(f"🔧 初始化虚拟转移泵 {self.device_id} ✨")
-        self.logger.info(f"Initializing virtual transfer pump {self.device_id}")
+        self._status = "Idle"
-        self.data.update({
+        self._position = 0.0
-            "status": "Idle",
+        self._current_volume = 0.0
-            "current_volume": 0.0,
+        self.logger.info(f"✅ 转移泵 {self.device_id} 初始化完成 🚰")
            "max_volume": self._max_volume,
            "transfer_rate": self._transfer_rate,
            "from_vessel": "",
            "to_vessel": "",
            "progress": 0.0,
            "transferred_volume": 0.0,
            "current_status": "Ready"
        })
        return True
    async def cleanup(self) -> bool:
-        """Cleanup virtual transfer pump"""
+        """清理虚拟泵 🧹"""
-        self.logger.info(f"Cleaning up virtual transfer pump {self.device_id}")
+        self.logger.info(f"🧹 清理虚拟转移泵 {self.device_id} 🔚")
        self._status = "Idle"
        self.logger.info(f"✅ 转移泵 {self.device_id} 清理完成 💤")
        return True
-    async def transfer(self, from_vessel: str, to_vessel: str, volume: float, 
+    # 基本属性
                      amount: str = "", time: float = 0, viscous: bool = False,
                      rinsing_solvent: str = "", rinsing_volume: float = 0.0,
                      rinsing_repeats: int = 0, solid: bool = False) -> bool:
        """Execute liquid transfer - matches Transfer action"""
        self.logger.info(f"Transfer: {volume}mL from {from_vessel} to {to_vessel}")
        # 计算转移时间
        if time > 0:
            transfer_time = time
        else:
            # 如果是粘性液体，降低转移速率
            rate = self._transfer_rate * 0.5 if viscous else self._transfer_rate
            transfer_time = volume / rate
        self.data.update({
            "status": "Running",
            "from_vessel": from_vessel,
            "to_vessel": to_vessel,
            "current_status": "Transferring",
            "progress": 0.0,
            "transferred_volume": 0.0
        })
        # 模拟转移过程
        steps = 10
        step_time = transfer_time / steps
        step_volume = volume / steps
        for i in range(steps):
            await asyncio.sleep(step_time)
            progress = (i + 1) / steps * 100
            transferred = (i + 1) * step_volume
            self.data.update({
                "progress": progress,
                "transferred_volume": transferred,
                "current_status": f"Transferring {progress:.1f}%"
            })
            self.logger.info(f"Transfer progress: {progress:.1f}% ({transferred:.1f}/{volume}mL)")
        # 如果需要冲洗
        if rinsing_solvent and rinsing_volume > 0 and rinsing_repeats > 0:
            self.data["current_status"] = "Rinsing"
            for repeat in range(rinsing_repeats):
                self.logger.info(f"Rinsing cycle {repeat + 1}/{rinsing_repeats} with {rinsing_solvent}")
                await asyncio.sleep(1)  # 模拟冲洗时间
        self.data.update({
            "status": "Idle",
            "current_status": "Transfer completed",
            "progress": 100.0,
            "transferred_volume": volume
        })
        return True
    # 添加所有在virtual_device.yaml中定义的状态属性
    @property
    def status(self) -> str:
-        return self.data.get("status", "Unknown")
+        return self._status
    @property
    def position(self) -> float:
        """当前柱塞位置 (ml) 📍"""
        return self._position
    @property
    def current_volume(self) -> float:
-        return self.data.get("current_volume", 0.0)
+        """当前注射器中的体积 (ml) 💧"""
        return self._current_volume
    @property
-    def max_volume(self) -> float:
+    def max_velocity(self) -> float:
-        return self.data.get("max_volume", self._max_volume)
+        return self._max_velocity
    @property
    def transfer_rate(self) -> float:
-        return self.data.get("transfer_rate", self._transfer_rate)
+        return self._transfer_rate
-    @property
+    def set_max_velocity(self, velocity: float):
-    def from_vessel(self) -> str:
+        """设置最大速度 (ml/s) 🌊"""
-        return self.data.get("from_vessel", "")
+        self._max_velocity = max(0.1, min(50.0, velocity))  # 限制在合理范围内
        self.logger.info(f"🌊 设置最大速度为 {self._max_velocity} mL/s")
-    @property
+    def get_status(self) -> str:
-    def to_vessel(self) -> str:
+        """获取泵状态 📋"""
-        return self.data.get("to_vessel", "")
+        return self._status
-    @property
+    async def _simulate_operation(self, duration: float):
-    def progress(self) -> float:
+        """模拟操作延时 ⏱️"""
-        return self.data.get("progress", 0.0)
+        self._status = "Busy"
        await asyncio.sleep(duration)
        self._status = "Idle"
-    @property
+    def _calculate_duration(self, volume: float, velocity: float = None) -> float:
-    def transferred_volume(self) -> float:
+        """
-        return self.data.get("transferred_volume", 0.0)
+        计算操作持续时间 ⏰
        🚀 快速模式：保留计算逻辑用于日志显示，但实际使用固定的快速时间
        """
        if velocity is None:
            velocity = self._max_velocity
-    @property
+        # 📊 计算理论时间（用于日志显示）
-    def current_status(self) -> str:
+        theoretical_duration = abs(volume) / velocity
-        return self.data.get("current_status", "Ready")
+        
        # 🚀 如果启用快速模式，使用固定的快速时间
        if self._fast_mode:
            # 根据操作类型选择快速时间
            if abs(volume) > 0.1:  # 大于0.1mL的操作
                actual_duration = self._fast_move_time
            else:  # 很小的操作
                actual_duration = 0.5
            self.logger.debug(f"⚡ 快速模式: 理论时间 {theoretical_duration:.2f}s → 实际时间 {actual_duration:.2f}s")
            return actual_duration
        else:
            # 正常模式使用理论时间
            return theoretical_duration
    def _calculate_display_duration(self, volume: float, velocity: float = None) -> float:
        """
        计算显示用的持续时间（用于日志） 📊
        这个函数返回理论计算时间，用于日志显示
        """
        if velocity is None:
            velocity = self._max_velocity
        return abs(volume) / velocity
    # 新的set_position方法 - 专门用于SetPumpPosition动作
    async def set_position(self, position: float, max_velocity: float = None):
        """
        移动到绝对位置 - 专门用于SetPumpPosition动作 🎯
        Args:
            position (float): 目标位置 (ml)
            max_velocity (float): 移动速度 (ml/s)
        Returns:
            dict: 符合SetPumpPosition.action定义的结果
        """
        try:
            # 验证并转换参数
            target_position = float(position)
            velocity = float(max_velocity) if max_velocity is not None else self._max_velocity
            # 限制位置在有效范围内
            target_position = max(0.0, min(float(self.max_volume), target_position))
            # 计算移动距离
            volume_to_move = abs(target_position - self._position)
            # 📊 计算显示用的时间（用于日志）
            display_duration = self._calculate_display_duration(volume_to_move, velocity)
            # ⚡ 计算实际执行时间（快速模式）
            actual_duration = self._calculate_duration(volume_to_move, velocity)
            # 🎯 确定操作类型和emoji
            if target_position > self._position:
                operation_type = "吸液"
                operation_emoji = "📥"
            elif target_position < self._position:
                operation_type = "排液"
                operation_emoji = "📤"
            else:
                operation_type = "保持"
                operation_emoji = "📍"
            self.logger.info(f"🎯 SET_POSITION: {operation_type} {operation_emoji}")
            self.logger.info(f"  📍 位置: {self._position:.2f}mL → {target_position:.2f}mL (移动 {volume_to_move:.2f}mL)")
            self.logger.info(f"  🌊 速度: {velocity:.2f} mL/s")
            self.logger.info(f"  ⏰ 预计时间: {display_duration:.2f}s")
            if self._fast_mode:
                self.logger.info(f"  ⚡ 快速模式: 实际用时 {actual_duration:.2f}s")
            # 🚀 模拟移动过程
            if volume_to_move > 0.01:  # 只有当移动距离足够大时才显示进度
                start_position = self._position
                steps = 5 if actual_duration > 0.5 else 2  # 根据实际时间调整步数
                step_duration = actual_duration / steps
                self.logger.info(f"🚀 开始{operation_type}... {operation_emoji}")
                for i in range(steps + 1):
                    # 计算当前位置和进度
                    progress = (i / steps) * 100 if steps > 0 else 100
                    current_pos = start_position + (target_position - start_position) * (i / steps) if steps > 0 else target_position
                    # 更新状态
                    if i < steps:
                        self._status = f"{operation_type}中"
                        status_emoji = "🔄"
                    else:
                        self._status = "Idle"
                        status_emoji = "✅"
                    self._position = current_pos
                    self._current_volume = current_pos
                    # 显示进度（每25%或最后一步）
                    if i == 0:
                        self.logger.debug(f"  🔄 {operation_type}开始: {progress:.0f}%")
                    elif progress >= 50 and i == steps // 2:
                        self.logger.debug(f"  🔄 {operation_type}进度: {progress:.0f}%")
                    elif i == steps:
                        self.logger.info(f"  ✅ {operation_type}完成: {progress:.0f}% | 当前位置: {current_pos:.2f}mL")
                    # 等待一小步时间
                    if i < steps and step_duration > 0:
                        await asyncio.sleep(step_duration)
            else:
                # 移动距离很小，直接完成
                self._position = target_position
                self._current_volume = target_position
                self.logger.info(f"  📍 微调完成: {target_position:.2f}mL")
            # 确保最终位置准确
            self._position = target_position
            self._current_volume = target_position
            self._status = "Idle"
            # 📊 最终状态日志
            if volume_to_move > 0.01:
                self.logger.info(f"🎉 SET_POSITION 完成! 📍 最终位置: {self._position:.2f}mL | 💧 当前体积: {self._current_volume:.2f}mL")
            # 返回符合action定义的结果
            return {
                "success": True,
                "message": f"✅ 成功移动到位置 {self._position:.2f}mL ({operation_type})",
                "final_position": self._position,
                "final_volume": self._current_volume,
                "operation_type": operation_type
            }
        except Exception as e:
            error_msg = f"❌ 设置位置失败: {str(e)}"
            self.logger.error(error_msg)
            return {
                "success": False,
                "message": error_msg,
                "final_position": self._position,
                "final_volume": self._current_volume
            }
    # 其他泵操作方法
    async def pull_plunger(self, volume: float, velocity: float = None):
        """
        拉取柱塞（吸液） 📥
        Args:
            volume (float): 要拉取的体积 (ml)
            velocity (float): 拉取速度 (ml/s)
        """
        new_position = min(self.max_volume, self._position + volume)
        actual_volume = new_position - self._position
        if actual_volume <= 0:
            self.logger.warning("⚠️ 无法吸液 - 已达到最大容量")
            return
        display_duration = self._calculate_display_duration(actual_volume, velocity)
        actual_duration = self._calculate_duration(actual_volume, velocity)
        self.logger.info(f"📥 开始吸液: {actual_volume:.2f}mL")
        self.logger.info(f"  📍 位置: {self._position:.2f}mL → {new_position:.2f}mL")
        self.logger.info(f"  ⏰ 预计时间: {display_duration:.2f}s")
        if self._fast_mode:
            self.logger.info(f"  ⚡ 快速模式: 实际用时 {actual_duration:.2f}s")
        await self._simulate_operation(actual_duration)
        self._position = new_position
        self._current_volume = new_position
        self.logger.info(f"✅ 吸液完成: {actual_volume:.2f}mL | 💧 当前体积: {self._current_volume:.2f}mL")
    async def push_plunger(self, volume: float, velocity: float = None):
        """
        推出柱塞（排液） 📤
        Args:
            volume (float): 要推出的体积 (ml)
            velocity (float): 推出速度 (ml/s)
        """
        new_position = max(0, self._position - volume)
        actual_volume = self._position - new_position
        if actual_volume <= 0:
            self.logger.warning("⚠️ 无法排液 - 已达到最小容量")
            return
        display_duration = self._calculate_display_duration(actual_volume, velocity)
        actual_duration = self._calculate_duration(actual_volume, velocity)
        self.logger.info(f"📤 开始排液: {actual_volume:.2f}mL")
        self.logger.info(f"  📍 位置: {self._position:.2f}mL → {new_position:.2f}mL")
        self.logger.info(f"  ⏰ 预计时间: {display_duration:.2f}s")
        if self._fast_mode:
            self.logger.info(f"  ⚡ 快速模式: 实际用时 {actual_duration:.2f}s")
        await self._simulate_operation(actual_duration)
        self._position = new_position
        self._current_volume = new_position
        self.logger.info(f"✅ 排液完成: {actual_volume:.2f}mL | 💧 当前体积: {self._current_volume:.2f}mL")
    # 便捷操作方法
    async def aspirate(self, volume: float, velocity: float = None):
        """吸液操作 📥"""
        await self.pull_plunger(volume, velocity)
    async def dispense(self, volume: float, velocity: float = None):
        """排液操作 📤"""
        await self.push_plunger(volume, velocity)
    async def transfer(self, volume: float, aspirate_velocity: float = None, dispense_velocity: float = None):
        """转移操作（先吸后排） 🔄"""
        self.logger.info(f"🔄 开始转移操作: {volume:.2f}mL")
        # 吸液
        await self.aspirate(volume, aspirate_velocity)
        # 短暂停顿
        self.logger.debug("⏸️ 短暂停顿...")
        await asyncio.sleep(0.1)
        # 排液
        await self.dispense(volume, dispense_velocity)
    async def empty_syringe(self, velocity: float = None):
        """清空注射器"""
        await self.set_position(0, velocity)
    async def fill_syringe(self, velocity: float = None):
        """充满注射器"""
        await self.set_position(self.max_volume, velocity)
    async def stop_operation(self):
        """停止当前操作"""
        self._status = "Idle"
        self.logger.info("Operation stopped")
    # 状态查询方法
    def get_position(self) -> float:
        """获取当前位置"""
        return self._position
    def get_current_volume(self) -> float:
        """获取当前体积"""
        return self._current_volume
    def get_remaining_capacity(self) -> float:
        """获取剩余容量"""
        return self.max_volume - self._current_volume
    def is_empty(self) -> bool:
        """检查是否为空"""
        return self._current_volume <= 0.01  # 允许小量误差
    def is_full(self) -> bool:
        """检查是否已满"""
        return self._current_volume >= (self.max_volume - 0.01)  # 允许小量误差
    # 调试和状态信息
    def get_pump_info(self) -> dict:
        """获取泵的详细信息"""
        return {
            "device_id": self.device_id,
            "status": self._status,
            "position": self._position,
            "current_volume": self._current_volume,
            "max_volume": self.max_volume,
            "max_velocity": self._max_velocity,
            "mode": self.mode.name,
            "is_empty": self.is_empty(),
            "is_full": self.is_full(),
            "remaining_capacity": self.get_remaining_capacity()
        }
    def __str__(self):
        return f"VirtualTransferPump({self.device_id}: {self._current_volume:.2f}/{self.max_volume} ml, {self._status})"
    def __repr__(self):
        return self.__str__()
 # 使用示例
 async def demo():
    """虚拟泵使用示例"""
    pump = VirtualTransferPump("demo_pump", {"max_volume": 50.0})
    await pump.initialize()
    print(f"Initial state: {pump}")
    # 测试set_position方法
    result = await pump.set_position(10.0, max_velocity=2.0)
    print(f"Set position result: {result}")
    print(f"After setting position to 10ml: {pump}")
    # 吸液测试
    await pump.aspirate(5.0, velocity=2.0)
    print(f"After aspirating 5ml: {pump}")
    # 清空测试
    result = await pump.set_position(0.0)
    print(f"Empty result: {result}")
    print(f"After emptying: {pump}")
    print("\nPump info:", pump.get_pump_info())
 if __name__ == "__main__":
    asyncio.run(demo())
--- a/unilabos/devices/virtual/virtual_vacuum_pump.py
+++ b/unilabos/devices/virtual/virtual_vacuum_pump.py
@@ -0,0 +1,47 @@
 import asyncio
 import time
 from typing import Dict, Any, Optional
 class VirtualVacuumPump:
    """Virtual vacuum pump for testing"""
    def __init__(self, device_id: Optional[str] = None, config: Optional[Dict[str, Any]] = None, **kwargs):
        self.device_id = device_id or "unknown_vacuum_pump"
        self.config = config or {}
        self.data = {}
        self._status = "OPEN"
    async def initialize(self) -> bool:
        """Initialize virtual vacuum pump"""
        self.data.update({
            "status": self._status
        })
        return True
    async def cleanup(self) -> bool:
        """Cleanup virtual vacuum pump"""
        return True
    @property
    def status(self) -> str:
        return self._status
    def get_status(self) -> str:
        return self._status
    def set_status(self, string):
        self._status = string
        time.sleep(5)
    def open(self):
        self._status = "OPEN"
    def close(self):
        self._status = "CLOSED"
    def is_open(self):
        return self._status
    def is_closed(self):
        return not self._status
--- a/unilabos/devices/zhida_hplc/zhida.py
+++ b/unilabos/devices/zhida_hplc/zhida.py
@@ -1,11 +1,9 @@
 #!/usr/bin/env python3
 # -*- coding: utf-8 -*-
 import socket
 import json
 import base64
-import argparse
+import json
-import sys
+import socket
 import time
@@ -96,17 +94,20 @@ class ZhidaClient:
    def abort(self) -> dict:
        return self._send_command({"command": "abort"})
 """
 a,b,c
 1,2,4
 2,4,5
 """
-client = ZhidaClient()
+if __name__ == "__main__":
-# 连接
+
-client.connect()
+    """
-# 获取状态
+    a,b,c
-print(client.status)
+    1,2,4
    2,4,5
    """
    client = ZhidaClient()
    # 连接
    client.connect()
    # 获取状态
    print(client.status)
-# 命令格式：python zhida.py <subcommand> [options]
+    # 命令格式：python zhida.py <subcommand> [options]
--- a/unilabos/messages/init.py
+++ b/unilabos/messages/init.py
@@ -10,18 +10,88 @@ class Point3D(BaseModel):
 # Start Protocols
 class PumpTransferProtocol(BaseModel):
    # === 核心参数（保持必需） ===
    from_vessel: str
    to_vessel: str
-    volume: float
+    
    # === 所有其他参数都改为可选，添加默认值 ===
    volume: float = 0.0  # 🔧 改为-1，表示转移全部体积
    amount: str = ""
-    time: float = 0
+    time: float = 0.0
    viscous: bool = False
-    rinsing_solvent: str = "air"
+    rinsing_solvent: str = ""
-    rinsing_volume: float = 5000
+    rinsing_volume: float = 0.0
-    rinsing_repeats: int = 2
+    rinsing_repeats: int = 0
    solid: bool = False
-    flowrate: float = 500
+    flowrate: float = 2.5
-    transfer_flowrate: float = 2500
+    transfer_flowrate: float = 0.5
    # === 新版XDL兼容参数（可选） ===
    rate_spec: str = ""
    event: str = ""
    through: str = ""
    def model_post_init(self, __context):
        """后处理：智能参数处理和兼容性调整"""
        # 如果指定了 amount 但volume是默认值，尝试解析 amount
        if self.amount and self.volume == 0.0:
            parsed_volume = self._parse_amount_to_volume(self.amount)
            if parsed_volume > 0:
                self.volume = parsed_volume
        # 如果指定了 time 但没有明确设置流速，根据时间计算流速
        if self.time > 0 and self.volume > 0:
            if self.flowrate == 2.5 and self.transfer_flowrate == 0.5:
                calculated_flowrate = self.volume / self.time
                self.flowrate = min(calculated_flowrate, 10.0)
                self.transfer_flowrate = min(calculated_flowrate, 5.0)
        # 🔧 核心修复：如果flowrate为0（ROS2传入），使用默认值
        if self.flowrate <= 0:
            self.flowrate = 2.5
        if self.transfer_flowrate <= 0:
            self.transfer_flowrate = 0.5
        # 根据 rate_spec 调整流速
        if self.rate_spec == "dropwise":
            self.flowrate = min(self.flowrate, 0.1)
            self.transfer_flowrate = min(self.transfer_flowrate, 0.1)
        elif self.rate_spec == "slowly":
            self.flowrate = min(self.flowrate, 0.5)
            self.transfer_flowrate = min(self.transfer_flowrate, 0.3)
        elif self.rate_spec == "quickly":
            self.flowrate = max(self.flowrate, 5.0)
            self.transfer_flowrate = max(self.transfer_flowrate, 2.0)
    def _parse_amount_to_volume(self, amount: str) -> float:
        """解析 amount 字符串为体积"""
        if not amount:
            return 0.0
        amount = amount.lower().strip()
        # 处理特殊关键词
        if amount == "all":
            return 0.0  # 🔧 "all"也表示转移全部
        # 提取数字
        import re
        numbers = re.findall(r'[\d.]+', amount)
        if numbers:
            volume = float(numbers[0])
            # 单位转换
            if 'ml' in amount or 'milliliter' in amount:
                return volume
            elif 'l' in amount and 'ml' not in amount:
                return volume * 1000
            elif 'μl' in amount or 'microliter' in amount:
                return volume / 1000
            else:
                return volume
        return 0.0
 class CleanProtocol(BaseModel):
@@ -33,33 +103,112 @@ class CleanProtocol(BaseModel):
 class SeparateProtocol(BaseModel):
-    purpose: str  # 'wash' or 'extract'. 'wash' means that product phase will not be the added solvent phase, 'extract' means product phase will be the added solvent phase. If no solvent is added just use 'extract'.
+    purpose: str
-    product_phase: str # 'top' or 'bottom'. Phase that product will be in.
+    product_phase: str
-    from_vessel: str #Contents of from_vessel are transferred to separation_vessel and separation is performed.
+    from_vessel: str
-    separation_vessel: str # Vessel in which separation of phases will be carried out.
+    separation_vessel: str
-    to_vessel: str # Vessel to send product phase to.
+    to_vessel: str
-    waste_phase_to_vessel: str # Optional. Vessel to send waste phase to.
+    waste_phase_to_vessel: str
-    solvent: str # Optional. Solvent to add to separation vessel after contents of from_vessel has been transferred to create two phases.
+    solvent: str
-    solvent_volume: float # Optional. Volume of solvent to add.
+    solvent_volume: float
-    through: str # Optional. Solid chemical to send product phase through on way to to_vessel, e.g. 'celite'.
+    through: str
-    repeats: int # Optional. Number of separations to perform.
+    repeats: int
-    stir_time: float # Optional. Time stir for after adding solvent, before separation of phases.
+    stir_time: float
-    stir_speed: float # Optional. Speed to stir at after adding solvent, before separation of phases.
+    stir_speed: float
-    settling_time: float # Optional. Time
+    settling_time: float
 class EvaporateProtocol(BaseModel):
-    vessel: str
+    # === 核心参数（必需） ===
-    pressure: float
+    vessel: str = Field(..., description="蒸发容器名称")
-    temp: float
+    
-    time: float
+    # === 所有其他参数都改为可选，添加默认值 ===
-    stir_speed: float
+    pressure: float = Field(0.1, description="真空度 (bar)，默认0.1 bar")
    temp: float = Field(60.0, description="加热温度 (°C)，默认60°C")
    time: float = Field(180.0, description="蒸发时间 (秒)，默认1800s (30分钟)")
    stir_speed: float = Field(100.0, description="旋转速度 (RPM)，默认100 RPM")
    # === 新版XDL兼容参数（可选） ===
    solvent: str = Field("", description="溶剂名称（用于识别蒸发的溶剂类型）")
    def model_post_init(self, __context):
        """后处理：智能参数处理和兼容性调整"""
        # 参数范围验证和修正
        if self.pressure <= 0 or self.pressure > 1.0:
            logger.warning(f"真空度 {self.pressure} bar 超出范围，修正为 0.1 bar")
            self.pressure = 0.1
        if self.temp < 10.0 or self.temp > 200.0:
            logger.warning(f"温度 {self.temp}°C 超出范围，修正为 60°C")
            self.temp = 60.0
        if self.time <= 0:
            logger.warning(f"时间 {self.time}s 无效，修正为 1800s")
            self.time = 1800.0
        if self.stir_speed < 10.0 or self.stir_speed > 300.0:
            logger.warning(f"旋转速度 {self.stir_speed} RPM 超出范围，修正为 100 RPM")
            self.stir_speed = 100.0
        # 根据溶剂类型调整参数
        if self.solvent:
            self._adjust_parameters_by_solvent()
    def _adjust_parameters_by_solvent(self):
        """根据溶剂类型调整蒸发参数"""
        solvent_lower = self.solvent.lower()
        # 水系溶剂：较高温度，较低真空度
        if any(s in solvent_lower for s in ['water', 'aqueous', 'h2o']):
            if self.temp == 60.0:  # 如果是默认值，则调整
                self.temp = 80.0
            if self.pressure == 0.1:
                self.pressure = 0.2
        # 有机溶剂：根据沸点调整
        elif any(s in solvent_lower for s in ['ethanol', 'methanol', 'acetone']):
            if self.temp == 60.0:
                self.temp = 50.0
            if self.pressure == 0.1:
                self.pressure = 0.05
        # 高沸点溶剂：更高温度
        elif any(s in solvent_lower for s in ['dmso', 'dmi', 'toluene']):
            if self.temp == 60.0:
                self.temp = 100.0
            if self.pressure == 0.1:
                self.pressure = 0.01
 class EvacuateAndRefillProtocol(BaseModel):
-    vessel: str
+    # === 必需参数 ===
-    gas: str
+    vessel: str = Field(..., description="目标容器名称")
-    repeats: int
+    gas: str = Field(..., description="气体名称")
    # 🔧 删除 repeats 参数，直接在代码中硬编码为 3 次
    def model_post_init(self, __context):
        """后处理：参数验证和兼容性调整"""
        # 验证气体名称
        if not self.gas.strip():
            logger.warning("气体名称为空，使用默认值 'nitrogen'")
            self.gas = "nitrogen"
        # 标准化气体名称
        gas_aliases = {
            'n2': 'nitrogen',
            'ar': 'argon', 
            'air': 'air',
            'o2': 'oxygen',
            'co2': 'carbon_dioxide',
            'h2': 'hydrogen'
        }
        gas_lower = self.gas.lower().strip()
        if gas_lower in gas_aliases:
            self.gas = gas_aliases[gas_lower]
 class AGVTransferProtocol(BaseModel):
@@ -67,6 +216,7 @@ class AGVTransferProtocol(BaseModel):
    to_repo: dict
    from_repo_position: str
    to_repo_position: str
 #=============新添加的新的协议================
 class AddProtocol(BaseModel):
    vessel: str
@@ -84,45 +234,285 @@ class CentrifugeProtocol(BaseModel):
    vessel: str
    speed: float
    time: float
-    temp: float  # 移除默认值
+    temp: float
 class FilterProtocol(BaseModel):
-    vessel: str
+    # === 必需参数 ===
-    filtrate_vessel: str  # 移除默认值
+    vessel: str = Field(..., description="过滤容器名称")
-    stir: bool  # 移除默认值
+    
-    stir_speed: float  # 移除默认值
+    # === 可选参数 ===
-    temp: float  # 移除默认值
+    filtrate_vessel: str = Field("", description="滤液容器名称（可选，自动查找）")
-    continue_heatchill: bool  # 移除默认值
+    
-    volume: float  # 移除默认值
+    def model_post_init(self, __context):
        """后处理：参数验证"""
        # 验证容器名称
        if not self.vessel.strip():
            raise ValueError("vessel 参数不能为空")
 class HeatChillProtocol(BaseModel):
-    vessel: str
+    # === 必需参数 ===
-    temp: float
+    vessel: str = Field(..., description="加热容器名称")
-    time: float
+    
-    stir: bool
+    # === 可选参数 - 温度相关 ===
-    stir_speed: float
+    temp: float = Field(25.0, description="目标温度 (°C)")
-    purpose: str
+    temp_spec: str = Field("", description="温度规格（如 'room temperature', 'reflux'）")
    # === 可选参数 - 时间相关 ===
    time: float = Field(300.0, description="加热时间 (秒)")
    time_spec: str = Field("", description="时间规格（如 'overnight', '2 h'）")
    # === 可选参数 - 其他XDL参数 ===
    pressure: str = Field("", description="压力规格（如 '1 mbar'），不做特殊处理")
    reflux_solvent: str = Field("", description="回流溶剂名称，不做特殊处理")
    # === 可选参数 - 搅拌相关 ===
    stir: bool = Field(False, description="是否搅拌")
    stir_speed: float = Field(300.0, description="搅拌速度 (RPM)")
    purpose: str = Field("", description="操作目的")
    def model_post_init(self, __context):
        """后处理：参数验证和解析"""
        # 验证必需参数
        if not self.vessel.strip():
            raise ValueError("vessel 参数不能为空")
        # 温度解析：优先使用 temp_spec，然后是 temp
        if self.temp_spec:
            self.temp = self._parse_temp_spec(self.temp_spec)
        # 时间解析：优先使用 time_spec，然后是 time
        if self.time_spec:
            self.time = self._parse_time_spec(self.time_spec)
        # 参数范围验证
        if self.temp < -50.0 or self.temp > 300.0:
            logger.warning(f"温度 {self.temp}°C 超出范围，修正为 25°C")
            self.temp = 25.0
        if self.time < 0:
            logger.warning(f"时间 {self.time}s 无效，修正为 300s")
            self.time = 300.0
        if self.stir_speed < 0 or self.stir_speed > 1500.0:
            logger.warning(f"搅拌速度 {self.stir_speed} RPM 超出范围，修正为 300 RPM")
            self.stir_speed = 300.0
    def _parse_temp_spec(self, temp_spec: str) -> float:
        """解析温度规格为具体温度"""
        temp_spec = temp_spec.strip().lower()
        # 特殊温度规格
        special_temps = {
            "room temperature": 25.0,      # 室温
            "reflux": 78.0,                 # 默认回流温度（乙醇沸点）
            "ice bath": 0.0,                # 冰浴
            "boiling": 100.0,               # 沸腾
            "hot": 60.0,                    # 热
            "warm": 40.0,                   # 温热
            "cold": 10.0,                   # 冷
        }
        if temp_spec in special_temps:
            return special_temps[temp_spec]
        # 解析带单位的温度（如 "256 °C"）
        import re
        temp_pattern = r'(\d+(?:\.\d+)?)\s*°?[cf]?'
        match = re.search(temp_pattern, temp_spec)
        if match:
            return float(match.group(1))
        return 25.0  # 默认室温
    def _parse_time_spec(self, time_spec: str) -> float:
        """解析时间规格为秒数"""
        time_spec = time_spec.strip().lower()
        # 特殊时间规格
        special_times = {
            "overnight": 43200.0,           # 12小时
            "several hours": 10800.0,       # 3小时
            "few hours": 7200.0,            # 2小时
            "long time": 3600.0,            # 1小时
            "short time": 300.0,            # 5分钟
        }
        if time_spec in special_times:
            return special_times[time_spec]
        # 解析带单位的时间（如 "2 h"）
        import re
        time_pattern = r'(\d+(?:\.\d+)?)\s*([a-zA-Z]+)'
        match = re.search(time_pattern, time_spec)
        if match:
            value = float(match.group(1))
            unit = match.group(2).lower()
            unit_multipliers = {
                's': 1.0,
                'sec': 1.0,
                'second': 1.0,
                'seconds': 1.0,
                'min': 60.0,
                'minute': 60.0,
                'minutes': 60.0,
                'h': 3600.0,
                'hr': 3600.0,
                'hour': 3600.0,
                'hours': 3600.0,
            }
            multiplier = unit_multipliers.get(unit, 3600.0)  # 默认按小时计算
            return value * multiplier
        return 300.0  # 默认5分钟
 class HeatChillStartProtocol(BaseModel):
-    vessel: str
+    # === 必需参数 ===
-    temp: float
+    vessel: str = Field(..., description="加热容器名称")
-    purpose: str
+
    # === 可选参数 - 温度相关 ===
    temp: float = Field(25.0, description="目标温度 (°C)")
    temp_spec: str = Field("", description="温度规格（如 'room temperature', 'reflux'）")
    # === 可选参数 - 其他XDL参数 ===
    pressure: str = Field("", description="压力规格（如 '1 mbar'），不做特殊处理")
    reflux_solvent: str = Field("", description="回流溶剂名称，不做特殊处理")
    # === 可选参数 - 搅拌相关 ===
    stir: bool = Field(False, description="是否搅拌")
    stir_speed: float = Field(300.0, description="搅拌速度 (RPM)")
    purpose: str = Field("", description="操作目的")
 class HeatChillStopProtocol(BaseModel):
-    vessel: str
+    # === 必需参数 ===
    vessel: str = Field(..., description="加热容器名称")
 class StirProtocol(BaseModel):
-    stir_time: float
+    # === 必需参数 ===
-    stir_speed: float
+    vessel: str = Field(..., description="搅拌容器名称")
-    settling_time: float
+    
    # === 可选参数 ===
    time: str = Field("5 min", description="搅拌时间（如 '0.5 h', '30 min'）")
    event: str = Field("", description="事件标识（如 'A', 'B'）")
    time_spec: str = Field("", description="时间规格（如 'several minutes', 'overnight'）")
    def model_post_init(self, __context):
        """后处理：参数验证和时间解析"""
        # 验证必需参数
        if not self.vessel.strip():
            raise ValueError("vessel 参数不能为空")
        # 优先使用 time_spec，然后是 time
        if self.time_spec:
            self.time = self.time_spec
        # 时间解析和验证
        if self.time:
            try:
                # 解析时间字符串为秒数
                parsed_time = self._parse_time_string(self.time)
                if parsed_time <= 0:
                    logger.warning(f"时间 '{self.time}' 解析结果无效，使用默认值 300s")
                    self.time = "5 min"
            except Exception as e:
                logger.warning(f"时间 '{self.time}' 解析失败: {e}，使用默认值 300s")
                self.time = "5 min"
    def _parse_time_string(self, time_str: str) -> float:
        """解析时间字符串为秒数"""
        import re
        time_str = time_str.strip().lower()
        # 特殊时间规格
        special_times = {
            "several minutes": 300.0,    # 5分钟
            "few minutes": 180.0,        # 3分钟
            "overnight": 43200.0,        # 12小时
            "room temperature": 300.0,   # 默认5分钟
        }
        if time_str in special_times:
            return special_times[time_str]
        # 正则表达式匹配数字和单位
        pattern = r'(\d+\.?\d*)\s*([a-zA-Z]+)'
        match = re.match(pattern, time_str)
        if not match:
            return 300.0  # 默认5分钟
        value = float(match.group(1))
        unit = match.group(2).lower()
        # 时间单位转换
        unit_multipliers = {
            's': 1.0,
            'sec': 1.0,
            'second': 1.0,
            'seconds': 1.0,
            'min': 60.0,
            'minute': 60.0,
            'minutes': 60.0,
            'h': 3600.0,
            'hr': 3600.0,
            'hour': 3600.0,
            'hours': 3600.0,
            'd': 86400.0,
            'day': 86400.0,
            'days': 86400.0,
        }
        multiplier = unit_multipliers.get(unit, 60.0)  # 默认按分钟计算
        return value * multiplier
    def get_time_in_seconds(self) -> float:
        """获取时间（秒）"""
        return self._parse_time_string(self.time)
 class StartStirProtocol(BaseModel):
-    vessel: str
+    # === 必需参数 ===
-    stir_speed: float
+    vessel: str = Field(..., description="搅拌容器名称")
-    purpose: str
+    
    # === 可选参数，添加默认值 ===
    stir_speed: float = Field(200.0, description="搅拌速度 (RPM)，默认200 RPM")
    purpose: str = Field("", description="搅拌目的（可选）")
    def model_post_init(self, __context):
        """后处理：参数验证和修正"""
        # 验证必需参数
        if not self.vessel.strip():
            raise ValueError("vessel 参数不能为空")
        # 修正参数范围
        if self.stir_speed < 10.0:
            logger.warning(f"搅拌速度 {self.stir_speed} RPM 过低，修正为 100 RPM")
            self.stir_speed = 100.0
        elif self.stir_speed > 1500.0:
            logger.warning(f"搅拌速度 {self.stir_speed} RPM 过高，修正为 1000 RPM")
            self.stir_speed = 1000.0
 class StopStirProtocol(BaseModel):
-    vessel: str
+    # === 必需参数 ===
    vessel: str = Field(..., description="搅拌容器名称")
    def model_post_init(self, __context):
        """后处理：参数验证"""
        # 验证必需参数
        if not self.vessel.strip():
            raise ValueError("vessel 参数不能为空")
 class TransferProtocol(BaseModel):
    from_vessel: str
@@ -137,45 +527,117 @@ class TransferProtocol(BaseModel):
    solid: bool = False
 class CleanVesselProtocol(BaseModel):
-    vessel: str                 # 要清洗的容器名称
+    vessel: str
-    solvent: str               # 用于清洗容器的溶剂名称
+    solvent: str
-    volume: float              # 清洗溶剂的体积，可选参数
+    volume: float
-    temp: float                # 清洗时的温度，可选参数
+    temp: float
-    repeats: int = 1           # 清洗操作的重复次数，默认为 1
+    repeats: int = 1
 class DissolveProtocol(BaseModel):
-    vessel: str                 # 装有要溶解物质的容器名称
+    vessel: str
-    solvent: str               # 用于溶解物质的溶剂名称
+    solvent: str
-    volume: float              # 溶剂的体积，可选参数
+    volume: float
-    amount: str = ""           # 要溶解物质的量，可选参数
+    amount: str = ""
-    temp: float = 25.0         # 溶解时的温度，可选参数
+    temp: float = 25.0
-    time: float = 0.0          # 溶解的时间，可选参数
+    time: float = 0.0
-    stir_speed: float = 0.0    # 搅拌速度，可选参数
+    stir_speed: float = 0.0
 class FilterThroughProtocol(BaseModel):
-    from_vessel: str              # 源容器的名称，即物质起始所在的容器
+    from_vessel: str
-    to_vessel: str                # 目标容器的名称，物质过滤后要到达的容器
+    to_vessel: str
-    filter_through: str           # 过滤时所通过的介质，如滤纸、柱子等
+    filter_through: str
-    eluting_solvent: str = ""     # 洗脱溶剂的名称，可选参数
+    eluting_solvent: str = ""
-    eluting_volume: float = 0.0   # 洗脱溶剂的体积，可选参数
+    eluting_volume: float = 0.0
-    eluting_repeats: int = 0      # 洗脱操作的重复次数，默认为 0
+    eluting_repeats: int = 0
-    residence_time: float = 0.0   # 物质在过滤介质中的停留时间，可选参数
+    residence_time: float = 0.0
 class RunColumnProtocol(BaseModel):
-    from_vessel: str              # 源容器的名称，即样品起始所在的容器
+    from_vessel: str
-    to_vessel: str                # 目标容器的名称，分离后的样品要到达的容器
+    to_vessel: str
-    column: str                   # 所使用的柱子的名称
+    column: str
 class WashSolidProtocol(BaseModel):
-    vessel: str                   # 装有固体物质的容器名称
+    # === 必需参数 ===
-    solvent: str                  # 用于清洗固体的溶剂名称
+    vessel: str = Field(..., description="装有固体的容器名称")
-    volume: float                 # 清洗溶剂的体积
+    solvent: str = Field(..., description="清洗溶剂名称")
-    filtrate_vessel: str = ""     # 滤液要收集到的容器名称，可选参数
+    volume: float = Field(..., description="清洗溶剂体积 (mL)")
    temp: float = 25.0            # 清洗时的温度，可选参数
    stir: bool = False            # 是否在清洗过程中搅拌，默认为 False
    stir_speed: float = 0.0       # 搅拌速度，可选参数
    time: float = 0.0             # 清洗的时间，可选参数
    repeats: int = 1              # 清洗操作的重复次数，默认为 1
-__all__ = ["Point3D", "PumpTransferProtocol", "CleanProtocol", "SeparateProtocol", "EvaporateProtocol", "EvacuateAndRefillProtocol", "AGVTransferProtocol", "CentrifugeProtocol", "AddProtocol", "FilterProtocol", "HeatChillProtocol", "HeatChillStartProtocol", "HeatChillStopProtocol", "StirProtocol", "StartStirProtocol", "StopStirProtocol", "TransferProtocol", "CleanVesselProtocol", "DissolveProtocol", "FilterThroughProtocol", "RunColumnProtocol", "WashSolidProtocol"]
+    # === 可选参数，添加默认值 ===
    filtrate_vessel: str = Field("", description="滤液收集容器（可选，自动查找）")
    temp: float = Field(25.0, description="清洗温度 (°C)，默认25°C")
    stir: bool = Field(False, description="是否搅拌，默认False")
    stir_speed: float = Field(0.0, description="搅拌速度 (RPM)，默认0")
    time: float = Field(0.0, description="清洗时间 (秒)，默认0")
    repeats: int = Field(1, description="重复次数，默认1")
    def model_post_init(self, __context):
        """后处理：参数验证和修正"""
        # 验证必需参数
        if not self.vessel.strip():
            raise ValueError("vessel 参数不能为空")
        if not self.solvent.strip():
            raise ValueError("solvent 参数不能为空")
        if self.volume <= 0:
            raise ValueError("volume 必须大于0")
        # 修正参数范围
        if self.temp < 0 or self.temp > 200:
            logger.warning(f"温度 {self.temp}°C 超出范围，修正为 25°C")
            self.temp = 25.0
        if self.stir_speed < 0 or self.stir_speed > 500:
            logger.warning(f"搅拌速度 {self.stir_speed} RPM 超出范围，修正为 0")
            self.stir_speed = 0.0
        if self.time < 0:
            logger.warning(f"时间 {self.time}s 无效，修正为 0")
            self.time = 0.0
        if self.repeats < 1:
            logger.warning(f"重复次数 {self.repeats} 无效，修正为 1")
            self.repeats = 1
        elif self.repeats > 10:
            logger.warning(f"重复次数 {self.repeats} 过多，修正为 10")
            self.repeats = 10
 class AdjustPHProtocol(BaseModel):
    vessel: str = Field(..., description="目标容器")
    ph_value: float = Field(..., description="目标pH值")  # 改为 ph_value
    reagent: str = Field(..., description="酸碱试剂名称")
    # 移除其他可选参数，使用默认值
 class ResetHandlingProtocol(BaseModel):
    solvent: str = Field(..., description="溶剂名称")
 class DryProtocol(BaseModel):
    compound: str = Field(..., description="化合物名称")
    vessel: str = Field(..., description="目标容器")
 class RecrystallizeProtocol(BaseModel):
    ratio: str = Field(..., description="溶剂比例（如 '1:1', '3:7'）")
    solvent1: str = Field(..., description="第一种溶剂名称")
    solvent2: str = Field(..., description="第二种溶剂名称")
    vessel: str = Field(..., description="目标容器")
    volume: float = Field(..., description="总体积 (mL)")
 class HydrogenateProtocol(BaseModel):
    temp: str = Field(..., description="反应温度（如 '45 °C'）")
    time: str = Field(..., description="反应时间（如 '2 h'）")
    vessel: str = Field(..., description="反应容器")
 __all__ = [
    "Point3D", "PumpTransferProtocol", "CleanProtocol", "SeparateProtocol", 
    "EvaporateProtocol", "EvacuateAndRefillProtocol", "AGVTransferProtocol", 
    "CentrifugeProtocol", "AddProtocol", "FilterProtocol", 
    "HeatChillProtocol",
    "HeatChillStartProtocol", "HeatChillStopProtocol",
    "StirProtocol", "StartStirProtocol", "StopStirProtocol", 
    "TransferProtocol", "CleanVesselProtocol", "DissolveProtocol", 
    "FilterThroughProtocol", "RunColumnProtocol", "WashSolidProtocol",
    "AdjustPHProtocol", "ResetHandlingProtocol", "DryProtocol", 
    "RecrystallizeProtocol", "HydrogenateProtocol"
 ]
 # End Protocols
--- a/unilabos/registry/device_comms/modbus_ioboard.yaml
+++ b/unilabos/registry/device_comms/modbus_ioboard.yaml
@@ -1,10 +1,10 @@
-io_snrd:
+#io_snrd:
-  description: IO Board with 16 IOs
+#  description: IO Board with 16 IOs
-  class:
+#  class:
-    module: ilabos.device_comms.SRND_16_IO:SRND_16_IO
+#    module: unilabos.device_comms.SRND_16_IO:SRND_16_IO
-    type: python
+#    type: python
-    hardware_interface:
+#    hardware_interface:
-      name: modbus_client
+#      name: modbus_client
-      extra_info: []
+#      extra_info: []
-      read: read_io_coil
+#      read: read_io_coil
-      write: write_io_coil
+#      write: write_io_coil
--- a/unilabos/registry/device_comms/serial.yaml
+++ b/unilabos/registry/device_comms/serial.yaml
@@ -1,7 +1,103 @@
 serial:
  description: Serial communication interface, used when sharing same serial port for multiple devices
  class:
    action_value_mappings:
      auto-handle_serial_request:
        feedback: {}
        goal: {}
        goal_default:
          request: null
          response: null
        handles: []
        result: {}
        schema:
          description: handle_serial_request的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                request:
                  type: string
                response:
                  type: string
              required:
              - request
              - response
              type: object
            result: {}
          required:
          - goal
          title: handle_serial_request参数
          type: object
        type: UniLabJsonCommand
      auto-read_data:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: read_data的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: read_data参数
          type: object
        type: UniLabJsonCommand
      auto-send_command:
        feedback: {}
        goal: {}
        goal_default:
          command: null
        handles: []
        result: {}
        schema:
          description: send_command的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              type: object
            result: {}
          required:
          - goal
          title: send_command参数
          type: object
        type: UniLabJsonCommand
    module: unilabos.ros.nodes.presets.serial_node:ROS2SerialNode
    status_types: {}
    type: ros2
-  schema:
+  description: Serial communication interface, used when sharing same serial port
-    properties: {}
+    for multiple devices
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        baudrate:
          default: 9600
          type: integer
        device_id:
          type: string
        port:
          type: string
        resource_tracker:
          type: string
      required:
      - device_id
      - port
      type: object
    data:
      properties: {}
      required: []
      type: object
  version: 0.0.1
--- a/unilabos/registry/devices/camera.yaml
+++ b/unilabos/registry/devices/camera.yaml
@@ -0,0 +1,70 @@
 camera:
  class:
    action_value_mappings:
      auto-destroy_node:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: 用于安全地关闭摄像头设备，释放摄像头资源，停止视频采集和发布服务。调用此函数将清理OpenCV摄像头连接并销毁ROS2节点。
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: destroy_node参数
          type: object
        type: UniLabJsonCommand
      auto-timer_callback:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: 定时器回调函数的参数schema。此函数负责定期采集摄像头视频帧，将OpenCV格式的图像转换为ROS Image消息格式，并发布到指定的视频话题。默认以10Hz频率执行，确保视频流的连续性和实时性。
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: timer_callback参数
          type: object
        type: UniLabJsonCommand
    module: unilabos.ros.nodes.presets.camera:VideoPublisher
    status_types: {}
    type: ros2
  description: VideoPublisher摄像头设备节点，用于实时视频采集和流媒体发布。该设备通过OpenCV连接本地摄像头（如USB摄像头、内置摄像头等），定时采集视频帧并将其转换为ROS2的sensor_msgs/Image消息格式发布到视频话题。主要用于实验室自动化系统中的视觉监控、图像分析、实时观察等应用场景。支持可配置的摄像头索引、发布频率等参数。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        camera_index:
          default: 0
          type: string
        device_id:
          default: video_publisher
          type: string
        period:
          default: 0.1
          type: number
        resource_tracker:
          type: string
      required: []
      type: object
    data:
      properties: {}
      required: []
      type: object
  version: 0.0.1
--- a/unilabos/registry/devices/characterization_optic.yaml
+++ b/unilabos/registry/devices/characterization_optic.yaml
@@ -1,67 +1,405 @@
 # 光学表征设备：红外、紫外可见、拉曼等
 raman_home_made:
  description: Raman spectroscopy device
  class:
    module: unilabos.devices.raman_uv.home_made_raman:RamanObj
    type: python
    status_types:
      status: String
    action_value_mappings:
      raman_cmd:
        type: SendCmd
        goal:
          command: command
        feedback: {}
        result:
          success: success
  schema:
    properties:
      status:
        type: string
    required:
    - status
    additionalProperties: false
    type: object
 hplc.agilent:
  description: HPLC device
  class:
    module: unilabos.devices.hplc.AgilentHPLC:HPLCDriver
    type: python
    status_types:
      device_status: String
      could_run: Bool
      driver_init_ok: Bool
      is_running: Bool
      finish_status: String
      status_text: String
    action_value_mappings:
      auto-check_status:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: 检查安捷伦HPLC设备状态的函数。用于监控设备的运行状态、连接状态、错误信息等关键指标。该函数定期查询设备状态，确保系统稳定运行，及时发现和报告设备异常。适用于自动化流程中的设备监控、故障诊断、系统维护等场景。
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: check_status参数
          type: object
        type: UniLabJsonCommand
      auto-extract_data_from_txt:
        feedback: {}
        goal: {}
        goal_default:
          file_path: null
        handles: []
        result: {}
        schema:
          description: 从文本文件中提取分析数据的函数。用于解析安捷伦HPLC生成的结果文件，提取峰面积、保留时间、浓度等关键分析数据。支持多种文件格式的自动识别和数据结构化处理，为后续数据分析和报告生成提供标准化的数据格式。适用于批量数据处理、结果验证、质量控制等分析工作流程。
          properties:
            feedback: {}
            goal:
              properties:
                file_path:
                  type: string
              required:
              - file_path
              type: object
            result: {}
          required:
          - goal
          title: extract_data_from_txt参数
          type: object
        type: UniLabJsonCommand
      auto-start_sequence:
        feedback: {}
        goal: {}
        goal_default:
          params: null
          resource: null
          wf_name: null
        handles: []
        result: {}
        schema:
          description: 启动安捷伦HPLC分析序列的函数。用于执行预定义的分析方法序列，包括样品进样、色谱分离、检测等完整的分析流程。支持参数配置、资源分配、工作流程管理等功能，实现全自动的样品分析。适用于批量样品处理、标准化分析、质量检测等需要连续自动分析的应用场景。
          properties:
            feedback: {}
            goal:
              properties:
                params:
                  type: string
                resource:
                  type: object
                wf_name:
                  type: string
              required:
              - wf_name
              type: object
            result: {}
          required:
          - goal
          title: start_sequence参数
          type: object
        type: UniLabJsonCommand
      auto-try_close_sub_device:
        feedback: {}
        goal: {}
        goal_default:
          device_name: null
        handles: []
        result: {}
        schema:
          description: 尝试关闭HPLC子设备的函数。用于安全地关闭泵、检测器、进样器等各个子模块，确保设备正常断开连接并保护硬件安全。该函数提供错误处理和状态确认机制，避免强制关闭可能造成的设备损坏。适用于设备维护、系统重启、紧急停机等需要安全关闭设备的场景。
          properties:
            feedback: {}
            goal:
              properties:
                device_name:
                  type: string
              required: []
              type: object
            result: {}
          required:
          - goal
          title: try_close_sub_device参数
          type: object
        type: UniLabJsonCommand
      auto-try_open_sub_device:
        feedback: {}
        goal: {}
        goal_default:
          device_name: null
        handles: []
        result: {}
        schema:
          description: 尝试打开HPLC子设备的函数。用于初始化和连接泵、检测器、进样器等各个子模块，建立设备通信并进行自检。该函数提供连接验证和错误恢复机制，确保子设备正常启动并准备就绪。适用于设备初始化、系统启动、设备重连等需要建立设备连接的场景。
          properties:
            feedback: {}
            goal:
              properties:
                device_name:
                  type: string
              required: []
              type: object
            result: {}
          required:
          - goal
          title: try_open_sub_device参数
          type: object
        type: UniLabJsonCommand
      execute_command_from_outer:
-        type: SendCmd
+        feedback: {}
        goal:
          command: command
-        feedback: {}
+        goal_default:
          command: ''
        handles: []
        result:
          success: success
-  schema:
+        schema:
-    properties:
+          description: ''
-      device_status:
+          properties:
-        type: string
+            feedback:
-      could_run:
+              properties:
-        type: boolean
+                status:
-      driver_init_ok:
+                  type: string
-        type: boolean
+              required:
-      is_running:
+              - status
-        type: boolean
+              title: SendCmd_Feedback
-      finish_status:
+              type: object
-        type: string
+            goal:
-      status_text:
+              properties:
-        type: string
+                command:
-    required:
+                  type: string
-    - device_status
+              required:
-    - could_run
+              - command
-    - driver_init_ok
+              title: SendCmd_Goal
-    - is_running
+              type: object
-    - finish_status
+            result:
-    - status_text
+              properties:
-    additionalProperties: false
+                return_info:
-    type: object
+                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.hplc.AgilentHPLC:HPLCDriver
    status_types:
      could_run: bool
      data_file: list
      device_status: str
      driver_init_ok: bool
      finish_status: str
      is_running: bool
      status_text: str
      success: bool
    type: python
  description: 安捷伦高效液相色谱（HPLC）分析设备，用于复杂化合物的分离、检测和定量分析。该设备通过UI自动化技术控制安捷伦ChemStation软件，实现全自动的样品分析流程。具备序列启动、设备状态监控、数据文件提取、结果处理等功能。支持多样品批量处理和实时状态反馈，适用于药物分析、环境检测、食品安全、化学研究等需要高精度色谱分析的实验室应用。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        driver_debug:
          default: false
          type: string
      required: []
      type: object
    data:
      properties:
        could_run:
          type: boolean
        data_file:
          type: array
        device_status:
          type: string
        driver_init_ok:
          type: boolean
        finish_status:
          type: string
        is_running:
          type: boolean
        status_text:
          type: string
        success:
          type: boolean
      required:
      - status_text
      - device_status
      - could_run
      - driver_init_ok
      - is_running
      - success
      - finish_status
      - data_file
      type: object
  version: 0.0.1
 raman_home_made:
  class:
    action_value_mappings:
      auto-ccd_time:
        feedback: {}
        goal: {}
        goal_default:
          int_time: null
        handles: []
        result: {}
        schema:
          description: 设置CCD检测器积分时间的函数。用于配置拉曼光谱仪的信号采集时间，控制光谱数据的质量和信噪比。较长的积分时间可获得更高的信号强度和更好的光谱质量，但会增加测量时间。该函数允许根据样品特性和测量要求动态调整检测参数，优化测量效果。
          properties:
            feedback: {}
            goal:
              properties:
                int_time:
                  type: string
              required:
              - int_time
              type: object
            result: {}
          required:
          - goal
          title: ccd_time参数
          type: object
        type: UniLabJsonCommand
      auto-laser_on_power:
        feedback: {}
        goal: {}
        goal_default:
          output_voltage_laser: null
        handles: []
        result: {}
        schema:
          description: 设置激光器输出功率的函数。用于控制拉曼光谱仪激光器的功率输出，调节激光强度以适应不同样品的测量需求。适当的激光功率能够获得良好的拉曼信号同时避免样品损伤。该函数支持精确的功率控制，确保测量结果的稳定性和重现性。
          properties:
            feedback: {}
            goal:
              properties:
                output_voltage_laser:
                  type: string
              required:
              - output_voltage_laser
              type: object
            result: {}
          required:
          - goal
          title: laser_on_power参数
          type: object
        type: UniLabJsonCommand
      auto-raman_without_background:
        feedback: {}
        goal: {}
        goal_default:
          int_time: null
          laser_power: null
        handles: []
        result: {}
        schema:
          description: 执行无背景扣除的拉曼光谱测量函数。用于直接采集样品的拉曼光谱信号，不进行背景校正处理。该函数配置积分时间和激光功率参数，获取原始光谱数据用于后续的数据处理分析。适用于对光谱数据质量要求较高或需要自定义背景处理流程的测量场景。
          properties:
            feedback: {}
            goal:
              properties:
                int_time:
                  type: string
                laser_power:
                  type: string
              required:
              - int_time
              - laser_power
              type: object
            result: {}
          required:
          - goal
          title: raman_without_background参数
          type: object
        type: UniLabJsonCommand
      auto-raman_without_background_average:
        feedback: {}
        goal: {}
        goal_default:
          average: null
          int_time: null
          laser_power: null
          sample_name: null
        handles: []
        result: {}
        schema:
          description: 执行多次平均的无背景拉曼光谱测量函数。通过多次测量取平均值来提高光谱数据的信噪比和测量精度，减少随机噪声影响。该函数支持自定义平均次数、积分时间、激光功率等参数，并可为样品指定名称便于数据管理。适用于对测量精度要求较高的定量分析和研究应用。
          properties:
            feedback: {}
            goal:
              properties:
                average:
                  type: string
                int_time:
                  type: string
                laser_power:
                  type: string
                sample_name:
                  type: string
              required:
              - sample_name
              - int_time
              - laser_power
              - average
              type: object
            result: {}
          required:
          - goal
          title: raman_without_background_average参数
          type: object
        type: UniLabJsonCommand
      raman_cmd:
        feedback: {}
        goal:
          command: command
        goal_default:
          command: ''
        handles: []
        result:
          success: success
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.raman_uv.home_made_raman:RamanObj
    status_types: {}
    type: python
  description: 拉曼光谱分析设备，用于物质的分子结构和化学成分表征。该设备集成激光器和CCD检测器，通过串口通信控制激光功率和光谱采集。具备背景扣除、多次平均、自动数据处理等功能，支持高精度的拉曼光谱测量。适用于材料表征、化学分析、质量控制、研究开发等需要分子指纹识别和结构分析的实验应用。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        baudrate_ccd:
          default: 921600
          type: string
        baudrate_laser:
          default: 9600
          type: string
        port_ccd:
          type: string
        port_laser:
          type: string
      required:
      - port_laser
      - port_ccd
      type: object
    data:
      properties: {}
      required: []
      type: object
  version: 0.0.1
--- a/unilabos/registry/devices/hotel.yaml
+++ b/unilabos/registry/devices/hotel.yaml
@@ -1,9 +1,32 @@
 hotel.thermo_orbitor_rs2_hotel:
  description: Thermo Orbitor RS2 Hotel
  class:
    action_value_mappings: {}
    module: unilabos.devices.resource_container.container:HotelContainer
    status_types:
      rotation: String
    type: python
  description: Thermo Orbitor RS2 Hotel容器设备，用于实验室样品的存储和管理。该设备通过HotelContainer类实现容器的旋转控制和状态监控，主要用于存储实验样品、试剂瓶或其他实验器具，支持旋转功能以便于样品的自动化存取。适用于需要有序存储和快速访问大量样品的实验室自动化场景。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        device_config:
          type: object
        rotation:
          type: object
      required:
      - rotation
      - device_config
      type: object
    data:
      properties:
        rotation:
          type: string
      required:
      - rotation
      type: object
  model:
    type: device
    mesh: thermo_orbitor_rs2_hotel
-
+    type: device
  version: 0.0.1
--- a/unilabos/registry/devices/laiyu_add_solid.yaml
+++ b/unilabos/registry/devices/laiyu_add_solid.yaml
@@ -1,56 +1,382 @@
 laiyu_add_solid:
  description: Laiyu Add Solid
  class:
    module: unilabos.devices.laiyu_add_solid.laiyu:Laiyu
    type: python
    status_types: {}
    action_value_mappings:
      add_powder_tube:
        feedback: {}
        goal:
          compound_mass: compound_mass
          powder_tube_number: powder_tube_number
          target_tube_position: target_tube_position
        goal_default:
          compound_mass: 0.0
          powder_tube_number: 0
          target_tube_position: ''
        handles: []
        result:
          actual_mass_mg: actual_mass_mg
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: SolidDispenseAddPowderTube_Feedback
              type: object
            goal:
              properties:
                compound_mass:
                  type: number
                powder_tube_number:
                  maximum: 2147483647
                  minimum: -2147483648
                  type: integer
                target_tube_position:
                  type: string
              required:
              - powder_tube_number
              - target_tube_position
              - compound_mass
              title: SolidDispenseAddPowderTube_Goal
              type: object
            result:
              properties:
                actual_mass_mg:
                  type: number
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - actual_mass_mg
              - success
              title: SolidDispenseAddPowderTube_Result
              type: object
          required:
          - goal
          title: SolidDispenseAddPowderTube
          type: object
        type: SolidDispenseAddPowderTube
      auto-calculate_crc:
        feedback: {}
        goal: {}
        goal_default:
          data: null
        handles: []
        result: {}
        schema:
          description: Modbus CRC-16校验码计算函数。计算Modbus RTU通信协议所需的CRC-16校验码，确保数据传输的完整性和可靠性。该函数实现标准的CRC-16算法，用于构造完整的Modbus指令帧。
          properties:
            feedback: {}
            goal:
              properties:
                data:
                  type: string
              required:
              - data
              type: object
            result: {}
          required:
          - goal
          title: calculate_crc参数
          type: object
        type: UniLabJsonCommand
      auto-send_command:
        feedback: {}
        goal: {}
        goal_default:
          command: null
        handles: []
        result: {}
        schema:
          description: Modbus指令发送函数。构造完整的Modbus RTU指令帧（包含CRC校验），发送给分装设备并等待响应。该函数处理底层通信协议，确保指令的正确传输和响应接收，支持最长3分钟的响应等待时间。
          properties:
            feedback: {}
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              type: object
            result: {}
          required:
          - goal
          title: send_command参数
          type: object
        type: UniLabJsonCommand
      discharge:
        feedback: {}
        goal:
          float_input: float_input
        goal_default:
          float_in: 0.0
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: FloatSingleInput_Feedback
              type: object
            goal:
              properties:
                float_in:
                  type: number
              required:
              - float_in
              title: FloatSingleInput_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: FloatSingleInput_Result
              type: object
          required:
          - goal
          title: FloatSingleInput
          type: object
        type: FloatSingleInput
      move_to_plate:
        feedback: {}
        goal:
          string: string
        goal_default:
          string: ''
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: StrSingleInput_Feedback
              type: object
            goal:
              properties:
                string:
                  type: string
              required:
              - string
              title: StrSingleInput_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: StrSingleInput_Result
              type: object
          required:
          - goal
          title: StrSingleInput
          type: object
        type: StrSingleInput
      move_to_xyz:
-        type: Point3DSeparateInput
+        feedback: {}
        goal:
          x: x
          y: y
          z: z
-        feedback: {}
+        goal_default:
          x: 0.0
          y: 0.0
          z: 0.0
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: Point3DSeparateInput_Feedback
              type: object
            goal:
              properties:
                x:
                  type: number
                y:
                  type: number
                z:
                  type: number
              required:
              - x
              - y
              - z
              title: Point3DSeparateInput_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: Point3DSeparateInput_Result
              type: object
          required:
          - goal
          title: Point3DSeparateInput
          type: object
        type: Point3DSeparateInput
      pick_powder_tube:
-        type: IntSingleInput
+        feedback: {}
        goal:
          int_input: int_input
-        feedback: {}
+        goal_default:
          int_input: 0
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: IntSingleInput_Feedback
              type: object
            goal:
              properties:
                int_input:
                  maximum: 2147483647
                  minimum: -2147483648
                  type: integer
              required:
              - int_input
              title: IntSingleInput_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: IntSingleInput_Result
              type: object
          required:
          - goal
          title: IntSingleInput
          type: object
        type: IntSingleInput
      put_powder_tube:
-        type: IntSingleInput
+        feedback: {}
        goal:
          int_input: int_input
-        feedback: {}
+        goal_default:
          int_input: 0
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: IntSingleInput_Feedback
              type: object
            goal:
              properties:
                int_input:
                  maximum: 2147483647
                  minimum: -2147483648
                  type: integer
              required:
              - int_input
              title: IntSingleInput_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: IntSingleInput_Result
              type: object
          required:
          - goal
          title: IntSingleInput
          type: object
        type: IntSingleInput
      reset:
-        type: EmptyIn
+        feedback: {}
        goal: {}
-        feedback: {}
+        goal_default: {}
        handles: []
        result: {}
-      add_powder_tube:
+        schema:
-        type: SolidDispenseAddPowderTube
+          description: ''
-        goal:
+          properties:
-          powder_tube_number: powder_tube_number
+            feedback:
-          target_tube_position: target_tube_position
+              properties: {}
-          compound_mass: compound_mass
+              required: []
-        feedback: {}
+              title: EmptyIn_Feedback
-        result: 
+              type: object
-          actual_mass_mg: actual_mass_mg
+            goal:
-      move_to_plate:
+              properties: {}
-        type: StrSingleInput
+              required: []
-        goal:
+              title: EmptyIn_Goal
-          string: string
+              type: object
-        feedback: {}
+            result:
-        result: {}
+              properties:
-      discharge:
+                return_info:
-        type: FloatSingleInput
+                  type: string
-        goal:
+              required:
-          float_input: float_input
+              - return_info
-        feedback: {}
+              title: EmptyIn_Result
-        result: {}
+              type: object
-        
+          required:
-  schema:
+          - goal
-    properties: {}
+          title: EmptyIn
          type: object
        type: EmptyIn
    module: unilabos.devices.laiyu_add_solid.laiyu:Laiyu
    status_types:
      status: str
    type: python
  description: 来渝固体粉末自动分装设备，用于实验室化学试剂的精确称量和分装。该设备通过Modbus RTU协议与控制系统通信，集成了精密天平、三轴运动平台、粉筒管理系统等组件。支持多种粉末试剂的自动拿取、精确称量、定点分装和归位操作。具备高精度称量、位置控制和批量处理能力，适用于化学合成、药物研发、材料制备等需要精确固体试剂配制的实验室应用场景。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        baudrate:
          default: 115200
          type: string
        port:
          type: string
        timeout:
          default: 0.5
          type: string
      required:
      - port
      type: object
    data:
      properties:
        status:
          type: string
      required:
      - status
      type: object
  version: 0.0.1
--- a/unilabos/registry/devices/liquid_handler.yaml
+++ b/unilabos/registry/devices/liquid_handler.yaml
--- a/unilabos/registry/devices/mock_devices.yaml
+++ b/unilabos/registry/devices/mock_devices.yaml
--- a/unilabos/registry/devices/moveit_config.yaml
+++ b/unilabos/registry/devices/moveit_config.yaml
@@ -1,56 +1,698 @@
 moveit.toyo_xyz:
  description: Toyo XYZ
  class:
    module: unilabos.devices.ros_dev.moveit_interface:MoveitInterface
    type: python
    action_value_mappings:
      set_position:
        type: SendCmd
        goal:
          command: command
        feedback: { }
        result: { }
      pick_and_place:
        type: SendCmd
        goal:
          command: command
        feedback: { }
        result: { }
      set_status:
        type: SendCmd
        goal:
          command: command
        feedback: { }
        result: { }
  model:
    type: device
    mesh: toyo_xyz
 moveit.arm_slider:
  description: Arm with Slider
  model:
    type: device
    mesh: arm_slider
  class:
    module: unilabos.devices.ros_dev.moveit_interface:MoveitInterface
    type: python
    action_value_mappings:
-      set_position:
+      auto-check_tf_update_actions:
        type: SendCmd
        goal:
          command: command
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: check_tf_update_actions的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: check_tf_update_actions参数
          type: object
        type: UniLabJsonCommand
      auto-moveit_joint_task:
        feedback: {}
        goal: {}
        goal_default:
          joint_names: null
          joint_positions: null
          move_group: null
          retry: 10
          speed: 1
        handles: []
        result: {}
        schema:
          description: moveit_joint_task的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                joint_names:
                  type: string
                joint_positions:
                  type: string
                move_group:
                  type: string
                retry:
                  default: 10
                  type: string
                speed:
                  default: 1
                  type: string
              required:
              - move_group
              - joint_positions
              type: object
            result: {}
          required:
          - goal
          title: moveit_joint_task参数
          type: object
        type: UniLabJsonCommand
      auto-moveit_task:
        feedback: {}
        goal: {}
        goal_default:
          cartesian: false
          move_group: null
          offsets:
          - 0
          - 0
          - 0
          position: null
          quaternion: null
          retry: 10
          speed: 1
          target_link: null
        handles: []
        result: {}
        schema:
          description: moveit_task的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                cartesian:
                  default: false
                  type: string
                move_group:
                  type: string
                offsets:
                  default:
                  - 0
                  - 0
                  - 0
                  type: string
                position:
                  type: string
                quaternion:
                  type: string
                retry:
                  default: 10
                  type: string
                speed:
                  default: 1
                  type: string
                target_link:
                  type: string
              required:
              - move_group
              - position
              - quaternion
              type: object
            result: {}
          required:
          - goal
          title: moveit_task参数
          type: object
        type: UniLabJsonCommand
      auto-post_init:
        feedback: {}
        goal: {}
        goal_default:
          ros_node: null
        handles: []
        result: {}
        schema:
          description: post_init的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                ros_node:
                  type: string
              required:
              - ros_node
              type: object
            result: {}
          required:
          - goal
          title: post_init参数
          type: object
        type: UniLabJsonCommand
      auto-resource_manager:
        feedback: {}
        goal: {}
        goal_default:
          parent_link: null
          resource: null
        handles: []
        result: {}
        schema:
          description: resource_manager的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                parent_link:
                  type: string
                resource:
                  type: string
              required:
              - resource
              - parent_link
              type: object
            result: {}
          required:
          - goal
          title: resource_manager参数
          type: object
        type: UniLabJsonCommand
      auto-wait_for_resource_action:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: wait_for_resource_action的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: wait_for_resource_action参数
          type: object
        type: UniLabJsonCommand
      pick_and_place:
-        type: SendCmd
+        feedback: {}
        goal:
          command: command
-        feedback: {}
+        goal_default:
          command: ''
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
      set_position:
        feedback: {}
        goal:
          command: command
        goal_default:
          command: ''
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
      set_status:
-        type: SendCmd
+        feedback: {}
        goal:
          command: command
-        feedback: {}
+        goal_default:
          command: ''
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.ros_dev.moveit_interface:MoveitInterface
    status_types: {}
    type: python
  description: 机械臂与滑块运动系统，基于MoveIt2运动规划框架的多自由度机械臂控制设备。该系统集成机械臂和线性滑块，通过ROS2和MoveIt2实现精确的轨迹规划和协调运动控制。支持笛卡尔空间和关节空间的运动规划、碰撞检测、逆运动学求解等功能。适用于复杂的pick-and-place操作、精密装配、多工位协作等需要高精度多轴协调运动的实验室自动化应用。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        device_config:
          type: string
        joint_poses:
          type: string
        moveit_type:
          type: string
        rotation:
          type: string
      required:
      - moveit_type
      - joint_poses
      type: object
    data:
      properties: {}
      required: []
      type: object
  model:
    mesh: arm_slider
    type: device
  version: 0.0.1
 moveit.toyo_xyz:
  class:
    action_value_mappings:
      auto-check_tf_update_actions:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: check_tf_update_actions的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: check_tf_update_actions参数
          type: object
        type: UniLabJsonCommand
      auto-moveit_joint_task:
        feedback: {}
        goal: {}
        goal_default:
          joint_names: null
          joint_positions: null
          move_group: null
          retry: 10
          speed: 1
        handles: []
        result: {}
        schema:
          description: moveit_joint_task的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                joint_names:
                  type: string
                joint_positions:
                  type: string
                move_group:
                  type: string
                retry:
                  default: 10
                  type: string
                speed:
                  default: 1
                  type: string
              required:
              - move_group
              - joint_positions
              type: object
            result: {}
          required:
          - goal
          title: moveit_joint_task参数
          type: object
        type: UniLabJsonCommand
      auto-moveit_task:
        feedback: {}
        goal: {}
        goal_default:
          cartesian: false
          move_group: null
          offsets:
          - 0
          - 0
          - 0
          position: null
          quaternion: null
          retry: 10
          speed: 1
          target_link: null
        handles: []
        result: {}
        schema:
          description: moveit_task的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                cartesian:
                  default: false
                  type: string
                move_group:
                  type: string
                offsets:
                  default:
                  - 0
                  - 0
                  - 0
                  type: string
                position:
                  type: string
                quaternion:
                  type: string
                retry:
                  default: 10
                  type: string
                speed:
                  default: 1
                  type: string
                target_link:
                  type: string
              required:
              - move_group
              - position
              - quaternion
              type: object
            result: {}
          required:
          - goal
          title: moveit_task参数
          type: object
        type: UniLabJsonCommand
      auto-post_init:
        feedback: {}
        goal: {}
        goal_default:
          ros_node: null
        handles: []
        result: {}
        schema:
          description: post_init的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                ros_node:
                  type: string
              required:
              - ros_node
              type: object
            result: {}
          required:
          - goal
          title: post_init参数
          type: object
        type: UniLabJsonCommand
      auto-resource_manager:
        feedback: {}
        goal: {}
        goal_default:
          parent_link: null
          resource: null
        handles: []
        result: {}
        schema:
          description: resource_manager的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                parent_link:
                  type: string
                resource:
                  type: string
              required:
              - resource
              - parent_link
              type: object
            result: {}
          required:
          - goal
          title: resource_manager参数
          type: object
        type: UniLabJsonCommand
      auto-wait_for_resource_action:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: wait_for_resource_action的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: wait_for_resource_action参数
          type: object
        type: UniLabJsonCommand
      pick_and_place:
        feedback: {}
        goal:
          command: command
        goal_default:
          command: ''
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
      set_position:
        feedback: {}
        goal:
          command: command
        goal_default:
          command: ''
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
      set_status:
        feedback: {}
        goal:
          command: command
        goal_default:
          command: ''
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.ros_dev.moveit_interface:MoveitInterface
    status_types: {}
    type: python
  description: 东洋XYZ三轴运动平台，基于MoveIt2运动规划框架的精密定位设备。该设备通过ROS2和MoveIt2实现三维空间的精确运动控制，支持复杂轨迹规划、多点定位、速度控制等功能。具备高精度定位、平稳运动、实时轨迹监控等特性。适用于精密加工、样品定位、检测扫描、自动化装配等需要高精度三维运动控制的实验室和工业应用场景。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        device_config:
          type: string
        joint_poses:
          type: string
        moveit_type:
          type: string
        rotation:
          type: string
      required:
      - moveit_type
      - joint_poses
      type: object
    data:
      properties: {}
      required: []
      type: object
  model:
    mesh: toyo_xyz
    type: device
  version: 0.0.1
--- a/unilabos/registry/devices/organic_miscellaneous.yaml
+++ b/unilabos/registry/devices/organic_miscellaneous.yaml
@@ -1,73 +1,364 @@
 separator.homemade:
  description: Separator device with homemade grbl controller
  class:
    module: unilabos.devices.separator.homemade_grbl_conductivity:SeparatorController
    type: python
    status_types:
      sensordata: Float64
      status: String
    action_value_mappings:
      stir:
        type: Stir
        goal:
          stir_time: stir_time,
          stir_speed: stir_speed
          settling_time: settling_time
        feedback:
          status: status
        result: 
          success: success
      valve_open_cmd:
        type: SendCmd
        goal: 
          command: command
        feedback: 
          status: status
        result": 
          success: success
  schema:
    type: object
    properties:
      status:
        type: string
        description: The status of the device
      sensordata:
        type: number
        description: 电导传感器数据
    required:
      - status
      - sensordata
    additionalProperties: false
 rotavap.one:
  description: Rotavap device
  class:
    module: unilabos.devices.rotavap.rotavap_one:RotavapOne
    type: python
    status_types:
      pump_time: Float64
      rotate_time: Float64
    action_value_mappings:
      auto-cmd_write:
        feedback: {}
        goal: {}
        goal_default:
          cmd: null
        handles: []
        result: {}
        schema:
          description: cmd_write的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                cmd:
                  type: string
              required:
              - cmd
              type: object
            result: {}
          required:
          - goal
          title: cmd_write参数
          type: object
        type: UniLabJsonCommand
      auto-main_loop:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: main_loop的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: main_loop参数
          type: object
        type: UniLabJsonCommand
      auto-set_pump_time:
        feedback: {}
        goal: {}
        goal_default:
          time: null
        handles: []
        result: {}
        schema:
          description: set_pump_time的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                time:
                  type: string
              required:
              - time
              type: object
            result: {}
          required:
          - goal
          title: set_pump_time参数
          type: object
        type: UniLabJsonCommand
      auto-set_rotate_time:
        feedback: {}
        goal: {}
        goal_default:
          time: null
        handles: []
        result: {}
        schema:
          description: set_rotate_time的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                time:
                  type: string
              required:
              - time
              type: object
            result: {}
          required:
          - goal
          title: set_rotate_time参数
          type: object
        type: UniLabJsonCommand
      set_timer:
-        type: SendCmd
+        feedback: {}
        goal:
          command: command
-        feedback: {}
+        goal_default:
          command: ''
        handles: []
        result:
          success: success
-  schema:
+        schema:
-    type: object
+          description: ''
-    properties:
+          properties:
-      temperature:
+            feedback:
-        type: number
+              properties:
-        description: 旋蒸水浴温度
+                status:
-      pump_time:
+                  type: string
-        type: number
+              required:
-        description: The pump time of the device
+              - status
-      rotate_time:
+              title: SendCmd_Feedback
-        type: number
+              type: object
-        description: The rotate time of the device
+            goal:
-    required:
+              properties:
-      - pump_time
+                command:
-      - rotate_time
+                  type: string
-    additionalProperties: false
+              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.rotavap.rotavap_one:RotavapOne
    status_types: {}
    type: python
  description: 旋转蒸发仪设备，用于有机化学实验中的溶剂回收和浓缩操作。该设备通过串口通信控制，集成旋转和真空泵功能，支持定时控制和自动化操作。具备旋转速度调节、真空度控制、温度管理等功能，实现高效的溶剂蒸发和回收。适用于有机合成、天然产物提取、药物制备等需要溶剂去除和浓缩的实验室应用场景。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        port:
          type: string
        rate:
          default: 9600
          type: string
      required:
      - port
      type: object
    data:
      properties: {}
      required: []
      type: object
  version: 0.0.1
 separator.homemade:
  class:
    action_value_mappings:
      auto-read_sensor_loop:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: read_sensor_loop的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: read_sensor_loop参数
          type: object
        type: UniLabJsonCommand
      auto-valve_open:
        feedback: {}
        goal: {}
        goal_default:
          condition: null
          value: null
        handles: []
        result: {}
        schema:
          description: valve_open的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                condition:
                  type: string
                value:
                  type: string
              required:
              - condition
              - value
              type: object
            result: {}
          required:
          - goal
          title: valve_open参数
          type: object
        type: UniLabJsonCommand
      auto-write:
        feedback: {}
        goal: {}
        goal_default:
          data: null
        handles: []
        result: {}
        schema:
          description: write的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                data:
                  type: string
              required:
              - data
              type: object
            result: {}
          required:
          - goal
          title: write参数
          type: object
        type: UniLabJsonCommand
      stir:
        feedback:
          status: status
        goal:
          settling_time: settling_time
          stir_speed: stir_speed
          stir_time: stir_time,
        goal_default:
          settling_time: 0.0
          stir_speed: 0.0
          stir_time: 0.0
        handles: []
        result:
          success: success
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: Stir_Feedback
              type: object
            goal:
              properties:
                settling_time:
                  type: number
                stir_speed:
                  type: number
                stir_time:
                  type: number
              required:
              - stir_time
              - stir_speed
              - settling_time
              title: Stir_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: Stir_Result
              type: object
          required:
          - goal
          title: Stir
          type: object
        type: Stir
      valve_open_cmd:
        feedback:
          status: status
        goal:
          command: command
        goal_default:
          command: ''
        handles: []
        result:
          success: success
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.separator.homemade_grbl_conductivity:SeparatorController
    status_types: {}
    type: python
  description: 液-液分离器设备，基于自制Grbl控制器的自动化分离系统。该设备集成搅拌、沉降、阀门控制和电导率传感器，通过串口通信实现精确的分离操作控制。支持自动搅拌、分层沉降、基于传感器反馈的智能分液等功能。适用于有机化学中的萃取分离、相分离、液-液提取等需要精确分离控制的实验应用。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        baudrate_executor:
          default: 115200
          type: integer
        baudrate_sensor:
          default: 115200
          type: integer
        port_executor:
          type: string
        port_sensor:
          type: string
      required:
      - port_executor
      - port_sensor
      type: object
    data:
      properties: {}
      required: []
      type: object
  version: 0.0.1
--- a/unilabos/registry/devices/pump_and_valve.yaml
+++ b/unilabos/registry/devices/pump_and_valve.yaml
@@ -1,83 +1,807 @@
-syringe_pump_with_valve.runze:
+solenoid_valve:
  description: Runze Syringe pump with valve
  class:
-    module: unilabos.devices.pump_and_valve.runze_backbone:RunzeSyringePump
+    action_value_mappings:
      auto-close:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: close的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: close参数
          type: object
        type: UniLabJsonCommand
      auto-is_closed:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: is_closed的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: is_closed参数
          type: object
        type: UniLabJsonCommand
      auto-is_open:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: is_open的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: is_open参数
          type: object
        type: UniLabJsonCommand
      auto-open:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: open参数
          type: object
        type: UniLabJsonCommand
      auto-read_data:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: read_data的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: read_data参数
          type: object
        type: UniLabJsonCommand
      auto-send_command:
        feedback: {}
        goal: {}
        goal_default:
          command: null
        handles: []
        result: {}
        schema:
          description: send_command的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              type: object
            result: {}
          required:
          - goal
          title: send_command参数
          type: object
        type: UniLabJsonCommand
      set_valve_position:
        feedback: {}
        goal:
          string: position
        goal_default:
          string: ''
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: StrSingleInput_Feedback
              type: object
            goal:
              properties:
                string:
                  type: string
              required:
              - string
              title: StrSingleInput_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: StrSingleInput_Result
              type: object
          required:
          - goal
          title: StrSingleInput
          type: object
        type: StrSingleInput
    module: unilabos.devices.pump_and_valve.solenoid_valve:SolenoidValve
    status_types:
      status: str
      valve_position: str
    type: python
  description: 电磁阀控制设备，用于精确的流体路径控制和开关操作。该设备通过串口通信控制电磁阀的开关状态，支持远程操作和状态监测。具备快速响应、可靠密封、状态反馈等特性，广泛应用于流体输送、样品进样、路径切换等需要精确流体控制的实验室自动化应用。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        io_device_port:
          type: string
      required:
      - io_device_port
      type: object
    data:
      properties:
        status:
          type: string
        valve_position:
          type: string
      required:
      - status
      - valve_position
      type: object
  version: 0.0.1
 solenoid_valve.mock:
  class:
    action_value_mappings:
      auto-is_closed:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: is_closed的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: is_closed参数
          type: object
        type: UniLabJsonCommand
      auto-is_open:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: is_open的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: is_open参数
          type: object
        type: UniLabJsonCommand
      auto-set_valve_position:
        feedback: {}
        goal: {}
        goal_default:
          position: null
        handles: []
        result: {}
        schema:
          description: set_valve_position的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                position:
                  type: string
              required:
              - position
              type: object
            result: {}
          required:
          - goal
          title: set_valve_position参数
          type: object
        type: UniLabJsonCommand
      close:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: EmptyIn_Feedback
              type: object
            goal:
              properties: {}
              required: []
              title: EmptyIn_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
              required:
              - return_info
              title: EmptyIn_Result
              type: object
          required:
          - goal
          title: EmptyIn
          type: object
        type: EmptyIn
      open:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: ''
          properties:
            feedback:
              properties: {}
              required: []
              title: EmptyIn_Feedback
              type: object
            goal:
              properties: {}
              required: []
              title: EmptyIn_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
              required:
              - return_info
              title: EmptyIn_Result
              type: object
          required:
          - goal
          title: EmptyIn
          type: object
        type: EmptyIn
    module: unilabos.devices.pump_and_valve.solenoid_valve_mock:SolenoidValveMock
    status_types:
      status: str
      valve_position: str
    type: python
  description: 模拟电磁阀设备，用于系统测试和开发调试。该设备模拟真实电磁阀的开关操作和状态变化，提供与实际设备相同的控制接口和反馈机制。支持流体路径的虚拟控制，便于在没有实际硬件的情况下进行流体系统的集成测试和算法验证。适用于系统开发、流程调试和培训演示等场景。
  handles:
  - data_type: fluid
    handler_key: in
    io_type: target
    label: in
    side: NORTH
  - data_type: fluid
    handler_key: out
    io_type: source
    label: out
    side: SOUTH
  icon: ''
  init_param_schema:
    config:
      properties:
        port:
          default: COM6
          type: string
      required: []
      type: object
    data:
      properties:
        status:
          type: string
        valve_position:
          type: string
      required:
      - status
      - valve_position
      type: object
  version: 0.0.1
 syringe_pump_with_valve.runze:
  class:
    action_value_mappings:
      auto-close:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: close的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: close参数
          type: object
        type: UniLabJsonCommand
      auto-initialize:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: initialize的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: initialize参数
          type: object
        type: UniLabJsonCommand
      auto-pull_plunger:
        feedback: {}
        goal: {}
        goal_default:
          volume: null
        handles: []
        result: {}
        schema:
          description: pull_plunger的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                volume:
                  type: number
              required:
              - volume
              type: object
            result: {}
          required:
          - goal
          title: pull_plunger参数
          type: object
        type: UniLabJsonCommand
      auto-push_plunger:
        feedback: {}
        goal: {}
        goal_default:
          volume: null
        handles: []
        result: {}
        schema:
          description: push_plunger的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                volume:
                  type: number
              required:
              - volume
              type: object
            result: {}
          required:
          - goal
          title: push_plunger参数
          type: object
        type: UniLabJsonCommand
      auto-query_aux_input_status_1:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: query_aux_input_status_1的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: query_aux_input_status_1参数
          type: object
        type: UniLabJsonCommand
      auto-query_aux_input_status_2:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: query_aux_input_status_2的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: query_aux_input_status_2参数
          type: object
        type: UniLabJsonCommand
      auto-query_backlash_position:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: query_backlash_position的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: query_backlash_position参数
          type: object
        type: UniLabJsonCommand
      auto-query_command_buffer_status:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: query_command_buffer_status的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: query_command_buffer_status参数
          type: object
        type: UniLabJsonCommand
      auto-query_software_version:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: query_software_version的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: query_software_version参数
          type: object
        type: UniLabJsonCommand
      auto-send_command:
        feedback: {}
        goal: {}
        goal_default:
          full_command: null
        handles: []
        result: {}
        schema:
          description: send_command的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                full_command:
                  type: string
              required:
              - full_command
              type: object
            result: {}
          required:
          - goal
          title: send_command参数
          type: object
        type: UniLabJsonCommand
      auto-set_baudrate:
        feedback: {}
        goal: {}
        goal_default:
          baudrate: null
        handles: []
        result: {}
        schema:
          description: set_baudrate的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                baudrate:
                  type: string
              required:
              - baudrate
              type: object
            result: {}
          required:
          - goal
          title: set_baudrate参数
          type: object
        type: UniLabJsonCommand
      auto-set_max_velocity:
        feedback: {}
        goal: {}
        goal_default:
          velocity: null
        handles: []
        result: {}
        schema:
          description: set_max_velocity的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                velocity:
                  type: number
              required:
              - velocity
              type: object
            result: {}
          required:
          - goal
          title: set_max_velocity参数
          type: object
        type: UniLabJsonCommand
      auto-set_position:
        feedback: {}
        goal: {}
        goal_default:
          max_velocity: null
          position: null
        handles: []
        result: {}
        schema:
          description: set_position的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                max_velocity:
                  type: number
                position:
                  type: number
              required:
              - position
              type: object
            result: {}
          required:
          - goal
          title: set_position参数
          type: object
        type: UniLabJsonCommand
      auto-set_valve_position:
        feedback: {}
        goal: {}
        goal_default:
          position: null
        handles: []
        result: {}
        schema:
          description: set_valve_position的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                position:
                  type: string
              required:
              - position
              type: object
            result: {}
          required:
          - goal
          title: set_valve_position参数
          type: object
        type: UniLabJsonCommand
      auto-set_velocity_grade:
        feedback: {}
        goal: {}
        goal_default:
          velocity: null
        handles: []
        result: {}
        schema:
          description: set_velocity_grade的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                velocity:
                  type: string
              required:
              - velocity
              type: object
            result: {}
          required:
          - goal
          title: set_velocity_grade参数
          type: object
        type: UniLabJsonCommand
      auto-stop_operation:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: stop_operation的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: stop_operation参数
          type: object
        type: UniLabJsonCommand
      auto-wait_error:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: wait_error的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: wait_error参数
          type: object
        type: UniLabJsonCommand
    hardware_interface:
      name: hardware_interface
      read: send_command
      write: send_command
-  schema:
+    module: unilabos.devices.pump_and_valve.runze_backbone:RunzeSyringePump
    type: object
    properties:
      status:
        type: string
        description: The status of the device
      position:
        type: number
        description: The volume of the syringe
      speed_max:
        type: number
        description: The speed of the syringe
      valve_position:
        type: string
        description: The position of the valve
    required:
    - status
    - position
    - valve_position
    additionalProperties: false
 solenoid_valve.mock:
  description: Mock solenoid valve
  class:
    module: unilabos.devices.pump_and_valve.solenoid_valve_mock:SolenoidValveMock
    type: python
    status_types:
-      status: String
+      max_velocity: float
-      valve_position: String
+      mode: int
-    action_value_mappings:
+      plunger_position: String
-      open:
+      position: float
-        type: EmptyIn
+      status: str
-        goal: {}
+      valve_position: str
-        feedback: {}
+      velocity_end: String
-        result: {}
+      velocity_grade: String
-      close:
+      velocity_init: String
-        type: EmptyIn
+    type: python
-        goal: {}
+  description: 润泽精密注射泵设备，集成阀门控制的高精度流体输送系统。该设备通过串口通信控制，支持多种运行模式和精确的体积控制。具备可变速度控制、精密定位、阀门切换、实时状态监控等功能。适用于微量液体输送、精密进样、流速控制、化学反应进料等需要高精度流体操作的实验室自动化应用。
-        feedback: {}
+  handles: []
-        result: {}
+  icon: ''
  handles:
    input:
    - handler_key: fluid-input
      label: Fluid Input
      data_type: fluid
    output:
    - handler_key: fluid-output
      label: Fluid Output
      data_type: fluid
  init_param_schema:
-    type: object
+    config:
-    properties:
+      properties:
-      port:
+        address:
-        type: string
+          default: '1'
-        description: "通信端口"
+          type: string
-        default: "COM6"
+        max_volume:
-    required:
+          default: 25.0
-    - port
+          type: number
-
+        mode:
-solenoid_valve:
+          type: string
-  description: Solenoid valve
+        port:
-  class:
+          type: string
-    module: unilabos.devices.pump_and_valve.solenoid_valve:SolenoidValve
+      required:
-    type: python
+      - port
-    status_types:
+      type: object
-      status: String
+    data:
-      valve_position: String
+      properties:
-    action_value_mappings:
+        max_velocity:
-      set_valve_position:
+          type: number
-        type: StrSingleInput
+        mode:
-        goal:
+          type: integer
-          string: position
+        plunger_position:
-        feedback: {}
+          type: string
-        result: {}
+        position:
          type: number
        status:
          type: string
        valve_position:
          type: string
        velocity_end:
          type: string
        velocity_grade:
          type: string
        velocity_init:
          type: string
      required:
      - status
      - mode
      - max_velocity
      - velocity_grade
      - velocity_init
      - velocity_end
      - valve_position
      - position
      - plunger_position
      type: object
  version: 0.0.1
--- a/unilabos/registry/devices/robot_agv.yaml
+++ b/unilabos/registry/devices/robot_agv.yaml
@@ -1,29 +1,106 @@
 # 仙工智能底盘（知行使用）
 agv.SEER:
  description: SEER AGV
  class:
    module: unilabos.devices.agv.agv_navigator:AgvNavigator
    type: python
    status_types:
      pose: Float64MultiArray
      status: String
    action_value_mappings:
      auto-send:
        feedback: {}
        goal: {}
        goal_default:
          cmd: null
          ex_data: ''
          obj: receive_socket
        handles: []
        result: {}
        schema:
          description: AGV底层通信命令发送函数。通过TCP socket连接向AGV发送底层控制命令，支持pose（位置）、status（状态）、nav（导航）等命令类型。用于获取AGV当前位置坐标、运行状态或发送导航指令。该函数封装了AGV的通信协议，将命令转换为十六进制数据包并处理响应解析。
          properties:
            feedback: {}
            goal:
              properties:
                cmd:
                  type: string
                ex_data:
                  default: ''
                  type: string
                obj:
                  default: receive_socket
                  type: string
              required:
              - cmd
              type: object
            result: {}
          required:
          - goal
          title: send参数
          type: object
        type: UniLabJsonCommand
      send_nav_task:
-        type: SendCmd
+        feedback: {}
        goal:
          command: command
-        feedback: {}
+        goal_default:
          command: ''
        handles: []
        result:
          success: success
-  schema:
+        schema:
-    properties:
+          description: ''
-      pose:
+          properties:
-        type: array
+            feedback:
-        items:
+              properties:
-          type: number
+                status:
-      status:
+                  type: string
-        type: string
+              required:
-    required:
+              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.agv.agv_navigator:AgvNavigator
    status_types:
      pose: list
      status: str
    type: python
  description: SEER AGV自动导引车设备，用于实验室内物料和设备的自主移动运输。该AGV通过TCP socket与导航系统通信，具备精确的定位和路径规划能力。支持实时位置监控、状态查询和导航任务执行，可在预设的实验室环境中自主移动至指定位置。适用于样品运输、设备转移、多工位协作等实验室自动化物流场景。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        host:
          type: string
      required:
      - host
      type: object
    data:
      properties:
        pose:
          type: array
        status:
          type: string
      required:
      - pose
      - status
-    additionalProperties: false
+      type: object
-    type: object
+  version: 0.0.1
--- a/unilabos/registry/devices/robot_arm.yaml
+++ b/unilabos/registry/devices/robot_arm.yaml
@@ -1,37 +1,173 @@
 robotic_arm.UR:
  description: UR robotic arm
  class:
    module: unilabos.devices.agv.ur_arm_task:UrArmTask
    type: python
    status_types:
      arm_pose: Float64MultiArray
      gripper_pose: Float64
      arm_status: String
      gripper_status: String
    action_value_mappings:
      auto-arm_init:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: 机械臂初始化函数。执行UR机械臂的完整初始化流程，包括上电、释放制动器、解除保护停止状态等。该函数确保机械臂从安全停止状态恢复到可操作状态，是机械臂使用前的必要步骤。初始化完成后机械臂将处于就绪状态，可以接收后续的运动指令。
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: arm_init参数
          type: object
        type: UniLabJsonCommand
      auto-load_pose_data:
        feedback: {}
        goal: {}
        goal_default:
          data: null
        handles: []
        result: {}
        schema:
          description: 从JSON字符串加载位置数据函数。接收包含机械臂位置信息的JSON格式字符串，解析并存储位置数据供后续运动任务使用。位置数据通常包含多个预定义的工作位置坐标，用于实现精确的多点运动控制。适用于动态配置机械臂工作位置的场景。
          properties:
            feedback: {}
            goal:
              properties:
                data:
                  type: string
              required:
              - data
              type: object
            result: {}
          required:
          - goal
          title: load_pose_data参数
          type: object
        type: UniLabJsonCommand
      auto-load_pose_file:
        feedback: {}
        goal: {}
        goal_default:
          file: null
        handles: []
        result: {}
        schema:
          description: 从文件加载位置数据函数。读取指定的JSON文件并加载其中的机械臂位置信息。该函数支持从外部配置文件中获取预设的工作位置，便于位置数据的管理和重用。适用于需要从固定配置文件中读取复杂位置序列的应用场景。
          properties:
            feedback: {}
            goal:
              properties:
                file:
                  type: string
              required:
              - file
              type: object
            result: {}
          required:
          - goal
          title: load_pose_file参数
          type: object
        type: UniLabJsonCommand
      auto-reload_pose:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: 重新加载位置数据函数。重新读取并解析之前设置的位置文件，更新内存中的位置数据。该函数用于在位置文件被修改后刷新机械臂的位置配置，无需重新初始化整个系统。适用于动态更新机械臂工作位置的场景。
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: reload_pose参数
          type: object
        type: UniLabJsonCommand
      move_pos_task:
-        type: SendCmd
+        feedback: {}
        goal:
          command: command
-        feedback: {}
+        goal_default:
          command: ''
        handles: []
        result:
          success: success
-  schema:
+        schema:
-    properties:
+          description: ''
-      arm_pose:
+          properties:
-        type: array
+            feedback:
-        items:
+              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.agv.ur_arm_task:UrArmTask
    status_types:
      arm_pose: list
      arm_status: str
      gripper_pose: float
      gripper_status: str
    type: python
  description: Universal Robots机械臂设备，用于实验室精密操作和自动化作业。该设备集成了UR机械臂本体、Robotiq夹爪和RTDE通信接口，支持六自由度精确运动控制和力觉反馈。具备实时位置监控、状态反馈、轨迹规划等功能，可执行复杂的多点位运动任务。适用于样品抓取、精密装配、实验器具操作等需要高精度和高重复性的实验室自动化场景。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        host:
          type: string
        retry:
          default: 30
          type: string
      required:
      - host
      type: object
    data:
      properties:
        arm_pose:
          type: array
        arm_status:
          type: string
        gripper_pose:
          type: number
-      gripper_pose:
+        gripper_status:
-        type: number
+          type: string
-      arm_status:
+      required:
-        type: string
+      - arm_pose
-        description: 机械臂设备状态
+      - gripper_pose
      gripper_status:
        type: string
        description: 机械爪设备状态
    required:
      - arm_status
      - gripper_status
-    additionalProperties: false
+      type: object
-    type: object
+  version: 0.0.1
--- a/unilabos/registry/devices/robot_gripper.yaml
+++ b/unilabos/registry/devices/robot_gripper.yaml
@@ -1,37 +1,590 @@
 gripper.mock:
  description: Mock gripper
  class:
    module: unilabos.devices.gripper.mock:MockGripper
    type: python
    status_types:
      position: Float64
      torque: Float64
      status: String
    action_value_mappings:
      push_to:
        type: GripperCommand
        goal:
          command.position: position
          command.max_effort: torque
        feedback:
          position: position
          effort: torque
        result:
          position: position
          effort: torque
 gripper.misumi_rz:
  description: Misumi RZ gripper
  class:
    module: unilabos.devices.motor:Grasp.EleGripper
    type: python
    status_types:
      status: String
    action_value_mappings:
      auto-data_loop:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: data_loop的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: data_loop参数
          type: object
        type: UniLabJsonCommand
      auto-data_reader:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: data_reader的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: data_reader参数
          type: object
        type: UniLabJsonCommand
      auto-gripper_move:
        feedback: {}
        goal: {}
        goal_default:
          force: null
          pos: null
          speed: null
        handles: []
        result: {}
        schema:
          description: 夹爪抓取运动控制函数。控制夹爪的开合运动，支持位置、速度、力矩的精确设定。位置参数控制夹爪开合程度，速度参数控制运动快慢，力矩参数控制夹持强度。该函数提供安全的力控制，避免损坏被抓取物体，适用于各种形状和材质的物品抓取。
          properties:
            feedback: {}
            goal:
              properties:
                force:
                  type: string
                pos:
                  type: string
                speed:
                  type: string
              required:
              - pos
              - speed
              - force
              type: object
            result: {}
          required:
          - goal
          title: gripper_move参数
          type: object
        type: UniLabJsonCommand
      auto-init_gripper:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: 夹爪初始化函数。执行Misumi RZ夹爪的完整初始化流程，包括Modbus通信建立、电机参数配置、传感器校准等。该函数确保夹爪系统从安全状态恢复到可操作状态，是夹爪使用前的必要步骤。初始化完成后夹爪将处于就绪状态，可接收抓取和旋转指令。
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: init_gripper参数
          type: object
        type: UniLabJsonCommand
      auto-modbus_crc:
        feedback: {}
        goal: {}
        goal_default:
          data: null
        handles: []
        result: {}
        schema:
          description: modbus_crc的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                data:
                  type: string
              required:
              - data
              type: object
            result: {}
          required:
          - goal
          title: modbus_crc参数
          type: object
        type: UniLabJsonCommand
      auto-move_and_rotate:
        feedback: {}
        goal: {}
        goal_default:
          grasp_F: null
          grasp_pos: null
          grasp_v: null
          spin_F: null
          spin_pos: null
          spin_v: null
        handles: []
        result: {}
        schema:
          description: move_and_rotate的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                grasp_F:
                  type: string
                grasp_pos:
                  type: string
                grasp_v:
                  type: string
                spin_F:
                  type: string
                spin_pos:
                  type: string
                spin_v:
                  type: string
              required:
              - spin_pos
              - grasp_pos
              - spin_v
              - grasp_v
              - spin_F
              - grasp_F
              type: object
            result: {}
          required:
          - goal
          title: move_and_rotate参数
          type: object
        type: UniLabJsonCommand
      auto-node_gripper_move:
        feedback: {}
        goal: {}
        goal_default:
          cmd: null
        handles: []
        result: {}
        schema:
          description: 节点夹爪移动任务函数。接收逗号分隔的命令字符串，解析位置、速度、力矩参数并执行夹爪抓取动作。该函数等待运动完成并返回执行结果，提供同步的运动控制接口。适用于需要可靠完成确认的精密抓取操作。
          properties:
            feedback: {}
            goal:
              properties:
                cmd:
                  type: string
              required:
              - cmd
              type: object
            result: {}
          required:
          - goal
          title: node_gripper_move参数
          type: object
        type: UniLabJsonCommand
      auto-node_rotate_move:
        feedback: {}
        goal: {}
        goal_default:
          cmd: null
        handles: []
        result: {}
        schema:
          description: 节点旋转移动任务函数。接收逗号分隔的命令字符串，解析角度、速度、力矩参数并执行夹爪旋转动作。该函数等待旋转完成并返回执行结果，提供同步的旋转控制接口。适用于需要精确角度定位和完成确认的旋转操作。
          properties:
            feedback: {}
            goal:
              properties:
                cmd:
                  type: string
              required:
              - cmd
              type: object
            result: {}
          required:
          - goal
          title: node_rotate_move参数
          type: object
        type: UniLabJsonCommand
      auto-read_address:
        feedback: {}
        goal: {}
        goal_default:
          address: null
          data_len: null
          id: null
        handles: []
        result: {}
        schema:
          description: read_address的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                address:
                  type: string
                data_len:
                  type: string
                id:
                  type: string
              required:
              - id
              - address
              - data_len
              type: object
            result: {}
          required:
          - goal
          title: read_address参数
          type: object
        type: UniLabJsonCommand
      auto-rotate_move_abs:
        feedback: {}
        goal: {}
        goal_default:
          force: null
          pos: null
          speed: null
        handles: []
        result: {}
        schema:
          description: 夹爪绝对位置旋转控制函数。控制夹爪主轴旋转到指定的绝对角度位置，支持360度连续旋转。位置参数指定目标角度，速度参数控制旋转速率，力矩参数设定旋转阻力限制。该函数提供高精度的角度定位，适用于需要精确方向控制的操作场景。
          properties:
            feedback: {}
            goal:
              properties:
                force:
                  type: string
                pos:
                  type: string
                speed:
                  type: string
              required:
              - pos
              - speed
              - force
              type: object
            result: {}
          required:
          - goal
          title: rotate_move_abs参数
          type: object
        type: UniLabJsonCommand
      auto-send_cmd:
        feedback: {}
        goal: {}
        goal_default:
          address: null
          data: null
          fun: null
          id: null
        handles: []
        result: {}
        schema:
          description: send_cmd的参数schema
          properties:
            feedback: {}
            goal:
              properties:
                address:
                  type: string
                data:
                  type: string
                fun:
                  type: string
                id:
                  type: string
              required:
              - id
              - fun
              - address
              - data
              type: object
            result: {}
          required:
          - goal
          title: send_cmd参数
          type: object
        type: UniLabJsonCommand
      auto-wait_for_gripper:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: wait_for_gripper的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: wait_for_gripper参数
          type: object
        type: UniLabJsonCommand
      auto-wait_for_gripper_init:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: wait_for_gripper_init的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: wait_for_gripper_init参数
          type: object
        type: UniLabJsonCommand
      auto-wait_for_rotate:
        feedback: {}
        goal: {}
        goal_default: {}
        handles: []
        result: {}
        schema:
          description: wait_for_rotate的参数schema
          properties:
            feedback: {}
            goal:
              properties: {}
              required: []
              type: object
            result: {}
          required:
          - goal
          title: wait_for_rotate参数
          type: object
        type: UniLabJsonCommand
      execute_command_from_outer:
-        type: SendCmd
+        feedback: {}
        goal:
          command: command
-        feedback: {}
+        goal_default:
          command: ''
        handles: []
        result:
          success: success
        schema:
          description: ''
          properties:
            feedback:
              properties:
                status:
                  type: string
              required:
              - status
              title: SendCmd_Feedback
              type: object
            goal:
              properties:
                command:
                  type: string
              required:
              - command
              title: SendCmd_Goal
              type: object
            result:
              properties:
                return_info:
                  type: string
                success:
                  type: boolean
              required:
              - return_info
              - success
              title: SendCmd_Result
              type: object
          required:
          - goal
          title: SendCmd
          type: object
        type: SendCmd
    module: unilabos.devices.motor.Grasp:EleGripper
    status_types:
      status: str
    type: python
  description: Misumi RZ系列电子夹爪设备，集成旋转和抓取双重功能的精密夹爪系统。该设备通过Modbus RTU协议与控制系统通信，支持位置、速度、力矩的精确控制。具备高精度的位置反馈、实时状态监控和故障检测功能。适用于需要精密抓取和旋转操作的实验室自动化场景，如样品管理、精密装配、器件操作等应用。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties:
        baudrate:
          default: 115200
          type: string
        id:
          default: 9
          type: string
        port:
          type: string
        pos_error:
          default: -11
          type: string
      required:
      - port
      type: object
    data:
      properties:
        status:
          type: string
      required:
      - status
      type: object
  version: 0.0.1
 gripper.mock:
  class:
    action_value_mappings:
      auto-edit_id:
        feedback: {}
        goal: {}
        goal_default:
          params: '{}'
          resource:
            Gripper1: {}
          wf_name: gripper_run
        handles: []
        result: {}
        schema:
          description: 模拟夹爪资源ID编辑函数。用于测试和演示资源管理功能，模拟修改夹爪资源的标识信息。该函数接收工作流名称、参数和资源对象，模拟真实的资源更新过程并返回修改后的资源信息。适用于系统测试和开发调试场景。
          properties:
            feedback: {}
            goal:
              properties:
                params:
                  default: '{}'
                  type: string
                resource:
                  default:
                    Gripper1: {}
                  type: object
                wf_name:
                  default: gripper_run
                  type: string
              required: []
              type: object
            result: {}
          required:
          - goal
          title: edit_id参数
          type: object
        type: UniLabJsonCommand
      push_to:
        feedback:
          effort: torque
          position: position
        goal:
          command.max_effort: torque
          command.position: position
        goal_default:
          command:
            max_effort: 0.0
            position: 0.0
        handles: []
        result:
          effort: torque
          position: position
        schema:
          description: ''
          properties:
            feedback:
              properties:
                effort:
                  type: number
                position:
                  type: number
                reached_goal:
                  type: boolean
                stalled:
                  type: boolean
              required:
              - position
              - effort
              - stalled
              - reached_goal
              title: GripperCommand_Feedback
              type: object
            goal:
              properties:
                command:
                  properties:
                    max_effort:
                      type: number
                    position:
                      type: number
                  required:
                  - position
                  - max_effort
                  title: GripperCommand
                  type: object
              required:
              - command
              title: GripperCommand_Goal
              type: object
            result:
              properties:
                effort:
                  type: number
                position:
                  type: number
                reached_goal:
                  type: boolean
                stalled:
                  type: boolean
              required:
              - position
              - effort
              - stalled
              - reached_goal
              title: GripperCommand_Result
              type: object
          required:
          - goal
          title: GripperCommand
          type: object
        type: GripperCommand
    module: unilabos.devices.gripper.mock:MockGripper
    status_types:
      position: float
      status: str
      torque: float
      velocity: float
    type: python
  description: 模拟夹爪设备，用于系统测试和开发调试。该设备模拟真实夹爪的位置、速度、力矩等物理特性，支持虚拟的抓取和移动操作。提供与真实夹爪相同的接口和状态反馈，便于在没有实际硬件的情况下进行系统集成测试和算法验证。适用于软件开发、系统调试和培训演示等场景。
  handles: []
  icon: ''
  init_param_schema:
    config:
      properties: {}
      required: []
      type: object
    data:
      properties:
        position:
          type: number
        status:
          type: string
        torque:
          type: number
        velocity:
          type: number
      required:
      - position
      - velocity
      - torque
      - status
      type: object
  version: 0.0.1
--- a/Show More
+++ b/Show More