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受电弓主动控制综述

鲁小兵 刘志刚 宋洋 韩志伟

鲁小兵, 刘志刚, 宋洋, 韩志伟. 受电弓主动控制综述[J]. 交通运输工程学报, 2014, 14(2): 49-61.
引用本文: 鲁小兵, 刘志刚, 宋洋, 韩志伟. 受电弓主动控制综述[J]. 交通运输工程学报, 2014, 14(2): 49-61.
LU Xiao-bing, LIU Zhi-gang, SONG Yang, HAN Zhi-wei. Review of pantograph active control[J]. Journal of Traffic and Transportation Engineering, 2014, 14(2): 49-61.
Citation: LU Xiao-bing, LIU Zhi-gang, SONG Yang, HAN Zhi-wei. Review of pantograph active control[J]. Journal of Traffic and Transportation Engineering, 2014, 14(2): 49-61.

受电弓主动控制综述

基金项目: 

国家自然科学基金项目 U1134205

国家自然科学基金项目 51377136

详细信息
    作者简介:

    鲁小兵(1988-), 男, 甘肃平凉人, 西南交通大学工学博士研究生, 从事受电弓主动控制研究

    刘志刚(1975-), 男, 河南巩义人, 西南交通大学教授, 工学博士

  • 中图分类号: U264.34

Review of pantograph active control

More Information
  • 摘要: 为了抑制弓网耦合振动, 提高高速列车集流能力, 综述了受电弓主动控制研究过程中弓网系统建模、控制目标与测量系统、控制算法、操动机构及其安装、试验验证等5个关键环节的研究进展, 分析了弓网模型对接触力仿真结果精度和计算时间的影响、不同控制算法的优缺点和操动机构的选择方法, 展望了受电弓主动控制在模型优化、算法设计和信号修正等方面的未来研究重点。分析结果表明: 在受电弓主动控制研究中, 弓网模型的建立要同时考虑对系统关键因素的表征与计算效率, 控制目标的选取以能反映受流质量为准则, 量测系统需尽量减少机车扰动对量测结果可靠性的影响, 控制结构不能影响原有升弓机构的工作, 这些与控制算法的实时性与执行机构的高效性一起共同决定了受电弓主动控制的实用效能。

     

  • 图  1  受电弓主动控制研究流程

    Figure  1.  Study flow chart of active control of pantograph

    图  2  质量块模型

    Figure  2.  Lumped mass models

    图  3  多体模型

    Figure  3.  Multibody model

    图  4  接触网结构

    Figure  4.  Catenary structure

    图  5  操动机构

    Figure  5.  Actuator

    图  6  电磁操动机构

    Figure  6.  Electromagnetic actuator

    图  7  线性操动机构

    Figure  7.  Wire actuator

    图  8  安装结构

    Figure  8.  Installation structures

    图  9  仿真原理

    Figure  9.  Simulation principle

    图  10  仿真结构

    Figure  10.  Simulation structure

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  • 收稿日期:  2014-01-21
  • 刊出日期:  2014-04-25

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