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综采支架液压系统动态特性研究及改进设计

郭新伟

郭新伟. 综采支架液压系统动态特性研究及改进设计[J]. 工矿自动化,2024,50(8):20-29.  doi: 10.13272/j.issn.1671-251x.2024060046
引用本文: 郭新伟. 综采支架液压系统动态特性研究及改进设计[J]. 工矿自动化,2024,50(8):20-29.  doi: 10.13272/j.issn.1671-251x.2024060046
GUO Xinwei. Research on dynamic features of hydraulic system for fully mechanized mining support and its improvement design[J]. Journal of Mine Automation,2024,50(8):20-29.  doi: 10.13272/j.issn.1671-251x.2024060046
Citation: GUO Xinwei. Research on dynamic features of hydraulic system for fully mechanized mining support and its improvement design[J]. Journal of Mine Automation,2024,50(8):20-29.  doi: 10.13272/j.issn.1671-251x.2024060046

综采支架液压系统动态特性研究及改进设计

doi: 10.13272/j.issn.1671-251x.2024060046
基金项目: 国家重点研发计划资助项目(2023YFC2907504);中国煤炭科工集团科技创新基金重点资助项目(2024-TD-MS012)。
详细信息
    作者简介:

    郭新伟(1981— ),男,安徽界首人,助理研究员,硕士,现主要从事煤矿智能开采工作,E-mail:guoxw@tdmarco.com

  • 中图分类号: TD355.4/67

Research on dynamic features of hydraulic system for fully mechanized mining support and its improvement design

  • 摘要: 综采工作面液压支架工作中常存在支架初撑力不足、移架速度慢等问题,目前大多基于支架液压系统的稳态运行规律,采用增大泵站流量、降低压力损失等方案来解决,对液压系统动态特性的研究较少。建立了综采支架液压系统动力方程,理论分析了支架初撑力和移架速度相关的液压系统动态特性和乳化液管路系统的液压冲击特性,得出立柱或千斤顶的近似空载运行和长距离管路液压冲击是造成支架液压系统压力大幅下降波动的主要原因。揭示了支架液压系统液压冲击的发生机理为电液换向阀突然启闭和立柱触顶加压。通过现场实测数据和AMESim仿真验证了理论分析的正确性。提出了综采支架液压系统改进方案,在支架上设置多个蓄能器,新增液控单向阀和电液换向阀控制液压系统蓄能器在不同移架阶段的充放液方式,利用蓄能器的瞬时大流量特性和长距离管路液压冲击压力峰值产生的超压作用来提升支架初撑力。仿真结果表明,改进系统能够有效提高液压支架的初撑力和移架速度。

     

  • 图  1  单台支架液压系统结构

    1—乳化液泵站;2—蓄能器;3—双向锁;4—推移千斤顶安全阀;5—推移千斤顶;6—左立柱; 7—立柱安全阀;8—右立柱; 9—液控单向阀;10—除推移千斤顶之外的其他千斤顶及其控制阀;11—降柱控制阀;12—升柱控制阀;13—推溜控制阀;14—拉架控制阀;15—电液换向阀。

    Figure  1.  Hydraulic system structure of single support

    图  2  理想情况下管路液压冲击波形

    Figure  2.  Hydraulic impact waveform of pipeline under ideal condition

    图  3  实际情况下管路液压冲击波形

    Figure  3.  Hydraulic impact waveform of pipeline under actual condition

    图  4  支架附近管路压力实测曲线

    Figure  4.  Measured curves of pipeline pressure near supports

    图  5  支架液压系统仿真模型

    Figure  5.  Simulation model of hydraulic system of support

    图  6  立柱位移和速度曲线

    Figure  6.  Column displacement and velocity curves

    图  7  支架动态压力曲线

    Figure  7.  Dynamic pressure curves of support

    图  8  升柱过程中支架压力曲线

    Figure  8.  Pressure curves of support in column lifting process

    图  9  立柱下腔流量曲线

    Figure  9.  Flow rate curve at the bottom of column

    图  10  综采支架液压系统改进方案

    1—乳化液泵站;2—新增电液换向阀;3—新增液控单向阀;4—泵站蓄能器;5—新增支架蓄能器;6—单架液压系统。

    Figure  10.  Improved scheme of hydraulic system for fully mechanized mining support

    图  11  改进的综采支架液压系统仿真模型

    Figure  11.  Simulation model of improved hydraulic system for fully mechanized mining support

    图  12  系统改进后立柱位移和速度曲线

    Figure  12.  Displacement and velocity curves of column of the improved system

    图  13  系统改进后支架动态压力曲线

    Figure  13.  Dynamic support pressure curves of the improved system

    图  14  系统改进后立柱下腔流量曲线

    Figure  14.  Flow rate curves at the bottom of the column of the improved system

    表  1  支架附近管路压力实测数据峰谷值及对应时间

    Table  1.   The peak and valley value of measured data of pipeline pressure near supports and corresponding time

    6号支架 46号支架 86号支架
    时间 压力/MPa 时间 压力/MPa 时间 压力/MPa
    19:06:27 30.1 19:06:27 28.0 19:06:23 28.2
    19:06:35 18.6 19:06:35 16.4 19:06:35 23.6
    19:06:37 26.2 19:06:38 28.5 19:06:38 28.5
    19:06:57 17.9 19:06:44 21.9 19:06:44 24.0
    19:07:00 27.0 19:06:48 28.9 19:06:48 28.0
    19:07:09 22.0 19:06:55 13.3 19:06:55 20.9
    19:07:11 25.3 19:07:00 29.1 19:07:00 29.5
    19:07:15 14.9 19:07:14 11.7 19:07:08 25.0
    19:07:19 29.8 19:07:18 27.6 19:07:11 28.2
    19:07:25 22.5 19:07:25 23.9 19:07:15 19.1
    19:07:27 30.2 19:07:27 28.2 19:07:19 27.8
    19:07:35 20.1 19:07:34 15.5 19:07:25
    19:07:37 27.6 19:07:38 26.2 19:07:27 27.8
    19:07:46 23.1 19:07:57 13.8 19:07:35 24.7
    19:07:51 26.8 19:08:11 28.9 19:07:37 27.8
    19:07:57 13.2 19:08:17 24.2 19:07:35 21.0
    19:08:11 29.5 19:08:30 27.3 19:07:38 29.2
    19:08:34 25.0 19:08:33 12.0 19:07:56 21.2
    19:08:37 29.0 19:08:37 28.9 19:08:03 28.3
    19:08:51 22.3 19:09:03 13.1 19:08:15 24.7
    下载: 导出CSV

    表  2  支架液压系统仿真参数

    Table  2.   Simulation parameters of hydraulic system of support

    部件名称 仿真参数
    双立柱 活塞$\phi $300 mm,活塞杆$\phi $280 mm,行程3 m
    推移千斤顶 活塞$\phi $200 mm,活塞杆$\phi $140 mm,行程1 m
    液控单向阀 压力31.5 MPa,压降6 MPa,最大阀口开度时流量600 L/min
    电液换向阀 压力31.5 MPa,压降6.6 MPa,最大阀口开度时流
    量500 L/min
    乳化液泵站 压力31.5 MPa,流量2×400 L/min
    泵站蓄能器 容积100 L,充气压力12 MPa
    主进液管 通径DN50
    主回液管 通径DN63
    高压进液管 通径DN25
    其他回液管 通径DN32
    下载: 导出CSV

    表  3  综采支架液压系统改进设计参数

    Table  3.   Improved design parameters of hydraulic system for fully mechanized mining support

    名称 参数
    乳化液泵站 压力31.5 MPa,流量400 L/min
    泵站蓄能器 容积100 L,充气压力12 MPa
    支架蓄能器 容积60 L,充气压力12 MPa
    主进液管 通径DN38
    下载: 导出CSV
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  • 收稿日期:  2024-06-13
  • 修回日期:  2024-08-13
  • 网络出版日期:  2024-08-22

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