Research on Adaptive Cutting Control Strategy of Roadheader Cutting Arms

doi:10.3969/j.issn.1004-132X.2022.20.013

Abstract

Abstract: Aiming at the problems of low intelligent cutting degree of underground roadheaders, and the swing speed of cutting arms might not be adjusted adaptively according to the hardness of coals and rocks, an adaptive cutting control strategy of roadheader cutting arms was proposed based on multiple sensor information. On the basis of the currents of the cutting motor, the pressures of the driving cylinder of the cutting arms and the vibration accelerations of the cutting arms, the signal recognizer of the cutting loads was designed by using RBF neural network, which provided an accurate basis for the swing speed control of the cutting arms. Aiming at the complex and time-varying swing speed control system of cutting arms, based on genetic algorithm optimization， a fuzzy PID intelligent controller was designed to realize the efficient control of swing speed of cutting arms. The mathematical model of cutting arms of roadheaders was established, and the adaptive cutting simulation control system of cutting arms was built in MATLAB/Simulink. The simulation results show that the control system has fast response speed and high control precision. An airborne adaptive cutting control system of roadheaders was built based on the software of B&R Automation Studio. The simulation cutting experiments were carried out with EBZ135 roadheader in the simulated roadway of Shijiazhuang Coal Mining Machinery Co., Ltd. the experimental results show that the proposed control strategy may realize the efficient adaptive control of the swing speed of cutting arms according to the changes of cutting loads.

Key words: roadheader, radial basis function(RBF) neural network, cutting arm swing speed control, genetic algorithm, fuzzy control

摘要： 针对井下掘进机截割智能化程度低、截割臂摆速不能根据煤岩硬度进行自适应调节的问题，提出了一种基于多传感器信息的掘进机截割臂自适应截割控制策略。以截割电机电流、截割臂驱动油缸压力、截割臂振动加速度作为煤岩截割载荷识别依据，采用径向基函数神经网络设计了截割载荷信号识别器，为截割臂摆速调控提供准确依据；针对复杂且具有时变性的截割臂摆速调控系统，设计了基于遗传算法优化的模糊PID智能控制器，实现对截割臂摆速的高效调控。建立了掘进机截割臂数学模型，在MATLAB/Simulink中搭建了截割臂自适应截割仿真控制系统，仿真结果表明，控制系统具有较快响应速度及较高控制精度。基于贝加莱Automation Studio软件搭建掘进机机载自适应截割控制系统，在石家庄煤矿机械有限公司模拟巷道中采用EBZ135型掘进机进行了模拟截割实验，实验结果表明，所提出的控制策略能够根据截割载荷变化实现对截割臂摆速的高效自适应调控。

关键词: 掘进机, 径向基函数神经网络, 截割臂摆速控制, 遗传算法, 模糊控制

CLC Number:

TD421

WANG Dongjie, WANG Pengjiang, LI Yue, GUO Mingze, ZHENG Weixiong, SHEN Yang, WU Miao. Research on Adaptive Cutting Control Strategy of Roadheader Cutting Arms[J]. China Mechanical Engineering, 2022, 33(20): 2492-2501.

王东杰, 王鹏江, 李悦, 郭明泽, 郑伟雄, 沈阳, 吴淼. 掘进机截割臂自适应截割控制策略研究[J]. 中国机械工程, 2022, 33(20): 2492-2501.

References

［1］谢和平, 周宏伟, 薛东杰, 等. 煤炭深部开采与极限开采深度的研究与思考［J］. 煤炭学报, 2012,37(4):535-542.
XIE Heping, ZHOU Hongwei, XUE Dongjie, et al. Research and Thinking on Deep Mining and Limit Mining Depth of Coal ［J］.Journal of Coal Science, 2012,37(4):535-542.
［2］贺春禄. 到2035年中国煤矿要基本实现智能化:解读《关于加快煤矿智能化发展的指导意见》［J］. 高科技与产业化, 2020(8):28-31.
HE Chunlu. To Basically Realize Intellectualization in Chinese Coal Mines by 2035:Interpretation of Guidance on Accelerating the Intellectualization Development of Coal Mines［J］.High Technology and Industrialization, 2020(8):28-31.
［3］王国法, 刘峰, 孟祥军, 等. 煤矿智能化(初级阶段)研究与实践［J］. 煤炭科学技术, 2019,47(8):1-36.
WANG Guofa, LIU Feng, MENG Xiangjun, et al. Research and Practice of Coal Mine Intelligentization(Primary Stage) ［J］.Coal Science and Technology, 2019,47(8):1-36.
［4］杨健健, 张强, 王超, 等. 煤矿掘进机的机器人化研究现状与发展［J］. 煤炭学报, 2020,45(8):2995-3005.
YANG Jianjian, ZHANG Qiang, WANG Chao, et al. Research Status and Development of Robotization of Coal Mine Roadheader ［J］.Acta Coal Sinica, 2020,45(8):2995-3005.
［5］ZONG K, Zhang P, Wang P, et al. Multifactor Analysis of Roadheaders Body Pose Responses during the Horizontal Cutting Process［J］. Shock and Vibration, 2018,2018（3）：2387408.1-2387408.18.
［6］高峰, 王苏彧, 高娟, 等. 掘进机截割臂摆速自动控制方法研究［J］.工矿自动化, 2011,37(8):38-41.
GAO Feng, WANG Suyu, GAO Juan, et al. Research on Automatic Control Method of Cutting Arm Swing Speed of Roadheader ［J］.Industrial and Mining Automation, 2011,37(8):38-41.
［7］贺文海, 焦可辉. 基于模糊PID的掘进机恒功率控制系统设计［J］. 煤炭工程, 2019,51(9):178-181.
HE Wenhai, JIAO Kehui. Design of Constant Power Control System of Roadheader Based on Fuzzy PID ［J］.Coal Engineering, 2019,51(9):178-181.
［8］宗凯. 悬臂式掘进机截割过程位姿响应与截割臂摆速控制研究［D］.北京：中国矿业大学(北京), 2019.
ZONG Kai. Research on Pose Response and Swing Speed Control of Cutting Arm in Cutting Process of Cantilever Roadheader ［D］.Beijing：China University of Mining and Technology(Beijing), 2019.
［9］WANG P, SHEN Y, LI R, et al. Multisensor Information-based Adaptive Control Method for Cutting Head Speed of Roadheader［J］. Proceedings of the Institution of Mechanical Engineers Part C:Journal of Mechanical Engineering Science, 2021, 235(11):1941-1955.
［10］李旭.悬臂式掘进机关键结构的力学特性研究［D］.北京：中国矿业大学(北京),2017.
LI Xu. Study on Mechanical Characteristics of Key Structures of Cantilever Roadheader ［D］. Beijing：China University of Mining and Technology(Beijing), 2017.
［11］田劼, 汪胜陆, 张立涛, 等. 悬臂掘进机巷道断面自动成形控制运动学分析［J］. 煤炭科学技术, 2007(8):86-88.
TIAN Jie, WANG Shenglu, ZHANG Litao, et al. Kinematics Analysis of Roadway Section Automatic Forming Control for Cantilever Tunneling Machine［J］.Coal Science and Technology, 2007(8):86-88.
［12］赵学雷. 基于多传感器信息融合的载荷及煤岩判定与识别技术研究［D］. 北京：中国矿业大学（北京）, 2011.
ZHAO Xuelei. Research on Load and Coal-rock Determination and Identification Technology Based on Multi-sensor Information Fusion ［D］.Beijing：China University of Mining and Technology(Beijing), 2011.
［13］张林锋. 超重型岩巷掘进机截割头动载荷识别方法的研究［D］. 太原:太原理工大学, 2019.
ZHANG Linfeng. Research on Dynamic Load Identification Method of Cutting Head of Ultra-Heavy Rock Roadheader ［D］. Taiyuan:Taiyuan University of Technology, 2019.
［14］韩红桂, 乔俊飞, 薄迎春. 基于信息强度的RBF神经网络结构设计研究［J］. 自动化学报, 2012,38(7):1083-1090.
HAN Honggui, QIAO Junfei, BO Yingchun. Structural Design of RBF Neural Network Based on Information Intensity ［J］.Journal of Automation, 2012,38(7):1083-1090.
［15］王述彦, 师宇, 冯忠绪. 基于模糊PID控制器的控制方法研究［J］. 机械科学与技术, 2011,30(1):166-172.
WANG Shuyan, SHI Yu, FENG Zhongxu. Research on Control Method Based on Fuzzy PID Controller ［J］.Mechanical Science and Technology, 2011,30(1):166-172.
［16］谢宏, 杨鹏, 陈海滨, 等. 遗传优化模糊PID融合算法的5自由度机械手控制［J］. 电子测量与仪器学报, 2015,29(1):21-30.
XIE Hong, YANG Peng, CHEN Haibin, et al. 5 DOF Manipulator Control Based on Genetic Optimization Fuzzy PID Fusion Algorithm ［J］.Journal of Electronic Measurement and Instrumentation, 2015,29(1):21-30.
［17］田劼. 悬臂掘进机掘进自动截割成形控制系统研究［D］. 北京：中国矿业大学（北京）, 2010.
TIAN Jie. Research on Automatic Cutting Forming Control System for Tunneling Machine with Cantilever ［D］. Beijing：China University of Mining and Technology(Beijing), 2010.
［18］杨阳. 基于振动测试的掘进机关键结构动态特性研究［D］. 北京：中国矿业大学(北京), 2017.
YANG Yang. Study on Dynamic Characteristics of Key Structure of Roadheader Based on Vibration Test ［D］. Beijing：China University of Mining and Technology(Beijing), 2017.
［19］张介夫. 纵轴掘进机自动截割成形和恒功率截割控制技术研究［D］. 哈尔滨：哈尔滨工业大学, 2013.
ZHANG Jiefu. Research on Automatic Cutting Forming and Constant Power Cutting Control Technology of Longitudinal Shaft Roadheader ［D］. Harbin：Harbin Institute of Technology, 2013.

[1]	SUN Yongguo, JIN Xin, XUE Dong, SHAN Jianping, SHI Xiaochun. Optimal Design of Slip Oil Pump Impeller Structures Based on NSGA-Ⅱ [J]. China Mechanical Engineering, 2024, 35(03): 559-569.
[2]	SUN Yuxiang, CHEN Li, LONG Bo, WANG Yanping, LIU Shihua, JIA Kun. Intelligent Layout for Pipeline Supports of Nuclear Power Plant under Complex Load [J]. China Mechanical Engineering, 2024, 35(02): 317-323，336.
[3]	XIE Miao, ZHU Yun, LIU Jie, REN Ze, YANG Zhiyong, LIU Zhixiang, WANG He, MENG Qingshuang. Prediction and Analysis of Cutting Stability Based on Improved Discrete Method [J]. China Mechanical Engineering, 2023, 34(18): 2153-2164，2176.
[4]	QU Ligang, SU Yan, XIN Yufei. Automatic Layout Method of Aircraft Tank Pipelines Based on SHO-NSGA Hybrid Algorithm [J]. China Mechanical Engineering, 2023, 34(15): 1864-1872.
[5]	ZHENG Kun, LIAN Zhiwei, GU Xinyan, ZHU Changjian, XU Hui, FENG Xueqing. Hybrid Flow Shop Scheduling Problems with Unrelated Parallel Machine Solved by Improved Adaptive Genetic Algorithm(IAGA) with ITPX [J]. China Mechanical Engineering, 2023, 34(14): 1647-1658，1671.
[6]	PENG Xiang, JIANG Haohao, GUO Yuliang, LI Jiquan, YI Bing, JIANG Shaofei, . Collaborative Optimization of Stacking Sequence and Material Distribution for Wing Skins [J]. China Mechanical Engineering, 2023, 34(12): 1415-1424,1435.
[7]	FU Xiang, WANG Yuxin, LIU Daoyuan, WANG Jijie, . Driving Force Control of Hub Motor Vehicle Based on Off-road Condition Identification [J]. China Mechanical Engineering, 2023, 34(08): 955-965.
[8]	ZHANG Junxin, CHEN Wei, HUANG Sikai, WU Haibin. Control Strategies for Industrial Robot Motion along Slot Based on Force and Position Hybrid Guidances [J]. China Mechanical Engineering, 2023, 34(06): 712-719，726.
[9]	ZHANG Ke, WANG Xiaokai, HUA Lin, HAN Xinghui, NING Xiangjin, . Study on Offset Mechanism and Adaptive Fuzzy Control Method for Radial-axial Ring Rolling Processes of Super Large Rings [J]. China Mechanical Engineering, 2023, 34(01): 109-117.
[10]	ZHANG Hongliang, XU Gongjie, BAO Qiang, PAN Ruilin. Distributed Flexible Job Shop Green Scheduling with Transportation Time [J]. China Mechanical Engineering, 2022, 33(21): 2554-2563,2645.
[11]	JIANG Yixiao , JI Weixi, HE Xin, SU Xuan. Low-carbon Scheduling of Multi-objective Flexible Job-shop Based on Improved NSGA-Ⅱ [J]. China Mechanical Engineering, 2022, 33(21): 2564-2577.
[12]	ZOU Xihong, LING Long, CHEN Jing, WANG Chao, GOU Linlin, JIANG Mingcong, YUAN Dongmei. Research on Durability Test Specifications of User-association Drive Axle Test Fields [J]. China Mechanical Engineering, 2022, 33(14): 1670-1679.
[13]	ZHANG Xin, SUI Zhiwei, LI Zhanlong, QIN Yuan, WANG Yao, DONG Di, ZHAO Junduo. Test and Optimization of Nonlinear Vibration Reduction Systems for Loader Cabs [J]. China Mechanical Engineering, 2022, 33(13): 1529-1536.
[14]	ZHANG Jiahua, LI Aiping, LIU Xuemei. Routing Planning for Assembly Line Material Distributions under Interval Uncertain Travel Time [J]. China Mechanical Engineering, 2021, 32(18): 2239-2246.
[15]	ZHANG Fengfeng, ZHANG Xin, CHEN Long, SUN Lining, ZHAN Wei. Binocular Camera Calibration Based on BP Neural Network Optimized by Improved Genetic Algorithm#br# [J]. China Mechanical Engineering, 2021, 32(12): 1423-1431.