Dead Zone Compensation Control of New Hydraulic Motor-mechanical Linear Actuator

doi:10.3901/JME.2024.08.337

Abstract

Abstract: In order to solve the problems of unsymmetrical area of pump controlled single rod hydraulic cylinder and low power density of electric cylinder, a new hydraulic motor-mechanical linear actuator system using closed pump controlled hydraulic motor instead of servo motor to drive ball screw is proposed. At the same time, in view of the defect that the new system is difficult to achieve accurate positioning due to the leakage dead zone, a variable universe fuzzy PID with load feedforward is designed to compensate the dead zone. The compensation method fully considers the nonlinearity of the dead zone and the uncertainty of load disturbance. In principle, it does not strictly depend on the mathematical model of the system, and can adaptively adjust the control system when the dead zone changes. Then, in Simulink and SimulationX, the joint simulation model of the system is established. The research results show that, compared with the traditional PID controller, the proposed variable universe fuzzy PID with load feedforward not only effectively solves the problem of dead time compensation, significantly improves the positioning accuracy of the system, but also improves the dynamic response characteristics of the system, and makes the system have good robustness and anti load interference ability.

Key words: pump-control-motor, ball screw, dead-zone compensation, load feed-forward, variable universe fuzzy PID

CLC Number:

TH137

GE Lei, NI Hao, HAO Yunxiao, ZHAO Bin, YUAN Yongliang, QUAN Long. Dead Zone Compensation Control of New Hydraulic Motor-mechanical Linear Actuator[J]. Journal of Mechanical Engineering, 2024, 60(8): 337-347.

References

[1] 陈超，赵升吨，崔敏超，等. 电动缸的研究现状与发展趋势[J]. 机械传动，2015，39(3)：181-186. CHEN Chao，ZHAO Shengdun，CUI Minchao，et al. Study statusand developing trend of electric cylinder[J]. Journal of Mechanical Transmission，2015，39(3)：181-186.
[2] 严亮，张波，梁维刚，等. 伺服电动缸在石油钻台机械手上的应用研究[J]. 机械工程师，2021(7)：20-22. YAN Liang, ZHANG Bo, LIANG Weigang, et al. Study on the application of servo electric cylinder in derrick floor manipulator[J]. Mechanical Engineer，2021(7)：20-22.
[3] 郝云晓，乔舒斐，夏连鹏，等. 液电混合直线驱动系统耦合特性及位置控制[J]. 机械工程学报，2021，57(22)：386-394. HAO Yunxiao，Qiao Shufei，XIA Lianpeng，et al. Coupling characteristics and position control of hydraulic-electric hybrid linear drive system[J]. Journal of Mechanical Engineering，2021，57(22)：386-394.
[4] LIU He，ZHANG Xiaogang，QUAN Long，et al. Research on energy consumption of injection molding machine driven by five different types of electro-hydraulic power units[J]. Journal of Cleaner Production，2020，242：1-11.
[5] 权龙. 泵控缸电液技术研究现状、存在问题及创新解决方案[J]. 机械工程学报，2008，44(11)：87-92. QUAN Long. Current state，problems and the innovative solution of electro-hydraulic technology of pump controlled cylinder[J]. Journal of Mechanical Engineering，2008，44(11)：87-92.
[6] 吴秋梅，刘会明，李强，等.变速泵控闭式转向系统复控策略设计及动态特性[J]. 锻压技术，2022，47(3)：159-163. WU Qiumei，LIU Huiming，LI Qiang，et al. Compound control strategy design and dynamic characteristic on variable speed pump-controlled closed steering system[J]. Forging & Stamping Technology，2022，47(3)：159-163.
[7] RAHMFELD R. Development and control of energy saving hydraulic servo drivens for mobile machine[D]. Hamburg：Hamburg University of Technology，2002.
[8] 王翔宇，张红娟，杨敬，等. 非对称泵控装载机动臂特性研究[J]. 机械工程学报，2021，57(12)：258-266，284. WANG Xiangyu，ZHANG Hongjuan，YANG Jing，et al. Research on the characteristics of wheel loader boom driven by the asymmetric pump controlled system[J]. Journal of Mechanical Engineering，2021，57(12)：258-266，284.
[9] 马艳斌，赵斌，郝云晓. 非对称泵控单出杆液压缸系统特性分析[J]. 液压与气动，2020(8)：167-175. MA Yanbin，ZHAO Bin，HAO Yunxiao. Characteristics analysis of asymmetric pump-controlled single-rod hydraulic cylinder system[J]. Chinese Hydraulics & Pneumatics，2020(8)：167-175.
[10] QUAN Zhongyi，QUAN Long，ZHANG Jinman. Review of energy efficient direct pump controlled cylinder electro-hydraulic technology[J]. Renewable and Sustainable Energy Reviews，2014，35：336-346.
[11] 赵斌，郭伟伟，葛磊，等. 新型流量自平衡泵控非对称液压缸运行特性试验研究[J]. 机械工程学报，2020，56(8)：257-264. ZHAO Bin，GUO Weiwei，GE Lei，et al. Experiment study on operation characteristics of new flow self-balancing pump controlled asymmetric hydraulic cylinder[J]. Journal of Mechanical Engineering，2020，56(8)：257-264.
[12] 姚静，蒋东廷，张伟，等. 开式泵控非对称缸系统一阶轨迹灵敏度分析[J]. 机械工程学报，2019，55(2)：223-232. YAO Jing，JIANG Dongting，ZHANG Wei，et al. First-order trajectory sensitivity analysis of open circuit pump controlled asymmetric cylinder systems[J]. Journal of Mechanical Engineering，2019，55(2)：223-232.
[13] COELHO L，CUNHA M. Adaptive cascade control of a hydraulic actuator with an adaptive dead-zone compensation and optimization based on evolutionary algorithms[J]. Expert Systems with Applications，2011，38(10)：12262-12269.
[14] DENG Wengxiang，YAO Jianyong，MA Dawei. Robust adaptive precision motion control of hydraulic actuators with valve dead-zone compensation[J]. ISA Transactions，2017，70：269-278.
[15] LUO Chengyang，YAO Jianyong，GU J. Extended-state-observer-based output feedback adaptive control of hydraulic system with continuous friction compensation[J]. Journal of the Franklin Institute， 2019， 356(15)：8414-8437.
[16] 沈伟，崔霞. 泵控马达速度伺服系统自抗扰与PID控制[J]. 机械与电子，2019，37(9)：42-46，50. SHEN Wei，CUI Xia. Comparative study of ADRC and PID control of hydraulic motor controlled by pump[J]. Machinery& Electronics，2019，37(9)：42-46，50.
[17] 张敬芳，艾超，闫桂山，等. 泵控马达液压调速系统负载扰动补偿控制[J]. 液压与气动，2016(8)：24-27. ZHANG Jingfang，AI Chao，YAN Guishan，et al. Load vibration compensation control in pump control motor system[J]. Chinese Hydraulics & Pneumatics，2016(8)：24-27.
[18] 董建园，曹旭妍，魏培，等. 电液比例位置控制系统的研究[J].机床与液压，2013，41(7)：40-44，47. DONG Jianyuan，CAO Xuyan，WEI Pei，et al. Research on electro-hydraulic proportional position servo system[J]. Machine Tool & Hydraulics，2013，41(7)：40-44，47.
[19] 刘霞勇，张潜，刘正浩，等. 死区直接补偿的电液系统BP神经网络控制[J]. 液压与气动，2022，46(4)：165-172. LIU Xiayong，ZHANG Qian，LIU Zhenghao，et al. BP neural network control of electro-hydraulic system with dead-zone direct compensation[J]. Chinese Hydraulics & Pneumatics，2022，46(4)：165-172.