Polynomial Excitation Current Compensation Control for Dead Zone and Hysteresis of Three-way Proportional Pressure Reducing Valve

IF 2.5 3区计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS

International Journal of Control Automation and Systems Pub Date : 2024-07-02 DOI:10.1007/s12555-022-0718-z

Yan-He Song, Kai-Xian Ba, Xin Chen, Yue-Yue Hao, Chao Ai, Xiang-Dong Kong

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Abstract

In this paper, aiming at the phenomenon that the dead zone and hysteresis of three-way proportional pressure reducing valve (TPPRV) will seriously affect the control accuracy of construction machinery, a polynomial excitation current compensation controller (PECC) is designed, which is novel and easy to realize in engineering. Firstly, the mathematical model of TPPRV is established, and the dead zone and hysteresis of TPPRV are quantitatively analyzed by using the performance test platform of proportional pressure reducing valve. Secondly, the design principle of PECC is expounded, and the controller model is deduced theoretically. The proposed PECC has two main advantages. One is that the method does not need to establish the nonlinear model of dead zone and hysteresis, and the other is that the method can compensate the dead zone and hysteresis simultaneously. Finally, the compensation control performance of PECC is verified by using the performance test platform of proportional pressure reducing valve. The experimental results show that PECC can greatly reduce the adverse effects of dead zone and hysteresis on TPPRV, and has great applicability under different working conditions. Relevant research results can significantly improve the proportional control accuracy of TPPRV, which has a certain engineering value.

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三通比例减压阀死区和滞后的多项式励磁电流补偿控制

本文针对三通比例减压阀（TPPRV）的死区和滞后会严重影响工程机械控制精度的现象，设计了一种新颖且易于在工程中实现的多项式励磁电流补偿控制器（PECC）。首先，建立了 TPPRV 的数学模型，并利用比例减压阀性能测试平台对 TPPRV 的死区和滞后进行了定量分析。其次，阐述了 PECC 的设计原理，并从理论上推导出控制器模型。所提出的 PECC 有两大优点。其一是该方法无需建立死区和滞后的非线性模型，其二是该方法可同时对死区和滞后进行补偿。最后，利用比例减压阀性能测试平台验证了 PECC 的补偿控制性能。实验结果表明，PECC 可大大降低死区和滞后对 TPPRV 的不利影响，在不同工况下具有很强的适用性。相关研究成果可显著提高 TPPRV 的比例控制精度，具有一定的工程价值。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Control Automation and Systems 工程技术-自动化与控制系统

CiteScore

5.80

自引率

21.90%

发文量

343

审稿时长

8.7 months

期刊介绍： International Journal of Control, Automation and Systems is a joint publication of the Institute of Control, Robotics and Systems (ICROS) and the Korean Institute of Electrical Engineers (KIEE). The journal covers three closly-related research areas including control, automation, and systems. The technical areas include Control Theory Control Applications Robotics and Automation Intelligent and Information Systems The Journal addresses research areas focused on control, automation, and systems in electrical, mechanical, aerospace, chemical, and industrial engineering in order to create a strong synergy effect throughout the interdisciplinary research areas.