车辆振动测试平台结构设计与控制策略优化

Zhiqiang Xi, Yongzheng Guo, Yiliu Wang, Kui Liu, Haiyang Yang, Zhanzheng Guo, Shuai Zhang
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引用次数: 0

摘要

针对车辆振动试验平台精度高、承载能力大、响应速度快的需求,对车辆振动试验平台进行了三维模型设计与分析;为提高平台的运动性能,提出了混合启发式算法与 PID 控制相结合的振动试验平台形式控制策略。根据设计的三维模型参数,推导出伺服电动缸的单通道数学模型,并建立了混合启发式算法 PID 优化模型,对比分析了平台与 Ziegler-Nichols 法 PID 的控制性能。结果表明,采用混合启发式算法 PID 控制时,阶跃系统过冲为 3.80%,系统动态性能显著提高。建立了车辆振动测试平台控制的仿真系统模型,运行结果表明,采用混合启发式算法 PID 控制时,平台在空间位置变化曲线上更接近输入信号。其最大位移误差为 0.09 mm,与 Ziegler-Nichols 法 PID 控制相比,系统的运动精度提高了 61%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Vehicle vibration test platform structure design and control strategy optimization

Vehicle vibration test platform structure design and control strategy optimization

For the needs of vehicle vibration test platform with high precision, large load capacity and fast response, the three-dimensional model design and analysis of vehicle vibration test platform are carried out; in order to improve the motion performance of the platform, a vibration test plat-form control strategy combining hybrid heuristic algorithm and PID control is proposed. Based on the designed 3D model parameters, the single-channel mathematical model of the servo-electric cylinder is derived and a hybrid heuristic algorithm PID optimization model is established to compare and analyze the control performance of the platform with the Ziegler-Nichols method PID. The results show that the step system overshoot is 3.80% and the dynamic performance of the system is significantly improved when the hybrid heuristic algorithm PID control is used. The simulation system model of vehicle vibration test platform control is established, and the operation results show that the platform is closer to the input signal in the spatial position change curve when the hybrid heuristic algorithm PID control is used. Its maximum displacement error is 0.09 mm, and the motion accuracy of the system is improved by 61% compared with the Ziegler-Nichols method PID control.

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