高速列车磁流变半主动悬挂控制策略研究
RESEARCH ON CONTROL STRATEGY OF MAGNETORHEOLOGICAL SEMI-ACTIVE SUSPENSION FOR HIGH-SPEED TRAIN
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摘要: 为了提高列车运行平稳性, 在经典的天棚控制和加速度控制的基础上, 提出了一种新型混合控制策略, 对高速列车磁流变半主动悬挂控制系统进行了仿真和实验研究. 首先, 对磁流变阻尼器(MRD)的力学特性测试分析, 引入具有电流饱和特性的修正函数, 建立了MRD的修正扩展双曲正切模型. 然后, 设计了面向列车平稳性的新型混合控制策略, 通过分析车体加速度传递特性, 比较了不同控制策略在全频域内的控制效果. 此外, 从相频特性的角度阐释了新型混合控制策略在全频段的控制优势. 将MRD修正模型应用于悬挂控制, 利用UM和Simulink软件建立了整车磁流变半主动悬挂控制系统联合仿真模型, 分析不同控制策略对车辆动力学性能的影响. 最后, 构建了基于MRD的整车悬挂系统硬件在环实验台, 通过开展硬件在环实验分析不同控制策略下的车体响应. 结果表明, 相比传统的控制策略, 新型混合控制策略能兼顾低频段和高频段的振动控制效果, 不仅可以提高列车的运行平稳性, 而且不会恶化列车的运行安全性. 硬件在环实验证明了新型混合控制策略的有效性, 以及高速列车应用半主动控制悬挂的可行性.Abstract: To improve the running stability of the trains, a new mixed control strategy is proposed based on the classical sky hook and acceleration-driven damping controls. The numerical simulation and hardware-in-the-loop experimental investigation on the control system of the high-speed train magnetorheological semi-active suspension are carried out, which verifies that the new mixed control strategy has a good control effect. Firstly, the mechanical characteristics of magnetorheological damper (MRD) are tested and analyzed, and a modified extended hyperbolic tangent model of MRD is established by introducing a modified function with current saturation characteristics. Then, a new mixed control strategy is designed to improve the running stability of the trains, and the proposed mixed control strategy parameters are determined. The control effects of different control strategies in the whole frequency domain are compared by analyzing the carbody acceleration transmission characteristics. Furthermore, the control advantages of the new mixed control strategy in the whole frequency domain are explained from the perspective of phase frequency characteristics. The modified MRD model is applied to the suspension control of the high-speed trains, and the joint simulation model of the vehicle magnetorheological semi-active suspension control system is established using UM software and Simulink software to analyze the influence of different control strategies on the vehicle's dynamic performance. Finally, a hardware-in-the-loop experimental table of the vehicle suspension system based on MRD is constructed, and the carbody response under different control strategies is analyzed through the hardware-in-the-loop experimental. The results reveal that compared with the traditional control strategy, the new mixed control strategy has a good control effect in low frequency and high frequency, which can not only improve the running stability of the trains, but also not deteriorate the running safety of the trains. The hardware-in-the-loop experiment proves the effectiveness of the new mixed control strategy and the feasibility of applying semi-active control suspension to high-speed trains.