冲击条件下基于自抗扰电流补偿的电动汽车电驱动系统振动主动控制

IF 2.8 Q2 TRANSPORTATION SCIENCE & TECHNOLOGY SAE International Journal of Vehicle Dynamics Stability and NVH Pub Date : 2023-10-17 DOI:10.4271/10-07-04-0033
Shuaishuai Ge, Shuang Hou, Yufan Yang, Zhigang Zhang, Fang Tang
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引用次数: 0

摘要

为解决电动汽车减速带、路面凹凸不平等冲击条件引起的扭转振动问题,建立了综合机电耦合动力学模型。该模型包括电动汽车电驱动系统中永磁同步电动机和齿轮传动系统的动力学行为。研究了系统在冲击条件下的机电耦合动力学和振动特性。在此基础上,提出了一种针对冲击工况下电动汽车电驱动系统的创新主动阻尼控制策略。该策略采用自抗扰电流补偿(ADRCC)实现半轴两端的速度差为零作为跟踪控制目标,并将补偿电流叠加在电机控制器的原给定电流上。结果表明了该策略的有效性。在单脉冲冲击条件下,齿轮传动系统的振动能量比不加控制器时减少了约63.1%。在连续冲击条件下,与不加控制器相比,齿轮传动系统的振动能量减少了约55.63%,速度差的累积误差减少了约61.4%。结果表明,所提出的策略成功地抑制了冲击条件下电驱动系统的连续振荡。研究结果为电动汽车电驱动系统的振动抑制提供了理论参考。
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Active Vibration Control of Electric Drive System in Electric Vehicles Based on Active Disturbance Rejection Current Compensation under Impact Conditions
To address the torsional vibration caused by impact conditions in electric vehicles (EVs), such as deceleration belts and road irregularities, a comprehensive electromechanical coupling dynamics model is developed. This model includes the dynamic behavior of the permanent magnet synchronous motor (PMSM) and the gear transmission system in the EV’s electric drive system. The study aims to investigate the electromechanical coupling dynamics and vibration characteristics of the system under impact conditions. Based on this, an innovative active damping control strategy is proposed for the EV’s electric drive system when subjected to impact conditions. This strategy incorporates active disturbance rejection current compensation (ADRCC) to achieve a speed difference of zero at two ends of the half-shaft as the tracking control target, and compensating current is superimposed on the original given current of the motor controller. The results highlight the effectiveness of the proposed strategy. Under single-pulse impact condition, the vibration energy of the gear transmission system is reduced by approximately 63.1% compared to without the controller. Under continuous impact conditions, the vibration energy of the gear transmission system is reduced by approximately 55.63% and the cumulative error of the speed difference is reduced by approximately 61.4% compared to without the controller. These findings demonstrate that the proposed strategy successfully suppresses the continuous oscillation of the electric drive system under impact conditions. The research results provide a theoretical reference for the vibration suppression of the electric drive system of EVs.
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6.40
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41.20%
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Reviewers Contribution to the Objective Evaluation of Combined Longitudinal and Lateral Vehicle Dynamics in Nonlinear Driving Range Active Vibration Control of Electric Drive System in Electric Vehicles Based on Active Disturbance Rejection Current Compensation under Impact Conditions Damping Magnetorheological Systems Based on Optimal Neural Networks Preview Control Integrated with New Hybrid Fuzzy Controller to Improve Ride Comfort Letter from the Special Issue Editors
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