电动汽车再生式防抱死制动系统的中保真度回路可行性研究

IF 2.8 Q2 TRANSPORTATION SCIENCE & TECHNOLOGY SAE International Journal of Vehicle Dynamics Stability and NVH Pub Date : 2023-07-29 DOI:10.4271/10-07-03-0022
Nastaran Ghanami, Kamyar Nikzadfar, Hamidreza Mohammadi Daniali
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引用次数: 0

摘要

尾气零排放立法推动了汽车行业向更加电气化的方向发展。再生制动是指电机提供制动扭矩的能力。到目前为止,再生制动功能主要考虑的是其对能源效率的影响。然而,由于永磁同步电动机(PMSM)的快速转矩跟踪特性,为每个车轮使用单独的电机可以应用防抱死制动功能。由于其相当大的成本降低,在这篇文章中,可行性研究进行了调查,如果ABS功能可以完全通过再生制动使用中保真度模型为基础的方法来完成。以整车为例,采用表面贴装式永磁同步电机(SPMSM)模型对该方法进行了验证。所提出的ABS控制系统具有层次结构,包括高级纵向滑移控制器和低级SPMSM转矩控制器。考虑到轮胎-路面动力学的不确定性,设计了一种滑模控制方法,并将其作为高级滑移控制器。同时,采用PID矢量控制方法使SPMSM制动转矩保持在高层控制器要求的最优值。此外,为了估计轮胎纵滑和车速,提出了一种同时估计这两个参数的扩展卡尔曼滤波器(EKF)。结果表明,在各种路况下,所提出的分级控制和估计方法均能使轮胎纵向滑移保持在最优值,并防止车轮锁死。
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A Mid-fidelity Model in the Loop Feasibility Study for Implementation of Regenerative Antilock Braking System in Electric Vehicles
The tailpipe zero-emission legislation has pushed the automotive industry toward more electrification. Regenerative braking is the capability of electric machines to provide brake torque. So far, the regenerative braking feature is primarily considered due to its effect on energy efficiency. However, using individual e-machines for each wheel makes it possible to apply the antilock braking function due to the fast torque-tracking characteristics of permanent magnet synchronous motors (PMSM). Due to its considerable cost reduction, in this article, a feasibility study is carried out to investigate if the ABS function can be done purely through regenerative braking using a mid-fidelity model-based approach. An uni-tire model of the vehicle with a surface-mount PMSM (SPMSM) model is used to verify the idea. The proposed ABS control system has a hierarchical structure containing a high-level longitudinal slip controller and a low-level SPMSM torque controller. Given the uncertainties of the tire–road dynamics, a sliding mode control method is designed and employed as a high-level slip controller. Also, a PID vector control method is used to keep the SPMSM braking torque at the optimal value requested by the high-level controller. Moreover, in order to estimate the tire longitudinal slip and vehicle velocity, an extended Kalman filter (EKF) is developed that estimates both parameters at the same time. The results show that the proposed hierarchical control and estimators can keep the tire longitudinal slip at the optimal value and prevent the wheel from locking in a variety of road conditions.
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自引率
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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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