Modelling and control of electromechanical disc brake for heavy-duty vehicles

İbrahim Can Güleryüz, Özgün Başer, Özgün Cem Yılmaz
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Abstract

This paper proposes a validated procedure that can be used for development stage of model-based controller for heavy-duty electromechanical disc brakes. Firstly, system dynamics model of a single piston electromechanical disc brake is constructed in Matlab/Simulink environment in consideration of nonlinear friction model. To ensure the accuracy of system dynamics model, open loop measurements (clamping force, motor angle and motor current) are conducted on a prototype of single piston electromechanical disc brake. Experimental data is used for the determination of system variables. The predicted outputs are verified by comparison of experimental measurement results. For the control purpose of electromechanical brake, a multi-stage closed loop architecture is introduced. To regulate clamping force, PID and sliding mode controllers are developed in Matlab/Simulink in consideration of braking performance requirements for heavy-duty vehicles. For management of running clearance between brake disc and pad, PID position controller is developed in simulation environment. Those controller parameters obtained in the simulation process are introduced to the control hardware. After that closed loop clamping force and position measurements are conducted. When the rise time values of both clamping force controllers are compared, it is seen that sliding mode controller can reach to the settling point faster than PID controller. As for the position controller, the rise time requirement has been achieved by the designed PID controller. The switching process of force and position controllers are implemented and functional closed loop measurements are conducted for different reference input signals. It is seen from the results that the rise time requirement for position controller has been achieved. The system response of clamping force parameter is considerably stable.
重型车辆机电盘式制动器的建模与控制
本文提出了一种可用于重型机电盘式制动器基于模型控制器开发阶段的验证程序。首先,考虑到非线性摩擦模型,在 Matlab/Simulink 环境中构建了单活塞机电盘式制动器的系统动力学模型。为确保系统动力学模型的准确性,对单活塞机电盘式制动器原型进行了开环测量(夹紧力、电机角度和电机电流)。实验数据用于确定系统变量。通过对比实验测量结果,验证了预测输出。为实现机电制动器的控制目的,引入了多级闭环结构。考虑到重型车辆的制动性能要求,在 Matlab/Simulink 中开发了 PID 和滑动模式控制器来调节夹紧力。为了管理制动盘和制动片之间的运行间隙,在仿真环境中开发了 PID 位置控制器。在仿真过程中获得的控制器参数被引入到控制硬件中。然后进行闭环夹紧力和位置测量。比较两种夹紧力控制器的上升时间值,可以看出滑动模式控制器比 PID 控制器更快到达稳定点。至于位置控制器,所设计的 PID 控制器已达到上升时间要求。力控制器和位置控制器的切换过程已经实现,并对不同的参考输入信号进行了功能闭环测量。从结果可以看出,位置控制器的上升时间要求已经达到。夹紧力参数的系统响应相当稳定。
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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