Vehicle drifting: mathematical theory and dynamic analysis for stabilised drifting of RWD vehicles

Q4 Engineering International Journal of Advanced Mechatronic Systems Pub Date : 2021-05-21 DOI:10.1504/IJAMECHS.2021.10038137

Sina Milani, H. Marzbani, R. Jazar

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引用次数: 1

Abstract

This paper introduces a mathematical definition for drifting of vehicles. A necessary kinematic condition for enabling negative body side-slip angle at centre of the front wheel during a left-hand turn is identified as drifting indicator. Dynamics of the drifting motion is investigated by means of a simplified three-wheel vehicle model in steady-state, focusing on rear wheel drive (RWD) vehicles. Drifting point is identified as an unstable equilibrium point of the nonlinear system. The equilibrium point is made stable by means of direct control only over yaw velocity, as a single key stabilising objective, and using the steady-state model as feedforward. A four-wheel planar dynamic simulation model is used together with a combined slip tyre model to investigate the accuracy of the proposed analysis. Steady-state RWD drifting motion is achieved by using the proposed method, validating the proposed dynamics analysis. Finally, the drifting metric is used to measure the amount of drifting achieved during a manoeuvre and its effectiveness is observed.

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车辆漂移：RWD车辆稳定漂移的数学理论和动力学分析

本文介绍了车辆漂移的数学定义。在左转弯过程中，在前轮中心启用负车身侧滑角的必要运动学条件被识别为漂移指示器。以后轮驱动（RWD）汽车为研究对象，采用简化的三轮汽车稳态模型研究了漂移运动的动力学。漂移点被识别为非线性系统的不稳定平衡点。通过仅对偏航速度进行直接控制，作为单一的关键稳定目标，并使用稳态模型作为前馈，使平衡点稳定。将四轮平面动力学仿真模型与组合滑移轮胎模型结合使用，以研究所提出分析的准确性。利用所提出的方法实现了RWD的稳态漂移运动，验证了所提出的动力学分析。最后，漂移度量用于测量机动过程中实现的漂移量，并观察其有效性。

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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来源期刊

International Journal of Advanced Mechatronic Systems Engineering-Mechanical Engineering

CiteScore

1.20

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0.00%

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