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Braking performance of a novel frictional-magnetic compound disc brake for automobiles

电子制动力分配系统 发动机制动 临界制动 动态制动 缓速器 汽车工程 盘式制动器 制动器 制动距离 刹车片 液压制动器 涡流制动器 扭矩 摩擦力矩 材料科学 机械 工程类 物理 热力学
作者
Yan Yin,Jiusheng Bao,Jinge Liu,Chaoxun Guo,Tonggang Liu,Yangyang Ji
出处
期刊:Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering [SAGE Publishing]
卷期号:233 (10): 2443-2454 被引量:6
标识
DOI:10.1177/0954407018791056
摘要

Disc brakes have been applied in various automobiles widely and their braking performance has vitally important effects on the safe operation of automobiles. Although numerous researches have been conducted to find out the influential law and mechanism of working condition parameters like braking pressure, initial braking speed, and interface temperature on braking performance of disc brakes, the influence of magnetic field is seldom taken into consideration. In this paper, based on the novel automotive frictional-magnetic compound disc brake, the influential law of magnetic field on braking performance was investigated deeply. First, braking simulation tests of disc brakes were carried out, and then dynamic variation laws and mechanisms of braking torque and interface temperature were discussed. Furthermore, some parameters including average braking torque, trend coefficient and fluctuation coefficient of braking torque, average temperature, maximum temperature rise, and the time corresponding to the maximum temperature rise were extracted to characterize the braking performance of disc brakes. Finally, the influential law and mechanism of excitation voltage on braking performance were analyzed through braking simulation tests and surface topography analysis of friction material. It is concluded that the performance of frictional-magnetic compound disc brake is prior to common brake. Magnetic field is greatly beneficial for improving the braking performance of frictional-magnetic compound disc brake.

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