双轮车制动盘优化材料的研究与选择:实验和有限元方法

C. Prakash, J. Prakash
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引用次数: 0

摘要

制动盘是汽车制动系统中的重要部件,可在需要时帮助降低车速或使车辆停止。而提高制动系统的效能对研究人员来说是一项极具挑战性的工作,因为只有最大限度地缩短制动时的停车距离,才能确保行车安全。然而,制动系统的性能主要取决于制动系统中使用的制动盘材料。当前的趋势是,使用强度重量比高的替代材料来降低汽车的油耗。因此,研究人员集中研究纤维增强聚合物复合材料和金属基复合材料,以制造汽车零部件。在这项研究工作中,现有低碳钢制动转子的性能与使用不同材料(如锆涂层钢、AA7075+nSiCp、AA6061+纳米稻壳灰颗粒、玻璃纤维增强聚合物复合材料和碳纤维增强聚合物复合材料)制造的制动盘相关联。报告了两轮车制动系统的制动距离、制动盘重量、摩擦系数和制动盘材料的耐磨性能。此外,还开发了三维有限元模型(3D FEM)并模拟了制动机制。实验和有限元分析结果表明,SiC 增强 AA7075 复合材料具有符合要求的性能,如 558 兆帕的最大应力、优异的耐磨性、0.40 的良好摩擦系数、良好的散热性能和 81 米的有效制动距离。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigation and selection of optimistic material for two wheeler brake disc: An experimental and finite element approach
The brake disc is a vital component in the braking system of the automobile which helps in reducing the speed or stopping the vehicle whenever required. Whereas, increasing the effectiveness of the braking system is highly challenging for the researchers to ensure safe driving by minimizing the stopping distance of the vehicle during braking. However, the performance of the braking system mainly relies on the brake disc material utilized in the braking system. In the current trend, the usage of alternate materials with a high strength-to-weight ratio is in practice to reduce the fuel consumption of the automobile. Hence, researchers concentrate on Fiber Reinforced Polymer Composites and Metal Matrix Composites to manufacture automotive components. In this research work, the performance of the existing mild steel brake rotor is correlated with brake discs fabricated using different materials such as zirconium-coated steel, AA7075+nSiCp, AA6061+nano Rice Husk Ash particles, Glass Fiber Reinforced Polymer composite, and Carbon Fiber Reinforced Polymer composites. The effectiveness of a two-wheeler braking system is reported concerning the stopping distance, disc weight, friction coefficient, and wear resistance properties of the brake disc material. Moreover, a 3D Finite Element Model (3D FEM) is also developed and the braking mechanism is simulated. The experimental and FEA results reveal that SiC reinforced AA7075 composite shows compromising properties as required such as maximum stress of 558 MPa, excellent wear resistance, good friction coefficient of 0.40, good temperature dissipation property, and effective stopping distance of 81 m.
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