B<sub>4</sub>C改性Cu基刹车片配对C/C-SiC的摩擦学行为及机理

doi:10.19976/j.cnki.43-1448/TF.2023026

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摘要 Cu基刹车片在高速循环制动过程中存在基体软化和摩擦膜破裂的问题。采用粉末冶金法制备碳化硼(B₄C)质量分数为0~6%的Cu基刹车片,并选取C/C-SiC制动盘作为对偶件,研究制动过程中形成的B₂O₃摩擦膜对摩擦磨损性能的影响,并分析磨损机制。结果表明,通过B₄C改性可降低Cu基摩擦材料的密度, w(B₄C)为4%和6%时,材料密度显著降低,强度大幅提高,并分别获得最优的抗热衰退性能和最低磨损率。制动过程中B₄C氧化形成的B₂O₃具有类似于MoS₂和石墨的层状晶体结构,在滑动界面处容易剪切,从而提高平均摩擦稳定系数并降低磨损率。在B₄C表面形成的B₂O₃与Cu基体结合良好。当B₄C质量分数超过4%时,Cu基刹车片的磨损机制从分层磨损为主转变为氧化磨损为主。

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	罗勇
	李专
	吴佳琦

关键词 ： B₄C, B₂O₃, Cu基刹车片, C/C-SiC, 磨损机制

Abstract：Copper based brake pads have the problems of matrix softening and friction film breaking during high-speed cycle braking. Cu-based brake pads with boron carbide (B₄C) mass fraction of 0-6% were prepared using powder metallurgy (PM) method, and C/C-SiC brake discs were selected as dual components to study the effect of B₂O₃ friction film formed during the braking process on friction and wear performance, and to analyze the wear mechanism. The results show that the density of copper based friction materials can be reduced by modifying with B₄C. When the mass fraction of B₄C is 4% and 6%, the material density significantly decrease and the strength increase, and the most excellent thermal degradation resistance and the lowest wear rate are obtained, respectively. During the braking process, B₂O₃ formed by B₄C oxidation has a layered crystal structure similar to MoS₂ and graphite, which is easy to shear at the sliding interface, thereby improving the mean friction stability coefficient and reducing wear rate. B₂O₃ formed on the surface of B₄C combines well with the Cu matrix. When the mass fraction of B₄C exceeds 4%, the wear mechanism of Cu-based brake pads shifts from delamination wear to oxidation wear.

Key words： B₄C B₂O₃ Cu-based brake pads C/C-SiC wear mechanism

收稿日期: 2023-03-24 出版日期: 2023-07-06

ZTFLH:

TB333

基金资助:国家重点研发计划资助项目(2021YFB3703803)

通讯作者: 李专,教授,博士。电话：0731-88879422;E-mail: 210137@csu.edu.cn

引用本文:

罗勇, 李专, 吴佳琦. B₄C改性Cu基刹车片配对C/C-SiC的摩擦学行为及机理[J]. 粉末冶金材料科学与工程, 2023, 28(3): 262-275.
LUO Yong, LI Zhuan, WU Jiaqi. Tribological performance and mechanism of B₄C modified Cu-based brake pads mated with C/C-SiC. Materials Science and Engineering of Powder Metallurgy, 2023, 28(3): 262-275.

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http://pmbjb.csu.edu.cn/CN/10.19976/j.cnki.43-1448/TF.2023026 或 http://pmbjb.csu.edu.cn/CN/Y2023/V28/I3/262

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