摩擦界面铜基粉末冶金材料的自修复特性及状态预测方法研究

IF 2 3区材料科学 Q2 ENGINEERING, MECHANICAL

Surface Topography: Metrology and Properties Pub Date : 2024-05-09 DOI:10.1088/2051-672x/ad44b7

Jianpeng Wu, Chengbing Yang, Wenya Shu, Yuxin Wang, Liyong Wang

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引用次数: 0

摘要

在高功率密度传动系统中，铜基粉末冶金材料的摩擦和磨损特性直接关系到工作可靠性。此外，这些材料在材料界面上具有摩擦自愈合特性。本文重点探讨了铜基粉末冶金材料的愈合机理，并进行了 "损伤愈合 "试验，提出了表征自愈合特性的方法。随后，通过对比试验，分析了温度、速度和压力对自愈合特性的影响。结果表明，温度升高会使沟宽和沟深分别减少 15.30% 和 59.76%。压力对表面粗糙度的影响最大，降低了 67%。同时，本文开发了一种 PSO（粒子群优化）-LSTM（长短期记忆）方法，可准确预测自愈表征参数和自愈时间，误差小（平均为 4.35%），相关系数（R2）高（平均为 0.976）。这项研究有助于摩擦材料界面修复技术的发展。

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Research on self-healing characteristic and state prediction method of the copper based powder metallurgy materials on friction interface

In high power density transmission systems, the friction and wear characteristic of copper based powder metallurgy materials is directly linked to working reliability. Moreover, these materials have frictional self-healing characteristic at the material interface. This paper focuses on exploring the healing mechanism of copper based powder metallurgy materials and conducts ‘damage-healing’ tests, proposing a method to characterize the self-healing characteristic. Subsequently, through comparative tests, the influence of temperature, speed, and pressure on the self-healing characteristics is analyzed. The results show that the increase in temperature reduces the furrow width and depth by 15.30% and 59.76%, respectively. Pressure has the greatest effect on surface roughness, reducing it by 67%. Meanwhile, this paper developed a PSO (Particle Swarm Optimization)-LSTM (Long Short-Term Memory) method to accurately predict the self-healing characterization parameters and self-healing time with small error (average 4.35%) and high correlation coefficient (R ²) (average 0.976). This study contributes to the development of interface repair technology for friction materials.

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来源期刊

Surface Topography: Metrology and Properties Materials Science-Materials Chemistry

CiteScore

4.10

自引率

22.20%

发文量

183

期刊介绍： An international forum for academics, industrialists and engineers to publish the latest research in surface topography measurement and characterisation, instrumentation development and the properties of surfaces.