Experimental and finite element analysis of surface asperity geometry during the running-in phase of rolling contact

IF 1.8 4区 工程技术 Q3 ENGINEERING, MECHANICAL
Nurul Farhana Mohd Yusof, Zaidi Mohd Ripin
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Abstract

This paper presents the experimental and finite element analysis of surface asperity geometry during the running-in phase of rolling contact. Previous research efforts typically relied on simulating various shapes of asperity geometry to elucidate rough surface characteristics. However, this approximation did not accurately represent the actual surface asperities. In this study, a rolling contact rig was fabricated, and periodic surface scans were utilized to track the deformation of roller surface asperities. The experimental findings reveal a notable 69% reduction in surface roughness throughout the running-in phase, alongside showcasing the deformation of asperity geometry. Subsequently, a simulation model is developed using data derived from these experiments. Stress analysis conducted on individual and multiple asperities illustrates a decrease in contact stress over time, indicating a transition in contact behavior from plastic to elastic. Furthermore, simulations involving multiple asperities demonstrate an expansion in contact length as roughness diminishes with increasing cycles. Initially, only the highest peaks of asperities make contact, resulting in elevated contact stress. However, as rolling cycles progress, a greater number of asperities come into contact, leading to a more uniform distribution of load. Notably, the more prominent asperities endure significant contact stress and deformation compared to their smaller counterparts.
滚动接触磨合阶段表面粗糙度几何形状的实验和有限元分析
本文介绍了对滚动接触磨合阶段表面粗糙度几何形状的实验和有限元分析。以往的研究通常依靠模拟各种形状的表面粗糙度来阐明粗糙表面的特征。然而,这种近似方法并不能准确反映实际的表面粗糙度。在这项研究中,我们制作了一个滚动接触装置,并利用周期性表面扫描来跟踪辊子表面粗糙度的变形情况。实验结果表明,在整个磨合阶段,表面粗糙度显著降低了 69%,同时还展示了表面粗糙度的几何变形。随后,利用这些实验数据开发了一个模拟模型。对单个和多个表面粗糙度进行的应力分析表明,接触应力随着时间的推移而减小,这表明接触行为已从塑性向弹性过渡。此外,涉及多个表面的模拟结果表明,随着循环次数的增加,粗糙度减小,接触长度也随之增加。起初,只有最高峰的表面进行接触,导致接触应力升高。然而,随着滚动周期的增加,更多的表面会发生接触,从而导致载荷分布更加均匀。值得注意的是,与较小的表面相比,较突出的表面会承受较大的接触应力和变形。
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
CiteScore
3.80
自引率
10.00%
发文量
625
审稿时长
4.3 months
期刊介绍: The Journal of Mechanical Engineering Science advances the understanding of both the fundamentals of engineering science and its application to the solution of challenges and problems in engineering.
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