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干燥和润滑条件下橡胶-玻璃接触的摩擦滑动起始

Onset of frictional sliding of rubber-glass contact under dry and lubricated conditions.

作者信息

Tuononen Ari J

机构信息

Aalto University Department of Mechanical Engineering, PO Box 14300, FI-00076 Aalto Finland.

出版信息

Sci Rep. 2016 Jun 13;6:27951. doi: 10.1038/srep27951.

DOI:10.1038/srep27951
PMID:27291939
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4904280/
Abstract

Rubber friction is critical in many applications ranging from automotive tyres to cylinder seals. The process where a static rubber sample transitions to frictional sliding is particularly poorly understood. The experimental and simulation results in this paper show a completely different detachment process from the static situation to sliding motion under dry and lubricated conditions. The results underline the contribution of the rubber bulk properties to the static friction force. In fact, simple Amontons' law is sufficient as a local friction law to produce the correct detachment pattern when the rubber material and loading conditions are modelled properly. Simulations show that micro-sliding due to vertical loading can release initial shear stresses and lead to a high static/dynamic friction coefficient ratio, as observed in the measurements.

摘要

橡胶摩擦在从汽车轮胎到气缸密封等许多应用中都至关重要。从静态橡胶样品过渡到摩擦滑动的过程尤其难以理解。本文的实验和模拟结果表明,在干燥和润滑条件下,从静态到滑动运动的分离过程完全不同。结果强调了橡胶本体性能对静摩擦力的贡献。事实上,当对橡胶材料和加载条件进行正确建模时,简单的阿蒙顿定律作为局部摩擦定律足以产生正确的分离模式。模拟表明,如测量中所观察到的,垂直加载引起的微滑动可以释放初始剪应力,并导致高静/动摩擦系数比。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/05c9/4904280/e6317d81f526/srep27951-f1.jpg

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