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contributor authorJ. Yang
contributor authorK. Komvopoulos
contributor authorProfessor Fellow ASME
date accessioned2017-05-09T00:17:58Z
date available2017-05-09T00:17:58Z
date copyrightApril, 2005
date issued2005
identifier issn0742-4787
identifier otherJOTRE9-28731#315_1.pdf
identifier urihttp://yetl.yabesh.ir/yetl/handle/yetl/132706
description abstractA contact mechanics theory of static friction is presented for isotropic rough surfaces exhibiting fractal behavior. The analysis is based on a piecewise power-law size distribution and a normal slope distribution of the asperity contacts and elastic–fully plastic deformation models. Numerical integration yields solutions for the normal and friction forces in terms of fractal parameters, elastic–plastic material properties, and interfacial shear strength. The variation of the static coefficient of friction with normal load is related to the effect of the surface topography on the dominant deformation mode at the asperity contacts. Plastic deformation of the smaller asperity contacts dominates at low loads and elastic deformation of the larger asperity contacts dominates at high loads. The critical load signifying the transition from predominantly plastic to elastic deformation depends on the fractal parameters and material properties. In the low-load range, the static coefficient of friction decreases with the increase of the load, while in the high-load range it increases with the load. Numerical results for copper fractal surfaces illustrate the effects of normal load, surface topography, and interfacial shear strength on the static coefficient of friction.
publisherThe American Society of Mechanical Engineers (ASME)
titleA Mechanics Approach to Static Friction of Elastic–Plastic Fractal Surfaces
typeJournal Paper
journal volume127
journal issue2
journal titleJournal of Tribology
identifier doi10.1115/1.1828080
journal fristpage315
journal lastpage324
identifier eissn1528-8897
keywordsForce
keywordsDeformation
keywordsFriction
keywordsSurface roughness
keywordsStress
keywordsFractals
keywordsShear strength
keywordsStiction AND Contact mechanics
treeJournal of Tribology:;2005:;volume( 127 ):;issue: 002
contenttypeFulltext


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