2D adaptive-surface description model for elastic-plastic asperity contact problems

Tianxiang Liu; Geng Liu; Qin Xie; Quanren Zeng

doi:10.3901/JME.2007.09.091

2D adaptive-surface description model for elastic-plastic asperity contact problems

Tianxiang Liu, Geng Liu, Qin Xie, Quanren Zeng

School of Mechanical Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

A new surface description model for elastic-plastic asperity contact problems is presented to remove the nodes, which have little influence for the description of the surface profile. Element-free Galerkin-finite element (EFG-FE) coupling method is utilized to fit the requirement of irregular surface node arrangement when some of the surface nodes are removed because of its flexibility in domain discretization and versatility in node arrangements. The results express that the computing time can be dramatically reduced to about 50% of original computing time in the example studied when the relative errors are about 5%. Some factors, which may influence the elastic-plastic contact of adaptive rough surfaces, are investigated and discussed.

Original language	English
Pages (from-to)	91-95
Number of pages	5
Journal	Jixie Gongcheng Xuebao/Journal of Mechanical Engineering
Volume	43
Issue number	9
DOIs	https://doi.org/10.3901/JME.2007.09.091
State	Published - Sep 2007

Keywords

Adaptive
Coupling method
Elastic-plastic contact
Element-free Galerking-finite element (EFG-FE)
Rough surface

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10.3901/JME.2007.09.091

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abstract = "A new surface description model for elastic-plastic asperity contact problems is presented to remove the nodes, which have little influence for the description of the surface profile. Element-free Galerkin-finite element (EFG-FE) coupling method is utilized to fit the requirement of irregular surface node arrangement when some of the surface nodes are removed because of its flexibility in domain discretization and versatility in node arrangements. The results express that the computing time can be dramatically reduced to about 50% of original computing time in the example studied when the relative errors are about 5%. Some factors, which may influence the elastic-plastic contact of adaptive rough surfaces, are investigated and discussed.",

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AU - Liu, Geng

AU - Xie, Qin

AU - Zeng, Quanren

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AB - A new surface description model for elastic-plastic asperity contact problems is presented to remove the nodes, which have little influence for the description of the surface profile. Element-free Galerkin-finite element (EFG-FE) coupling method is utilized to fit the requirement of irregular surface node arrangement when some of the surface nodes are removed because of its flexibility in domain discretization and versatility in node arrangements. The results express that the computing time can be dramatically reduced to about 50% of original computing time in the example studied when the relative errors are about 5%. Some factors, which may influence the elastic-plastic contact of adaptive rough surfaces, are investigated and discussed.

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KW - Coupling method

KW - Elastic-plastic contact

KW - Element-free Galerking-finite element (EFG-FE)

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2D adaptive-surface description model for elastic-plastic asperity contact problems

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Keywords

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