Contact analysis in the presence of an ellipsoidal inhomogeneity within a half space

Contact analysis in the presence of an ellipsoidal inhomogeneity within a half space

Many materials contain inhomogeneities or inclusions that may greatly affect their mechanical properties. Such inhomogeneities are for example encountered in the case of composite materials or materials containing precipitates. This paper presents an analysis of contact pressure and subsurface stres...

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Bibliographic Details
Published in:International journal of solids and structures Vol. 51; no. 6; pp. 1390 - 1402
Main Authors: Koumi, Koffi Espoir, Zhao, Lv, Leroux, Julien, Chaise, Thibaut, Nelias, Daniel
Format: Journal Article
Language:English
Published: Elsevier Ltd 15-03-2014
Elsevier
Subjects:
Anisotropy
Contact
Contact Mechanics
Contact pressure
Contact stresses
Eigenstrain
Elastic anisotropy
Engineering Sciences
Enrichment
Eshelby’s equivalent inclusion method (EIM)
Half spaces
Inclusion
Inclusions
Inhomogeneity
Mathematical models
Three dimensional
Inhomogeneity
Inclusion
Eigenstrain
Anisotropy
Contact Mechanics
Eshelby’s equivalent inclusion method (EIM)
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Summary:Many materials contain inhomogeneities or inclusions that may greatly affect their mechanical properties. Such inhomogeneities are for example encountered in the case of composite materials or materials containing precipitates. This paper presents an analysis of contact pressure and subsurface stress field for contact problems in the presence of anisotropic elastic inhomogeneities of ellipsoidal shape. Accounting for any orientation and material properties of the inhomogeneities are the major novelties of this work. The semi-analytical method proposed to solve the contact problem is based on Eshelby’s formalism and uses 2D and 3D Fast Fourier Transforms to speed up the computation. The time and memory necessary are greatly reduced in comparison with the classical finite element method. The model can be seen as an enrichment technique where the enrichment fields from the heterogeneous solution are superimposed to the homogeneous problem. The definition of complex geometries made by combination of inclusions can easily be achieved. A parametric analysis on the effect of elastic properties and geometrical features of the inhomogeneity (size, depth and orientation) is proposed. The model allows to obtain the contact pressure distribution – disturbed by the presence of inhomogeneities – as well as subsurface and matrix/inhomogeneity interface stresses. It is shown that the presence of an inclusion below the contact surface affects significantly the contact pressure and subsurfaces stress distributions when located at a depth lower than 0.7 times the contact radius. The anisotropy directions and material data are also key elements that strongly affect the elastic contact solution. In the case of normal contact between a spherical indenter and an elastic half space containing a single inhomogeneity whose center is located straight below the contact center, the normal stress at the inhomogeneity/matrix interface is mostly compressive. Finally when the axes of the ellipsoidal inclusion do not coincide with the contact problem axes, the pressure distribution is not symmetrical.
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ISSN:0020-7683
1879-2146
DOI:10.1016/j.ijsolstr.2013.12.035