Winkler Support Model and Nonlinear Boundary Conditions Applied to 3D Elastic Contact Problem Using the Boundary Element Method

This work presents a numerical methodology for modeling the Winkler supports and nonlinear conditions by proposing new boundary conditions. For the boundary conditions of Winkler support model, the surface tractions and the displacements normal to the surface of the solid are unknown, but their rela...

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Veröffentlicht in:Acta mechanica solida Sinica Jg. 32; H. 2; S. 230 - 248
Hauptverfasser: Vallepuga-Espinosa, J., Sánchez-González, Lidia, Ubero-Martínez, Iván
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Singapore Springer Singapore 11.04.2019
Schlagworte:
Classical Mechanics
Engineering
Surfaces and Interfaces
Theoretical and Applied Mechanics
Thin Films
Winkler support model
Nonlinear boundary conditions
Boundary element method
Elastic contact problem
ISSN:0894-9166, 1860-2134
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Beschreibung
Zusammenfassung:This work presents a numerical methodology for modeling the Winkler supports and nonlinear conditions by proposing new boundary conditions. For the boundary conditions of Winkler support model, the surface tractions and the displacements normal to the surface of the solid are unknown, but their relationship is known by means of the ballast coefficient, whereas for nonlinear boundary conditions, the displacements normal to the boundary of the solid are zero in the positive direction but are allowed in the negative direction. In those zones, detachments of nodes might appear, leading to a nonlinearity, because the number of nodes that remain fixed or of the detached ones (under tensile tractions) is unknown. The proposed methodology is applied to the 3D elastic receding contact problem using the boundary element method. The surface tractions and the displacements of the common interface between the two solids in contact under the influence of different supports are calculated as well as the boundary zone of the solid where the new boundary conditions are applied. The problem is solved by a double-iterative method, so in the final solution, there are no tractions or penetrations between the two solids or at the boundary of the solid where the nonlinear boundary conditions are simulated. The effectiveness of the proposed method is verified by examples.
ISSN:0894-9166
1860-2134
DOI:10.1007/s10338-018-00073-4