A 3D beam-to-beam contact finite element for coupled electric-mechanical fields

D. P. Boso; Przemyslaw Litewka; B. A. Schrefler; P. Wriggers

doi:10.1002/nme.1427

A 3D beam-to-beam contact finite element for coupled electric-mechanical fields

D. P. Boso, Przemyslaw Litewka, B. A. Schrefler, P. Wriggers

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

12 Scopus citations

Abstract

In this paper the formulation of an electric-mechanical beam-to-beam contact element is presented. Beams with circular cross-sections are assumed to get in contact in a point-wise manner and with clean metallic surfaces. The voltage distribution is influenced by the contact mechanics, since the current flow is constricted to small contacting spots. Therefore, the solution is governed by the contacting areas and hence by the contact forces. As a consequence the problem is semi-coupled with the mechanical field influencing the electric one. The electric-mechanical contact constraints are enforced with the penalty method within the finite element technique. The virtual work equations for the mechanical and electric fields are written and consistently linearized to achieve a good level of computational efficiency with the finite element method. The set of equations is solved with a monolithic approach.

Original language	English (US)
Pages (from-to)	1800-1815
Number of pages	16
Journal	International Journal for Numerical Methods in Engineering
Volume	64
Issue number	13
DOIs	https://doi.org/10.1002/nme.1427
State	Published - Dec 7 2005

Keywords

Beam-to-beam contact
Contact mechanics
Electric-mechanical coupling
Finite element method

ASJC Scopus subject areas

Engineering (miscellaneous)
Applied Mathematics
Computational Mechanics

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10.1002/nme.1427

Cite this

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title = "A 3D beam-to-beam contact finite element for coupled electric-mechanical fields",

abstract = "In this paper the formulation of an electric-mechanical beam-to-beam contact element is presented. Beams with circular cross-sections are assumed to get in contact in a point-wise manner and with clean metallic surfaces. The voltage distribution is influenced by the contact mechanics, since the current flow is constricted to small contacting spots. Therefore, the solution is governed by the contacting areas and hence by the contact forces. As a consequence the problem is semi-coupled with the mechanical field influencing the electric one. The electric-mechanical contact constraints are enforced with the penalty method within the finite element technique. The virtual work equations for the mechanical and electric fields are written and consistently linearized to achieve a good level of computational efficiency with the finite element method. The set of equations is solved with a monolithic approach.",

keywords = "Beam-to-beam contact, Contact mechanics, Electric-mechanical coupling, Finite element method",

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AU - Boso, D. P.

AU - Litewka, Przemyslaw

AU - Schrefler, B. A.

AU - Wriggers, P.

PY - 2005/12/7

Y1 - 2005/12/7

N2 - In this paper the formulation of an electric-mechanical beam-to-beam contact element is presented. Beams with circular cross-sections are assumed to get in contact in a point-wise manner and with clean metallic surfaces. The voltage distribution is influenced by the contact mechanics, since the current flow is constricted to small contacting spots. Therefore, the solution is governed by the contacting areas and hence by the contact forces. As a consequence the problem is semi-coupled with the mechanical field influencing the electric one. The electric-mechanical contact constraints are enforced with the penalty method within the finite element technique. The virtual work equations for the mechanical and electric fields are written and consistently linearized to achieve a good level of computational efficiency with the finite element method. The set of equations is solved with a monolithic approach.

AB - In this paper the formulation of an electric-mechanical beam-to-beam contact element is presented. Beams with circular cross-sections are assumed to get in contact in a point-wise manner and with clean metallic surfaces. The voltage distribution is influenced by the contact mechanics, since the current flow is constricted to small contacting spots. Therefore, the solution is governed by the contacting areas and hence by the contact forces. As a consequence the problem is semi-coupled with the mechanical field influencing the electric one. The electric-mechanical contact constraints are enforced with the penalty method within the finite element technique. The virtual work equations for the mechanical and electric fields are written and consistently linearized to achieve a good level of computational efficiency with the finite element method. The set of equations is solved with a monolithic approach.

KW - Beam-to-beam contact

KW - Contact mechanics

KW - Electric-mechanical coupling

KW - Finite element method

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A 3D beam-to-beam contact finite element for coupled electric-mechanical fields

Abstract

Keywords

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