Wear simulation based on node-to-segment element

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  • Guangdong University of Technology
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Details

OriginalspracheEnglisch
Seiten (von - bis)577-582
Seitenumfang6
FachzeitschriftKey Engineering Materials
Jahrgang274-276
Ausgabenummer3
PublikationsstatusVeröffentlicht - 2004

Abstract

Wear phenomenon concerned with two sliding contactors is simulated by the nonlinear finite element method. Holm-Archard wear law is used to build model for mild oxidation and delaminating wear. A modified wear law is implemented to calculate wear profile, which is affected strongly by the initial surface topology. The node-to-segment contact element is applied to obtain contact stresses and sliding distance between two contact bodies. Two illustrative examples of indentation and pin-on-disk test show the ability of the proposed method to simulate wear phenomenon.

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Wear simulation based on node-to-segment element. / Feng, Liu; Wriggers, Peter; Lijuan, Li.
in: Key Engineering Materials, Jahrgang 274-276, Nr. 3, 2004, S. 577-582.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Feng, L, Wriggers, P & Lijuan, L 2004, 'Wear simulation based on node-to-segment element', Key Engineering Materials, Jg. 274-276, Nr. 3, S. 577-582.
Feng, L., Wriggers, P., & Lijuan, L. (2004). Wear simulation based on node-to-segment element. Key Engineering Materials, 274-276(3), 577-582.
Feng L, Wriggers P, Lijuan L. Wear simulation based on node-to-segment element. Key Engineering Materials. 2004;274-276(3):577-582.
Feng, Liu ; Wriggers, Peter ; Lijuan, Li. / Wear simulation based on node-to-segment element. in: Key Engineering Materials. 2004 ; Jahrgang 274-276, Nr. 3. S. 577-582.
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AU - Wriggers, Peter

AU - Lijuan, Li

PY - 2004

Y1 - 2004

N2 - Wear phenomenon concerned with two sliding contactors is simulated by the nonlinear finite element method. Holm-Archard wear law is used to build model for mild oxidation and delaminating wear. A modified wear law is implemented to calculate wear profile, which is affected strongly by the initial surface topology. The node-to-segment contact element is applied to obtain contact stresses and sliding distance between two contact bodies. Two illustrative examples of indentation and pin-on-disk test show the ability of the proposed method to simulate wear phenomenon.

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KW - FEM

KW - Wear simulation

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