On the use of the theory of critical distances with mesh control for fretting fatigue lifetime assessment

A. Zabala; D. Infante-García; E. Giner; S. Goel; J. L. Endrino; I. Llavori

doi:10.1016/j.triboint.2019.105985

On the use of the theory of critical distances with mesh control for fretting fatigue lifetime assessment

A. Zabala, D. Infante-García, E. Giner, S. Goel, J. L. Endrino, I. Llavori

Research output: Journal Publication › Article › peer-review

29 Citations (Scopus)

Abstract

This work analyses the viability of the theory of critical distances (TCD) using mesh control for fretting fatigue lifetime assessment. More than seven hundred sets of simulations were performed by taking seventy different experimental tests reported previously in the literature. The outcome of the present study suggests that the TCD mesh control method can be extended to fretting fatigue problems by the reasonable assumption of setting the right element size proportional to critical distance. In this study, a significant computational time reduction of up to 97% was obtained. Thus, this study provides a simple method to design complex 3D industrial components subjected to fretting fatigue phenomena using finite element analysis efficiently without requiring complex remeshing techniques.

Original language	English
Article number	105985
Journal	Tribology International
Volume	142
DOIs	https://doi.org/10.1016/j.triboint.2019.105985
Publication status	Published - Feb 2020
Externally published	Yes

Keywords

Finite element analysis
Fretting fatigue
Theory of critical distances (TCD)

ASJC Scopus subject areas

Mechanics of Materials
Mechanical Engineering
Surfaces and Interfaces
Surfaces, Coatings and Films

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10.1016/j.triboint.2019.105985

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title = "On the use of the theory of critical distances with mesh control for fretting fatigue lifetime assessment",

abstract = "This work analyses the viability of the theory of critical distances (TCD) using mesh control for fretting fatigue lifetime assessment. More than seven hundred sets of simulations were performed by taking seventy different experimental tests reported previously in the literature. The outcome of the present study suggests that the TCD mesh control method can be extended to fretting fatigue problems by the reasonable assumption of setting the right element size proportional to critical distance. In this study, a significant computational time reduction of up to 97% was obtained. Thus, this study provides a simple method to design complex 3D industrial components subjected to fretting fatigue phenomena using finite element analysis efficiently without requiring complex remeshing techniques.",

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AU - Zabala, A.

AU - Infante-García, D.

AU - Giner, E.

AU - Goel, S.

AU - Endrino, J. L.

AU - Llavori, I.

PY - 2020/2

Y1 - 2020/2

N2 - This work analyses the viability of the theory of critical distances (TCD) using mesh control for fretting fatigue lifetime assessment. More than seven hundred sets of simulations were performed by taking seventy different experimental tests reported previously in the literature. The outcome of the present study suggests that the TCD mesh control method can be extended to fretting fatigue problems by the reasonable assumption of setting the right element size proportional to critical distance. In this study, a significant computational time reduction of up to 97% was obtained. Thus, this study provides a simple method to design complex 3D industrial components subjected to fretting fatigue phenomena using finite element analysis efficiently without requiring complex remeshing techniques.

AB - This work analyses the viability of the theory of critical distances (TCD) using mesh control for fretting fatigue lifetime assessment. More than seven hundred sets of simulations were performed by taking seventy different experimental tests reported previously in the literature. The outcome of the present study suggests that the TCD mesh control method can be extended to fretting fatigue problems by the reasonable assumption of setting the right element size proportional to critical distance. In this study, a significant computational time reduction of up to 97% was obtained. Thus, this study provides a simple method to design complex 3D industrial components subjected to fretting fatigue phenomena using finite element analysis efficiently without requiring complex remeshing techniques.

KW - Finite element analysis

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JO - Tribology International

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On the use of the theory of critical distances with mesh control for fretting fatigue lifetime assessment

Abstract

Keywords

ASJC Scopus subject areas

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