Trevor S. Slack scite author profile

Ball and rolling element bearings are perhaps the most widely used components in industrial machinery. They are used to support load and allow relative motion inherent in the mechanism to take place. Subsurface originated spalling has been recognized as one of the main modes of failure for rolling contact fatigue (RCF) of bearings. In the past few decades a significant number of investigators have attempted to determine the physical mechanisms involved in rolling contact fatigue of bearings and proposed models to predict their fatigue lives. In this paper, some of the most widely used RCF models are reviewed and discussed, and their limitations are addressed. The paper also presents the modeling approaches recently proposed by the authors to develop life models and better understanding of the RCF.

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Explicit finite element modeling of subsurface initiated spalling in rolling contacts

Slack

Sadeghi

2010

Tribology International

115

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A discrete damage mechanics model for high cycle fatigue in polycrystalline materials subject to rolling contact

Raje

Slack

Sadeghi

2009

International Journal of Fatigue

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A new finite element fatigue modeling approach for life scatter in tensile steel specimens

Warhadpande

Jalalahmadi

Slack

et al. 2010

International Journal of Fatigue

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EHL Modeling for Nonhomogeneous Materials: The Effect of Material Inclusions

Slack

Raje

Sadeghi

et al. 2007

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Inclusions are common in bearing materials and are a primary site for sub-surface fatigue crack initiation in rolling element bearings. This paper presents a new approach for computing the pressure, film thickness, and subsurface stresses in an EHL contact when inclusions are present in the elastic halfspace. The approach is based on using the Discrete Element Method (DEM) to determine the surface elastic deformation in the EHL film thickness equation. The model is validated through comparison with the smooth EHL line contact results generated using linear elasticity. Studies are then carried out to investigate the effects of size, location, orientation, and elastic properties of inclusions on the EHL pressure and film thickness profiles. Both, inclusions that are stiffer than and/or softer than the base material are seen to have effects on the pressure distribution within the lubricant film and to give rise to stress concentrations. For inclusions that are stiffer than the base material (hard inclusions), the pressure distribution within the lubricant film behaves as though there is a bump on the surface whereas for inclusions that are less stiff than the base material (soft inclusions), the pressure distribution behaves in a manner similar to that of a dented surface. Inclusions close to the surface cause significant changes in the contact stresses that are very significant considering the stress life relationship. For inclusions that are located deep within the surface, there is little change in the EHL pressure and film thickness. Nomenclature b half-width of Hertzian contact (m) d surface deformation (m) E E E

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Trevor S. Slack

A Review of Rolling Contact Fatigue

Explicit finite element modeling of subsurface initiated spalling in rolling contacts

A discrete damage mechanics model for high cycle fatigue in polycrystalline materials subject to rolling contact

A new finite element fatigue modeling approach for life scatter in tensile steel specimens

EHL Modeling for Nonhomogeneous Materials: The Effect of Material Inclusions

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