Micropitting Modelling in Rolling–Sliding Contacts: Application to Rolling Bearings

Morales-Espejel, Guillermo E.; Brizmer, Victor

doi:10.1080/10402004.2011.587633

Cited by 127 publications

(148 citation statements)

References 35 publications

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“…They observed a good agreement with the experimental data in the prediction of the size of micro-pits [89] and the topography evolution [91]. In their approach the evolution of the surfaces in time could be simulated.…”

Section: Particle-by-particle Removal In Boundary Lubricationsupporting

confidence: 69%

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Generation of wear particles in lubricated contcats during running-in

Akchurin¹

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Section: Particle-by-particle Removal In Boundary Lubricationsupporting

confidence: 69%

“…Morales-Espejel et al [89,90] combined a cumulative damage model and a local Archard wear equation to simulate the generation of micro-pits. They observed a good agreement with the experimental data in the prediction of the size of micro-pits [89] and the topography evolution [91].…”

Section: Particle-by-particle Removal In Boundary Lubricationmentioning

confidence: 99%

Generation of wear particles in lubricated contcats during running-in

Akchurin¹

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“…In the current formulation, the treatment of the surface stresses and damage can be accomplished by using an advanced surface distress model for elastohydrodynamically lubricated (EHL) rolling-sliding rough contacts developed by MoralesEspejel and Brizmer (18); further description of this model is given below.…”

Section: Surface Model Behaviormentioning

confidence: 99%

“…Tribological models can be used to derive these damage functions. When several mechanisms are present-for example, surface distress and mild wear-the damage function should account for possible competitive mechanisms (Morales-Espejel and Brizmer (18)) and the statistical treatment should follow (McCool (32)). As an example of surface fatigue (Lubrecht,et al (33)), the following damage function is considered:…”

Section: Surface Damagementioning

confidence: 99%

“…Because of this, there is an increased need for more versatile or generalized rolling bearing life models, able to adapt and incorporate new developed knowledge about the tribology of surface initiated failures of the rolling contact. Despite the progress achieved in the last few years in the numerical modeling of the tribology and surface performance of rolling contacts (e.g., Epstein,et al (16), (17); Morales-Espejel and Brizmer (18); Morales-Espejel and Gabelli (19); Brizmer, et al (20); Warhadpande and Sadeghi (21)), the integration of this new knowledge into an engineering model for bearing life estimation is, to some extent, hindered by the simplicity of present standardized life rating formulation (ISO 281:2007 (15)), which only relies on averaged global de-rating factors. This approach, although sufficient for most common situations, is not designed to give an account and differentiate among surface/subsurface competing failure modes that may occur in a bearing when exposed to a hostile environment and tough operating conditions.…”

Section: Introductionmentioning

confidence: 99%

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A Model for Rolling Bearing Life with Surface and Subsurface Survival—Tribological Effects

Morales-Espejel¹,

Gabelli²,

Vries³

2015

Tribology Transactions

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International audienceUntil now the estimation of rolling bearing life has been based on engineering models that consider an equivalent stress, originated beneath the contact surface, that is applied to the stressed volume of the rolling contact. Through the years, fatigue surface–originated failures, resulting from reduced lubrication or contamination, have been incorporated into the estimation of the bearing life by applying a penalty to the overall equivalent stress of the rolling contact. Due to this simplification, the accounting of some specific failure modes originated directly at the surface of the rolling contact can be challenging. In the present article, this issue is addressed by developing a general approach for rolling contact life in which the surface-originated damage is explicitly formulated into the basic fatigue equations of the rolling contact. This is achieved by introducing a function to describe surface-originated failures and coupling it with the traditional subsurface-originated fatigue risk of the rolling contact. The article presents the fundamental theory of the new model and its general behavior. The ability of the present general method to provide an account for the surface–subsurface competing fatigue mechanisms taking place in rolling bearings is discussed with reference to endurance testing data

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Effect of base oil polarity on the micropitting behaviour in rolling‐sliding contacts

Cen

Morina

Neville

2019

Lubrication Science

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An automated micropitting test rig that uses the proven three‐point contact configuration was applied to study the effect of base oil polarity on micropitting behaviour in rolling‐sliding contacts. The tribological tests using one polar (ester) and one non‐polar (polyalpha olefin [PAO]) base oil mixed with four different additives were first done in a micropitting rig to study the friction, wear, and micropitting performance. The tested specimen after tribological tests were examined by an optical microscope to study the micropitting on the surface. The X‐ray photoelectron spectroscopy (XPS) was applied to obtain the related tribochemical information from the reaction layer. The results showed that higher wear and less micropits formed when testing with ester‐based lubricants. This was related to the higher affinity to the steel surface of polar base oil molecules that can compete with additives to attach to the surface, resulting in a thinner reaction layer and shorter chain phosphates.

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Micropitting Modelling in Rolling–Sliding Contacts: Application to Rolling Bearings

Cited by 127 publications

References 35 publications

Generation of wear particles in lubricated contcats during running-in

Generation of wear particles in lubricated contcats during running-in

A Model for Rolling Bearing Life with Surface and Subsurface Survival—Tribological Effects

Effect of base oil polarity on the micropitting behaviour in rolling‐sliding contacts

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