A novel approach for modeling retained austenite transformations during rolling contact fatigue

Sadeghi, Farshid; Chen, Y.-C.; Wang, C.; Wang, B.

doi:10.1111/ffe.12731

Cited by 6 publications

(4 citation statements)

References 41 publications

(96 reference statements)

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“…It is believed that the microstructural alterations in bearing steels occur at the steady-state response stage or even as early as the plastic shakedown stage of RCF where a steady state plastic flow is present [97,143,144]. DERs usually form under moderate to high contact stress in the area of maximum shear stress after a large number of rolling cycles (5-100 million cycles) [2,13,87,88,90,97,[145][146][147]. In accordance with the contact geometry and loaddependent depth of maximum shear stresses, the depth of the region has been found to vary from approximately 0.1-0.65 mm beneath the contact surface.…”

Section: Microstructural Alterations: Dark Etching Regionsmentioning

confidence: 99%

Further understanding of rolling contact fatigue in rolling element bearings - A review

Laithy

Wang

Harvey

et al. 2019

Tribology International

115

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Rolling bearings are one of the most widely used components in industrial machinery. If suitably mounted, loaded, lubricated and isolated from contamination, rolling contact fatigue (RCF) is believed to be the most probable mode of failure resulting in subsurface originated failures. Over the past several decades many researchers have studied the failure and microstructural alterations in bearings such as dark etching regions and white etching bands and how operating conditions such as pressure, temperature and running time impact them during RCF. This paper aims to provide an overview of such alterations, their properties, formation mechanisms and impact on bearing failure.

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Section: Microstructural Alterations: Dark Etching Regionsmentioning

confidence: 99%

Further understanding of rolling contact fatigue in rolling element bearings - A review

Laithy

Wang

Harvey

et al. 2019

Tribology International

115

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“…Thus, our previously developed 2D continuum damage mechanics (CDM) finite element model (FEM) was further modified to investigate the effects of RA stability (E T ) on RCF performance. The RCF CDM ABAQUS FE model described in previous works 26,27 will be briefly described here. Figure 8A depicts the ABAQUS domain developed and used in this investigation.…”

Section: Rcf Simulationmentioning

confidence: 99%

“…This reduces the barrier restricting the phase transformation from occurring until the transformation may occur spontaneously. Morris et al 26 combined damage mechanics with principles of phase transformations in solids to formulate an energy criteria to predict RA transformations during a fatigue process. This was accomplished by recognizing that the Gibb's free energy enthalpy term could be directly related to the damage.…”

Section: Rcf Simulationmentioning

confidence: 99%

“…In Equation (8),

normalΔ Ψ^{*}, normalΔ Ψ_{e}^{*}, normalΔ Ψ_{p}, ρ, normalΔ σ_{ij}, normalΔ ϵ_{ij}^{p}

are the change in the specific Gibbs free energy to drive the phase transformation, the elastic contribution, the plastic contribution attributed to kinematic hardening, the material density, the change in stress, and corresponding plastic strain, respectively 26 . The elastic contribution

normalΔ Ψ_{e}^{*}

, Equation (9), is calculated from the equivalent von Mises stress σ eq , the elastic modulus E , the damage variable D , and the triaxiality function defined in Equation (10), where ν and σ H are the Poisson's ratio and hydrostatic stress, respectively.…”

Section: Rcf Simulationmentioning

confidence: 99%

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Retained austenite stability on rolling contact fatigue performance of 8620 case‐carburized steel

Sadeghi

2021

Fatigue Fract Eng Mat Struct

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Varying levels of retained austenite (RA) were achieved through varying undercooling severity in uniformly treated case carburized 8620 steel. Specimens were characterized via XRD and EBSD techniques to determine RA volume fraction and material characteristics prior to rolling contact fatigue (RCF). Higher RA volume fractions did not lead to improvement in RCF lives.XRD measurements after RCF testing indicated that little RA decomposition had occurred during RCF. A continuum damage mechanics (CDM) finite element model (FEM) was then developed to investigate the effects of RA stability on RCF. The results obtained from the CDM FEM captured similar behavior observed in the experimental results. Utilizing the CDM FEM, a parametric study was undertaken to examine the effects of RA quantity, RA stability, and applied pressure on RCF performance. The study demonstrates that the energy requirements to transform the RA phase are critical to RCF performance.

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Study on the gear fatigue behavior considering the effect of residual stress based on the continuum damage approach

Liu

Zhu

Tang

2019

Engineering Failure Analysis

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A novel approach for modeling retained austenite transformations during rolling contact fatigue

Cited by 6 publications

References 41 publications

Further understanding of rolling contact fatigue in rolling element bearings - A review

Further understanding of rolling contact fatigue in rolling element bearings - A review

Retained austenite stability on rolling contact fatigue performance of 8620 case‐carburized steel

Study on the gear fatigue behavior considering the effect of residual stress based on the continuum damage approach

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