Elevated Temperature Axial and Torsional Fatigue Behavior of Haynes 188

Bonacuse, Peter J.; Kalluri, Sreeramesh

doi:10.1115/1.2804529

Cited by 30 publications

(6 citation statements)

References 9 publications

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“…The strain life equation modified by stress multiaxiality (see appendix of Bonascue and Kalluri 42 ) is…”

Section: Fatigue Life Assessmentmentioning

confidence: 99%

On thermal stress and fatigue life evaluation in work rolls of hot rolling mill

Benasciutti

2012

The Journal of Strain Analysis for Engineering Design

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The paper proposes an approach for thermal stress evaluation and fatigue life assessment of work rolls in hot rolling mills. Temperature and thermal stress distributions are calculated with a simplified finite element approach, based on a plane model of work roll loaded on its boundary by rotating thermal actions for a typical hot rolling configuration. A transient of one hour is simulated and the calculated temperature field is next applied as thermal loading in elastic–plastic mechanical simulation, to get thermal stresses and elastic–plastic strains in work roll. Calculated cyclic stresses and strains are finally used to estimate work roll service life, based on Universal Slopes equation that is modified to account for the multiaxial stress state. A comparison of results by three multiaxial fatigue criteria is provided. The obtained results show that, according to such multiaxial criteria, stress multiaxiality would have a great effect on fatigue life, despite it is generally neglected in approaches usually adopted in literature

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“…The strain life equation modified by stress multiaxiality (see appendix of Bonascue and Kalluri 42 ) is…”

Section: Fatigue Life Assessmentmentioning

confidence: 99%

On thermal stress and fatigue life evaluation in work rolls of hot rolling mill

Benasciutti

2012

The Journal of Strain Analysis for Engineering Design

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“…Many effective damage parameters have been suggested, e.g. an equivalent strain parameter (extended from the Coffin–Manson approach to multiaxial low‐cycle fatigue), 11 , 12 von Mises strain modified by triaxiality, 13 , 14 cyclic plastic strain energy, 8 , 9 and the critical plane approach first suggested by Brown and Miller, 10 and then modified by Fatemi and Socie, 2 and Socie 1 …”

Section: Predictions Of Low‐cycle Fatigue Lifementioning

confidence: 99%

A critical plane‐strain energy density criterion for multiaxial low‐cycle fatigue life under non‐proportional loading

Chen

Huang

1999

Fatigue Fract Eng Mat Struct

155

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A series of multiaxial low‐cycle fatigue experiments was performed on 45 steel under non‐proportional loading. The present evaluations of multiaxial low‐cycle fatigue life were systematically analysed. A combined energy density and critical plane concept is proposed that considers different failure mechanisms for a shear‐type failure and a tensile‐type failure, and from which different damage parameters for the critical plane‐strain energy density are proposed. For tensile‐type failures in material 45 steel and shear‐type failures in material 42CrMo steel, the new damage parameters permit a good prediction for multiaxial low‐cycle fatigue failure under non‐proportional loading. The currently used critical plane models are a special and simple form of the new model.

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“…It is widely used in the combustion tank, transition tube, and afterburner of military and commercial gas turbine engines (Haynes International, 2020;Bhanu et al, 1997). In such applications, the components are subjected to complicated conditions, such as high temperature, high pressure, severe environment, and combinations of them (Coutsouradis et al, 1987;Bonacuse and Kalluri, 1995;Lee et al, 2008). In order to obtain excellent properties, it is very important to control the microstructure of the alloy during hot deformation (Cai et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Investigation into Microstructure Evolution of Co–Ni–Cr–W–Based Superalloy During Hot Deformation

Zhang

Zhu

et al. 2021

Front. Mater.

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Hot compression tests were conducted using a Gleeble 3500 thermomechanical simulator at temperatures ranging from 1,000 to 1,200°C with the strain rate ranging from 0.1 to 10 s−1. Electron backscatter diffraction (EBSD) technique was employed by investigating the microstructure evolution during hot deformation. Microstructure observations reveal that deformation temperatures and strain rates have a significant effect on the DRX process. It is found that the fraction and grain size of DRX increase with the decreasing deformation temperature, along with the increasing high-angle grain boundaries (HAGBs). The fraction of DRX first decreases and then increases with the increase of strain rates. It is noted that there are both the nucleation mechanisms of discontinuous dynamic recrystallization (DDRX) and continuous dynamic recrystallization (CDRX) during the DRX process for Co–Ni–Cr–W–based superalloys. DDRX and CDRX are the primary and subsidiary nucleation mechanisms of DRX, respectively. It is also found that deformation temperatures and strain rates have almost no effect on the primary and subsidiary nucleation mechanisms of DRX. At the temperature above 1,150°C, the complete DRX occurred with the average grain sizes of about 25.32–29.01 μm. The homogeneity and refinement of microstructure can be obtained by selecting the suitable hot deformation parameters.

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Elevated Temperature Axial and Torsional Fatigue Behavior of Haynes 188

Cited by 30 publications

References 9 publications

On thermal stress and fatigue life evaluation in work rolls of hot rolling mill

On thermal stress and fatigue life evaluation in work rolls of hot rolling mill

A critical plane‐strain energy density criterion for multiaxial low‐cycle fatigue life under non‐proportional loading

Investigation into Microstructure Evolution of Co–Ni–Cr–W–Based Superalloy During Hot Deformation

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