Small Crack Propagation Behavior of 316FR Stainless Steel under Thermo-Mechanical Fatigue Conditions

Yamazaki, Yasuhiro; Fujiki, Wataru; Abe, Osamu; Hara, Yutaro

doi:10.2472/jsms.62.93

Cited by 2 publications

(1 citation statement)

References 14 publications

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“…The data points and the lines in Fig. 5 show the crack growth rates measured for the multiple small cracks in a smooth specimen and the long crack growth curves obtained in the previous work [3], as a function of the fatigue J integral range, ∆J f , where ∆J f for small cracks was evaluated from following equation [1,2].…”

Section: Resultsmentioning

confidence: 99%

Propagation Behavior of Naturally Initiated Small Crack in Austenitic Heat Resistant Steel under Thermo-Mechanical Fatigue Loading

Yamazaki

Fujiki

Hara

2013

KEM

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In this paper, the crack propagation behavior of naturally initiated small crack in in low-carbon/medium-nitrogen 316 stainless steel under thermo-mechanical fatigue loading was investigated. The experimental results indicated that the importance of the investigation of small crack propagation behavior because the information on the basis of physically long crack growth rate provides a dangerous evaluation on reliability to actual components. The small crack exhibits high growth rate under the In-phase TMF loading because of irreversible creep and plastic strains. However, the growth rates of small crack under the Out-of-phase TMF loading were lower because the effect of creep deformation became negligible in such condition.

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Section: Resultsmentioning

confidence: 99%

Propagation Behavior of Naturally Initiated Small Crack in Austenitic Heat Resistant Steel under Thermo-Mechanical Fatigue Loading

Yamazaki

Fujiki

Hara

2013

KEM

Self Cite

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Small Crack Propagation Behavior and Life Prediction in a Polycrystalline Ni-Base Superalloy under Thermomechanical Fatigue Loading

Yamazaki

2016

J. Soc. Mat. Sci., Japan

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The propagation behavers of naturally initiated small crack in a conventional cast polycrystalline Ni-base superalloy were studied under the thermomechanical fatigue conditions. The small crack propagation tests were carried out under the in-phase (IP) and the out-of-phase (OP) type thermomechanical fatigue (TMF) conditions as well as the isothermal low-cycle fatigue (LCF) condition at the maximum temperature of the TMF conditions. The experimental results revealed that the initiation and propagation morphologies of the naturally initiated small crack were affected by the thermomechanical loading condition. Under the LCF and IP-TMF conditions, the small cracks were initiated and propagated at the grain boundaries perpendicular to the loading axis. On the other hand, under the OP-TMF condition, the small cracks were initiated and propagated with the transgranular modes. When the crack growth rates of naturally initiated small crack were correlated with fatigue J-integral range, which is the continuum mechanics parameters for homogeneous and isotropic materials, the crack growth rates under the TMF conditions were almost similar to those under LCF condition even if the propagation morphologies of small cracks were varied with the thermomechanical fatigue conditions. In addition, it could be considered that the crack growth morphologies, grain structure and grain orientation affect the scatter of the small crack growth rate. The prediction method for TMF and LCF lives was proposed based on the small crack propagation considered with the crack opening-closing behavior. The TMF and LCF lives of Ni-base superalloys could be predicted with higher accuracy by the proposed method.

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Small Crack Propagation Behavior of 316FR Stainless Steel under Thermo-Mechanical Fatigue Conditions

Cited by 2 publications

References 14 publications

Propagation Behavior of Naturally Initiated Small Crack in Austenitic Heat Resistant Steel under Thermo-Mechanical Fatigue Loading

Propagation Behavior of Naturally Initiated Small Crack in Austenitic Heat Resistant Steel under Thermo-Mechanical Fatigue Loading

Small Crack Propagation Behavior and Life Prediction in a Polycrystalline Ni-Base Superalloy under Thermomechanical Fatigue Loading

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