Modeling of cyclic stress-strain behavior and damage mechanisms under thermomechanical fatigue conditions

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OriginalspracheEnglisch
Seiten (von - bis)S267-S274
FachzeitschriftInternational journal of fatigue
Jahrgang19
AusgabenummerSUPPL.1
PublikationsstatusVeröffentlicht - 1997
Extern publiziertJa

Abstract

A multi-component model was applied to predict the cyclic stress-strain response of different alloys under thermomechanical fatigue conditions based upon isothermal hysteresis loops. A ductile AISI 304 L-type stainless steel and two high strength alloys, the near-α titanium alloy IMI 834 and the nickel-base superalloy IN 100, were chosen as test materials. These represent alloys with rather different dislocation slip modes, stress-strain characteristics and damage mechanisms. Model predictions are compared with experiments and the differences in cyclic stress-strain response and damage mechanisms under isothermal and thermomechanical fatigue conditions, respectively, are discussed based upon micro structural observations.

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Modeling of cyclic stress-strain behavior and damage mechanisms under thermomechanical fatigue conditions. / Maier, H. J.; Christ, H. J.
in: International journal of fatigue, Jahrgang 19, Nr. SUPPL.1, 1997, S. S267-S274.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

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keywords = "Damage mechanisms, Modeling of cyclic stress-strain response, Thermomechanical fatigue",
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TY - JOUR

T1 - Modeling of cyclic stress-strain behavior and damage mechanisms under thermomechanical fatigue conditions

AU - Maier, H. J.

AU - Christ, H. J.

N1 - Funding Information: Financial support of this work by Deutsche Forschungsgemeinschaft is gratefully acknowledged. The assistance of R.P. Skelton in sharing data for IN 100 is greatly appreciated.

PY - 1997

Y1 - 1997

N2 - A multi-component model was applied to predict the cyclic stress-strain response of different alloys under thermomechanical fatigue conditions based upon isothermal hysteresis loops. A ductile AISI 304 L-type stainless steel and two high strength alloys, the near-α titanium alloy IMI 834 and the nickel-base superalloy IN 100, were chosen as test materials. These represent alloys with rather different dislocation slip modes, stress-strain characteristics and damage mechanisms. Model predictions are compared with experiments and the differences in cyclic stress-strain response and damage mechanisms under isothermal and thermomechanical fatigue conditions, respectively, are discussed based upon micro structural observations.

AB - A multi-component model was applied to predict the cyclic stress-strain response of different alloys under thermomechanical fatigue conditions based upon isothermal hysteresis loops. A ductile AISI 304 L-type stainless steel and two high strength alloys, the near-α titanium alloy IMI 834 and the nickel-base superalloy IN 100, were chosen as test materials. These represent alloys with rather different dislocation slip modes, stress-strain characteristics and damage mechanisms. Model predictions are compared with experiments and the differences in cyclic stress-strain response and damage mechanisms under isothermal and thermomechanical fatigue conditions, respectively, are discussed based upon micro structural observations.

KW - Damage mechanisms

KW - Modeling of cyclic stress-strain response

KW - Thermomechanical fatigue

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VL - 19

SP - S267-S274

JO - International journal of fatigue

JF - International journal of fatigue

SN - 0142-1123

IS - SUPPL.1

ER -

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