Wake length and loading history effects on crack closure of through-thickness long and short cracks in 304L: Part II – 3D numerical simulation

► 3D numerical calculation of plasticity-induced crack closure is investigated under fatigue loading. ► The influence of crack length is particularly investigated. ► Plasticity-induced crack closure appears to be limited to the edge of the coupon. ► The corresponding experimental observations were p...

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Veröffentlicht in:	Engineering fracture mechanics 2013-02, Vol.99, p.306-323
Hauptverfasser:	Vor, Kokleang, Gardin, Catherine, Sarrazin-Baudoux, Christine, Petit, Jean
Format:	Artikel
Sprache:	eng
Schlagworte:	3D finite element analysis Austenitic stainless steels Computer simulation Crack closure Fatigue crack growth Finite element method Fracture mechanics Mathematical models Plasticity Short crack Steels Stress intensity factor Three dimensional Wakes
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creator	Vor, Kokleang Gardin, Catherine Sarrazin-Baudoux, Christine Petit, Jean
description	► 3D numerical calculation of plasticity-induced crack closure is investigated under fatigue loading. ► The influence of crack length is particularly investigated. ► Plasticity-induced crack closure appears to be limited to the edge of the coupon. ► The corresponding experimental observations were presented in a first part of this paper. ► Very good agreement between experiments and predictions is obtained. The plasticity-induced crack closure shielding effect for long and short through-thickness cracks is studied in a 304L steel. A main objective is to uncouple the effect of the wake length from that of the wake history. The experimental results are presented in a first part of this contribution. In the present second part, a 3D finite elements analysis (ABAQUS) for 2D cracks with a straight crack front is proposed. Globally, a remarkable consistence is obtained between simulation and experiments. The effective stress intensity factor range is confirmed as the driving force when the LEFM concepts are applicable.
doi_str_mv	10.1016/j.engfracmech.2013.01.014
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subjects	3D finite element analysis Austenitic stainless steels Computer simulation Crack closure Fatigue crack growth Finite element method Fracture mechanics Mathematical models Plasticity Short crack Steels Stress intensity factor Three dimensional Wakes
title	Wake length and loading history effects on crack closure of through-thickness long and short cracks in 304L: Part II – 3D numerical simulation
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