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Influence of surface conditions on fatigue strength through thenumerical simulation of microstructure*

Published online by Cambridge University Press:  06 July 2011

A. Le Pecheur ,
M. Clavel ,
F. Curtit ,
C. Rey ,
J.-M. Stephan  and
P. Bompard
A. Le Pecheur
Affiliation:
Laboratoire MSSMat, UMR 8579 CNRS, École Centrale Paris, France. e-mail: [email protected] Département MMC, EDF R&D, Site des Renardières, France
M. Clavel
Affiliation:
Laboratoire MSSMat, UMR 8579 CNRS, École Centrale Paris, France. e-mail: [email protected]
F. Curtit
Affiliation:
Département MMC, EDF R&D, Site des Renardières, France
C. Rey
Affiliation:
Laboratoire MSSMat, UMR 8579 CNRS, École Centrale Paris, France. e-mail: [email protected]
J.-M. Stephan
Affiliation:
Département MMC, EDF R&D, Site des Renardières, France
P. Bompard
Affiliation:
Laboratoire MSSMat, UMR 8579 CNRS, École Centrale Paris, France. e-mail: [email protected]
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Abstract

A thermal fatigue test (INTHERPOL) was developed by EDF in order to study the initiationof cracks. These tests are carried out on tubular specimens under various thermal loadingsand surface finish qualities in order to give an account of these parameters on crackinitiation. The main topic of this study is to test the sensitivity of different fatiguecriteria to surface conditions using a micro/macro modelling approach. Therefore a 304Lpolycrystalline aggregate, used for cyclic plasticity based FE modelling, have beenconsidered as a Representative Volume Element located at the surface and subsurface of thetest tube. This aggregate has been cyclically strained according to the results issuedfrom FE simulation of INTHERPOL thermal fatigue experiment. Different surface parametershave been numerically simulated: effects of local microstructure and of grainsorientation, effects of machining: metallurgical prehardening, residual stress gradient,and surface roughness. Three different fatigue criteria (Manson Coffin, Fatemi Socie anddissipated energy types), previously fitted at a macroscale for thermal fatigue of 304L,have been computed at a meso scale, in order to show the surface “hot spots” features andtest the sensitivity of these three criteria to different surface conditions. Results showthat grain orientation and neighbouring play an important role on the location of hotspots, and also that the positive effect of prestraining and the negative effect ofroughness on fatigue life are not all similarly predicted by these different fatiguecriteria.

Keywords

Thermal fatiguestainless steelcyclic plasticitynumerical simulationsurface conditionFatigue thermiqueacier inoxydableplasticité cycliquesimulation numériqueétat de surface
Type
Research Article
Information
Metallurgical Research & Technology , Volume 107 , Issue 10-11 , November 2010 , pp. 477 - 489
Copyright
© EDP Sciences

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References

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