Title of article
Competition between mesoplasticity and damage under HCF – Elasticity/damage shakedown concept
Author/Authors
Laurent Flaceliere، نويسنده , , Daniel Bellett · David Taylor · Franck Morel، نويسنده , , Andre Dragon، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2007
Pages
17
From page
2281
To page
2297
Abstract
The aim of this paper is to present new modelling dedicated to multiaxial high cycle fatigue (HCF), and applied to polycrystalline metals. The model presented is based on the experimental characterization of damage during HCF tests, under pure tension and torsion modes. The origin of this approach is a mesoscopic model considering three plastic behaviour stages (hardening, saturation and softening) suggested by Papadopoulos [Papadopoulos I.V. Fatigue limit of metals under multiaxial stress conditions: the microscopic approach. Technical Note No. I.93.101, Commission of the European Communities, Joint Research Centre; 1993. [ISEI/IE 2495/93].], and used by Morel [Morel F. A critical plane approach for life prediction of high cycle fatigue under multiaxial variable loading. Int J Fatigue 2000;22:101–119.]. The principal evolution brought in by this study is a competition description during all the sample lifetime of the plasticity and damage effects. The plasticity mechanisms induce a hardening saturating effects (resulting from movement and accumulation of dislocations), especially significant at the beginning of the crystal life. Damage, present at the end of crystal lifetime, is considered as a degradation process inducing a strong reduction of the crystal ductility, leading to its failure (decohesion). The coexistence and the competition between these two effect (hardening and damage-induced softening) describe cyclic crystal behavior, including shakedown phase. The model is formulated in the framework of the continuum damage mechanics, according to the identified physical mechanisms during the tests.
Keywords
Mesoscopic scale , Multiaxial fatigue , Life prediction , Continuum damage mechanics , Mesoplasticity , Multiaxial loading , High cycle fatigue , Experiment , Damage model
Journal title
INTERNATIONAL JOURNAL OF FATIGUE
Serial Year
2007
Journal title
INTERNATIONAL JOURNAL OF FATIGUE
Record number
1161551
Link To Document