Fatigue modelling in fretting contact with a crystal plasticity model
T. Dick, S. Basseville, и G. Cailletaud. Computational Materials Science, 43 (1):
36 - 42(2008)<ce:title>Proceedings of the 16th International Workshop on Computational Mechanics of Materials</ce:title> <ce:subtitle>IWCMM-16</ce:subtitle>.
DOI: 10.1016/j.commatsci.2007.07.055
Аннотация
The damage mechanisms in fretting tests are wear and fatigue cracking. The gradients of the stress and strain fields are quite high under the contact, so that the typical associated lengths can be compared to grain size. Since the microstructure size is not negligible when compared to the length associated to the loadings, it seems reasonable to explicitly represent the grains in the computations. This is proposed in this paper: a polycrystal plasticity model is used for the case of a disk-plane contact with two bodies made of titanium alloy. The simulations corresponding to a material response fretting map are compared to fretting experiments. The fatigue prediction is made by means of the Dang Van high cycle fatigue parameter.
Описание
ScienceDirect.com - Computational Materials Science - Fatigue modelling in fretting contact with a crystal plasticity model
%0 Journal Article
%1 Dick200836
%A Dick, T.
%A Basseville, S.
%A Cailletaud, G.
%D 2008
%J Computational Materials Science
%K FEM fretting
%N 1
%P 36 - 42
%R 10.1016/j.commatsci.2007.07.055
%T Fatigue modelling in fretting contact with a crystal plasticity model
%U http://www.sciencedirect.com/science/article/pii/S0927025607002169
%V 43
%X The damage mechanisms in fretting tests are wear and fatigue cracking. The gradients of the stress and strain fields are quite high under the contact, so that the typical associated lengths can be compared to grain size. Since the microstructure size is not negligible when compared to the length associated to the loadings, it seems reasonable to explicitly represent the grains in the computations. This is proposed in this paper: a polycrystal plasticity model is used for the case of a disk-plane contact with two bodies made of titanium alloy. The simulations corresponding to a material response fretting map are compared to fretting experiments. The fatigue prediction is made by means of the Dang Van high cycle fatigue parameter.
@article{Dick200836,
abstract = {The damage mechanisms in fretting tests are wear and fatigue cracking. The gradients of the stress and strain fields are quite high under the contact, so that the typical associated lengths can be compared to grain size. Since the microstructure size is not negligible when compared to the length associated to the loadings, it seems reasonable to explicitly represent the grains in the computations. This is proposed in this paper: a polycrystal plasticity model is used for the case of a disk-plane contact with two bodies made of titanium alloy. The simulations corresponding to a material response fretting map are compared to fretting experiments. The fatigue prediction is made by means of the Dang Van high cycle fatigue parameter.},
added-at = {2012-06-15T09:49:53.000+0200},
author = {Dick, T. and Basseville, S. and Cailletaud, G.},
biburl = {https://www.bibsonomy.org/bibtex/26becea14822989dae28dd47159678c36/heprom},
description = {ScienceDirect.com - Computational Materials Science - Fatigue modelling in fretting contact with a crystal plasticity model},
doi = {10.1016/j.commatsci.2007.07.055},
interhash = {34c0c15a6395265f58ee8ae7344703ab},
intrahash = {6becea14822989dae28dd47159678c36},
issn = {0927-0256},
journal = {Computational Materials Science},
keywords = {FEM fretting},
note = {<ce:title>Proceedings of the 16th International Workshop on Computational Mechanics of Materials</ce:title> <ce:subtitle>IWCMM-16</ce:subtitle>},
number = 1,
pages = {36 - 42},
timestamp = {2012-06-15T09:52:25.000+0200},
title = {Fatigue modelling in fretting contact with a crystal plasticity model},
url = {http://www.sciencedirect.com/science/article/pii/S0927025607002169},
volume = 43,
year = 2008
}