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Modelling the Mechanical and Thermal Properties of Cellular Materials from the Knowledge of their Architecture

Published online by Cambridge University Press:  31 January 2011

Eric Maire ,
O. Caty ,
R. Bouchet ,
M. Loretz  and
J. Adrien
Eric Maire
Affiliation:
eric.maire@insa-lyon.fr, mateis, insa lyon, villeurbanne, 69621, United States
O. Caty
Affiliation:
fakeemail@mrs.org, University de Lyon and ONERA Chatillon, Chatillon, France
R. Bouchet
Affiliation:
fakeemail2@mrs.org, ONERA Chatillon, Chatillon, France
M. Loretz
Affiliation:
fakeemail3@mrs.org, University de Lyon, Villeurbanne, France
J. Adrien
Affiliation:
fakeemail4@mrs.org, University de Lyon, Chatillon, France
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Abstract

This paper shows different examples where the architecture of cellular materials has been determined exactly using 3D X ray computed tomography. The images were then subsequently used to generate FE meshes reproducing the architecture as exactly as possible. The FE meshes where in turn used to simulate the mechanical (monotonous and fatigue compression) and the thermal (radiative properties) behavior of the studied materials.

Keywords

cellular (material type)fatiguesimulation
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1188: Symposium LL – Architectured Multifunctional Materials , 2009 , 1188-LL06-05
Copyright
Copyright © Materials Research Society 2009

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