Analysis of two- and three-dimensional hyperelastic model foams under complex loading conditions

Subject of the present study is the numerical analysis of hyperelastic two- and three-dimensional model foams at large strains. The macroscopic stress–strain relationships are determined by means of a strain energy based homogenization procedure from the behavior of the cellular structure at the mes...

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Published inMechanics of materials Vol. 38; no. 11; pp. 985 - 1000
Main Authors Demiray, S., Becker, W., Hohe, J.
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier Ltd 01.11.2006
Amsterdam Elsevier Science
New York, NY
Subjects
Exact sciences and technology
Foams
Fundamental areas of phenomenology (including applications)
Homogenization
Material modeling
Physics
Solid mechanics
Static elasticity (thermoelasticity...)
Structural and continuum mechanics
Foams
Homogenization
Material modeling
Cell structure
Representative volume element
High strain
Foarns
Open cell porosity
Strain energy
Stress strain relation
Multiaxial load
Porous material
Modeling
Hyperelasticity
Combined load
Homogeneous medium
Mesoscale
Honeycomb structure
Solid geometry
Rubber
Microstructure
Effective medium model
Stretching
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Summary:Subject of the present study is the numerical analysis of hyperelastic two- and three-dimensional model foams at large strains. The macroscopic stress–strain relationships are determined by means of a strain energy based homogenization procedure from the behavior of the cellular structure at the mesoscopic level. The proposed homogenization procedure is based on the assumption that a representative volume element with the cellular microstructure and a volume element containing the homogeneous effective medium are macroscopically equivalent if both volume elements hold the same amount of strain energy. As a first and simplifying approach spatially periodic 2-D and 3-D lattices are adopted for representing open-cell foams. The 2-D approximation is the commonly used honeycomb microstructure, whereas its 3-D counterpart is a regular lattice with tetrakaidecahedral cells. Subsequently, the effective mechanical response of these models is compared under uniaxial and multi-axial loading cases. On the macroscale, it is observed that the 2-D model foam covers most of the basic features of the three-dimensional cellular structure. Also on the mesoscale the same principal deformation mechanisms like cell wall bending and stretching are observed. However, the effect of different modeling dimensions of a solid foam should be taken into account if quantitative predictions are required.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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ISSN:0167-6636
1872-7743
DOI:10.1016/j.mechmat.2005.11.009