Hypo-Elastic vs Hyper-Elastic Constitutive Equation for Textile Materials at Meso-Scale

Emmanuelle Vidal-Sallé; Charlotte Florimond; Adrien Charmetant; Philippe Boisse

doi:10.4028/www.scientific.net/KEM.611-612.243

Paper Titles

Potentials of Ceramic Die Materials for Isothermal Forging Purposes of a Titanium Alloy
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Buckling of Long Thin Plates under Residual Stresses with Application to Strip Rolling
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Surface Modifications for Optimized Forming Operations
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Hypo-Elastic vs Hyper-Elastic Constitutive Equation for Textile Materials at Meso-Scale
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The Effect of Mandrel Configuration on the Warpage in Pultrusion of Rectangular Hollow Profiles
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Deformability of a Flax Reinforcement for Composite Materials
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A Computational Approach Based on Flow Front Shape Dynamic Behavior for the Process Characterization during Filling in Liquid Resin Infusion
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Hypo-Elastic vs Hyper-Elastic Constitutive Equation for Textile Materials at Meso-Scale

Abstract:

The increasing use of finite element simulation in the field of composite material forming involved in the past few years a large among of research on the constitutive modelling of textile material at the mesoscopic scale (i.e. the scale of individual fibre tow). Up to now, a consensus does not exist on the most appropriate approach. The present contribution aims on the comparison between hypo-and hyper-elastic approaches to describe the mechanical behaviour of a single tow in the framework of nonlinear continuum mechanics. A particular attention is paid to the ease of implementation in standard finite element codes.

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Periodical:

Key Engineering Materials (Volumes 611-612)

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243-249

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https://doi.org/10.4028/www.scientific.net/KEM.611-612.243

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Online since:

May 2014

Authors:

Emmanuelle Vidal-Sallé*, Charlotte Florimond, Adrien Charmetant, Philippe Boisse

Keywords:

Composite, Constitutive Equation, Large Displacement

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