Multi-scale structure modeling of damage behaviors of 3D orthogonal woven composite materials subject to quasi-static and high strain rate compressions

We proposed a multi-scale structure modeling scheme to analyze the damage behaviors of three-dimensional orthogonal woven composite materials subject to quasi-static and high strain rate compressions. The multi-scale structure model includes: (1) micro/meso/macro-structure model with periodic bounda...

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Veröffentlicht in:	Mechanics of materials 2016-03, Vol.94, p.1-25
Hauptverfasser:	Wan, Yumin, Sun, Baozhong, Gu, Bohong
Format:	Artikel
Sprache:	eng
Schlagworte:	3D orthogonal woven composite material Compressing Compressive damage Compressive strength Damage Failure Finite element method (FEM) High strain rate Impact loading Mathematical models Multi-scale structure Strain rates Three dimensional models Woven composites
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creator	Wan, Yumin Sun, Baozhong Gu, Bohong
description	We proposed a multi-scale structure modeling scheme to analyze the damage behaviors of three-dimensional orthogonal woven composite materials subject to quasi-static and high strain rate compressions. The multi-scale structure model includes: (1) micro/meso/macro-structure model with periodic boundary conditions for homogenizing the heterogeneous fiber/resin system into unit cells, and (2) a macroscopic rate dependent plasticity model combined with critical damage area failure theory that accounts for the compressive deformation and failure strength of the composite material. The numerical results from the multi-scale structure model provide the locations of stress propagation and the progressive failure behavior within the 3D orthogonal woven composite material. The multi-scale model and the numerical simulation results are validated using compression test results at the strain rate range from 0.001 to 2100 s−1. The methodology we proposed could be applied to understand the microstructure damage mechanisms of 3-D textile composite materials from meso- and macro-structure levels in simpler geometrical model and easier design approaches.
doi_str_mv	10.1016/j.mechmat.2015.11.012
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subjects	3D orthogonal woven composite material Compressing Compressive damage Compressive strength Damage Failure Finite element method (FEM) High strain rate Impact loading Mathematical models Multi-scale structure Strain rates Three dimensional models Woven composites
title	Multi-scale structure modeling of damage behaviors of 3D orthogonal woven composite materials subject to quasi-static and high strain rate compressions
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