This paper proposes a multiscale mechanistic approach to damage in short-fiber polymer composites (SFPC). At the microscale, the damage mechanisms are analyzed using micromechanical modeling, and the associated damage variables are defined. The stiffness reduction law dependent on these variables is then established. The macroscopic response is determined using thermodynamics of continuous media, continuum damage mechanics and finite element analysis. Final failure resulting from saturation of matrix microcracks, fiber/matrix debonding, fiber pull-out and breakage is modeled by a vanishing element technique. The model was validated using the experimental data and results from literature, as well as those obtained from a random glass/vinyl ester system.

Volume Subject Area:
Applied Mechanics
Topics:
Composite materials, Damage, Fibers, Microscale devices, Damage mechanics, Ester, Failure, Finite element analysis, Glass, Microcracks, Modeling, Polymer composites, Stiffness, Thermodynamics
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Copyright © 2004
 by ASME
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