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An Elastic-Plastic Damage Model for Long-Fiber Thermoplastics
1 Pacific Northwest National Laboratory
* To whom correspondence should be addressed. E-mail: ba.nguyen{at}pnl.gov.
This article proposes an elastic-plastic damage model that combines micromechanical modeling with continuum damage mechanics to predict the stress–strain response of injection-molded long-fiber thermoplastics. The model accounts for distributions of orientation and length of elastic fibers embedded in a thermoplastic matrix whose behavior is elastic-plastic and damageable. The elastic-plastic damage behavior of the matrix is described by the modified Ramberg–Osgood relation and the 3D damage model in deformation assuming isotropic hardening. Fiber/matrix debonding is accounted for using a parameter that governs the fiber/matrix interface compliance. A linear relationship between this parameter and the matrix damage variable is assumed. First, the elastic-plastic damage behavior of the reference aligned fiber composite containing the same fiber volume fraction and length distribution as the actual composite is computed using an incremental Eshelby–Mori–Tanaka mean field approach. The incremental response of the latter is then obtained from the solution for the aligned-fiber composite by averaging over all fiber orientations. The model is validated against the experimental stress–strain results obtained for long-glass-fiber/polypropylene specimens.
First published on August 11, 2009 |
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