Numerical prediction of composite damage behavior: A modeling approach including the strain-rate-dependent material response

Prognosis of dynamic damage in fiber-reinforced plastic structures is still a challenging engineering issue. This study presents a novel approach to physically motivate the damage evolution parameters in LS-DYNA material model *MAT_058 for numerical predictions of strain-rate-dependent damage in com...

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Bibliographic Details
Published in:Composite structures 2022-07, Vol.292, p.115628, Article 115628
Main Authors: Pohl, C., Toenjes, M., Liebold, C., Ploeckl, M., Koerber, H., Avila Gray, L., Colin, D., Drechsler, K.
Format: Article
Language:English
Subjects:
Crash
Crushing
Fiber-reinforced composites
Finite element method
LS-DYNA
Strain rate dependency
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Summary:Prognosis of dynamic damage in fiber-reinforced plastic structures is still a challenging engineering issue. This study presents a novel approach to physically motivate the damage evolution parameters in LS-DYNA material model *MAT_058 for numerical predictions of strain-rate-dependent damage in composites. Well-characterized properties of carbon/epoxy prepreg material IM7/8552 are used as a thoroughly studied database. Models on coupon and component level are gradually investigated to reproduce the inter- and intralaminar failure mechanisms observed in open-hole-compression and crushing experiments. Stacked-shell coupon simulations agree well with experimental results. In the case of crushing, the predictive quality is excellent for double-stacked-shell models as long as the failure mode is reproduced. The study indicates the importance of a strain-rate-dependent material representation to correctly replicate the load bearing capacity in highly dynamic simulations of composites. The results of this study contribute to a more efficient design of weight-optimized composite crash absorbers and structures in general.
ISSN:0263-8223
1879-1085
DOI:10.1016/j.compstruct.2022.115628