TY - GEN

T1 - Simulating the effect of porosities on stiffness and strength of composite materials

AU - Rolfes, R.

AU - Czichon, S.

AU - Vogler, M.

AU - Jansen, E.

PY - 2010

Y1 - 2010

N2 - Predicting the material properties of imperfect composite structures with manufacturing defects such as waviness defects or porosities remains an open challenge. Several analytical approaches exist to determine the reduction of elastic properties due to porosity. However, these analytical methods do not account for the spatial distribution and the geometry of the voids. Size, shape, location and geometric distribution of the voids significantly influence the effect of porosity defects on material properties. In the work presented, a continuum damage mechanics approach is chosen to model porosity defects. Elastic-plastic material models for epoxy resin and fiber bundles have been developed. An invariant based quadratic failure criterion is used to model damage propagation. These material models are applied to study the failure modes induced by porosity defects and to obtain reduced homogenized material parameters for the macro scale. Different failure modes, such as kink-band failure can be observed and give valuable insight on the micromechanical behavior of imperfect structures. It is shown that the fiber misalignment angle has a significant influence on strength reduction.

AB - Predicting the material properties of imperfect composite structures with manufacturing defects such as waviness defects or porosities remains an open challenge. Several analytical approaches exist to determine the reduction of elastic properties due to porosity. However, these analytical methods do not account for the spatial distribution and the geometry of the voids. Size, shape, location and geometric distribution of the voids significantly influence the effect of porosity defects on material properties. In the work presented, a continuum damage mechanics approach is chosen to model porosity defects. Elastic-plastic material models for epoxy resin and fiber bundles have been developed. An invariant based quadratic failure criterion is used to model damage propagation. These material models are applied to study the failure modes induced by porosity defects and to obtain reduced homogenized material parameters for the macro scale. Different failure modes, such as kink-band failure can be observed and give valuable insight on the micromechanical behavior of imperfect structures. It is shown that the fiber misalignment angle has a significant influence on strength reduction.

KW - Composite

KW - Finite element method

KW - Multiscale

KW - Porosities

KW - Voids

UR - http://www.scopus.com/inward/record.url?scp=84893818405&partnerID=8YFLogxK

U2 - doi:10.4203/ccp.93.272

DO - doi:10.4203/ccp.93.272

M3 - Conference contribution

SN - 9781905088386

VL - 93

BT - Proceedings of the 10th International Conference on Computational Structures Technology, CST 2010

PB - Civil-Comp Press

T2 - 10th International Conference on Computational Structures Technology, CST 2010

Y2 - 14 September 2010 through 17 September 2010

ER -