TY - GEN
T1 - Periodic unit-cell simulation for transverse tensile failure of unidirectional composites with cohesive zone model
AU - Koyanagi, J.
AU - Sato, Y.
AU - Okabe, T.
AU - Yoneyama, S.
PY - 2012
Y1 - 2012
N2 - This study investigates strain-rate dependent transverse tensile failure of unidirectional composite materials with a periodic unit-cell simulation. The unit cell consists of 20 fibers aligned at random in the matrix. Elasto-viscoplastic constitutive equation including continuum damage mechanics is used for the matrix. This enables us to simulate strain-rate dependence of matrix plastic deformation and damage. For the fiber/matrix interface, cohesive zone model is also employed. Interface failure under combined stress state of normal and shear is considered. Fibers are assumed to be elastic body. When strain rate is relatively high, naturally, the maximum matrix stress is relatively large due to the viscoplastic properties so that the interface tends to fail in advance of matrix yielding and/or failure. On the contrary, when strain rate is low, the maximum matrix stress becomes small and interface failure does not appear.
AB - This study investigates strain-rate dependent transverse tensile failure of unidirectional composite materials with a periodic unit-cell simulation. The unit cell consists of 20 fibers aligned at random in the matrix. Elasto-viscoplastic constitutive equation including continuum damage mechanics is used for the matrix. This enables us to simulate strain-rate dependence of matrix plastic deformation and damage. For the fiber/matrix interface, cohesive zone model is also employed. Interface failure under combined stress state of normal and shear is considered. Fibers are assumed to be elastic body. When strain rate is relatively high, naturally, the maximum matrix stress is relatively large due to the viscoplastic properties so that the interface tends to fail in advance of matrix yielding and/or failure. On the contrary, when strain rate is low, the maximum matrix stress becomes small and interface failure does not appear.
KW - Cohesive zone model
KW - Periodic unit-cell simulation
KW - Polymer matrix composite
KW - Strain-rate dependence
KW - Transverse failure
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M3 - Conference contribution
AN - SCOPUS:84904015842
SN - 9788888785332
T3 - ECCM 2012 - Composites at Venice, Proceedings of the 15th European Conference on Composite Materials
BT - ECCM 2012 - Composites at Venice, Proceedings of the 15th European Conference on Composite Materials
PB - European Conference on Composite Materials, ECCM
T2 - 15th European Conference on Composite Materials: Composites at Venice, ECCM 2012
Y2 - 24 June 2012 through 28 June 2012
ER -