Experimental verification of a constitutive model of fibre composite with hyperelastic matrix.

Experimental verification of a constitutive model of fibre composite with hyperelastic matrix.

Paper in proceedings (conference paper)

The paper compares computational simulations of tension and bending tests on the basis of an anisotropic hyperelastic constitutive model with experimental results. The tested specimens are made of rubber with a single family of textile fibres under different angles. As our previous studies have shown substantial discrepancies between computational and experimental results, now we used textile fibres (with zero bending stiffness) instead of steel wires and the matrix was made of rubber with a very limited Mullins effect to eliminate the possible causes of errors. The results have shown that the simulations correspond well to the experiments.

The paper compares computational simulations of tension and bending tests on the basis of an anisotropic hyperelastic constitutive model with experimental results. The tested specimens are made of rubber with a single family of textile fibres under different angles. As our previous studies have shown substantial discrepancies between computational and experimental results, now we used textile fibres (with zero bending stiffness) instead of steel wires and the matrix was made of rubber with a very limited Mullins effect to eliminate the possible causes of errors. The results have shown that the simulations correspond well to the experiments.

Anisotropy; Hyperelasticity; Fibre composite; Finite strain.

Anisotropy; Hyperelasticity; Fibre composite; Finite strain.

FEDOROVA, S.; LASOTA, T.; BURŠA, J.; SKÁCEL, P.

2013

04.06.2012

CTU Prague

Tábor

978-80-01-05060-6

EAN Proceedings 50th annual conference on experimental stress analysis

65

72

8

http://hdl.handle.net/