In the present paper, a computational model for brittle-matrix fibre-reinforced composite (FRC) materials is discussed. The main mechanical phenomena involved, such as matrix cracking, fibre orientation effect, fibre debonding and failure, and fibre-fibre interaction, are modelled by taking into account the micromechanical behaviour of such a class of materials. The developed mechanical model is implemented through a computational approach in the context of the finite element method. The proposed approach seems to be very effective making use of typical mechanical quantities related to the FRC materials (fibre content, strength, orientation, etc.). The results obtained provide useful information on the state of the composite, such as the matrix crack pattern, the effectiveness fibre content, the sliding function, the fibre length at failure.
A COMPUTATIONAL MODEL FOR THE MECHANICAL BEHAVIOUR OF BRITTLE MATRIX MATERIALS WITH UNIDIRECTIONAL OR RANDOMLY DISTRIBUTED FIBRES / BRIGHENTI, Roberto; CARPINTERI, Andrea; SCORZA, Daniela. - (2011), pp. 79-79. (Intervento presentato al convegno 21st Int. Workshop on Computational Mechanics of Materials (IWCMM 2011) tenutosi a Limerick, Ireland nel 22nd–24th August 2011).
A COMPUTATIONAL MODEL FOR THE MECHANICAL BEHAVIOUR OF BRITTLE MATRIX MATERIALS WITH UNIDIRECTIONAL OR RANDOMLY DISTRIBUTED FIBRES
BRIGHENTI, Roberto;
2011
Abstract
In the present paper, a computational model for brittle-matrix fibre-reinforced composite (FRC) materials is discussed. The main mechanical phenomena involved, such as matrix cracking, fibre orientation effect, fibre debonding and failure, and fibre-fibre interaction, are modelled by taking into account the micromechanical behaviour of such a class of materials. The developed mechanical model is implemented through a computational approach in the context of the finite element method. The proposed approach seems to be very effective making use of typical mechanical quantities related to the FRC materials (fibre content, strength, orientation, etc.). The results obtained provide useful information on the state of the composite, such as the matrix crack pattern, the effectiveness fibre content, the sliding function, the fibre length at failure.
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