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Abstract
SiC/SiC composites are studied for their potential use in the next generation of nuclear reactors. A multiscale approach is under development to construct a predictive modelling of their complex damageable mechanical behaviour due to their heterogeneous microstructure. This paper focuses on the damage characterisation of the composite at the scale of the tow at room temperature, both in terms of its spatial distribution and its chronology. Such observations are necessary to validate a multiscale damage modelling at the microscopic scale. The nonlinear behaviour is related to the accumulation of damages such as matrix cracking, fibre/matrix debonding and finally fibre breaking. Therefore, in-situ tensile tests were carried out on SiC/SiC minicomposites using scanning electron microscopy. Specific procedures could be used to get statistical data on the crack evolution. The first results especially show that the growth of the crack openings over the global strain is related to inter-crack distance. This test was complemented by a microtomographic investigation, conducted at the ESRF, performed on a minicomposite submitted to a tensile load. An analysis conducted on the 3D image of a crack shows a slow propagation of the matrix cracking through the minicomposite section.
Highlights
This paper focuses on the damage characterisation of the composite at the scale of the tow at room temperature, both in terms of its spatial distribution and its chronology
The crack spacing distance decreases and tends to stabilize around an average value (378 μm) along the sample. This distance is higher than the expected average crack spacing distance at saturation, which could be due to the premature failure of the minicomposite
In-situ Scanning electron microscopic (SEM) tensile tests lead to a surface observation of the matrix cracking at various strain states
Summary
EPJ Web of Conferences taking into account their heterogeneous microstructure [1,2] This nonlinear behaviour is related to the accumulation of damages such as matrix cracking, fibre/matrix debonding and fibre breaking. In order to validate a multiscale damage modelling at the microscopic scale, it is necessary to characterise initiation, propagation and distribution of the matrix cracks, associated fibre/matrix debonding and fibre breaking. In this purpose in-situ tensile tests, at room temperature, were carried out on SiC/SiC minicomposites (1D composites containing 500 fibres) to study the damage at the tow scale. The first results presented here focus on the study of the matrix cracking
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