Modelling of the mechanical behavior and damage processes of fibrous ceramic matrix composites: application to a 2-D SiC/SiC

A continuum damage mechanics constitutive model is developed to describe the mechanical behavior of ®berreinforced ceramic matrix composites submitted to complex multiaxial loadings. This model relies on the use of a phenomenological internal damage variable de®ned as the change of the compliance tensor induced by any given loading. Microstructural observations of the damage entities provide qualitative data allowing us to formulate physically founded simplifying hypotheses. The evolution laws of scalar damage variables derived from the components of the compliance tensor are established within a classical thermodynamic framework, using coupled multicriteria expressed in the space of the associated thermodynamic forces. Damage deactivation processes related to the unilateral crack closure eect observed under compressive loadings are introduced through the de®nition of eective compliance tensor components. This approach is applied to a 2-D woven SiC/SiC composite processed by chemical vapor in®ltration (CVI). Major advantages and drawbacks of the proposed approach as observed from various validation tests are discussed.