Abstract

A micromechanical model is presented to relate the mechanical properties of low‐density fibrous ceramic bodies to their micro‐structures and the properties of the fibers. It is found that properties such as the elastic moduli, fracture toughness, and strength depend on the fiber spacing. In particular, it is shown that the critical stress intensity ( K c ) depends on the density of the body with respect to the fiber density, the degree of preferred orientation, the fiber strength, and the fiber radius, suggesting ways of increasing K c . Furthermore, it is predicted that K c will be related to the sonic velocity in the material, reflecting variations in the degree of preferred orientation. The model is found to be consistent with the experimental observations on a silica‐based fibrous ceramic, which is being used in the thermal protection system of the Space Shuttle.