Interfacial Stress Transfer Mechanism in SiC Fiber-reinforced Ti Matrix Composites

Abstract

The interfacial shear stress transfer mechanism of fiber-matrix sliding interfaces in SiC fiber-reinforced Ti matrix composites have been studied using both the push-out and pull-out tests. The interfacial shear sliding stress (τ_s) is expressed as the form of τ_s=μ(σ_T+σ_R+σ_P), where μ is the coefficient of sliding friction at the sliding interface and σ_T, σ_R, σ_P, respectively, are the thermal residual stress at the fiber radial-direction, the interfacial roughness induced stress and the stress occurred by the Poisson’s ratio difference between fiber and matrix.
Quantitative evaluations of the μ, σ_T, σ_R, σ_P and their contribution to the shear sliding stress can become possible by the use of both the push-out and pull-out tests. In case of the SiC(SCS-6) fiber-reinforced commercially-pure Ti matrix composites, τ_s=30∼50 MPa, μ≈0.2. It was confirmed that the thermal residual stress (σ_T), which was introduced at the fiber-matrix interface during the cooling process from the processing temperature, plays a major role in the generation of fiber radial-direction stresses during the shear sliding process of the interface.