Micromechanical modeling of thermo-mechanical properties of high volume fraction particle-reinforced refractory composites using 3D Finite Element analysis

Previously, we have developed several particle-reinforced castable ceramic composites for refractory applications with exposure to thermal shock and measured their effective thermo-elastic properties experimentally. These composites contained silicon-carbide (SiC) solid particles, zirconia (ZrO₂) bubbles, and ZrO₂ solid particles, dispersed in an alumina (Al₂O₃) matrix. The present work aims to implement representative volume element (RVE) approach and periodic boundary condition (PBC) to accurately predict those properties, namely elastic and shear modulus, thermal conductivity, and coefficient of thermal expansion (CTE), using three-dimensional (3D) Finite Element (FE) simulations while accounting for the effect of porosity. In comparison to established micromechanical schemes and two-dimensional (2D) FE predictions, 3D FE simulations specifically show more accuracy in prediction of elastic properties and thermal conductivity. This novel and thorough comparison across various thermo-mechanical properties for complex microstructures (with up to three types of inclusions) can be valuable for designing comparable high volume fraction (VF) composites.