Modelling of Thermal Fracture of Functionally Graded/Homogeneous Bimaterial Structures under Thermo-Mechanical Loading

Vera Petrova; Siegfried Schmauder

doi:10.4028/www.scientific.net/KEM.592-593.145

Paper Titles

Thermodynamically Consistent Model of Damage in Laminated Rocks
p.129

Micromechanics of Discontinuities and High Porosity Bands Formation in the Unconsolidated Sedimentary Rocks
p.133

Micromechanical Modelling of Advanced Ceramics with Statistically Representative Synthetic Microstructures
p.137

Mass-Velocity Correlation in Impact Fragmentation
p.141

Modelling of Thermal Fracture of Functionally Graded/Homogeneous Bimaterial Structures under Thermo-Mechanical Loading
p.145

Compression of Heterogeneous Material Systems Based on Wang Tilings
p.149

Numerical Investigation on the Size Effect of a WC/Co 3D Representative Volume Element Based on the Homogenized Elasto-Plastic Response and Fracture Energy Dissipation
p.153

Identification of Structural Parameters of Metal Fibre Concrete Using Magnetic Approach
p.157

Dynamic Recrystallization of the Alloy Fe-40at.%Al-Zr-B
p.161

HomeKey Engineering MaterialsKey Engineering Materials Vols. 592-593Modelling of Thermal Fracture of Functionally...

Modelling of Thermal Fracture of Functionally Graded/Homogeneous Bimaterial Structures under Thermo-Mechanical Loading

Abstract:

Mathematical modeling of thermal fracture of functionally graded/homogeneous bimaterial structures with a system of arbitrarily located cracks is performed and based on the previously suggested theoretical approach [1-which used the integral equation method. It is supposed that the structure is subjected to thermal loading (a thermal flux) and mechanical loading (a tension). The properties of the functionally graded material (FGM) are described by a continuous exponential function. The main fracture characteristics (stress intensity factors and fracture angles) are presented as functions of the geometry of the problem and special inhomogeneity parameters of FGMs. Some typical crack patterns for FGM/homogeneous bimaterial structures resulting from experiments available in literature are studied in detail. Thermal fracture of actual material combinations of FGMs such as: ceramic/ceramic, e.g., TiC/SiC, MoSi₂/Al₂O₃ and MoSi₂/SiC, and also ceramic/metal FGMs, e.g., zirconia/nickel and zirconia/steel, is investigated.