Two Dynamic Fracture Problems Concerning Bridging Fiber Pull-Out of Composite Materials

Nian Chun Lü; Yun Hong Cheng; Yun Tao Wang

doi:10.4028/www.scientific.net/AMR.177.173

Paper Titles

High Temperature Creep Behavior of In Situ TiC/Ni Composites
p.157

Finite-Element Simulations of Residual Stresses Developed in Ti₃AlC₂ Diffusion Bonds with a Si Interlayer
p.161

DEM Simulation of Machining Damage in SiC Pre-Stressing Cutting Process
p.165

Cracking Stress of Fiber-Eutectics and Transformation Particles Composite Ceramic
p.170

Two Dynamic Fracture Problems Concerning Bridging Fiber Pull-Out of Composite Materials
p.173

Bridging Toughening Mechanism of Fiber Eutectics and Transformation Particles Composite Ceramic
p.178

Effective Elastic Constants of Fiber-Eutectics and Transformation Particles Composite Ceramic
p.182

Binding Performance of a Zirconia Framework Material and Veneering Porcelain
p.186

Electrical Properties of ZnO Film Prepared by Thermal Oxidation Method
p.190

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 177Two Dynamic Fracture Problems Concerning Bridging...

Two Dynamic Fracture Problems Concerning Bridging Fiber Pull-Out of Composite Materials

Abstract:

By means of the built dynamic fracture model of bridging fiber pull-out of composite materials, the problems considered will be transformed into Riemann-Hilbert problem in terms of the theory of complex functions. Analytical solutions of the stresses displacements, dynamic stress intensity factors, strain energy release rate and bridging fibrous fracture speeds under the conditions of an moving increasing loads, Pt/x, Px2/t, respectively, can be facilely obtained by the approaches of self-similar functions. After those solutions were utilized by superposition theorem, the solutions of arbitrary complex problems can be attained.