Mechanical Behavior of metallic Materials Maximum Strengths of solids Material f, GPa EGPa E Silica fiber 24.1 971 4 Iron whisker 13.1 295.2 23 Silicon whisker 647 1657 26 Alum ina whisker 15.2 4962 33 Ausformed steel 3.14 200.1 64 Piano wire 2.75 200.1 73 CHONGQING UNIVENTTY
Mechanical Behavior of Metallic Materials Material , GPa E, GPa Silica fiber 24.1 97.1 4 Iron whisker 13.1 295.2 23 Silicon whisker 6.47 165.7 26 Alumina whisker 15.2 496.2 33 Ausformed steel 3.14 200.1 64 Piano wire 2.75 200.1 73 f E f Maximum Strengths of Solids
Mechanical Behavior of metallic Materials Deformation and accumulation of irreversible damage Defects such as porosity, shrin kage cavities, quench cracks, grinding and stamping marks, seams, and weld-related cracks nclusions, brittle second-phase particles, and grain boundary films-lead to crack formation stress growth defect C今 crack fracture ③大季
Mechanical Behavior of Metallic Materials Deformation and accumulation of irreversible damage Defects such as porosity, shrinkage cavities, quench cracks, grinding and stamping marks, seams, and weld-related cracks. Inclusions, brittle second-phase particles, and grain boundary films—lead to crack formation defect crack fracture growth stress
Mechanical Behavior of metallic Materials The Stress-Concentration Factor 2a max 1+ b 2 b O max a(1+2/p) ≈2o√a ③大季
Mechanical Behavior of Metallic Materials The Stress-Concentration Factor max 2 1 a a b = + 2 b a = max (1 2 ) 2 a a a a = +
Mechanical Behavior of metallic Materials is defined as the stress-concentration k,=2√a factor and describes the effect of crack geometry on the local crack- tip stress level The stress-concentration factor increase with increasing crack length and decreasing crack tip radius Plastic deformation in the highly stressed The crack tip blunts. crack-tip region ③大季
