Role of Fracture Mechanics in Modern Technology: Proceedings of the International Conference on the Role of Fracture Mechanics in Modern Technology, Fukuoka, Japan, 2-6 June, 1986George C. Sih, Hironobu Nisitani, Tomoo Ishihara |
Contents
Role of fracture mechanics in modern technology | 3 |
Linear notch mechanics as an extension of linear fracture mechanics | 25 |
Advanced experimental mechanics and material defects | 39 |
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Common terms and phrases
analysis analytical applied ASTM boundary element boundary element method calculated constant crack closure crack growth rate crack initiation crack length crack opening crack propagation crack tip creep creep-fatigue curve cyclic da/dN damage defects diffraction displacement ductile dynamic effect elastic-plastic element method energy density engineering equation evaluated fatigue crack growth fatigue crack propagation fatigue limit fatigue tests finite element fracture mechanics fracture surface fracture toughness frequency function G.C. Sih grain boundary increase interface Ishihara editors J-integral Japan K₁ Kmax line-spring linear material maximum measured Mech mixed mode Nisitani notch root number of cycles obtained oxide parameters photoelastic plane strain plastic deformation plastic zone prediction region relation residual stress shown in Figure shows solution specimen stainless steel stress amplitude stress distribution stress fields stress intensity factor stress ratio structure surface crack technique temperature tensile theory tion Trans ultrasonic void X-ray Young's modulus