Multiaxial Notch Fracture and Fatigue

<p>This book presents the unified fatigue life prediction equation for low/medium/high cycle fatigue of metallic materials relevant to plain materials and notched components. The unified fatigue life prediction equation is the Wöhler equation in which the stress-based intensity parameter is calculated based on the linear-elastic analysis.</p><p>A local approach for the static fracture analysis for notched components is presented based on the notch linear-elastic stress field. In the local approach a stress intensity parameter is taken as a stress-based intensity parameter. Experimental verifications show that the local approach is also suited for the static fracture analysis for notched components made of ductile materials.</p><p>The book is also concerned with a material failure problem under the multiaxial stress states. A concept of the material intensity parameter is introduced in this book. It is a material property parameter that depends on both Mode-I fracture toughness and Mode-II (or Mode-III) fracture toughness and the multiaxial parameter to characterize the variation of the material failure resistance (notch fracture toughness) with the multiaxial stresses states. The failure condition to assess mixed-mode fracture of notched (or cracked) components is stated as the stress-based intensity parameter being equal to the material intensity parameter.</p><p>With respect to the traditional S-N equation a similar S-N equation is presented and verified to have high accuracy.</p><p>This book will be of interest to professionals in the field of fatigue and fracture for both brittle and ductile materials.</p>