Jia, Liang-Jiu.
Ultra-low-Cycle Fatigue Failure of Metal Structures under Strong Earthquakes [electronic resource] / by Liang-Jiu Jia, Hanbin Ge. - 1st ed. 2019. - XVI, 221 p. 148 illus. online resource. - Springer Tracts in Civil Engineering , 2366-2603 . - Springer Tracts in Civil Engineering , .
Foreword by Prof. Yiyi Chen -- Foreword by Prof. Hitoshi Kuwamura -- Preface -- Steel and aluminum -- Fracture of metal structures in past strong earthquakes -- Metal plasticity under monotonic loading till fracture -- Cyclic metal plasticity at extremely large plastic strain -- Ductile fracture of steel under monotonic loading -- Ultra-low-cycle fatigue of steel -- Ultra-low-cycle fatigue failure of aluminum -- Applications to metal structures -- Appendix: Integration algorithm for modified Yoshida-Uemori model.
This book presents experimental results and theoretical advances in the field of ultra-low-cycle fatigue failure of metal structures under strong earthquakes, where the dominant failure mechanism is ductile fracture. Studies on ultra-low-cycle fatigue failure of metal materials and structures have caught the interest of engineers and researchers from various disciplines, such as material, civil and mechanical engineering. Pursuing a holistic approach, the book establishes a fundamental framework for this topic, while also highlighting the importance of theoretical analysis and experimental results in the fracture evaluation of metal structures under seismic loading. Accordingly, it offers a valuable resource for undergraduate and graduate students interested in ultra-low-cycle fatigue, researchers investigating steel and aluminum structures, and structural engineers working on applications related to cyclic large plastic loading conditions.
9789811326615
10.1007/978-981-13-2661-5 doi
Mechanics, Applied.
Solids.
Building materials.
Buildings—Design and construction.
Fire prevention.
Buildings—Protection.
Geotechnical engineering.
Solid Mechanics.
Building Materials.
Building Construction and Design.
Fire Science, Hazard Control, Building Safety.
Geotechnical Engineering and Applied Earth Sciences.
TA349-359
620.105
Ultra-low-Cycle Fatigue Failure of Metal Structures under Strong Earthquakes [electronic resource] / by Liang-Jiu Jia, Hanbin Ge. - 1st ed. 2019. - XVI, 221 p. 148 illus. online resource. - Springer Tracts in Civil Engineering , 2366-2603 . - Springer Tracts in Civil Engineering , .
Foreword by Prof. Yiyi Chen -- Foreword by Prof. Hitoshi Kuwamura -- Preface -- Steel and aluminum -- Fracture of metal structures in past strong earthquakes -- Metal plasticity under monotonic loading till fracture -- Cyclic metal plasticity at extremely large plastic strain -- Ductile fracture of steel under monotonic loading -- Ultra-low-cycle fatigue of steel -- Ultra-low-cycle fatigue failure of aluminum -- Applications to metal structures -- Appendix: Integration algorithm for modified Yoshida-Uemori model.
This book presents experimental results and theoretical advances in the field of ultra-low-cycle fatigue failure of metal structures under strong earthquakes, where the dominant failure mechanism is ductile fracture. Studies on ultra-low-cycle fatigue failure of metal materials and structures have caught the interest of engineers and researchers from various disciplines, such as material, civil and mechanical engineering. Pursuing a holistic approach, the book establishes a fundamental framework for this topic, while also highlighting the importance of theoretical analysis and experimental results in the fracture evaluation of metal structures under seismic loading. Accordingly, it offers a valuable resource for undergraduate and graduate students interested in ultra-low-cycle fatigue, researchers investigating steel and aluminum structures, and structural engineers working on applications related to cyclic large plastic loading conditions.
9789811326615
10.1007/978-981-13-2661-5 doi
Mechanics, Applied.
Solids.
Building materials.
Buildings—Design and construction.
Fire prevention.
Buildings—Protection.
Geotechnical engineering.
Solid Mechanics.
Building Materials.
Building Construction and Design.
Fire Science, Hazard Control, Building Safety.
Geotechnical Engineering and Applied Earth Sciences.
TA349-359
620.105