Buch, Englisch, 588 Seiten, Format (B × H): 161 mm x 240 mm, Gewicht: 1033 g
Bridging Theoretical Foundations and Real-World Disasters
Buch, Englisch, 588 Seiten, Format (B × H): 161 mm x 240 mm, Gewicht: 1033 g
ISBN: 978-1-032-84281-3
Verlag: CRC Press
Structural Mechanics covers three different aspects of modern engineering: the foundation of structural mechanics, the solution to urgent industrial problems, and the reconstruction of major accidents. This book offers six case studies that teach how to identify the most important phase of the collapse or fracture of a complex system, develop a simple mathematically tractable model, and offer a discussion of the analytical and numerical solutions. This book originated from the lecture notes of Professor Tomasz Wierzbicki who taught at MIT and Stanford University. The notes were amended and improved many times over the years to provide a link between rigorous theoretical foundations with solutions to important engineering problems. The book discusses complex man-made structures under accidental impact or explosive loads, resulting in the loss of life and/or extensive property, infrastructural, and environmental damage. The book deals with reconstructing the sequence of events of such accidents from the structural point of view. The book is not restricted to the accident reconstruction only - concepts and solutions of the elasticity, advance plasticity and ductile fracture were used throughout the reconstruction of the accidents. The additional 17 lectures provide theoretical foundations for the elastic structures, plastic plates and shells, and ductile fracture. Not only is this an essential textbook for graduate students studying structural mechanics, it is also relevant to industry professionals, researchers, and academics in the field of engineering.
Zielgruppe
Postgraduate
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Part I From Continuum Mechanics to Elastic Structures
Lecture 1: The concept of strain
Lecture 2: The Concept of Stress, Generalized Stresses and Equilibrium
Lecture 3: Development of Constitutive Equations of Continuum, Beams and Plates Lecture
4: Solution Method for Beam Deflections
Lecture 5: Moderately Large Deflection Theory of Beams
Lecture 6: Bending Response of Plates and Optimum Design
Lecture 7: Energy Methods in Elasticity
Lecture 8: Stability of Elastic Structures
Lecture 9: Advanced Topic in Column Buckling
Lecture 10: Buckling of Plates and Sections
Part II Plastic Analysis of Plates and Shells, and Ductile Fracture
Lecture 11: Fundamental concepts in plasticity
Lecture 12: Von Mises yield condition
Lecture 13: Tresca yield condition
Lecture 14: Yield condition in generalized stresses
Lecture 15: Principle of virtual velocity and Limit Analysis
Lecture 16: Fundamental concepts of ductile fracture
Lecture 17: Fracture Calibration and Experimental Validation
Part III Dynamic Loading and Failure of Structures
Lecture 18: Space Shuttle Challenger mid-air break-up (1986)
Lecture 19: Denting Analysis of Short Tubular Members
Lecture 20: Buckle Propagation In Undersea Pipelines (1987)
Lecture 21: Grounding Damage of Exxon Valdez (1989)
Lecture 22: Airplane Wing Cutting Into Twin Tower External Columns(2003)
Lecture 23: Fracture And Collapse of the BP Horizon Oil Rig (2010)
Lecture 24: Road Debris Impact on EV Battery Pack (2014) Appendix
