Providing real world applications for different structural types and seismic characteristics, Seismic Design of Steel Structures combines knowledge of seismic behavior of steel structures with the principles of earthquake engineering. This book focuses on seismic design, and concentrates specifically on seismic-resistant steel structures.
Providing real world applications for different structural types and seismic characteristics, Seismic Design of Steel Structures combines knowledge of seismic behavior of steel structures with the principles of earthquake engineering. This book focuses on seismic design, and concentrates specifically on seismic-resistant steel structures.
Drawing on experience from the Northridge to the Tohoku earthquakes, it combines understanding of the seismic behavior of steel structures with the principles of earthquake engineering. The book focuses on the global as well as local behavior of steel structures and their effective seismic-resistant design. It recognises different types of earthquakes, takes into account the especial danger of fire after earthquake, and proposes new bracing and connecting systems for new seismic resistant steel structures, and also for upgrading existing reinforced concrete structures.
Includes the results of the extensive use of the DUCTROCT M computer program, which is used for the evaluation of the seismic available ductility, both monotonic and cyclic, for different types of earthquakes
Demonstrates good design principles by highlighting the behavior of seismic-resistant steel structures in many applications from around the world
Provides a methodological approach, making a clear distinction between strong and low-to-moderate seismic regions
This book serves as a reference for structural engineers involved in seismic design, as well as researchers and graduate students of seismic structural analysis and design
CONTENTS
Failure of a myth
The myth of steel as a perfect material for seismic-resistant structures
Behavior of steel structures during American and Asian earthquakes
Behavior of steel structures during the European earthquakes
Engineering lessons learned from the last strong earthquakes
References
Steel against earthquakes
Steel as the material of choice for seismic areas
Development of steel structural systems
References
Challenges in seismic design
Gap in seismic design methodologies
Earthquake types
Strong seismic regions
Low-to-moderate seismic regions
Proposals for improving the new code provisions
References
New generation of steel structures
Introduction
Improving existing solutions
New solutions of bracing systems
New solutions for connections
References
Advances in steel beam ductility
New concepts on structural ductility
DUCTROT-M Computer program
Monotonic available ductility
Local ductility under far-field earthquakes
Near-field earthquake effects on the available ductility of steel beams
Acknowledgments
References
Fire after earthquake
Introduction
Structural behavior under the effect of fire
From the historical events to date
Post-earthquake fire and risk management
Computational aspects
Analysis assumptions
Structural behavior
Methodology for assessing robustness
Conclusive remarks
References
Index