Concrete buildings in seismic regions

Bearing in mind that reinforced concrete is a key component in a majority of built environment structures, Concrete Buildings in Seismic Regions combines the scientific knowledge of earthquake engineering with a focus on the design of reinforced concrete buildings in seismic regions. This book addresses practical design issues, providing an integrated, comprehensible, and clear presentation that is suitable for design practice. It combines current approaches to seismic analysis and design, with a particular focus on reinforced concrete structures, and includes: an overview of structural dynamics analysis and design of new R/C buildings in seismic regions post-earthquake damage evaluation, pre earthquake assessment of buildings and retrofitting procedures seismic risk management of R/C buildings within urban nuclei extended numerical example applications Concrete Buildings in Seismic Regions determines guidelines for the proper structural system for many types of buildings, explores recent developments, and covers the last two decades of analysis, design, and earthquake engineering. Divided into three parts, the book specifically addresses seismic demand issues and the basic issues of structural dynamics, considers the "capacity" of structural systems to withstand seismic effects in terms of strength and deformation, and highlights existing R/C buildings under seismic action. All of the book material has been adjusted to fit a modern seismic code and offers in-depth knowledge of the background upon which the code rules are based. It complies with the last edition of European Codes of Practice for R/C buildings in seismic regions, and includes references to the American Standards in effect for seismic design.

Introduction Historical notes Structure of this book An overview of structural dynamics General Dynamic analysis of elastic single-degree-of-freedom systems Dynamic analysis of inelastic SDOF systems Dynamic analysis of MDOF elastic systems Dynamic analysis of MDOF inelastic systems Application example Design principles - seismic actions - performance requirements -compliance criteria Introduction The conceptual framework of seismic design: Energy balance Earthquake input Ground conditions and design seismic actions Performance requirements and compliance criteria Configuration of earthquake-resistant R/C structural systems: Structural behaviour General Basic principles of conceptual design Primary and secondary seismic members Structural R/C types covered by seismic codes Response of structural systems to lateral loading Structural configuration of multi-storey R/C buildings Analysis of the structural system General Structural Regularity Torsional Flexibility Ductility Classes and Behaviour Factors Analysis Methods Elastic Analysis Methods Inelastic analysis methods Combination of the components of gravity loads and seismic action Example: Modelling and elastic analysis of an eight-storey RC building Examples: Applications using inelastic analysis Capacity design - design action effects - safety verifications Impact of capacity design on design action effects Safety verifications Reinforced concrete materials under seismic actions Introduction Plain (unconfined) concrete Steel Confined concrete Bonding between steel and concrete Basic Conclusions for materials and their synergy Seismic-resistant R/C frames General Design of beams Design of Columns Beam-column joints Masonry infilled frames General Example: Detailed design of an internal frame Seismic-resistant R/C walls and diaphragms General Slender ductile walls Ductile coupled walls Squat ductile walls Large lightly reinforced walls Special issues in the design of walls Seismic design of diaphragms Example: Dimensioning of a ductile and slender Wall with a composite cross-section Seismic design of foundations General Ground properties General considerations for foundation analysis and design Analysis and design of foundation ground under the design action effects Analysis and design of foundation members under the design action effects Example: Dimensioning of foundation beams Seismic pathology Classification of damage to R/C structural members Factors affecting the degree of damage to buildings Emergency post-earthquake damage inspection, assessment and human life protection measures General Inspections and damage assessment Organisational scheme for inspections Action plan Emergency measures for temporary propping Final remarks Seismic assessment and retrofitting of R/C buildings General Pre-Earthquake Seismic Evaluation of R/C Buildings Post-Earthquake Seismic Evaluation of R/C Buildings Design of Repair of R/C Buildings Detailed seismic assessment and rehabilitation of R/C buildings General Overview of displacement-based design for seismic actions Scope of the detailed seismic assessment and rehabilitation of R/C buildings Performance requirements and compliance criteria Information for structural assessment Quantitative assessment of seismic capacity Decisions for structural retrofitting of R/C buildings Design of structural rehabilitation Technology of repair and strengthening General Materials and intervention techniques Redimensioning and safety verification of structural elements Repair and strengthening of structural elements using conventional means Repair and strengthening of structural elements using FRPs Addition of new structural elements Quality assurance of interventions Final remarks Seismic risk management General Conceptual approach to the steps of seismic risk management Seismic risk assessment in the United States and European Union Seismic hazard Seismic vulnerability Seismic risk analysis Cost-benefit analysis References Index