Enhanced descriptions from Syndetics:

As known, each bridge presents a unique set of design, construction, and maintenance challenges. The designer must determine the appropriate methods and level of refinement necessary to design and analyze each bridge on a case-by-case basis. The Innovative Bridge Design Handbook: Construction, Rehabilitation, and Maintenance encompasses the state of the art in bridge design, construction, maintenance, and safety assessment. Written by an international group of experts, this book provides innovative design approaches used in various parts of the world and explores concepts in design, construction, and maintenance that will reduce project costs and increase structural safety and durability. Furthermore, research and innovative solutions are described throughout chapters.

The Innovative Bridge Design Handbook: Construction, Rehabilitation, and Maintenance brings together the specific knowledge of a bevy of experts and academics in bridge engineering in the areas of design, assessment, research, and construction. The handbook begins with an analysis of the history and development of bridge aesthetics and design; various types of loads including seismic and wind loads are then described, together with fatigue and fracture. Bridge design based on material such as reinforced concrete, prestressed reinforced concrete, steel and composite, timber, masonry bridges is analyzed and detailed according to international codes and standards. Then bridge design based on geometry, such as arch bridges, girders, cable stayed and suspension bridges, is illustrated. This is followed by a discussion of a number of special topics, including integral, movable, highway and railway bridges, together with seismic component devices, cables, orthotropic decks, foundations, and case studies. Finally, bridge construction equipment, bridge assessment retrofit and management, bridge monitoring, fiber-reinforced polymers to reinforce bridges, bridge collapse issues are covered.

Loads including seismic and wind loads, fatigue and fracture, local effects Structural analysis including numerical methods (FEM), dynamics, risk and reliability, innovative structural typologies Bridge design based on material type: RC and PRC, steel and composite, timber and masonry bridges Bridge design based on geometry: arch bridges, girders, cable stayed and suspension bridges Special topics: integral, movable, highway, railway bridges, seismic component devices, cables, orthotropic decks, foundations Construction including construction case studies, construction equipment, bridge assessment, bridge management, retrofit and strengthening, monitoring procedures

Table of contents provided by Syndetics

• Section I Fundamentals
• Chapter 1 The history, aesthetics, and design of bridges
• Section II Loads on bridges
• Chapter 2 Loads on bridges
• Chapter 3 Wind loads
• Chapter 4 Fatigue and fracture
• Section III Structural analysis
• Chapter 5 Bridge structural theory and modeling
• Chapter 6 Dynamics of bridge structures
• Chapter 7 Risk and reliability in bridges
• Chapter 8 Innovative structural typologies
• Section IV Bridge design based on construction material type
• Chapter 9 Reinforced and prestressed concrete bridges
• Chapter 10 Steel and composite bridges
• Chapter 11 Timber bridges
• Chapter 12 Masonry bridges
• Section V Bridge design based on geometry
• Chapter 13 Arch bridges
• Chapter 14 Girders
• Chapter 15 Long-span bridges
• Section VI Special topics
• Chapter 16 Integral bridges
• Chapter 17 Movable bridges
• Chapter 18 Highway bridges
• Chapter 19 Railway bridges
• Section VII Bridge components
• Chapter 20 Seismic component devices
• Chapter 21 Cables
• Chapter 22 Orthotropic steel decks
• Chapter 23 Bridge foundations
• Section VIII Bridge construction
• Chapter 24 Case study: the Reno bridge
• Chapter 25 Case study: the Russky bridge
• Chapter 26 Case study: the Akashi-Kaikyo bridge
• Chapter 27 Bridge construction equipment
• Section IX Assessment, managment, retrofit, monitoring and rehabilitation of existing bridges
• Chapter 28 Bridge assessment, retrofit, and management
• Chapter 29 Bridge monitoring
• Chapter 30 Application of fiber-reinforced polymers to reinforced concrete bridges
• Chapter 31 Bridge collapse