Structural Engineering Handbook, Fifth Edition /

Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Mahamid, Mustafa (Editor ), Gaylord, Edwin H. (Editor ), Gaylord, Charles N. (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: New York, N.Y. : McGraw-Hill Education, [2020].
Edición:5th edition.
Temas:
Structural engineering > Handbooks, manuals, etc.
Structural engineering.
Tragwerk.
TECHNOLOGY & ENGINEERING / Civil / General
Electronic books.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover
  • Title Page
  • Copyright Page
  • About the Editors
  • Contents
  • Contributors
  • Preface
  • Chapter 1. Structural Loads Mustafa Mahamid, David A. Fanella
  • 1.1 Introduction
  • 1.2 Dead Loads
  • 1.3 Live Loads
  • 1.4 Rain Loads
  • 1.5 Soil Lateral Loads
  • 1.6 Snow and Ice Loads
  • 1.7 Wind Loads
  • 1.8 Earthquake Loads
  • 1.9 Flood and Tsunami Loads
  • 1.10 Load Combinations
  • References
  • Chapter 2. Structural Analysis Aly M. Said, Anas S. Issa, M. Shahria Alam
  • PART A FUNDAMENTALS AND APPLICATIONS TO STRUCTURAL FRAMEWORKS
  • PART B ARCHES AND RIGID FRAMES
  • References
  • Chapter 3. The Finite-Element Method Craig D. Foster, Sheng-Wei Chi
  • 3.1 Overview of Theory of Finite-Element Analysis
  • 3.2 Outline of Steps in a Finite-Element Analysis
  • 3.3 Types of Structural and Mechanical Analyses
  • 3.4 Elements and Nodes
  • 3.5 Meshing
  • 3.6 Applying Loads and Displacement Boundary Conditions
  • 3.7 Material Models and Other Properties
  • 3.8 Solving the Quasi-Static Problem
  • 3.9 Postprocessing?Solving for Strain, Stress, and Other Quantities
  • 3.10 Dynamic Finite-Element Analysis
  • 3.11 Nonlinear Finite-Element Analysis
  • 3.12 Verification and Validation
  • 3.13 Issues and Pitfalls in Finite-Element Analysis
  • 3.14 Introduction to Finite Elements for Thermal, Thermomechanical, and Other Problems
  • References
  • Chapter 4. Computer Applications in Structural Engineering Raoul Karp, Bulent N. Alemdar, Sam Rubenzer
  • 4.1 Introduction
  • 4.2 Computer Structural Analysis Simulation
  • 4.3 Structural Finite Elements
  • 4.4 Foundations
  • 4.5 Verifying Analysis Results
  • 4.6 Building Information Modeling and Interoperability
  • 4.7 Summary
  • References
  • Chapter 5. Earthquake-Resistant Design S. K. Ghosh
  • 5.1 Overview
  • 5.2 Nature of Earthquake Motion
  • 5.3 Design Philosophy
  • 5.4 Seismic Design Requirements of the 2018 IBC/ASCE 7-16
  • References
  • Chapter 6. Fracture and Fatigue Kedar S. Kirane, Zdenek P. Ba?ant, J. Ernesto Indacochea, Vineeth Kumar Gattu
  • PART A CONCRETE AND COMPOSITES
  • PART B STRUCTURAL STEELS
  • Chapter 7. Soil Mechanics and Foundations Joseph W. Schulenberg, Krishna R. Reddy
  • 7.1 Soil Behavior
  • 7.2 Shallow Foundation Analyses
  • 7.3 Deep Foundations
  • 7.4 Retaining Structures
  • 7.5 Investigations
  • 7.6 Soil Improvement
  • 7.7 Monitoring
  • References
  • Chapter 8. Design of Structural Steel Members Jay Shen, Bulent Akbas, Onur Seker, Charlies J. Carter
  • 8.1 Design of Steel and Composite Members
  • 8.2 Seismic Design of Steel Members in Moment and Braced Frames
  • 8.3 Concluding Remarks
  • References
  • Chapter 9. Design of Cold-Formed Steel Structural Members Nabil A. Rahman, Helen Chen, Cheng Yu
  • 9.1 Shapes and Applications
  • 9.2 Materials
  • 9.3 Corrosion Protection
  • 9.4 Member Design Methodology
  • 9.5 Structural Stability in Determining Member Forces
  • 9.6 Member Design
  • 9.7 Assemblies and Systems
  • 9.8 Connections
  • References
  • Chapter 10. Aluminum Structural Design J. Randolph Kissell
  • 10.1 Introduction
  • 10.2 Design Overview
  • 10.3 Determining Required Forces
  • 10.4 Axial Tension
  • 10.5 Axial Compression
  • 10.6 Flexure
  • 10.7 Shear and Torsion
  • 10.8 Combined Forces
  • 10.9 Connections
  • 10.10 Serviceability
  • 10.11 Fabrication and Erection
  • 10.12 Fatigue
  • References
  • Chapter 11. Design of Reinforced-Concrete Structural Members Mustafa Mahamid, David A. Fanella
  • 11.1 Concrete
  • 11.2 Reinforcement
  • 11.3 Specifications, Codes, and Standards
  • 11.4 General Requirements for Strength and Serviceability
  • 11.5 General Principles of the Strength Design Method
  • 11.6 General Principles and Requirements
  • 11.7 One-Way Slabs, Two-Way Slabs, and Beams
  • 11.8 Columns
  • 11.9 Tension Members
  • 11.10 Members Subjected to Flexure and Axial Load
  • 11.11 Walls
  • 11.12 Footings
  • 11.13 Two-Way Slab Systems
  • 11.14 Seismic
  • References
  • Chapter 12. Design of Prestressed-Concrete Structural Members Sri Sritharan, Maryam Nazari
  • Notation
  • References
  • Chapter 13. Masonry Construction Richard Bennett, Sam Rubenzer
  • Notation
  • References
  • Chapter 14. Timber Structures Thomas Williamson, Mustafa Mahamid
  • 14.1 Wood as an Engineering Material
  • 14.2 Allowable Stress Design (ASD) vs. Load and Resistance Factor Design (LRFD)
  • 14.3 Structural Wood Products
  • 14.4 Member Design
  • 14.5 Connection Design
  • 14.6 Lateral Load Resistance
  • References
  • Chapter 15. Bridge Engineering Soliman Khudeira, Tony Shkurti, Eric Stone, James Carter III, Jamshid Mohammadi, Bora Jang
  • PART A STEEL AND CONCRETE BRIDGES
  • PART B STEEL BOX-GIRDER BRIDGES
  • PART C CURVED STEEL I-GIRDER BRIDGES
  • PART D CURVED STEEL BOX-GIRDER BRIDGES
  • PART E CURVED CONCRETE BOX-GIRDER BRIDGES
  • Chapter 16. Railroad Bridge Design Mohsen Issa, Ahmad Hammad
  • 16.1 Introduction
  • 16.2 General Requirements
  • 16.3 Loading
  • 16.4 Timber
  • 16.5 Steel
  • 16.6 Concrete
  • References
  • Chapter 17. Industrial Buildings Jules Van de Pas, John Rolfes
  • 17.1 Planning Industrial Buildings
  • 17.2 Code Requirements and Industrial Loads
  • 17.3 Framing Systems
  • References
  • Chapter 18. Tall Buildings Charles Besjak, Brian McElhatten, Preetam Biswas
  • 18.1 Definition of Tall Building
  • 18.2 General Design Considerations
  • 18.3 Structural Design Considerations
  • 18.4 Serviceability Considerations
  • 18.5 Structural Systems for Tall Buildings
  • 18.6 System Conceptualization
  • 18.7 System Parameters and Choices
  • 18.8 Analysis Parameters and Techniques
  • 18.9 Performance-Based Design for Wind
  • 18.10 Performance-Based Design for Seismic
  • 18.11 Creep and Shrinkage
  • 18.12 High-Rise Building Glossary
  • 18.13 Additional Credits
  • Acknowledgments
  • References
  • Chapter 19. Thin-Shell Concrete Structures Edmond Saliklis, Mustafa Mahamid, David P. Billington, Julian A. Dumitrescu
  • 19.1 Introduction and Historical Overview
  • 19.2 Shells of Rotation
  • 19.3 Domes
  • 19.4 Cylindrical Barrel Shells
  • 19.5 Folded Plates
  • 19.6 Translation Shells of Double Curvature
  • 19.7 Dimensioning
  • 19.8 Stability and Safety
  • 19.9 Construction
  • 19.10 Appearance
  • References
  • Chapter 20. Cable-Supported Roofs Paul A. Gossen, Keith M. MacBain
  • 20.1 Introduction
  • 20.2 Cable Materials and Construction
  • 20.3 Structural Systems
  • 20.4 Dynamics
  • 20.5 Analysis and Design
  • 20.6 Erection
  • References
  • Chapter 21. Reinforced-Concrete Silos Ramez B. Gayed, Mustafa Mahamid, Amin Ghali
  • 21.1 General
  • 21.2 Design of Walls
  • 21.3 Design of Bottoms
  • References
  • Chapter 22. Design of Steel Tanks Leslie D. Scott
  • 22.1 Introduction
  • 22.2 Design Considerations
  • 22.3 Design of Reservoirs and Standpipes
  • 22.4 Elevated Tanks
  • 22.5 Accessories
  • 22.6 Materials
  • 22.7 Commercially Available Computer Programs
  • 22.8 The Engineer?s Role
  • References
  • Chapter 23. Electrical Transmission and Substation Structures Michael D. Miller, Robert E. Nickerson
  • 23.1 Introduction
  • 23.2 Referenced Standards and Manuals of Practice
  • 23.3 Transmission Line Structures
  • 23.4 Substation Structures
  • References
  • Chapter 24. Chimneys Shu-Jin Fang, Victor Bochicchio
  • 24.1 Introduction
  • 24.2 Design Loads
  • 24.3 Steel Stacks
  • 24.4 Reinforced-Concrete Chimneys
  • 24.5 Liners and Linings
  • 24.6 Foundations
  • References
  • Chapter 25.
  • Health Monitoring and Nondestructive Testing Didem Ozevin, Farhad Ansari
  • 25.1 Introduction
  • 25.2 Components of NDE Methods
  • 25.3 Waveform-Based NDE Methods and Applications
  • 25.4 The Applications of Waveform-Based NDE Methods to Infrastructure Systems
  • References
  • Chapter 26. Building Information Modeling (BIM) for Structural Engineering Nawari O. Nawari
  • 26.1 Introduction
  • 26.2 BIM Fundamentals
  • 26.3 BIM Processes in Practice
  • 26.4 Structure and Architecture Synergy (SAS) Framework
  • 26.5 Conclusions
  • References
  • Chapter 27. Structural Fire Engineering V. K. R. Kodur, M. Z. Naser
  • 27.1 General
  • 27.2 Designing Structures for Fire Safety
  • 27.3 Fire Growth and Development
  • 27.4 Properties of Construction Materials at Elevated Temperatures
  • 27.5 Fire Resistance Evaluation
  • 27.6 Prescriptive-Based Approaches
  • 27.7 Rational Design Approaches
  • 27.8 Summary
  • References
  • Chapter 28. Disproportionate Collapse and Blast-Resistant Design Shalva Marjanishvili, Robert Smilowitz
  • PART A STRUCTURAL ROBUSTNESS AND DISPROPORTIONATE COLLAPSE
  • PART B BLAST-RESISTANT DESIGN
  • Chapter 29. FRP Strengthening of Reinforced-Concrete Members Hayder A. Rasheed
  • 29.1 FRP Properties for Strengthening Applications
  • 29.2 Flexural Strengthening Design for Beams and Slabs
  • 29.3 Shear Strengthening Design for Beams
  • 29.4 Confinement Strengthening Design for Circular Columns
  • References
  • Chapter 30. Structural Glass and Glazing Rui de S. Camposinhos
  • 30.1 Introduction
  • 30.2 Glass: Production and Properties
  • 30.3 Glass as a Structural Material
  • 30.4 Actions
  • 30.5 Codes and Standards
  • 30.6 Plate Buckling
  • 30.7 Lateral-Torsional Buckling
  • 30.8 Glass Columns
  • References
  • Chapter 31. Machine Foundations O. Salem Ali
  • 31.1 Background
  • 31.2 Classification of Machine Based on Machine Type
  • 31.3 Classification of Machine Based on Type of Excitation Force
  • 31.4 Classification of Machine Based on Foundation Type
  • 31.5 Classification of Machine Load Transfer Mechanism
  • 31.6 Design Limits for Machine Foundations
  • 31.7 Effect of the Supporting Soil
  • 31.8 Energy Transfer Mechanism
  • 31.9 Effect of Embedment of Foundation
  • 31.10 Reduction in Permissible Soil Stress
  • 31.11 Damping in Soil
  • 31.12 Modeling Techniques for Machine Foundations
  • 31.13 Block-Type Foundation
  • 31.14 Mat Foundations
  • 31.15 Elevated Machine Foundation
  • 31.16 Three-Dimensional Finite-Element Modeling
  • 31.17 Soil Modeling
  • 31.18 Current Approach of Soil Modeling
  • 31.19 Methods to Compute Dynamic Impedance Functions
  • 31.20 Foundations Supported on Piles
  • 31.21 Piles Subjected to Lateral Vibrations
  • 31.22 Elastic Continuum
  • 31.23 Piles Subjected to Vertical Vibrations
  • 31.24 Pile Group Effect
  • References
  • Chapter 32. Value Methodology Muthiah Kasi, Charles A. Bartlett
  • 32.1 Introduction
  • 32.2 VM Job Plan
  • 32.3 The Key Features of VM Job Plan: Function Analysis
  • 32.4 Example 1: Parapet Joint Detail
  • 32.5 Evaluation Phase
  • 32.6 Implementation
  • 32.7 Summary
  • References
  • Chapter 33. Stone Cladding Rui de S. Camposinhos
  • 33.1 Introduction: Natural Stone Cladding
  • 33.2 Natural Stone Depiction
  • 33.3 Mechanical Properties
  • 33.4 Cladding Systems and Methods
  • 33.5 Limit States Design
  • 33.6 Dowel Anchorage
  • 33.7 Kerf Anchorage
  • 33.8 Undercut Anchorage
  • References
  • Index.

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