Structural Steel Designer's Handbook, Sixth Edition /

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Brockenbrough, Roger L. (Autor), Merritt, Frederick S. (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: New York, N.Y. : McGraw-Hill Education, [2020].
Edición:6th edition.
Temas:
Building, Iron and steel.
Steel, Structural.
TECHNOLOGY & ENGINEERING / Civil / General.
Electronic books.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover
  • Title Page
  • Copyright Page
  • Dedication
  • About the Editors
  • Contents
  • Contributors
  • Preface to the Sixth Edition
  • Preface to the Second Edition
  • Factors for Conversion to SI Units of Measurement
  • Chapter 1. Properties of Structural Steels and Effects of Steelmaking and Fabrication
  • 1.1 Structural Steel Shapes and Plates
  • 1.2 Steel-Quality Designations
  • 1.3 Steel Sheet and Strip for Structural Applications
  • 1.4 Tubing for Structural Applications
  • 1.5 Steel Cable for Structural Applications
  • 1.6 Tensile Properties
  • 1.7 Properties in Shear
  • 1.8 Hardness Tests
  • 1.9 Effect of Cold Work on Tensile Properties
  • 1.10 Effect of Strain Rate on Tensile Properties
  • 1.11 Effect of Elevated Temperatures on Tensile Properties
  • 1.12 Fatigue
  • 1.13 Brittle Fracture
  • 1.14 Residual Stresses
  • 1.15 Lamellar Tearing
  • 1.16 Welded Splices in Heavy Sections
  • 1.17 k-Area Cracking
  • 1.18 Variations in Mechanical Properties
  • 1.19 Changes in Carbon Steels on Heating and Cooling
  • 1.20 Effects of Grain Size
  • 1.21 Annealing and Normalizing
  • 1.22 Effects of Chemistry on Steel Properties
  • 1.23 Steelmaking Methods
  • 1.24 Casting and Hot Rolling
  • 1.25 Effects of Punching Holes and Shearing
  • 1.26 Effects of Welding
  • 1.27 Effects of Thermal Cutting
  • Chapter 2. Fabrication and Erection
  • 2.1 Estimates, Material Orders, and Shop Drawings
  • 2.2 Requirements for Drawings
  • 2.3 Fabrication Practices and Processes: Material Preparation
  • 2.4 Fabrication Practices and Processes: Assembly, Fitting, and Fastening
  • 2.5 Shop Assembly
  • 2.6 Rolled Sections
  • 2.7 Built-Up Sections
  • 2.8 Cleaning and Painting and Architecturally Exposed Structural Steel
  • 2.9 Fabrication Tolerances
  • 2.10 Steel Frame Erection
  • 2.11 Erection Equipment
  • 2.12 Erection Methods for Buildings
  • 2.13 Erection Procedure for Bridges
  • 2.14 Field Tolerances
  • 2.15 Coordination and Constructability
  • 2.16 Safety Concerns
  • 2.17 Quality Control and Quality Assurance
  • Chapter 3. Connections
  • 3.1 General Considerations for Connection Design
  • 3.2 Design of Fasteners and Welds
  • 3.3 General Connection Design Procedure
  • 3.4 Shear and Axial Beam End Connections
  • 3.5 Axial Connections
  • 3.6 Moment Connections
  • 3.7 Vertical Brace Design by Uniform Force Method
  • 3.8 References
  • Chapter 4. Building Codes, Loads, and Fire Protection
  • 4.1 Building Codes
  • 4.2 Approval of Special Construction
  • 4.3 Standard Specifications
  • 4.4 Building Occupancy Loads
  • 4.5 Roof Loads
  • 4.6 Wind Loads
  • 4.7 Seismic Loads
  • 4.8 Tsunami Loads
  • 4.9 Impact Loads
  • 4.10 Crane-Runway Loads
  • 4.11 Self-Straining Load Effects
  • 4.12 Combined Loads
  • 4.13 Fire Protection
  • Chapter 5. Criteria for Building Design
  • 5.1 Materials, Design Methods, and Other Considerations
  • 5.2 Design for Stability
  • 5.3 Design of Tension Members
  • 5.4 Design of Compression Members
  • 5.5 Design of Flexural Members
  • 5.6 Design of Members for Shear
  • 5.7 Design for Combined Forces and Torsion
  • 5.8 Design of Composite Members
  • 5.9 Design of Connections
  • Chapter 6. Design of Building Members
  • 6.1 Tension Members
  • 6.2 Example?LRFD for Double-Angle Hanger
  • 6.3 Example?LRFD for Wide-Flange Truss Members
  • 6.4 Compression Members
  • 6.5 Example?LRFD for Steel Pipe in Axial Compression
  • 6.6 Example?LRFD for Wide-Flange Section with Axial Compression
  • 6.7 Example?LRFD for Double Angles with Axial Compression
  • 6.8 Steel Beams
  • 6.9 Example?LRFD for Simple-Span Floor Beam
  • 6.10 Example?LRFD for Floor Beam with Unbraced Top Flange
  • 6.11 Example?LRFD for Floor Beam with Overhang
  • 6.12 Composite Beams
  • 6.13 LRFD for Composite Beam with Uniform Loads
  • 6.14 Example?LRFD for Composite Beam with Concentrated Loads and End Moments
  • 6.15 Example?LRFD for Wide-Flange Column in a Multistory Rigid Frame
  • Chapter 7. Floor and Roof Systems
  • Floor Decks
  • Roof Decks
  • Floor Framing
  • Roof Framing
  • Chapter 8. Lateral-Force Design
  • 8.1 Description of Wind Forces
  • 8.2 Determination of Wind Loads
  • 8.3 Seismic Loads in Model Codes
  • 8.4 Seismic Design Loads
  • 8.5 Dynamic Method of Seismic Load Distribution
  • 8.6 Alternate Seismic Design Methods
  • 8.7 Structural Steel Systems for Seismic Design
  • 8.8 Seismic-Design Limitations on Steel Frames
  • 8.9 Forces in Frames Subjected to Lateral Loads
  • 8.10 Member and Connection Design for Lateral Loads
  • 8.11 Designing for Tsunami Loads
  • Chapter 9. Cold-Formed Steel Design
  • 9.1 Design Specifications and Materials
  • 9.2 Manufacturing Methods and Effects
  • 9.3 Nominal Loads
  • 9.4 Design Methods
  • 9.5 Section Property Calculations
  • 9.6 Effective Width Concept
  • 9.7 Maximum Width-to-Thickness Ratios Using Effective Width Method
  • 9.8 Effective Widths of Stiffened Elements
  • 9.9 Effective Widths of Unstiffened Elements
  • 9.10 Effective Widths of Uniformly Compressed Elements with Simple Lip Edge Stiffener
  • 9.11 Tension Members
  • 9.12 Flexural Members
  • 9.13 Concentrically Loaded Compression Members
  • 9.14 Combined Tensile Axial Load and Bending
  • 9.15 Combined Compressive Axial Load and Bending
  • 9.16 Cylindrical Tubular Members
  • 9.17 Welded Connections
  • 9.18 Bolted Connections
  • 9.19 Screw Connections
  • 9.20 Rupture (Fracture in Net Section)
  • 9.21 Cold-Formed Steel Framing Design Resources
  • 9.22 Example of Effective Section Calculation
  • 9.23 Example of Bending Strength Calculation
  • Chapter 10. Highway Bridge Design Criteria
  • 10.1 Specifications
  • 10.2 General Design Considerations
  • 10.3 Design Methods
  • 10.4 Highway Design Loadings
  • 10.5 Distribution of Loads Through Decks
  • 10.6 Fracture Control
  • 10.7 Repetitive Loading and Fatigue
  • 10.8 Detailing for Earthquakes
  • 10.9 Detailing for Buckling
  • 10.10 Criteria for Built-Up Tension Members
  • 10.11 Criteria for Built-Up Compression Members
  • 10.12 Plate Girders and Rolled Beams
  • 10.13 Composite Construction with I-Girders
  • 10.14 Cost-Effective Plate-Girder Designs
  • 10.15 Box Girders
  • 10.16 Hybrid Girders
  • 10.17 Orthotropic-Deck Bridges
  • 10.18 Bearings
  • 10.19 Detailing for Weldability
  • 10.20 Bridge Decks
  • 10.21 Elimination of Expansion Joints in Highway Bridges
  • 10.22 Bridge Steels and Corrosion Protection
  • Chapter 11. Beam and Girder Bridges
  • 11.1 Characteristics of Beam Bridges
  • 11.2 Characteristics of Plate-Girder Stringer Bridges
  • 11.3 Example?Load Factor Design of Composite Plate-Girder Bridge
  • 11.4 Characteristics of Curved-Girder Bridges
  • 11.5 Deck Plate-Girder Bridges with Floor Beams
  • 11.6 Through Plate-Girder Bridges with Floor Beams
  • 11.7 Composite Box-Girder Bridges
  • 11.8 Continuous-Beam Bridges
  • 11.9 Example?Load and Resistance Factor Design (LRFD) of Composite Plate-Girder Bridge
  • Chapter 12. Truss Bridges
  • 12.1 Specifications
  • 12.2 Truss Components
  • 12.3 Types of Trusses
  • 12.4 Bridge Layout
  • 12.5 Deck Design
  • 12.6 Lateral Bracing, Portals, and Sway Frames
  • 12.7 Resistance to Longitudinal Forces
  • 12.8 Truss Design Procedure
  • 12.9 Truss Member Details
  • 12.10 Member and Joint Design Examples?LFD and SLD
  • 12.11 Member Design Example?LRFD
  • 12.12 Truss Joint Design Procedure
  • 12.13 Truss Joint Design and Rating
  • 12.14 Example?Load and Resistance Factor Rating of a Truss Joint
  • 12.15 Skewed Bridges
  • 12.16 Truss Bridges on Curves
  • 12.17 Truss Supports and Other Details
  • 12.18 Continuous Trusses
  • 12.19 References
  • Chapter 13.
  • Arch Bridges
  • 13.1 Types of Arches
  • 13.2 Arch Forms
  • 13.3 Selection of Arch Type and Form
  • 13.4 Comparison of Arch with Other Bridge Types
  • 13.5 Erection of Arch Bridges
  • 13.6 Design of Arch Ribs and Ties
  • 13.7 Design of Other Elements
  • 13.8 Examples of Arch Bridges
  • 13.9 Guidelines for Preliminary Designs and Estimates
  • 13.10 Buckling Considerations for Arches
  • 13.11 Example?Design of Tied-Arch Bridge
  • Chapter 14. Cable-Suspended Bridges
  • 14.1 Evolution of Cable-Suspended Bridges
  • 14.2 Classification of Cable-Suspended Bridges
  • 14.3 Classification and Characteristics of Suspension Bridges
  • 14.4 Classification and Characteristics of Cable-Stayed Bridges
  • 14.5 Classification of Bridges by Span
  • 14.6 Cable-Suspended Bridges for Rail Loading
  • 14.7 Specifications and Loadings for Cable-Suspended Bridges
  • 14.8 Cables
  • 14.9 Cable Saddles, Anchorages, and Connections
  • 14.10 Corrosion Protection of Cables
  • 14.11 Statics of Cables
  • 14.12 Suspension Bridge Analysis
  • 14.13 Preliminary Suspension Bridge Design
  • 14.14 Self-Anchored Suspension Bridges
  • 14.15 Cable-Stayed Bridge Analysis
  • 14.16 Preliminary Design of Cable-Stayed Bridges
  • 14.17 Aerodynamic Analysis of Cable-Suspended Bridges
  • 14.18 Seismic Analysis of Cable-Suspended Structures
  • 14.19 Erection of Cable-Suspended Bridges
  • Index.

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