Learn the fundamentals of structural steel design with STEEL DESIGN�s unique emphasis on the design of members and their connections. With this best-selling book, you can learn LRFD (Load and Resistance Factor Design) or ASD (Allowable Stress Design), depending on how your course is taught. You will master the application of fundamental principles for design procedures, as well as for practical design. You will also study the theory behind these procedures, which further strengthens your engineering knowledge. While this market-leading book is ideal for your junior-and senior-level steel design class, later chapters are also useful for graduate courses. The book functions as a valuable ongoing reference tool for success in your career as a practicing engineer.
Author(s): William T. Segui
Edition: 6th (Watermark free)
Publisher: Cengage Learning
Year: 2017
Language: English
Pages: 800
Tags: Steel Structures, Structural Engineering, Civil and Environmental Engineering
Cover
Title Page
Copyright
About the Author
Contents
Preface
MindTap Online Course
Chapter 1: Introduction
1.1 Structural Design
1.2 Loads
1.3 Building Codes
1.4 Design Specifications
1.5 Structural Steel
1.6 Standard Cross -Sectional Shapes
Problems
Chapter 2: Concepts in Structural Steel Design
2.1 Design Philosophies
2.2 American Institute of Steel Construction Specification
2.3 Load Factors, Resistance Factors, and Load Combinations for LRFD
2.4 Safety Factors and Load Combinations for ASD
2.5 Probabilistic Basis of Load and Resistance Factors
2.6 Steel Construction Manual
2.7 Design Computations and Precision
Problems
Chapter 3: Tension Members
3.1 Introduction
3.2 Tensile Strength
3.3 Effective Area
3.4 Staggered Fasteners
3.5 Block Shear
3.6 Design of Tension Members
3.7 Hreaded Rods and Cables
3.8 Tension Members in Roof Trusses
3.9 Pin-Connected Members
Problems
Chapter 4: Compression Members
4.1 Introduction
4.2 Column Theory
4.3 Aisc Requirements
4.4 Local Stability
4.5 Tables for Compression Members
4.6 Design
4.7 More on Effective Length
4.8 Torsional and Flexural-Torsional Buckling
4.9 Built-Up Members
Problems
Chapter 5: Beams
5.1 Introduction
5.2 Bending Stress and the Plastic Moment
5.3 Stability
5.4 Classification of Shapes
5.5 Bending Strength of Compact Shapes
5.6 Bending Strength of Noncompact Shapes
5.7 Summary of Moment Strength
5.8 Shear Strength
5.9 Deflection
5.10 Design
5.11 Floor and Roof Framing Systems
5.12 Holes in Beams
5.13 Open-Web Steel Joists
5.14 Beam Bearing Plates and Column Base Plates
5.15 Biaxial Bending
5.16 Bending Strength of Various Shapes
Problems
Chapter 6: Beam–Columns
6.1 Definition
6.2 Interaction Formulas
6.3 Methods of Analysis for Required Strength
6.4 The Moment Amplification Method
6.5 Braced versus Unbraced Frames
6.6 Members in Braced Frames
6.7 Members in Unbraced Frames
6.8 Design of Beam–Columns
6.9 Trusses with Top-Chord Loads Between Joints
Problems
Chapter 7: Simple Connections
7.1 Introduction
7.2 Bolted Shear Connections: Failure Modes
7.3 Bearing Strength, Spacing, and Edge-Dis tance Requirements
7.4 Shear Strength
7.5 Installation of High-Strength Bolts
7.6 Slip-Critical and Bearing-Type Connections
7.7 Design Examples
7.8 High-Strength Bolts in Tension
7.9 Combined Shear and Tension in Fasteners
7.10 Welded Connections
7.11 Fillet Welds
Problems
Chapter 8: Eccentric Connections
8.1 Examples of Eccentric Connections
8.2 Eccentric Bolted Connections: Shear Only
8.3 Eccentric Bolted Connections: Shear Plus Tension
8.4 Eccentric Welded Connections: Shear Only
8.5 Eccentric Welded Connections: Shear Plus Te nsion
8.6 Moment-Resisting Connections
8.7 Column Stiffeners and Other Reinforcement
8.8 End Plate Connections
8.9 Concluding Remarks
Problems
Chapter 9: Composite Construction
9.1 Introduction
9.2 Shored versus Unshored Construction
9.3 Effective Flange Width
9.4 Steel Headed Stud Anchors
9.5 Design
9.6 Deflections
9.7 Composite Beams with Formed Steel Deck
9.8 Tables for Composite Beam Analysis and Design
9.9 Continuous Beams
9.10 Composite Columns
Problems
Chapter 10: Plate Girders
10.1 Introduction
10.2 General Considerations
10.3 AISC Requirements for Proportions of Plate Girders
10.4 Flexural Strength
10.5 Shear Strength
10.6 Bearing Stiffeners
10.7 Design
Problems
Appendix: Plastic Analysis and Design
A.1 Introduction
A.2 AISC Requirements
A.3 Analysis
A.4 Design
References
Answers to Selected Problems
Index
