Structural Steel Design : International Edition （5TH）

Csernak, Stephen/ McCormac, Jack

Pearson Education Limited（2011/10発売）

• 製本 Paperback:紙装版/ペーパーバック版／ページ数 736 p.
• 言語 ENG
• 商品コード 9780273751359
• DDC分類 624.1821

Full Description

For undergraduate courses in Steel Design. * Both Load and Resistance Factor Design (LRFD) and Allowable Stress Design (ASD) methods of designing steel structures are presented throughout the book. The book is carefully designed so that an instructor can easily teach LRFD or ASD (material exclusively pertaining to ASD is shaded). * This text is presented using an easy-to-read, student-friendly style.

Contents

Contents
Preface iii
CHAPTER 1 Introduction to Structural Steel Design 1
1.1 Advantages of Steel as a Structural Material 1
1.2 Disadvantages of Steel as a Structural Material 3
1.3 Early Uses of Iron and Steel 4
1.4 Steel Sections 7
1.5 Metric Units 12
1.6 Cold-Formed Light-Gage Steel Shapes 12
1.7 Stress—Strain Relationships in Structural Steel 13
1.8 Modern Structural Steels 19
1.9 Uses of High-Strength Steels 22
1.10 Measurement of Toughness 24
1.11 Jumbo Sections 26
1.12 Lamellar Tearing 26
1.13 Furnishing of Structural Steel 27
1.14 The Work of the Structural Designer 30
1.15 Responsibilities of the Structural Designer 31
1.16 Economical Design of Steel Members 31
1.17 Failure of Structures 34
1.18 Handling and Shipping Structural Steel 37
1.19 Calculation Accuracy 37
1.20 Computers and Structural Steel Design 37
1.21 Problems for Solution 38

CHAPTER 2 Specifications, Loads, and Methods of Design 39
2.1 Specifications and Building Codes 39
2.2 Loads 41
2.3 Dead Loads 41
2.4 Live Loads 42
2.5 Environmental Loads 45
2.6 Load and Resistance Factor Design (LRFD) and Allowable Strength Design (ASD) 51
2.7 Nominal Strengths 52
2.8 Shading 52
2.9 Computation of Loads for LRFD and ASD 52
2.10 Computing Combined Loads with LRFD Expressions 53
2.11 Computing Combined Loads with ASD Expressions 57
2.12 Two Methods of Obtaining an Acceptable Level of Safety 58
2.13 Discussion of Sizes of Load Factors and Safety Factors 59
2.14 Author's Comment 60
2.15 Problems for Solution 60

CHAPTER 3 Analysis of Tension Members 62
3.1 Introduction 62
3.2 Nominal Strengths of Tension Members 65
3.3 Net Areas 67
3.4 Effect of Staggered Holes 69
3.5 Effective Net Areas 74
3.6 Connecting Elements for Tension Members 84
3.7 Block Shear 85
3.8 Problems for Solution 94

CHAPTER 4 Design of Tension Members 103
4.1 Selection of Sections 103
4.2 Built-Up Tension Members 111
4.3 Rods and Bars 115
4.4 Pin-Connected Members 120
4.5 Design for Fatigue Loads 122
4.6 Problems for Solution 125

CHAPTER 5 Introduction to Axially Loaded Compression Members 129
5.1 General 129
5.2 Residual Stresses 132
5.3 Sections Used for Columns 133
5.4 Development of Column Formulas 137
5.5 The Euler Formula 139
5.6 End Restraint and Effective Lengths of Columns 141
5.7 Stiffened and Unstiffened Elements 144
5.8 Long, Short, and Intermediate Columns 145
5.9 Column Formulas 148
5.10 Maximum Slenderness Ratios 150

CHAPTER 6 Design of Axially Loaded Compression Members 163
6.1 Introduction 163
6.2 AISC Design Tables 166
6.3 Column Splices 171
6.4 Built-Up Columns 174
6.5 Built-Up Columns with Components
in Contact with Each Other 175
6.6 Connection Requirements for Built-Up Columns Whose Components Are in Contact with Each Other 176
6.7 Built-Up Columns with Components not in Contact with Each Other 182
6.8 Single-Angle Compression Members 187
6.9 Sections Containing Slender Elements 189
6.10 Flexural-Torsional Buckling of Compression Members 191
6.11 Problems for Solution 196

CHAPTER 7 Design of Axially Loaded Compression Members (Continued) and Column Base Plates 200
7.1 Introduction 200
7.2 Further Discussion of Effective Lengths 201
7.3 Frames Meeting Alignment Chart Assumptions 205
7.4 Frames Not Meeting Alignment Chart Assumptions as to Joint Rotations 208
7.5 Stiffness-Reduction Factors 211
7.6 Columns Leaning on Each Other for In-Plane Design 215
7.7 Base Plates for Concentrically Loaded Columns 218
7.8 Problems for Solution 232

CHAPTER 8 Introduction to Beams 237
8.1 Types of Beams 237
8.2 Sections Used as Beams 237
8.3 Bending Stresses 238
8.4 Plastic Hinges 239
8.5 Elastic Design 240
8.6 The Plastic Mo