Gouqiang Li
Advanced Analysis and Design of Steel Frames
Gouqiang Li
Advanced Analysis and Design of Steel Frames
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The book begins with an introductory chapter to provide you with background knowledge of the different types of steel frames. The following chapter introduces the elastic stiffness equation for beam element, both general and special form is explained, before providing you with application examples of the equation.
Steel frames are used in many commercial high-rise buildings, as well as industrial structures, such as ore mines and oilrigs. Enabling construction of ever lighter and safer structures, steel frames have become an important topic for engineers.
This book, split into two parts…mehr
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The book begins with an introductory chapter to provide you with background knowledge of the different types of steel frames. The following chapter introduces the elastic stiffness equation for beam element, both general and special form is explained, before providing you with application examples of the equation.
Steel frames are used in many commercial high-rise buildings, as well as industrial structures, such as ore mines and oilrigs. Enabling construction of ever lighter and safer structures, steel frames have become an important topic for engineers.
This book, split into two parts covering advanced analysis and advanced design of steel frames, guides the reader from a broad array of frame elements through to advanced design methods such as deterministic, reliability, and system reliability design approaches. This book connects reliability evaluation of structural systems to advanced analysis of steel frames, and ensures that the steel frame design described is founded on system reliability.
Important features of the this book include:
_ fundamental equations governing the elastic and elasto-plastic equilibrium of beam, sheer-beam, column, joint-panel, and brace elements for steel frames;
_ analysis of elastic buckling, elasto-plastic capacity and earthquake-excited behaviour of steel frames;
_ background knowledge of more precise analysis and safer design of steel frames against gravity and wind, as well as key discussions on seismic analysis.
_ theoretical treatments, followed by numerous examples and applications;
_ a review of the evolution of structural design approaches, and reliability-based advanced analysis, followed by the methods and procedures for how to establish practical design formula.
Advanced Design and Analysis of Steel Frames provides students, researchers, and engineers with an integrated examination of this core civil and structural engineering topic. The logical treatment of both advanced analysis followed by advanced design makes this an invaluable reference tool, comprising of reviews, methods, procedures, examples, and applications of steel frames in one complete volume.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Steel frames are used in many commercial high-rise buildings, as well as industrial structures, such as ore mines and oilrigs. Enabling construction of ever lighter and safer structures, steel frames have become an important topic for engineers.
This book, split into two parts covering advanced analysis and advanced design of steel frames, guides the reader from a broad array of frame elements through to advanced design methods such as deterministic, reliability, and system reliability design approaches. This book connects reliability evaluation of structural systems to advanced analysis of steel frames, and ensures that the steel frame design described is founded on system reliability.
Important features of the this book include:
_ fundamental equations governing the elastic and elasto-plastic equilibrium of beam, sheer-beam, column, joint-panel, and brace elements for steel frames;
_ analysis of elastic buckling, elasto-plastic capacity and earthquake-excited behaviour of steel frames;
_ background knowledge of more precise analysis and safer design of steel frames against gravity and wind, as well as key discussions on seismic analysis.
_ theoretical treatments, followed by numerous examples and applications;
_ a review of the evolution of structural design approaches, and reliability-based advanced analysis, followed by the methods and procedures for how to establish practical design formula.
Advanced Design and Analysis of Steel Frames provides students, researchers, and engineers with an integrated examination of this core civil and structural engineering topic. The logical treatment of both advanced analysis followed by advanced design makes this an invaluable reference tool, comprising of reviews, methods, procedures, examples, and applications of steel frames in one complete volume.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 384
- Erscheinungstermin: 1. Juni 2007
- Englisch
- Abmessung: 250mm x 175mm x 25mm
- Gewicht: 875g
- ISBN-13: 9780470030615
- ISBN-10: 0470030615
- Artikelnr.: 22546694
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 384
- Erscheinungstermin: 1. Juni 2007
- Englisch
- Abmessung: 250mm x 175mm x 25mm
- Gewicht: 875g
- ISBN-13: 9780470030615
- ISBN-10: 0470030615
- Artikelnr.: 22546694
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
Professor Li received his PhD in Structural Engineering at Tongji University in 1988. That same year he started working at the University as a lecturer in Structural Engineering, and over the next six years he worked his way up to Associate Professor, and then Professor in 1994. His research interests lie mainly in the behavior and design of multi-storey steel buildings, the fire-resistance of steel structures and the dynamic identification of structures. He is an active member on the Editorial board of five International journals covering areas of research in steel and composite structures, structural engineering and materials, computational structural engineering, and advanced steel construction. He is the author of four books in Chinese, and over eighty research papers.
Preface xi
Symbols xiii
Part One Advanced Analysis of Steel Frames 1
Chapter 1 Introduction 3
1.1 Type of Steel Frames 3
1.2 Type of Components for Steel Frames 3
1.3 Type of Beam-Column Connections 7
1.4 Deformation of Joint Panel 7
1.5 Analysis Tasks and Method for Steel Frame Design 8
1.6 Definition of Elements in Steel Frames 9
Chapter 2 Elastic Stiffness Equation of Prismatic Beam Element 11
2.1 General Form of Equation 11
2.1.1 Beam Element in Tension 11
2.1.2 Beam Element in Compression 16
2.1.3 Series Expansion of Stiffness Equations 16
2.1.4 Beam Element with Initial Geometric Imperfection 17
2.2 Special Forms of Elemental Equations 19
2.2.1 Neglecting Effect of Shear Deformation 19
2.2.2 Neglecting Effect of Axial Force 21
2.2.3 Neglecting Effects of Shear Deformation and Axial Force 22
2.3 Examples 22
2.3.1 Bent Frame 22
2.3.2 Simply Supported Beam 24
Chapter 3 Elastic Stiffness Equation of Tapered Beam Element 25
3.1 Tapered Beam Element 25
3.1.1 Differential Equilibrium Equation 25
3.1.2 Stiffness Equation 27
3.2 Numerical Verification 29
3.2.1 Symmetry of Stiffness Matrix 29
3.2.2 Static Deflection 30
3.2.3 Elastic Critical Load 30
3.2.4 Frequency of Free Vibration 30
3.2.5 Effect of Term Number Truncated in Polynomial Series 31
3.2.6 Steel Portal Frame 31
3.3 Appendix 33
3.3.1 Chebyshev Polynomial Approach (Rice, 1992) 33
3.3.2 Expression of Elements in Equation (3.23) 34
Chapter 4 Elastic Stiffness Equation of Composite Beam Element 35
4.1 Characteristics and Classification of Composite Beam 35
4.2 Effects of Composite Action on Elastic Stiffness of Composite Beam 37
4.2.1 Beam without Composite Action 37
4.2.2 Beam with Full Composite Action 38
4.2.3 Beam with Partial Composite Action 39
4.3 Elastic Stiffness Equation of Steel-Concrete Composite Beam Element 40
4.3.1 Basic Assumptions 40
4.3.2 Differential Equilibrium Equation of Partially Composite Beam 41
4.3.3 Stiffness Equation of Composite Beam Element 42
4.3.4 Equivalent Nodal Load Vector 46
4.4 Example 49
4.5 Problems in Present Work 51
Chapter 5 Sectional Yielding and Hysteretic Model of Steel Beam Columns 53
5.1 Yielding of Beam Section Subjected to Uniaxial Bending 53
5.2 Yielding of Column Section Subjected to Uniaxial Bending 53
5.3 Yielding of Column Section Subjected to Biaxial Bending 56
5.3.1 Equation of Initial Yielding Surface 56
5.3.2 Equation of Ultimate Yielding Surface 56
5.3.3 Approximate Expression of Ultimate Yielding Surface 61
5.3.4 Effects of Torsion Moment 62
5.4 Hysteretic Model 64
5.4.1 Cyclic Loading and Hysteretic Behaviour 64
5.4.2 Hysteretic Model of Beam Section 65
5.4.3 Hysteretic Model of Column Section Subjected to Uniaxial Bending 67
5.4.4 Hysteretic Model of Column Section Subjected to Biaxial Bending 67
5.5 Determination of Loading and Deformation States of Beam-Column Sections
68
Chapter 6 Hysteretic Behaviour of Composite Beams 71
6.1 Hysteretic Model of Steel and Concrete Material Under Cyclic Loading 71
6.1.1 Hysteretic Model of Steel Stress-Strain Relationship 71
6.1.2 Hysteretic Model of Concrete Stress-Strain Relationship 71
6.2 Numerical Method for Moment-Curvature Hysteretic Curves 75
6.2.1 Assumptions 75
6.2.2 Sectional Division 75
6.2.3 Calculation Procedure of Moment-Curvature Relationship 76
6.3 Hysteretic Characteristics of Moment-Curvature Relationships 77
6.3.1 Characteristics of Hysteretic Curves 77
6.3.2 Typical Phases 78
6.4 Parametric Studies 79
6.4.1 Height of Concrete Flange hc 79
6.4.2 Width of Concrete Flange Bc 79
6.4.3 Height of Steel Beam hs 80
6.4.4 Strength Ratio g 83
6.4.5 Yielding Strength of Steel fy 84
6.4.6 Compressive Strength of Concrete fck 84
6.4.7 Summary of Parametric Studies 85
6.5 Simplified Hysteretic Model 86
6.5.1 Skeletal Curve 86
6.5.2 Hysteresis Model 89
Chapter 7 Elasto-Plastic Stiffness Equation of Beam Element 93
7.1 Plastic Hinge Theory 93
7.1.1 Hinge Formed at One End of Element 94
7.1.2 Hinge Formed at Both Ends of Element 97
7.2 Clough Model 97
7.3 Generalized Clough Model 98
7.4 Elasto-Plastic Hinge Model 99
7.4.1 Both Ends Yielding 102
7.4.2 Only End 1 Yielding 103
7.4.3 Only End 2 Yielding 103
7.4.4 Summary 104
7.5 Comparison Between Elasto-Plastic Hinge Model and Generalized Clough
Model 104
7.5.1 Only End 1 Yielding 104
7.5.2 Both Ends Yielding 105
7.5.3 Numerical Example 106
7.6 Effects of Residual Stresses and Treatment of Tapered Element 107
7.6.1 Effects of Residual Stresses on Plasticity Spread Along Element
Section 107
7.6.2 Effects of Residual Stresses on Plasticity Spread Along Element
Length 109
7.6.3 Treatment of Tapered Element 110
7.7 Beam Element with Plastic Hinge Between Two Ends 110
7.8 Subdivided Model with Variable Stiffness for Composite Beam Element 113
7.8.1 Subdivided Model 113
7.8.2 Stiffness Equation of Composite Beam Element 114
7.9 Examples 117
7.9.1 A Steel Portal Frame with Prismatic Members 117
7.9.2 A Steel Portal Frame with Tapered Members 118
7.9.3 Vogel Portal Frame 119
7.9.4 Vogel Six-Storey Frame 120
7.9.5 A Single-Storey Frame with Mid-Span Concentrated Load 121
7.9.6 A Single-Storey Frame with Distributed Load 123
7.9.7 A Four-Storey Frame with Mid-Span Concentrated Load 124
7.9.8 A Two-Span Three-Storey Composite Frame 126
Chapter 8 Elastic and Elasto-Plastic Stiffness Equations of Column Element
127
8.1 Force and Deformation of Column Element 127
8.2 Elastic Stiffness Equation of Column Element Subjected to Biaxial
Bending 127
8.3 Elasto-Plastic Stiffness Equations of Column Element Subjected to
Biaxial Bending 129
8.3.1 Both Ends Yielding 131
8.3.2 Only End 1 Yielding 132
8.3.3 Only End 2 Yielding 133
8.3.4 Summary 133
8.4 Elastic and Elasto-Plastic Stiffness Equations of Column Element
Subjected to Uniaxial Bending 134
8.5 Axial Stiffness of Tapered Column Element 135
8.5.1 Elastic Stiffness 135
8.5.2 Elasto-Plastic Stiffness 135
8.6 Experiment Verification 136
8.6.1 Experiment Specimen 136
8.6.2 Set-Up and Instrumentation 139
8.6.3 Horizontal Loading Scheme 140
8.6.4 Theoretical Predictions of Experiments 141
8.6.5 Comparison of Analytical and Tested Results 144
Chapter 9 Effects of Joint Panel and Beam-Column Connection 147
9.1 Behaviour of Joint Panel 147
9.1.1 Elastic Stiffness of Joint Panel 147
9.1.2 Elasto-Plastic Stiffness of Joint Panel 149
9.2 Effect of Shear Deformation of Joint Panel on Beam/Column Stiffness 150
9.2.1 Stiffness Equation of Beam Element with Joint Panel 150
9.2.2 Stiffness Equation of Column Element with Joint Panel Subjected to
Uniaxial Bending 153
9.2.3 Stiffness Equation of Column Element with Joint Panel Subjected to
Biaxial Bending 154
9.3 Behaviour of Beam-Column Connections 155
9.3.1 Moment-Rotation Relationship 156
9.3.2 Hysteretic Behaviour 161
9.4 Effect of Deformation of Beam-Column Connection on Beam Stiffness 163
9.4.1 Stiffness Equation of Beam Element with Beam-Column Connections 164
9.4.2 Stiffness Equation of Beam Element with Connections and Joint Panels
166
9.5 Examples 166
9.5.1 Effect of Joint Panel 166
9.5.2 Effect of Beam-Column Connection 170
Chapter 10 Brace Element and its Elastic and Elasto-Plastic Stiffness
Equations 175
10.1 Hysteretic Behaviour of Braces 175
10.2 Theoretical Analysis of Elastic and Elasto-Plastic Stiffnesses of
Brace Element 175
10.3 Hysteretic Model of Ordinary Braces 181
10.4 Hysteretic Characteristics and Model of Buckling-Restrained Brace 183
10.5 Stiffness Equation of Brace Element 185
Chapter 11 Shear Beam and its Elastic and Elasto-Plastic Stiffness
Equations 187
11.1 Eccentrically Braced Frame and Shear Beam 187
11.1.1 Eccentrically Braced Frame 187
11.1.2 Condition of Shear Beam 187
11.2 Hysteretic Model of Shear Beam 189
11.3 Stiffness Equation of Shear Beam 190
Chapter 12 Elastic Stability Analysis of Planar Steel Frames 193
12.1 General Analytical Method 193
12.2 Effective Length of Prismatic Frame Column 194
12.2.1 Concept of Effective Length 194
12.2.2 Assumption and Analytical Model 195
12.2.3 Formulations of Effective Length 197
12.2.4 Simplified Formula of Effective Length 202
12.2.5 Modification of Effective Length 203
12.2.6 Effect of Shear Deformation on Effective Length of Column 205
12.2.7 Examples 205
12.3 Effective Length of Tapered Steel Columns 211
12.3.1 Tapered Columns Under Different Boundary Conditions 211
12.3.2 Tapered Column in Steel Portal Frame 213
Chapter 13 Nonlinear Analysis of Planar Steel Frames 219
13.1 General Analysis Method 219
13.1.1 Loading Types 219
13.1.2 Criteria for the Limit State of Ultimate Load-Carrying Capacity 220
13.1.3 Analysis Procedure 221
13.1.4 Basic Elements and Unknown Variables 222
13.1.5 Structural Analysis of the First Loading Type 222
13.1.6 Structural Analysis of the Second Loading Type 223
13.1.7 Numerical Examples 223
13.2 Approximate Analysis Considering P_D Effect 226
13.2.1 Formulation 226
13.2.2 Example 227
13.3 Simplified Analysis Model Considering P_D Effect 228
13.3.1 Development of Simplified Model 228
13.3.2 Example 231
Chapter 14 Seismic Response Analysis of Planar Steel Frames 233
14.1 General Analysis Method 233
14.1.1 Kinetic Differential Equation 233
14.1.2 Solution of Kinetic Differential Equation 235
14.1.3 Determination of Mass, Stiffness and Damping Matrices 238
14.1.4 Numerical Example 240
14.2 Half-Frame Model 241
14.2.1 Assumption and Principle of Half-Frame 241
14.2.2 Stiffness Equation of Beam Element in Half-Frame 244
14.2.3 Numerical Examples 244
14.3 Shear-Bending Storey Model 248
14.3.1 Equivalent Stiffness 248
14.3.2 Inter-Storey Shear Yielding Parameters 251
14.3.3 Examples 252
14.4 Simplified Model for Braced Frame 255
14.4.1 Decomposition and Simplification of Braced Frame 255
14.4.2 Stiffness Matrix of Pure Frame 256
14.4.3 Stiffness Matrix of Pure Bracing System 257
14.4.4 Example 258
Chapter 15 Analysis Model for Space Steel Frames 259
15.1 Space Bar Model 259
15.1.1 Transformation from Local to Global Coordinates 259
15.1.2 Requirement of Rigid Floor 264
15.1.3 Global Stiffness Equation of Frame and Static Condensation 267
15.2 Planar Substructure Model 268
15.2.1 Stiffness Equation of Planar Substructure in Global Coordinates 268
15.2.2 Global Stiffness Equation of Spatial Frame 271
15.2.3 Numerical Example 272
15.3 Component Mode Synthesis Method 274
15.3.1 Principle of Component Mode Synthesis Method 274
15.3.2 Analysis of Generalized Elements 276
15.3.3 Stiffness Equation of Generalized Structure 281
15.3.4 Structural Analysis Procedure 282
15.3.5 Numerical Example 283
Part Two Advanced Design of Steel Frames 287
Chapter 16 Development of Structural Design Approach 289
16.1 Deterministic Design Approach 289
16.1.1 Allowable Stress Design (ASD) (AISC, 1989) 289
16.1.2 Plastic Design (PD) (AISC, 1978) 290
16.2 Reliability Design Approach Based on Limit States of Structural
Members 290
16.3 Structural System Reliability Design Approach 292
Chapter 17 Structural System Reliability Calculation 293
17.1 Fundamentals of Structural Reliability Theory 293
17.1.1 Performance Requirements of Structures 293
17.1.2 Performance Function of Structures 293
17.1.3 Limit State of Structures 294
17.1.4 Structural Reliability 294
17.1.5 Reliability Index 296
17.2 The First-Order Second-Moment (FOSM) Methods for Structural
Reliability Assessment 297
17.2.1 Central Point Method 298
17.2.2 Design Point Method 299
17.3 Effects of Correlation Among Random Variables 302
17.4 Structural System Reliability and Boundary Theory 302
17.4.1 Basic Concepts 302
17.4.2 Upper-Lower Boundary Method 305
17.5 Semi-Analytical Simulation Method for System Reliability 306
17.5.1 General Principle 306
17.5.2 Random Sampling 307
17.5.3 Exponential Polynomial Method (EPM) 309
17.6 Example 309
17.6.1 A Steel Beam Section 309
17.6.2 A Steel Portal Frame 313
Chapter 18 System Reliability Assessment of Steel Frames 317
18.1 Randomness of Steel Frame Resistance 317
18.2 Randomness of Loads 318
18.3 System Reliability Evaluation of Typical Steel Frames 319
18.3.1 Effect of Correlation Among Random Variables 319
18.3.2 Evaluation of Structural System Reliability Under Vertical Loads 320
18.3.3 Evaluation of Structural System Reliability Under Horizontal and
Vertical Loads 323
18.4 Comparison of System Reliability Evaluation 325
Chapter 19 Reliability-Based Advanced Design of Steel Frames 327
19.1 Structural Design Based on System Reliability 327
19.1.1 Target Reliability of Design 327
19.1.2 Load and Load Combination 329
19.1.3 Practical Design Formula 329
19.2 Effect of Correlation on Load and Resistance Factors 335
19.3 Comparison of Different Design Methods 337
19.3.1 For Steel Portal Frames 337
19.3.2 For Multi-Storey Steel Frames 340
References/Bibliography 345
Author Index 363
Subject Index 365
Symbols xiii
Part One Advanced Analysis of Steel Frames 1
Chapter 1 Introduction 3
1.1 Type of Steel Frames 3
1.2 Type of Components for Steel Frames 3
1.3 Type of Beam-Column Connections 7
1.4 Deformation of Joint Panel 7
1.5 Analysis Tasks and Method for Steel Frame Design 8
1.6 Definition of Elements in Steel Frames 9
Chapter 2 Elastic Stiffness Equation of Prismatic Beam Element 11
2.1 General Form of Equation 11
2.1.1 Beam Element in Tension 11
2.1.2 Beam Element in Compression 16
2.1.3 Series Expansion of Stiffness Equations 16
2.1.4 Beam Element with Initial Geometric Imperfection 17
2.2 Special Forms of Elemental Equations 19
2.2.1 Neglecting Effect of Shear Deformation 19
2.2.2 Neglecting Effect of Axial Force 21
2.2.3 Neglecting Effects of Shear Deformation and Axial Force 22
2.3 Examples 22
2.3.1 Bent Frame 22
2.3.2 Simply Supported Beam 24
Chapter 3 Elastic Stiffness Equation of Tapered Beam Element 25
3.1 Tapered Beam Element 25
3.1.1 Differential Equilibrium Equation 25
3.1.2 Stiffness Equation 27
3.2 Numerical Verification 29
3.2.1 Symmetry of Stiffness Matrix 29
3.2.2 Static Deflection 30
3.2.3 Elastic Critical Load 30
3.2.4 Frequency of Free Vibration 30
3.2.5 Effect of Term Number Truncated in Polynomial Series 31
3.2.6 Steel Portal Frame 31
3.3 Appendix 33
3.3.1 Chebyshev Polynomial Approach (Rice, 1992) 33
3.3.2 Expression of Elements in Equation (3.23) 34
Chapter 4 Elastic Stiffness Equation of Composite Beam Element 35
4.1 Characteristics and Classification of Composite Beam 35
4.2 Effects of Composite Action on Elastic Stiffness of Composite Beam 37
4.2.1 Beam without Composite Action 37
4.2.2 Beam with Full Composite Action 38
4.2.3 Beam with Partial Composite Action 39
4.3 Elastic Stiffness Equation of Steel-Concrete Composite Beam Element 40
4.3.1 Basic Assumptions 40
4.3.2 Differential Equilibrium Equation of Partially Composite Beam 41
4.3.3 Stiffness Equation of Composite Beam Element 42
4.3.4 Equivalent Nodal Load Vector 46
4.4 Example 49
4.5 Problems in Present Work 51
Chapter 5 Sectional Yielding and Hysteretic Model of Steel Beam Columns 53
5.1 Yielding of Beam Section Subjected to Uniaxial Bending 53
5.2 Yielding of Column Section Subjected to Uniaxial Bending 53
5.3 Yielding of Column Section Subjected to Biaxial Bending 56
5.3.1 Equation of Initial Yielding Surface 56
5.3.2 Equation of Ultimate Yielding Surface 56
5.3.3 Approximate Expression of Ultimate Yielding Surface 61
5.3.4 Effects of Torsion Moment 62
5.4 Hysteretic Model 64
5.4.1 Cyclic Loading and Hysteretic Behaviour 64
5.4.2 Hysteretic Model of Beam Section 65
5.4.3 Hysteretic Model of Column Section Subjected to Uniaxial Bending 67
5.4.4 Hysteretic Model of Column Section Subjected to Biaxial Bending 67
5.5 Determination of Loading and Deformation States of Beam-Column Sections
68
Chapter 6 Hysteretic Behaviour of Composite Beams 71
6.1 Hysteretic Model of Steel and Concrete Material Under Cyclic Loading 71
6.1.1 Hysteretic Model of Steel Stress-Strain Relationship 71
6.1.2 Hysteretic Model of Concrete Stress-Strain Relationship 71
6.2 Numerical Method for Moment-Curvature Hysteretic Curves 75
6.2.1 Assumptions 75
6.2.2 Sectional Division 75
6.2.3 Calculation Procedure of Moment-Curvature Relationship 76
6.3 Hysteretic Characteristics of Moment-Curvature Relationships 77
6.3.1 Characteristics of Hysteretic Curves 77
6.3.2 Typical Phases 78
6.4 Parametric Studies 79
6.4.1 Height of Concrete Flange hc 79
6.4.2 Width of Concrete Flange Bc 79
6.4.3 Height of Steel Beam hs 80
6.4.4 Strength Ratio g 83
6.4.5 Yielding Strength of Steel fy 84
6.4.6 Compressive Strength of Concrete fck 84
6.4.7 Summary of Parametric Studies 85
6.5 Simplified Hysteretic Model 86
6.5.1 Skeletal Curve 86
6.5.2 Hysteresis Model 89
Chapter 7 Elasto-Plastic Stiffness Equation of Beam Element 93
7.1 Plastic Hinge Theory 93
7.1.1 Hinge Formed at One End of Element 94
7.1.2 Hinge Formed at Both Ends of Element 97
7.2 Clough Model 97
7.3 Generalized Clough Model 98
7.4 Elasto-Plastic Hinge Model 99
7.4.1 Both Ends Yielding 102
7.4.2 Only End 1 Yielding 103
7.4.3 Only End 2 Yielding 103
7.4.4 Summary 104
7.5 Comparison Between Elasto-Plastic Hinge Model and Generalized Clough
Model 104
7.5.1 Only End 1 Yielding 104
7.5.2 Both Ends Yielding 105
7.5.3 Numerical Example 106
7.6 Effects of Residual Stresses and Treatment of Tapered Element 107
7.6.1 Effects of Residual Stresses on Plasticity Spread Along Element
Section 107
7.6.2 Effects of Residual Stresses on Plasticity Spread Along Element
Length 109
7.6.3 Treatment of Tapered Element 110
7.7 Beam Element with Plastic Hinge Between Two Ends 110
7.8 Subdivided Model with Variable Stiffness for Composite Beam Element 113
7.8.1 Subdivided Model 113
7.8.2 Stiffness Equation of Composite Beam Element 114
7.9 Examples 117
7.9.1 A Steel Portal Frame with Prismatic Members 117
7.9.2 A Steel Portal Frame with Tapered Members 118
7.9.3 Vogel Portal Frame 119
7.9.4 Vogel Six-Storey Frame 120
7.9.5 A Single-Storey Frame with Mid-Span Concentrated Load 121
7.9.6 A Single-Storey Frame with Distributed Load 123
7.9.7 A Four-Storey Frame with Mid-Span Concentrated Load 124
7.9.8 A Two-Span Three-Storey Composite Frame 126
Chapter 8 Elastic and Elasto-Plastic Stiffness Equations of Column Element
127
8.1 Force and Deformation of Column Element 127
8.2 Elastic Stiffness Equation of Column Element Subjected to Biaxial
Bending 127
8.3 Elasto-Plastic Stiffness Equations of Column Element Subjected to
Biaxial Bending 129
8.3.1 Both Ends Yielding 131
8.3.2 Only End 1 Yielding 132
8.3.3 Only End 2 Yielding 133
8.3.4 Summary 133
8.4 Elastic and Elasto-Plastic Stiffness Equations of Column Element
Subjected to Uniaxial Bending 134
8.5 Axial Stiffness of Tapered Column Element 135
8.5.1 Elastic Stiffness 135
8.5.2 Elasto-Plastic Stiffness 135
8.6 Experiment Verification 136
8.6.1 Experiment Specimen 136
8.6.2 Set-Up and Instrumentation 139
8.6.3 Horizontal Loading Scheme 140
8.6.4 Theoretical Predictions of Experiments 141
8.6.5 Comparison of Analytical and Tested Results 144
Chapter 9 Effects of Joint Panel and Beam-Column Connection 147
9.1 Behaviour of Joint Panel 147
9.1.1 Elastic Stiffness of Joint Panel 147
9.1.2 Elasto-Plastic Stiffness of Joint Panel 149
9.2 Effect of Shear Deformation of Joint Panel on Beam/Column Stiffness 150
9.2.1 Stiffness Equation of Beam Element with Joint Panel 150
9.2.2 Stiffness Equation of Column Element with Joint Panel Subjected to
Uniaxial Bending 153
9.2.3 Stiffness Equation of Column Element with Joint Panel Subjected to
Biaxial Bending 154
9.3 Behaviour of Beam-Column Connections 155
9.3.1 Moment-Rotation Relationship 156
9.3.2 Hysteretic Behaviour 161
9.4 Effect of Deformation of Beam-Column Connection on Beam Stiffness 163
9.4.1 Stiffness Equation of Beam Element with Beam-Column Connections 164
9.4.2 Stiffness Equation of Beam Element with Connections and Joint Panels
166
9.5 Examples 166
9.5.1 Effect of Joint Panel 166
9.5.2 Effect of Beam-Column Connection 170
Chapter 10 Brace Element and its Elastic and Elasto-Plastic Stiffness
Equations 175
10.1 Hysteretic Behaviour of Braces 175
10.2 Theoretical Analysis of Elastic and Elasto-Plastic Stiffnesses of
Brace Element 175
10.3 Hysteretic Model of Ordinary Braces 181
10.4 Hysteretic Characteristics and Model of Buckling-Restrained Brace 183
10.5 Stiffness Equation of Brace Element 185
Chapter 11 Shear Beam and its Elastic and Elasto-Plastic Stiffness
Equations 187
11.1 Eccentrically Braced Frame and Shear Beam 187
11.1.1 Eccentrically Braced Frame 187
11.1.2 Condition of Shear Beam 187
11.2 Hysteretic Model of Shear Beam 189
11.3 Stiffness Equation of Shear Beam 190
Chapter 12 Elastic Stability Analysis of Planar Steel Frames 193
12.1 General Analytical Method 193
12.2 Effective Length of Prismatic Frame Column 194
12.2.1 Concept of Effective Length 194
12.2.2 Assumption and Analytical Model 195
12.2.3 Formulations of Effective Length 197
12.2.4 Simplified Formula of Effective Length 202
12.2.5 Modification of Effective Length 203
12.2.6 Effect of Shear Deformation on Effective Length of Column 205
12.2.7 Examples 205
12.3 Effective Length of Tapered Steel Columns 211
12.3.1 Tapered Columns Under Different Boundary Conditions 211
12.3.2 Tapered Column in Steel Portal Frame 213
Chapter 13 Nonlinear Analysis of Planar Steel Frames 219
13.1 General Analysis Method 219
13.1.1 Loading Types 219
13.1.2 Criteria for the Limit State of Ultimate Load-Carrying Capacity 220
13.1.3 Analysis Procedure 221
13.1.4 Basic Elements and Unknown Variables 222
13.1.5 Structural Analysis of the First Loading Type 222
13.1.6 Structural Analysis of the Second Loading Type 223
13.1.7 Numerical Examples 223
13.2 Approximate Analysis Considering P_D Effect 226
13.2.1 Formulation 226
13.2.2 Example 227
13.3 Simplified Analysis Model Considering P_D Effect 228
13.3.1 Development of Simplified Model 228
13.3.2 Example 231
Chapter 14 Seismic Response Analysis of Planar Steel Frames 233
14.1 General Analysis Method 233
14.1.1 Kinetic Differential Equation 233
14.1.2 Solution of Kinetic Differential Equation 235
14.1.3 Determination of Mass, Stiffness and Damping Matrices 238
14.1.4 Numerical Example 240
14.2 Half-Frame Model 241
14.2.1 Assumption and Principle of Half-Frame 241
14.2.2 Stiffness Equation of Beam Element in Half-Frame 244
14.2.3 Numerical Examples 244
14.3 Shear-Bending Storey Model 248
14.3.1 Equivalent Stiffness 248
14.3.2 Inter-Storey Shear Yielding Parameters 251
14.3.3 Examples 252
14.4 Simplified Model for Braced Frame 255
14.4.1 Decomposition and Simplification of Braced Frame 255
14.4.2 Stiffness Matrix of Pure Frame 256
14.4.3 Stiffness Matrix of Pure Bracing System 257
14.4.4 Example 258
Chapter 15 Analysis Model for Space Steel Frames 259
15.1 Space Bar Model 259
15.1.1 Transformation from Local to Global Coordinates 259
15.1.2 Requirement of Rigid Floor 264
15.1.3 Global Stiffness Equation of Frame and Static Condensation 267
15.2 Planar Substructure Model 268
15.2.1 Stiffness Equation of Planar Substructure in Global Coordinates 268
15.2.2 Global Stiffness Equation of Spatial Frame 271
15.2.3 Numerical Example 272
15.3 Component Mode Synthesis Method 274
15.3.1 Principle of Component Mode Synthesis Method 274
15.3.2 Analysis of Generalized Elements 276
15.3.3 Stiffness Equation of Generalized Structure 281
15.3.4 Structural Analysis Procedure 282
15.3.5 Numerical Example 283
Part Two Advanced Design of Steel Frames 287
Chapter 16 Development of Structural Design Approach 289
16.1 Deterministic Design Approach 289
16.1.1 Allowable Stress Design (ASD) (AISC, 1989) 289
16.1.2 Plastic Design (PD) (AISC, 1978) 290
16.2 Reliability Design Approach Based on Limit States of Structural
Members 290
16.3 Structural System Reliability Design Approach 292
Chapter 17 Structural System Reliability Calculation 293
17.1 Fundamentals of Structural Reliability Theory 293
17.1.1 Performance Requirements of Structures 293
17.1.2 Performance Function of Structures 293
17.1.3 Limit State of Structures 294
17.1.4 Structural Reliability 294
17.1.5 Reliability Index 296
17.2 The First-Order Second-Moment (FOSM) Methods for Structural
Reliability Assessment 297
17.2.1 Central Point Method 298
17.2.2 Design Point Method 299
17.3 Effects of Correlation Among Random Variables 302
17.4 Structural System Reliability and Boundary Theory 302
17.4.1 Basic Concepts 302
17.4.2 Upper-Lower Boundary Method 305
17.5 Semi-Analytical Simulation Method for System Reliability 306
17.5.1 General Principle 306
17.5.2 Random Sampling 307
17.5.3 Exponential Polynomial Method (EPM) 309
17.6 Example 309
17.6.1 A Steel Beam Section 309
17.6.2 A Steel Portal Frame 313
Chapter 18 System Reliability Assessment of Steel Frames 317
18.1 Randomness of Steel Frame Resistance 317
18.2 Randomness of Loads 318
18.3 System Reliability Evaluation of Typical Steel Frames 319
18.3.1 Effect of Correlation Among Random Variables 319
18.3.2 Evaluation of Structural System Reliability Under Vertical Loads 320
18.3.3 Evaluation of Structural System Reliability Under Horizontal and
Vertical Loads 323
18.4 Comparison of System Reliability Evaluation 325
Chapter 19 Reliability-Based Advanced Design of Steel Frames 327
19.1 Structural Design Based on System Reliability 327
19.1.1 Target Reliability of Design 327
19.1.2 Load and Load Combination 329
19.1.3 Practical Design Formula 329
19.2 Effect of Correlation on Load and Resistance Factors 335
19.3 Comparison of Different Design Methods 337
19.3.1 For Steel Portal Frames 337
19.3.2 For Multi-Storey Steel Frames 340
References/Bibliography 345
Author Index 363
Subject Index 365
Preface xi
Symbols xiii
Part One Advanced Analysis of Steel Frames 1
Chapter 1 Introduction 3
1.1 Type of Steel Frames 3
1.2 Type of Components for Steel Frames 3
1.3 Type of Beam-Column Connections 7
1.4 Deformation of Joint Panel 7
1.5 Analysis Tasks and Method for Steel Frame Design 8
1.6 Definition of Elements in Steel Frames 9
Chapter 2 Elastic Stiffness Equation of Prismatic Beam Element 11
2.1 General Form of Equation 11
2.1.1 Beam Element in Tension 11
2.1.2 Beam Element in Compression 16
2.1.3 Series Expansion of Stiffness Equations 16
2.1.4 Beam Element with Initial Geometric Imperfection 17
2.2 Special Forms of Elemental Equations 19
2.2.1 Neglecting Effect of Shear Deformation 19
2.2.2 Neglecting Effect of Axial Force 21
2.2.3 Neglecting Effects of Shear Deformation and Axial Force 22
2.3 Examples 22
2.3.1 Bent Frame 22
2.3.2 Simply Supported Beam 24
Chapter 3 Elastic Stiffness Equation of Tapered Beam Element 25
3.1 Tapered Beam Element 25
3.1.1 Differential Equilibrium Equation 25
3.1.2 Stiffness Equation 27
3.2 Numerical Verification 29
3.2.1 Symmetry of Stiffness Matrix 29
3.2.2 Static Deflection 30
3.2.3 Elastic Critical Load 30
3.2.4 Frequency of Free Vibration 30
3.2.5 Effect of Term Number Truncated in Polynomial Series 31
3.2.6 Steel Portal Frame 31
3.3 Appendix 33
3.3.1 Chebyshev Polynomial Approach (Rice, 1992) 33
3.3.2 Expression of Elements in Equation (3.23) 34
Chapter 4 Elastic Stiffness Equation of Composite Beam Element 35
4.1 Characteristics and Classification of Composite Beam 35
4.2 Effects of Composite Action on Elastic Stiffness of Composite Beam 37
4.2.1 Beam without Composite Action 37
4.2.2 Beam with Full Composite Action 38
4.2.3 Beam with Partial Composite Action 39
4.3 Elastic Stiffness Equation of Steel-Concrete Composite Beam Element 40
4.3.1 Basic Assumptions 40
4.3.2 Differential Equilibrium Equation of Partially Composite Beam 41
4.3.3 Stiffness Equation of Composite Beam Element 42
4.3.4 Equivalent Nodal Load Vector 46
4.4 Example 49
4.5 Problems in Present Work 51
Chapter 5 Sectional Yielding and Hysteretic Model of Steel Beam Columns 53
5.1 Yielding of Beam Section Subjected to Uniaxial Bending 53
5.2 Yielding of Column Section Subjected to Uniaxial Bending 53
5.3 Yielding of Column Section Subjected to Biaxial Bending 56
5.3.1 Equation of Initial Yielding Surface 56
5.3.2 Equation of Ultimate Yielding Surface 56
5.3.3 Approximate Expression of Ultimate Yielding Surface 61
5.3.4 Effects of Torsion Moment 62
5.4 Hysteretic Model 64
5.4.1 Cyclic Loading and Hysteretic Behaviour 64
5.4.2 Hysteretic Model of Beam Section 65
5.4.3 Hysteretic Model of Column Section Subjected to Uniaxial Bending 67
5.4.4 Hysteretic Model of Column Section Subjected to Biaxial Bending 67
5.5 Determination of Loading and Deformation States of Beam-Column Sections
68
Chapter 6 Hysteretic Behaviour of Composite Beams 71
6.1 Hysteretic Model of Steel and Concrete Material Under Cyclic Loading 71
6.1.1 Hysteretic Model of Steel Stress-Strain Relationship 71
6.1.2 Hysteretic Model of Concrete Stress-Strain Relationship 71
6.2 Numerical Method for Moment-Curvature Hysteretic Curves 75
6.2.1 Assumptions 75
6.2.2 Sectional Division 75
6.2.3 Calculation Procedure of Moment-Curvature Relationship 76
6.3 Hysteretic Characteristics of Moment-Curvature Relationships 77
6.3.1 Characteristics of Hysteretic Curves 77
6.3.2 Typical Phases 78
6.4 Parametric Studies 79
6.4.1 Height of Concrete Flange hc 79
6.4.2 Width of Concrete Flange Bc 79
6.4.3 Height of Steel Beam hs 80
6.4.4 Strength Ratio g 83
6.4.5 Yielding Strength of Steel fy 84
6.4.6 Compressive Strength of Concrete fck 84
6.4.7 Summary of Parametric Studies 85
6.5 Simplified Hysteretic Model 86
6.5.1 Skeletal Curve 86
6.5.2 Hysteresis Model 89
Chapter 7 Elasto-Plastic Stiffness Equation of Beam Element 93
7.1 Plastic Hinge Theory 93
7.1.1 Hinge Formed at One End of Element 94
7.1.2 Hinge Formed at Both Ends of Element 97
7.2 Clough Model 97
7.3 Generalized Clough Model 98
7.4 Elasto-Plastic Hinge Model 99
7.4.1 Both Ends Yielding 102
7.4.2 Only End 1 Yielding 103
7.4.3 Only End 2 Yielding 103
7.4.4 Summary 104
7.5 Comparison Between Elasto-Plastic Hinge Model and Generalized Clough
Model 104
7.5.1 Only End 1 Yielding 104
7.5.2 Both Ends Yielding 105
7.5.3 Numerical Example 106
7.6 Effects of Residual Stresses and Treatment of Tapered Element 107
7.6.1 Effects of Residual Stresses on Plasticity Spread Along Element
Section 107
7.6.2 Effects of Residual Stresses on Plasticity Spread Along Element
Length 109
7.6.3 Treatment of Tapered Element 110
7.7 Beam Element with Plastic Hinge Between Two Ends 110
7.8 Subdivided Model with Variable Stiffness for Composite Beam Element 113
7.8.1 Subdivided Model 113
7.8.2 Stiffness Equation of Composite Beam Element 114
7.9 Examples 117
7.9.1 A Steel Portal Frame with Prismatic Members 117
7.9.2 A Steel Portal Frame with Tapered Members 118
7.9.3 Vogel Portal Frame 119
7.9.4 Vogel Six-Storey Frame 120
7.9.5 A Single-Storey Frame with Mid-Span Concentrated Load 121
7.9.6 A Single-Storey Frame with Distributed Load 123
7.9.7 A Four-Storey Frame with Mid-Span Concentrated Load 124
7.9.8 A Two-Span Three-Storey Composite Frame 126
Chapter 8 Elastic and Elasto-Plastic Stiffness Equations of Column Element
127
8.1 Force and Deformation of Column Element 127
8.2 Elastic Stiffness Equation of Column Element Subjected to Biaxial
Bending 127
8.3 Elasto-Plastic Stiffness Equations of Column Element Subjected to
Biaxial Bending 129
8.3.1 Both Ends Yielding 131
8.3.2 Only End 1 Yielding 132
8.3.3 Only End 2 Yielding 133
8.3.4 Summary 133
8.4 Elastic and Elasto-Plastic Stiffness Equations of Column Element
Subjected to Uniaxial Bending 134
8.5 Axial Stiffness of Tapered Column Element 135
8.5.1 Elastic Stiffness 135
8.5.2 Elasto-Plastic Stiffness 135
8.6 Experiment Verification 136
8.6.1 Experiment Specimen 136
8.6.2 Set-Up and Instrumentation 139
8.6.3 Horizontal Loading Scheme 140
8.6.4 Theoretical Predictions of Experiments 141
8.6.5 Comparison of Analytical and Tested Results 144
Chapter 9 Effects of Joint Panel and Beam-Column Connection 147
9.1 Behaviour of Joint Panel 147
9.1.1 Elastic Stiffness of Joint Panel 147
9.1.2 Elasto-Plastic Stiffness of Joint Panel 149
9.2 Effect of Shear Deformation of Joint Panel on Beam/Column Stiffness 150
9.2.1 Stiffness Equation of Beam Element with Joint Panel 150
9.2.2 Stiffness Equation of Column Element with Joint Panel Subjected to
Uniaxial Bending 153
9.2.3 Stiffness Equation of Column Element with Joint Panel Subjected to
Biaxial Bending 154
9.3 Behaviour of Beam-Column Connections 155
9.3.1 Moment-Rotation Relationship 156
9.3.2 Hysteretic Behaviour 161
9.4 Effect of Deformation of Beam-Column Connection on Beam Stiffness 163
9.4.1 Stiffness Equation of Beam Element with Beam-Column Connections 164
9.4.2 Stiffness Equation of Beam Element with Connections and Joint Panels
166
9.5 Examples 166
9.5.1 Effect of Joint Panel 166
9.5.2 Effect of Beam-Column Connection 170
Chapter 10 Brace Element and its Elastic and Elasto-Plastic Stiffness
Equations 175
10.1 Hysteretic Behaviour of Braces 175
10.2 Theoretical Analysis of Elastic and Elasto-Plastic Stiffnesses of
Brace Element 175
10.3 Hysteretic Model of Ordinary Braces 181
10.4 Hysteretic Characteristics and Model of Buckling-Restrained Brace 183
10.5 Stiffness Equation of Brace Element 185
Chapter 11 Shear Beam and its Elastic and Elasto-Plastic Stiffness
Equations 187
11.1 Eccentrically Braced Frame and Shear Beam 187
11.1.1 Eccentrically Braced Frame 187
11.1.2 Condition of Shear Beam 187
11.2 Hysteretic Model of Shear Beam 189
11.3 Stiffness Equation of Shear Beam 190
Chapter 12 Elastic Stability Analysis of Planar Steel Frames 193
12.1 General Analytical Method 193
12.2 Effective Length of Prismatic Frame Column 194
12.2.1 Concept of Effective Length 194
12.2.2 Assumption and Analytical Model 195
12.2.3 Formulations of Effective Length 197
12.2.4 Simplified Formula of Effective Length 202
12.2.5 Modification of Effective Length 203
12.2.6 Effect of Shear Deformation on Effective Length of Column 205
12.2.7 Examples 205
12.3 Effective Length of Tapered Steel Columns 211
12.3.1 Tapered Columns Under Different Boundary Conditions 211
12.3.2 Tapered Column in Steel Portal Frame 213
Chapter 13 Nonlinear Analysis of Planar Steel Frames 219
13.1 General Analysis Method 219
13.1.1 Loading Types 219
13.1.2 Criteria for the Limit State of Ultimate Load-Carrying Capacity 220
13.1.3 Analysis Procedure 221
13.1.4 Basic Elements and Unknown Variables 222
13.1.5 Structural Analysis of the First Loading Type 222
13.1.6 Structural Analysis of the Second Loading Type 223
13.1.7 Numerical Examples 223
13.2 Approximate Analysis Considering P_D Effect 226
13.2.1 Formulation 226
13.2.2 Example 227
13.3 Simplified Analysis Model Considering P_D Effect 228
13.3.1 Development of Simplified Model 228
13.3.2 Example 231
Chapter 14 Seismic Response Analysis of Planar Steel Frames 233
14.1 General Analysis Method 233
14.1.1 Kinetic Differential Equation 233
14.1.2 Solution of Kinetic Differential Equation 235
14.1.3 Determination of Mass, Stiffness and Damping Matrices 238
14.1.4 Numerical Example 240
14.2 Half-Frame Model 241
14.2.1 Assumption and Principle of Half-Frame 241
14.2.2 Stiffness Equation of Beam Element in Half-Frame 244
14.2.3 Numerical Examples 244
14.3 Shear-Bending Storey Model 248
14.3.1 Equivalent Stiffness 248
14.3.2 Inter-Storey Shear Yielding Parameters 251
14.3.3 Examples 252
14.4 Simplified Model for Braced Frame 255
14.4.1 Decomposition and Simplification of Braced Frame 255
14.4.2 Stiffness Matrix of Pure Frame 256
14.4.3 Stiffness Matrix of Pure Bracing System 257
14.4.4 Example 258
Chapter 15 Analysis Model for Space Steel Frames 259
15.1 Space Bar Model 259
15.1.1 Transformation from Local to Global Coordinates 259
15.1.2 Requirement of Rigid Floor 264
15.1.3 Global Stiffness Equation of Frame and Static Condensation 267
15.2 Planar Substructure Model 268
15.2.1 Stiffness Equation of Planar Substructure in Global Coordinates 268
15.2.2 Global Stiffness Equation of Spatial Frame 271
15.2.3 Numerical Example 272
15.3 Component Mode Synthesis Method 274
15.3.1 Principle of Component Mode Synthesis Method 274
15.3.2 Analysis of Generalized Elements 276
15.3.3 Stiffness Equation of Generalized Structure 281
15.3.4 Structural Analysis Procedure 282
15.3.5 Numerical Example 283
Part Two Advanced Design of Steel Frames 287
Chapter 16 Development of Structural Design Approach 289
16.1 Deterministic Design Approach 289
16.1.1 Allowable Stress Design (ASD) (AISC, 1989) 289
16.1.2 Plastic Design (PD) (AISC, 1978) 290
16.2 Reliability Design Approach Based on Limit States of Structural
Members 290
16.3 Structural System Reliability Design Approach 292
Chapter 17 Structural System Reliability Calculation 293
17.1 Fundamentals of Structural Reliability Theory 293
17.1.1 Performance Requirements of Structures 293
17.1.2 Performance Function of Structures 293
17.1.3 Limit State of Structures 294
17.1.4 Structural Reliability 294
17.1.5 Reliability Index 296
17.2 The First-Order Second-Moment (FOSM) Methods for Structural
Reliability Assessment 297
17.2.1 Central Point Method 298
17.2.2 Design Point Method 299
17.3 Effects of Correlation Among Random Variables 302
17.4 Structural System Reliability and Boundary Theory 302
17.4.1 Basic Concepts 302
17.4.2 Upper-Lower Boundary Method 305
17.5 Semi-Analytical Simulation Method for System Reliability 306
17.5.1 General Principle 306
17.5.2 Random Sampling 307
17.5.3 Exponential Polynomial Method (EPM) 309
17.6 Example 309
17.6.1 A Steel Beam Section 309
17.6.2 A Steel Portal Frame 313
Chapter 18 System Reliability Assessment of Steel Frames 317
18.1 Randomness of Steel Frame Resistance 317
18.2 Randomness of Loads 318
18.3 System Reliability Evaluation of Typical Steel Frames 319
18.3.1 Effect of Correlation Among Random Variables 319
18.3.2 Evaluation of Structural System Reliability Under Vertical Loads 320
18.3.3 Evaluation of Structural System Reliability Under Horizontal and
Vertical Loads 323
18.4 Comparison of System Reliability Evaluation 325
Chapter 19 Reliability-Based Advanced Design of Steel Frames 327
19.1 Structural Design Based on System Reliability 327
19.1.1 Target Reliability of Design 327
19.1.2 Load and Load Combination 329
19.1.3 Practical Design Formula 329
19.2 Effect of Correlation on Load and Resistance Factors 335
19.3 Comparison of Different Design Methods 337
19.3.1 For Steel Portal Frames 337
19.3.2 For Multi-Storey Steel Frames 340
References/Bibliography 345
Author Index 363
Subject Index 365
Symbols xiii
Part One Advanced Analysis of Steel Frames 1
Chapter 1 Introduction 3
1.1 Type of Steel Frames 3
1.2 Type of Components for Steel Frames 3
1.3 Type of Beam-Column Connections 7
1.4 Deformation of Joint Panel 7
1.5 Analysis Tasks and Method for Steel Frame Design 8
1.6 Definition of Elements in Steel Frames 9
Chapter 2 Elastic Stiffness Equation of Prismatic Beam Element 11
2.1 General Form of Equation 11
2.1.1 Beam Element in Tension 11
2.1.2 Beam Element in Compression 16
2.1.3 Series Expansion of Stiffness Equations 16
2.1.4 Beam Element with Initial Geometric Imperfection 17
2.2 Special Forms of Elemental Equations 19
2.2.1 Neglecting Effect of Shear Deformation 19
2.2.2 Neglecting Effect of Axial Force 21
2.2.3 Neglecting Effects of Shear Deformation and Axial Force 22
2.3 Examples 22
2.3.1 Bent Frame 22
2.3.2 Simply Supported Beam 24
Chapter 3 Elastic Stiffness Equation of Tapered Beam Element 25
3.1 Tapered Beam Element 25
3.1.1 Differential Equilibrium Equation 25
3.1.2 Stiffness Equation 27
3.2 Numerical Verification 29
3.2.1 Symmetry of Stiffness Matrix 29
3.2.2 Static Deflection 30
3.2.3 Elastic Critical Load 30
3.2.4 Frequency of Free Vibration 30
3.2.5 Effect of Term Number Truncated in Polynomial Series 31
3.2.6 Steel Portal Frame 31
3.3 Appendix 33
3.3.1 Chebyshev Polynomial Approach (Rice, 1992) 33
3.3.2 Expression of Elements in Equation (3.23) 34
Chapter 4 Elastic Stiffness Equation of Composite Beam Element 35
4.1 Characteristics and Classification of Composite Beam 35
4.2 Effects of Composite Action on Elastic Stiffness of Composite Beam 37
4.2.1 Beam without Composite Action 37
4.2.2 Beam with Full Composite Action 38
4.2.3 Beam with Partial Composite Action 39
4.3 Elastic Stiffness Equation of Steel-Concrete Composite Beam Element 40
4.3.1 Basic Assumptions 40
4.3.2 Differential Equilibrium Equation of Partially Composite Beam 41
4.3.3 Stiffness Equation of Composite Beam Element 42
4.3.4 Equivalent Nodal Load Vector 46
4.4 Example 49
4.5 Problems in Present Work 51
Chapter 5 Sectional Yielding and Hysteretic Model of Steel Beam Columns 53
5.1 Yielding of Beam Section Subjected to Uniaxial Bending 53
5.2 Yielding of Column Section Subjected to Uniaxial Bending 53
5.3 Yielding of Column Section Subjected to Biaxial Bending 56
5.3.1 Equation of Initial Yielding Surface 56
5.3.2 Equation of Ultimate Yielding Surface 56
5.3.3 Approximate Expression of Ultimate Yielding Surface 61
5.3.4 Effects of Torsion Moment 62
5.4 Hysteretic Model 64
5.4.1 Cyclic Loading and Hysteretic Behaviour 64
5.4.2 Hysteretic Model of Beam Section 65
5.4.3 Hysteretic Model of Column Section Subjected to Uniaxial Bending 67
5.4.4 Hysteretic Model of Column Section Subjected to Biaxial Bending 67
5.5 Determination of Loading and Deformation States of Beam-Column Sections
68
Chapter 6 Hysteretic Behaviour of Composite Beams 71
6.1 Hysteretic Model of Steel and Concrete Material Under Cyclic Loading 71
6.1.1 Hysteretic Model of Steel Stress-Strain Relationship 71
6.1.2 Hysteretic Model of Concrete Stress-Strain Relationship 71
6.2 Numerical Method for Moment-Curvature Hysteretic Curves 75
6.2.1 Assumptions 75
6.2.2 Sectional Division 75
6.2.3 Calculation Procedure of Moment-Curvature Relationship 76
6.3 Hysteretic Characteristics of Moment-Curvature Relationships 77
6.3.1 Characteristics of Hysteretic Curves 77
6.3.2 Typical Phases 78
6.4 Parametric Studies 79
6.4.1 Height of Concrete Flange hc 79
6.4.2 Width of Concrete Flange Bc 79
6.4.3 Height of Steel Beam hs 80
6.4.4 Strength Ratio g 83
6.4.5 Yielding Strength of Steel fy 84
6.4.6 Compressive Strength of Concrete fck 84
6.4.7 Summary of Parametric Studies 85
6.5 Simplified Hysteretic Model 86
6.5.1 Skeletal Curve 86
6.5.2 Hysteresis Model 89
Chapter 7 Elasto-Plastic Stiffness Equation of Beam Element 93
7.1 Plastic Hinge Theory 93
7.1.1 Hinge Formed at One End of Element 94
7.1.2 Hinge Formed at Both Ends of Element 97
7.2 Clough Model 97
7.3 Generalized Clough Model 98
7.4 Elasto-Plastic Hinge Model 99
7.4.1 Both Ends Yielding 102
7.4.2 Only End 1 Yielding 103
7.4.3 Only End 2 Yielding 103
7.4.4 Summary 104
7.5 Comparison Between Elasto-Plastic Hinge Model and Generalized Clough
Model 104
7.5.1 Only End 1 Yielding 104
7.5.2 Both Ends Yielding 105
7.5.3 Numerical Example 106
7.6 Effects of Residual Stresses and Treatment of Tapered Element 107
7.6.1 Effects of Residual Stresses on Plasticity Spread Along Element
Section 107
7.6.2 Effects of Residual Stresses on Plasticity Spread Along Element
Length 109
7.6.3 Treatment of Tapered Element 110
7.7 Beam Element with Plastic Hinge Between Two Ends 110
7.8 Subdivided Model with Variable Stiffness for Composite Beam Element 113
7.8.1 Subdivided Model 113
7.8.2 Stiffness Equation of Composite Beam Element 114
7.9 Examples 117
7.9.1 A Steel Portal Frame with Prismatic Members 117
7.9.2 A Steel Portal Frame with Tapered Members 118
7.9.3 Vogel Portal Frame 119
7.9.4 Vogel Six-Storey Frame 120
7.9.5 A Single-Storey Frame with Mid-Span Concentrated Load 121
7.9.6 A Single-Storey Frame with Distributed Load 123
7.9.7 A Four-Storey Frame with Mid-Span Concentrated Load 124
7.9.8 A Two-Span Three-Storey Composite Frame 126
Chapter 8 Elastic and Elasto-Plastic Stiffness Equations of Column Element
127
8.1 Force and Deformation of Column Element 127
8.2 Elastic Stiffness Equation of Column Element Subjected to Biaxial
Bending 127
8.3 Elasto-Plastic Stiffness Equations of Column Element Subjected to
Biaxial Bending 129
8.3.1 Both Ends Yielding 131
8.3.2 Only End 1 Yielding 132
8.3.3 Only End 2 Yielding 133
8.3.4 Summary 133
8.4 Elastic and Elasto-Plastic Stiffness Equations of Column Element
Subjected to Uniaxial Bending 134
8.5 Axial Stiffness of Tapered Column Element 135
8.5.1 Elastic Stiffness 135
8.5.2 Elasto-Plastic Stiffness 135
8.6 Experiment Verification 136
8.6.1 Experiment Specimen 136
8.6.2 Set-Up and Instrumentation 139
8.6.3 Horizontal Loading Scheme 140
8.6.4 Theoretical Predictions of Experiments 141
8.6.5 Comparison of Analytical and Tested Results 144
Chapter 9 Effects of Joint Panel and Beam-Column Connection 147
9.1 Behaviour of Joint Panel 147
9.1.1 Elastic Stiffness of Joint Panel 147
9.1.2 Elasto-Plastic Stiffness of Joint Panel 149
9.2 Effect of Shear Deformation of Joint Panel on Beam/Column Stiffness 150
9.2.1 Stiffness Equation of Beam Element with Joint Panel 150
9.2.2 Stiffness Equation of Column Element with Joint Panel Subjected to
Uniaxial Bending 153
9.2.3 Stiffness Equation of Column Element with Joint Panel Subjected to
Biaxial Bending 154
9.3 Behaviour of Beam-Column Connections 155
9.3.1 Moment-Rotation Relationship 156
9.3.2 Hysteretic Behaviour 161
9.4 Effect of Deformation of Beam-Column Connection on Beam Stiffness 163
9.4.1 Stiffness Equation of Beam Element with Beam-Column Connections 164
9.4.2 Stiffness Equation of Beam Element with Connections and Joint Panels
166
9.5 Examples 166
9.5.1 Effect of Joint Panel 166
9.5.2 Effect of Beam-Column Connection 170
Chapter 10 Brace Element and its Elastic and Elasto-Plastic Stiffness
Equations 175
10.1 Hysteretic Behaviour of Braces 175
10.2 Theoretical Analysis of Elastic and Elasto-Plastic Stiffnesses of
Brace Element 175
10.3 Hysteretic Model of Ordinary Braces 181
10.4 Hysteretic Characteristics and Model of Buckling-Restrained Brace 183
10.5 Stiffness Equation of Brace Element 185
Chapter 11 Shear Beam and its Elastic and Elasto-Plastic Stiffness
Equations 187
11.1 Eccentrically Braced Frame and Shear Beam 187
11.1.1 Eccentrically Braced Frame 187
11.1.2 Condition of Shear Beam 187
11.2 Hysteretic Model of Shear Beam 189
11.3 Stiffness Equation of Shear Beam 190
Chapter 12 Elastic Stability Analysis of Planar Steel Frames 193
12.1 General Analytical Method 193
12.2 Effective Length of Prismatic Frame Column 194
12.2.1 Concept of Effective Length 194
12.2.2 Assumption and Analytical Model 195
12.2.3 Formulations of Effective Length 197
12.2.4 Simplified Formula of Effective Length 202
12.2.5 Modification of Effective Length 203
12.2.6 Effect of Shear Deformation on Effective Length of Column 205
12.2.7 Examples 205
12.3 Effective Length of Tapered Steel Columns 211
12.3.1 Tapered Columns Under Different Boundary Conditions 211
12.3.2 Tapered Column in Steel Portal Frame 213
Chapter 13 Nonlinear Analysis of Planar Steel Frames 219
13.1 General Analysis Method 219
13.1.1 Loading Types 219
13.1.2 Criteria for the Limit State of Ultimate Load-Carrying Capacity 220
13.1.3 Analysis Procedure 221
13.1.4 Basic Elements and Unknown Variables 222
13.1.5 Structural Analysis of the First Loading Type 222
13.1.6 Structural Analysis of the Second Loading Type 223
13.1.7 Numerical Examples 223
13.2 Approximate Analysis Considering P_D Effect 226
13.2.1 Formulation 226
13.2.2 Example 227
13.3 Simplified Analysis Model Considering P_D Effect 228
13.3.1 Development of Simplified Model 228
13.3.2 Example 231
Chapter 14 Seismic Response Analysis of Planar Steel Frames 233
14.1 General Analysis Method 233
14.1.1 Kinetic Differential Equation 233
14.1.2 Solution of Kinetic Differential Equation 235
14.1.3 Determination of Mass, Stiffness and Damping Matrices 238
14.1.4 Numerical Example 240
14.2 Half-Frame Model 241
14.2.1 Assumption and Principle of Half-Frame 241
14.2.2 Stiffness Equation of Beam Element in Half-Frame 244
14.2.3 Numerical Examples 244
14.3 Shear-Bending Storey Model 248
14.3.1 Equivalent Stiffness 248
14.3.2 Inter-Storey Shear Yielding Parameters 251
14.3.3 Examples 252
14.4 Simplified Model for Braced Frame 255
14.4.1 Decomposition and Simplification of Braced Frame 255
14.4.2 Stiffness Matrix of Pure Frame 256
14.4.3 Stiffness Matrix of Pure Bracing System 257
14.4.4 Example 258
Chapter 15 Analysis Model for Space Steel Frames 259
15.1 Space Bar Model 259
15.1.1 Transformation from Local to Global Coordinates 259
15.1.2 Requirement of Rigid Floor 264
15.1.3 Global Stiffness Equation of Frame and Static Condensation 267
15.2 Planar Substructure Model 268
15.2.1 Stiffness Equation of Planar Substructure in Global Coordinates 268
15.2.2 Global Stiffness Equation of Spatial Frame 271
15.2.3 Numerical Example 272
15.3 Component Mode Synthesis Method 274
15.3.1 Principle of Component Mode Synthesis Method 274
15.3.2 Analysis of Generalized Elements 276
15.3.3 Stiffness Equation of Generalized Structure 281
15.3.4 Structural Analysis Procedure 282
15.3.5 Numerical Example 283
Part Two Advanced Design of Steel Frames 287
Chapter 16 Development of Structural Design Approach 289
16.1 Deterministic Design Approach 289
16.1.1 Allowable Stress Design (ASD) (AISC, 1989) 289
16.1.2 Plastic Design (PD) (AISC, 1978) 290
16.2 Reliability Design Approach Based on Limit States of Structural
Members 290
16.3 Structural System Reliability Design Approach 292
Chapter 17 Structural System Reliability Calculation 293
17.1 Fundamentals of Structural Reliability Theory 293
17.1.1 Performance Requirements of Structures 293
17.1.2 Performance Function of Structures 293
17.1.3 Limit State of Structures 294
17.1.4 Structural Reliability 294
17.1.5 Reliability Index 296
17.2 The First-Order Second-Moment (FOSM) Methods for Structural
Reliability Assessment 297
17.2.1 Central Point Method 298
17.2.2 Design Point Method 299
17.3 Effects of Correlation Among Random Variables 302
17.4 Structural System Reliability and Boundary Theory 302
17.4.1 Basic Concepts 302
17.4.2 Upper-Lower Boundary Method 305
17.5 Semi-Analytical Simulation Method for System Reliability 306
17.5.1 General Principle 306
17.5.2 Random Sampling 307
17.5.3 Exponential Polynomial Method (EPM) 309
17.6 Example 309
17.6.1 A Steel Beam Section 309
17.6.2 A Steel Portal Frame 313
Chapter 18 System Reliability Assessment of Steel Frames 317
18.1 Randomness of Steel Frame Resistance 317
18.2 Randomness of Loads 318
18.3 System Reliability Evaluation of Typical Steel Frames 319
18.3.1 Effect of Correlation Among Random Variables 319
18.3.2 Evaluation of Structural System Reliability Under Vertical Loads 320
18.3.3 Evaluation of Structural System Reliability Under Horizontal and
Vertical Loads 323
18.4 Comparison of System Reliability Evaluation 325
Chapter 19 Reliability-Based Advanced Design of Steel Frames 327
19.1 Structural Design Based on System Reliability 327
19.1.1 Target Reliability of Design 327
19.1.2 Load and Load Combination 329
19.1.3 Practical Design Formula 329
19.2 Effect of Correlation on Load and Resistance Factors 335
19.3 Comparison of Different Design Methods 337
19.3.1 For Steel Portal Frames 337
19.3.2 For Multi-Storey Steel Frames 340
References/Bibliography 345
Author Index 363
Subject Index 365