Structural Steel Design to Eurocode 3 and AISC Specifications
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portes grátis
Structural Steel Design to Eurocode 3 and AISC Specifications
Cordova, Benedetto; Bernuzzi, Claudio
John Wiley & Sons Inc
05/2016
536
Dura
Inglês
9781118631287
15 a 20 dias
Structural Steel Design to Eurocode 3 and AISC Specifications deals with the theory and practical applications of structural steel design in Europe and the USA.
Preface x 1 The Steel Material 1 1.1 General Points about the Steel Material 1 1.1.1 Materials in Accordance with European Provisions 4 1.1.2 Materials in Accordance with United States Provisions 7 1.2 Production Processes 10 1.3 Thermal Treatments 13 1.4 Brief Historical Note 14 1.5 The Products 15 1.6 Imperfections 18 1.6.1 Mechanical Imperfections 19 1.6.2 Geometric Imperfections 22 1.7 Mechanical Tests for the Characterization of the Material 24 1.7.1 Tensile Testing 25 1.7.2 Stub Column Test 27 1.7.3 Toughness Test 29 1.7.4 Bending Test 32 1.7.5 Hardness Test 32 2 References for the Design of Steel Structures 34 2.1 Introduction 34 2.1.1 European Provisions for Steel Design 35 2.1.2 United States Provisions for Steel Design 37 2.2 Brief Introduction to Random Variables 37 2.3 Measure of the Structural Reliability and Design Approaches 39 2.4 Design Approaches in Accordance with Current Standard Provisions 44 2.4.1 European Approach for Steel Design 44 2.4.2 United States Approach for Steel Design 47 3 Framed Systems and Methods of Analysis 49 3.1 Introduction 49 3.2 Classification Based on Structural Typology 51 3.3 Classification Based on Lateral Deformability 52 3.3.1 European Procedure 53 3.3.2 AISC Procedure 56 3.4 Classification Based on Beam-to-Column Joint Performance 56 3.4.1 Classification According to the European Approach 57 3.4.2 Classification According to the United States Approach 60 3.4.3 Joint Modelling 61 3.5 Geometric Imperfections 63 3.5.1 The European Approach 63 3.5.2 The United States Approach 67 3.6 The Methods of Analysis 68 3.6.1 Plasticity and Instability 69 3.6.2 Elastic Analysis with Bending Moment Redistribution 76 3.6.3 Methods of Analysis Considering Mechanical Non-Linearity 78 3.6.4 Simplified Analysis Approaches 80 3.7 Simple Frames 84 3.7.1 Bracing System Imperfections in Accordance with EU Provisions 88 3.7.2 System Imperfections in Accordance with AISC Provisions 89 3.7.3 Examples of Braced Frames 92 3.8 Worked Examples 96 4 Cross-Section Classification 107 4.1 Introduction 107 4.2 Classification in Accordance with European Standards 108 4.2.1 Classification for Compression or Bending Moment 110 4.2.2 Classification for Compression and Bending Moment 110 4.2.3 Effective Geometrical Properties for Class 4 Sections 115 4.3 Classification in Accordance with US Standards 118 4.4 Worked Examples 121 5 Tension Members 134 5.1 Introduction 134 5.2 Design According to the European Approach 134 5.3 Design According to the US Approach 137 5.4 Worked Examples 140 6 Members in Compression 147 6.1 Introduction 147 6.2 Strength Design 147 6.2.1 Design According to the European Approach 147 6.2.2 Design According to the US Approach 148 6.3 Stability Design 148 6.3.1 Effect of Shear on the Critical Load 155 6.3.2 Design According to the European Approach 158 6.3.3 Design According to the US Approach 162 6.4 Effective Length of Members in Frames 166 6.4.1 Design According to the EU Approach 166 6.4.2 Design According to the US Approach 169 6.5 Worked Examples 172 7 Beams 176 7.1 Introduction 176 7.1.1 Beam Deformability 176 7.1.2 Dynamic Effects 178 7.1.3 Resistance 179 7.1.4 Stability 179 7.2 European Design Approach 184 7.2.1 Serviceability Limit States 184 7.2.2 Resistance Verifications 186 7.2.3 Buckling Resistance of Uniform Members in Bending 190 7.3 Design According to the US Approach 199 7.3.1 Serviceability Limit States 199 7.3.2 Shear Strength Verification 200 7.3.3 Flexural Strength Verification 204 7.4 Design Rules for Beams 228 7.5 Worked Examples 233 8 Torsion 243 8.1 Introduction 243 8.2 Basic Concepts of Torsion 245 8.2.1 I- and H-Shaped Profiles with Two Axes of Symmetry 250 8.2.2 Mono-symmetrical Channel Cross-Sections 252 8.2.3 Warping Constant for Most Common Cross-Sections 255 8.3 Member Response to Mixed Torsion 258 8.4 Design in Accordance with the European Procedure 263 8.5 Design in Accordance with the AISC Procedure 265 8.5.1 Round and Rectangular HSS 266 8.5.2 Non-HSS Members (Open Sections Such as W, T, Channels, etc.) 267 9 Members Subjected to Flexure and Axial Force 268 9.1 Introduction 268 9.2 Design According to the European Approach 271 9.2.1 The Resistance Checks 271 9.2.2 The Stability Checks 274 9.2.3 The General Method 280 9.3 Design According to the US Approach 281 9.4 Worked Examples 284 10 Design for Combination of Compression, Flexure, Shear and Torsion 303 10.1 Introduction 303 10.2 Design in Accordance with the European Approach 308 10.3 Design in Accordance with the US Approach 309 10.3.1 Round and Rectangular HSS 310 10.3.2 Non-HSS Members (Open Sections Such as W, T, Channels, etc.) 310 11 Web Resistance to Transverse Forces 311 11.1 Introduction 311 11.2 Design Procedure in Accordance with European Standards 312 11.3 Design Procedure in Accordance with US Standards 316 12 Design Approaches for Frame Analysis 319 12.1 Introduction 319 12.2 The European Approach 319 12.2.1 The EC3-1 Approach 320 12.2.2 The EC3-2a Approach 321 12.2.3 The EC3-2b Approach 321 12.2.4 The EC3-3 Approach 322 12.3 AISC Approach 323 12.3.1 The Direct Analysis Method (DAM) 323 12.3.2 The Effective Length Method (ELM) 327 12.3.3 The First Order Analysis Method (FOM) 329 12.3.4 Method for Approximate Second Order Analysis 330 12.4 Comparison between the EC3 and AISC Analysis Approaches 332 12.5 Worked Example 334 13 The Mechanical Fasteners 345 13.1 Introduction 345 13.2 Resistance of the Bolted Connections 345 13.2.1 Connections in Shear 347 13.2.2 Connections in Tension 354 13.2.3 Connection in Shear and Tension 358 13.3 Design in Accordance with European Practice 358 13.3.1 European Practice for Fastener Assemblages 358 13.3.2 EU Structural Verifications 363 13.4 Bolted Connection Design in Accordance with the US Approach 369 13.4.1 US Practice for Fastener Assemblage 369 13.4.2 US Structural Verifications 376 13.5 Connections with Rivets 382 13.5.1 Design in Accordance with EU Practice 383 13.5.2 Design in Accordance with US Practice 383 13.6 Worked Examples 384 14 Welded Connections 395 14.1 Generalities on Welded Connections 395 14.1.1 European Specifications 397 14.1.2 US Specifications 399 14.1.3 Classification of Welded Joints 400 14.2 Defects and Potential Problems in Welds 401 14.3 Stresses in Welded Joints 403 14.3.1 Tension 404 14.3.2 Shear and Flexure 406 14.3.3 Shear and Torsion 408 14.4 Design of Welded Joints 411 14.4.1 Design According to the European Approach 411 14.4.2 Design According to the US Practice 414 14.5 Joints with Mixed Typologies 420 14.6 Worked Examples 420 15 Connections 424 15.1 Introduction 424 15.2 Articulated Connections 425 15.2.1 Pinned Connections 426 15.2.2 Articulated Bearing Connections 427 15.3 Splices 429 15.3.1 Beam Splices 430 15.3.2 Column Splices 431 15.4 End Joints 434 15.4.1 Beam-to-Column Connections 434 15.4.2 Beam-to-Beam Connections 434 15.4.3 Bracing Connections 437 15.4.4 Column Bases 438 15.4.5 Beam-to-Concrete Wall Connection 441 15.5 Joint Modelling 444 15.5.1 Simple Connections 450 15.5.2 Rigid Joints 454 15.5.3 Semi-Rigid Joints 458 15.6 Joint Standardization 462 16 Built-Up Compression Members 466 16.1 Introduction 466 16.2 Behaviour of Compound Struts 466 16.2.1 Laced Compound Struts 471 16.2.2 Battened Compound Struts 473 16.3 Design in Accordance with the European Approach 475 16.3.1 Laced Compression Members 477 16.3.2 Battened Compression Members 477 16.3.3 Closely Spaced Built-Up Members 478 16.4 Design in Accordance with the US Approach 480 16.5 Worked Examples 482 Appendix A: Conversion Factors 491 Appendix B: References and Standards 492 Index 502
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Structural Steel Design to Eurocode 3 and AISC Specifications deals with the theory and practical applications of structural steel design in Europe and the USA.
Preface x 1 The Steel Material 1 1.1 General Points about the Steel Material 1 1.1.1 Materials in Accordance with European Provisions 4 1.1.2 Materials in Accordance with United States Provisions 7 1.2 Production Processes 10 1.3 Thermal Treatments 13 1.4 Brief Historical Note 14 1.5 The Products 15 1.6 Imperfections 18 1.6.1 Mechanical Imperfections 19 1.6.2 Geometric Imperfections 22 1.7 Mechanical Tests for the Characterization of the Material 24 1.7.1 Tensile Testing 25 1.7.2 Stub Column Test 27 1.7.3 Toughness Test 29 1.7.4 Bending Test 32 1.7.5 Hardness Test 32 2 References for the Design of Steel Structures 34 2.1 Introduction 34 2.1.1 European Provisions for Steel Design 35 2.1.2 United States Provisions for Steel Design 37 2.2 Brief Introduction to Random Variables 37 2.3 Measure of the Structural Reliability and Design Approaches 39 2.4 Design Approaches in Accordance with Current Standard Provisions 44 2.4.1 European Approach for Steel Design 44 2.4.2 United States Approach for Steel Design 47 3 Framed Systems and Methods of Analysis 49 3.1 Introduction 49 3.2 Classification Based on Structural Typology 51 3.3 Classification Based on Lateral Deformability 52 3.3.1 European Procedure 53 3.3.2 AISC Procedure 56 3.4 Classification Based on Beam-to-Column Joint Performance 56 3.4.1 Classification According to the European Approach 57 3.4.2 Classification According to the United States Approach 60 3.4.3 Joint Modelling 61 3.5 Geometric Imperfections 63 3.5.1 The European Approach 63 3.5.2 The United States Approach 67 3.6 The Methods of Analysis 68 3.6.1 Plasticity and Instability 69 3.6.2 Elastic Analysis with Bending Moment Redistribution 76 3.6.3 Methods of Analysis Considering Mechanical Non-Linearity 78 3.6.4 Simplified Analysis Approaches 80 3.7 Simple Frames 84 3.7.1 Bracing System Imperfections in Accordance with EU Provisions 88 3.7.2 System Imperfections in Accordance with AISC Provisions 89 3.7.3 Examples of Braced Frames 92 3.8 Worked Examples 96 4 Cross-Section Classification 107 4.1 Introduction 107 4.2 Classification in Accordance with European Standards 108 4.2.1 Classification for Compression or Bending Moment 110 4.2.2 Classification for Compression and Bending Moment 110 4.2.3 Effective Geometrical Properties for Class 4 Sections 115 4.3 Classification in Accordance with US Standards 118 4.4 Worked Examples 121 5 Tension Members 134 5.1 Introduction 134 5.2 Design According to the European Approach 134 5.3 Design According to the US Approach 137 5.4 Worked Examples 140 6 Members in Compression 147 6.1 Introduction 147 6.2 Strength Design 147 6.2.1 Design According to the European Approach 147 6.2.2 Design According to the US Approach 148 6.3 Stability Design 148 6.3.1 Effect of Shear on the Critical Load 155 6.3.2 Design According to the European Approach 158 6.3.3 Design According to the US Approach 162 6.4 Effective Length of Members in Frames 166 6.4.1 Design According to the EU Approach 166 6.4.2 Design According to the US Approach 169 6.5 Worked Examples 172 7 Beams 176 7.1 Introduction 176 7.1.1 Beam Deformability 176 7.1.2 Dynamic Effects 178 7.1.3 Resistance 179 7.1.4 Stability 179 7.2 European Design Approach 184 7.2.1 Serviceability Limit States 184 7.2.2 Resistance Verifications 186 7.2.3 Buckling Resistance of Uniform Members in Bending 190 7.3 Design According to the US Approach 199 7.3.1 Serviceability Limit States 199 7.3.2 Shear Strength Verification 200 7.3.3 Flexural Strength Verification 204 7.4 Design Rules for Beams 228 7.5 Worked Examples 233 8 Torsion 243 8.1 Introduction 243 8.2 Basic Concepts of Torsion 245 8.2.1 I- and H-Shaped Profiles with Two Axes of Symmetry 250 8.2.2 Mono-symmetrical Channel Cross-Sections 252 8.2.3 Warping Constant for Most Common Cross-Sections 255 8.3 Member Response to Mixed Torsion 258 8.4 Design in Accordance with the European Procedure 263 8.5 Design in Accordance with the AISC Procedure 265 8.5.1 Round and Rectangular HSS 266 8.5.2 Non-HSS Members (Open Sections Such as W, T, Channels, etc.) 267 9 Members Subjected to Flexure and Axial Force 268 9.1 Introduction 268 9.2 Design According to the European Approach 271 9.2.1 The Resistance Checks 271 9.2.2 The Stability Checks 274 9.2.3 The General Method 280 9.3 Design According to the US Approach 281 9.4 Worked Examples 284 10 Design for Combination of Compression, Flexure, Shear and Torsion 303 10.1 Introduction 303 10.2 Design in Accordance with the European Approach 308 10.3 Design in Accordance with the US Approach 309 10.3.1 Round and Rectangular HSS 310 10.3.2 Non-HSS Members (Open Sections Such as W, T, Channels, etc.) 310 11 Web Resistance to Transverse Forces 311 11.1 Introduction 311 11.2 Design Procedure in Accordance with European Standards 312 11.3 Design Procedure in Accordance with US Standards 316 12 Design Approaches for Frame Analysis 319 12.1 Introduction 319 12.2 The European Approach 319 12.2.1 The EC3-1 Approach 320 12.2.2 The EC3-2a Approach 321 12.2.3 The EC3-2b Approach 321 12.2.4 The EC3-3 Approach 322 12.3 AISC Approach 323 12.3.1 The Direct Analysis Method (DAM) 323 12.3.2 The Effective Length Method (ELM) 327 12.3.3 The First Order Analysis Method (FOM) 329 12.3.4 Method for Approximate Second Order Analysis 330 12.4 Comparison between the EC3 and AISC Analysis Approaches 332 12.5 Worked Example 334 13 The Mechanical Fasteners 345 13.1 Introduction 345 13.2 Resistance of the Bolted Connections 345 13.2.1 Connections in Shear 347 13.2.2 Connections in Tension 354 13.2.3 Connection in Shear and Tension 358 13.3 Design in Accordance with European Practice 358 13.3.1 European Practice for Fastener Assemblages 358 13.3.2 EU Structural Verifications 363 13.4 Bolted Connection Design in Accordance with the US Approach 369 13.4.1 US Practice for Fastener Assemblage 369 13.4.2 US Structural Verifications 376 13.5 Connections with Rivets 382 13.5.1 Design in Accordance with EU Practice 383 13.5.2 Design in Accordance with US Practice 383 13.6 Worked Examples 384 14 Welded Connections 395 14.1 Generalities on Welded Connections 395 14.1.1 European Specifications 397 14.1.2 US Specifications 399 14.1.3 Classification of Welded Joints 400 14.2 Defects and Potential Problems in Welds 401 14.3 Stresses in Welded Joints 403 14.3.1 Tension 404 14.3.2 Shear and Flexure 406 14.3.3 Shear and Torsion 408 14.4 Design of Welded Joints 411 14.4.1 Design According to the European Approach 411 14.4.2 Design According to the US Practice 414 14.5 Joints with Mixed Typologies 420 14.6 Worked Examples 420 15 Connections 424 15.1 Introduction 424 15.2 Articulated Connections 425 15.2.1 Pinned Connections 426 15.2.2 Articulated Bearing Connections 427 15.3 Splices 429 15.3.1 Beam Splices 430 15.3.2 Column Splices 431 15.4 End Joints 434 15.4.1 Beam-to-Column Connections 434 15.4.2 Beam-to-Beam Connections 434 15.4.3 Bracing Connections 437 15.4.4 Column Bases 438 15.4.5 Beam-to-Concrete Wall Connection 441 15.5 Joint Modelling 444 15.5.1 Simple Connections 450 15.5.2 Rigid Joints 454 15.5.3 Semi-Rigid Joints 458 15.6 Joint Standardization 462 16 Built-Up Compression Members 466 16.1 Introduction 466 16.2 Behaviour of Compound Struts 466 16.2.1 Laced Compound Struts 471 16.2.2 Battened Compound Struts 473 16.3 Design in Accordance with the European Approach 475 16.3.1 Laced Compression Members 477 16.3.2 Battened Compression Members 477 16.3.3 Closely Spaced Built-Up Members 478 16.4 Design in Accordance with the US Approach 480 16.5 Worked Examples 482 Appendix A: Conversion Factors 491 Appendix B: References and Standards 492 Index 502
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