FIFTH EDITION JACK C. McCORMAC STEPHEN F. CSERNAK Prentice Hall Boston Columbus Indianapolis New York San Francisco Upper Saddle River Amsterdam Cape Town Dubai London Madrid Milan Munich Paris Montreal Toronto Delhi Mexico City Sao Paulo Sydney Hong Kong Seoul Singapore Taipei Tokyo Vice Pre>ident and Edotorial Director. ECS: Marcia I. /lorton Executive Editor: Holly Stark Editorial Assistant: William Opaluclo Vice President. Production: Vinet O'Brien Senior Managing Editor: Scou Dosanno Production Liaison: Greg Dulles Production Editor: Pavithra Jayapaul. TexTech lmemationa/ Operations Specialist: Lua McDo..-ell Executive Marketing Manager: Tim Galligan Market Assistant: Jon Byr ant Art Editor: Greg Dulles Compositoon/Fuii·Servicc Project Management: TaT«illlllt'mallonal Copyright C 2012 by Pearson Education, lnc., Upper Saddle ruver, New Jersey 07458. All rights reserved. Manufactured in the United States of America. This publication is protected by Copyright and permissions should he obtamed from the publisher prior to any prohoboted reproduction. storage in a retrieval system. or transmossion in any form or by any meon'i. electronoc. mechanical. photocopying. record mg. or likewise. To obtain permission(s) to usc materials from this work. please submit a "Tinen request to Pearson Higher Education. Permissions Department, I Lake Street. Upper Saddle River. NJ 07458. The author and publi~her of this book have used their best efforiS in preparing thos book. Thc..e efforts mclude the development. research. and testing of the theories and programs to determine their effectiveness. The author and publosher make no warranty of any kind, expressed or implied, with regard to these programs or the documentation contained in this book. The author and publisher shall not be hable in any event for incidental or consequentoal damages on conncctoon with. or arising out of. the furnishing. performance, or usc or these programs. Ubrary or Congress Cataloging-in-Publication Data McCormac. Jack C. Structural steel dcsi!!n I Jack C. McCormac. Stephen F. Csemak. - 5th ed. p.cm. ISBN-13: 978·0·13-607948-4 ISBN-10: 0-13-607948-2 I. Building. Iron and steel-Textbooks. 2. Steel. Structural-Textbooks. I. Cwmak, Stephen F. II 1itle. TA684.M25 2011 624.1'821- dc22 2011010788 Prentice Hall is an imprint of 10 9 8 7 6 5 4 3 2 I ---- PEARSON ISBN-13: 978-0-13-607948-4 www.pearsonhighered.com ISBN-10: 0-13-607948-2 Preface This textbook has been prepared with the hope that its readers will, as have so many engi neers in the past, become interested in structural steel design and want to maintain and increase their knowledge on the subject throughout their careers in the engineering and construction industries. The material was prepared primarily for an introductory course in the junior or senior year but the last several chapters may be used for a graduate class. The authors have assumed that the student has previously taken introductory courses in mechanics of materials and structural analysis. The authors' major objective in preparing this new edition was to update the text to conform to both the American Institute of Steel Construction (A IS C) 2010 Specification for Structural Steel Buildings and the 14th edition of the AISC Steel Construction Manual published in 2011. WHAT'S NEW IN THIS EDITION Several changes to the text were made to the textbook in this edition: 1. End of chapter Problems for Solution have been added for Chapter 1 of the textbook. 2. The load factors and load combinations defined in Chapter 2 of the textbook and used throughout the book in example problems and end of chapter problems for solution have been revised to meet those given in the ASCE 7-10 and Part 2 of the AISC Steel Construction Manual. 3. The classification of compression sections for local buckling defined in Chapter 5 of the textbook has been revised to the new definition given in Section B4.1 of the new AISC Specification. For compression, sections are now classified as non-slender element or slender element sections. 4. The AISC Specification provides several methods to deal with stability analy sis and the design of beam-columns. In Chapter 7 of the textbook, the Effective Length Method (ELM) is still used, though a brief introduction to the Direct Analysis Method ( DM) has been added. A more comprehensive discussion of the DM is reserved for Chapter 11 of the text. 5. In Chapter 11 of the textbook, both the Direct Analysis Method and the Effective Length Method are presented for the analysis and design of beam-columns. This is to address the fact that the presentation of the Direct Analysis Method was moved from an appendix to Chapter C of the new AISC Specification while the Effective Length Method moved from Chapter C to Appendix 7. 6. Most of the end of chapter Problems for Solution for Chapters 2 through 11 have been revised. For Chapters 12 through 18 about half the problems have been revised. 7. Various photos were updated throughout the textbook. iii iv Preface The authors would like to express appreciation to Dr. Bryant G. Nielson of Clemson University for his assistance in developing the changes to this manuscript and to Sara Elise Roberts, former Clemson University graduate student, for her assistance in the review of the end of chapter problems and their solutions. In addition, the American Institute of Steel Construction was very helpful in providing advance copies of the AISC Specification and Steel Construction Manual revisions. Finally, we would like to thank our families for their encouragement and support in the revising of the manuscript of this textbook. We also thank the reviewers and users of the previous editions of this book for their suggestions, corrections, and criticisms. We welcome any comments on this edition. Jack C. McCormac, P.E. Stephen F. Csernak, P.E. 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 v vi Contents 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 Contents vii 5.11 Example Problems 150 5.12 Problems for Solution 158 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 Colnmn 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 Modulus 240 8.7 Theory of Plastic Analysis 243 8.8 The Collapse Mechanism 244 8.9 The Virtual-Work Method 245 viii Contents 8.10 Location of Plastic Hinge for Uniform Loadings 249 8.11 Continuous Beams 250 8.12 Building Frames 252 8.13 Problems for Solution 254 CHAPTER 9 Design of Beams for Moments 263 9.1 Introduction 263 9.2 Yielding Behavior-Full Plastic Moment, Zone 1 266 9.3 Design of Beams, Zone 1 267 9.4 Lateral Support of Beams 275 9.5 Introduction to Inelastic Buckling, Zone 2 277 9.6 Moment Capacities, Zone 2 281 9.7 Elastic Buckling, Zone 3 283 9.8 Design Charts 285 9.9 Noncompact Sections 290 9.10 Problems for Solution 295 CHAPTER 10 Design ofBeams-Miscellaneons Topics (Shear, Deflection, etc.) 302 10.1 Design of Continuous Beams 302 10.2 Shear 304 10.3 Deflections 310 10.4 Webs and Flanges with Concentrated Loads 316 10.5 Unsymmetrical Bending 324 10.6 Design of Purlins 327 10.7 The Shear Center 330 10.8 Beam-Bearing Plates 335 10.9 Lateral Bracing at Member Ends Supported on Base Plates 339 10.10 Problems for Solution 340 CHAPTER 11 Bending and Axial Force 346 11.1 Occurrence 346 11.2 Members Subject to Bending and Axial Tension 347 11.3 First-Order and Second-Order Moments for Members Subject to Axial Compression and Bending 350 11.4 Direct Analysis Method (DAM) 352 11.5 Effective Length Method (ELM) 353 11.6 Approximate Second-Order Analysis 354 11.7 Beam-Columns in Braced Frames 359 11.8 Beam-Columns in Unbraced Frames 371 11.9 Design of Beam-Columns-Braced or Unbraced 378 11.10 Problems for Solution 386 Contents ix CHAPTER 12 Bolted Connections 390 12.1 Introduction 390 12.2 Types of Bolts 390 12.3 History of High-Strength Bolts 391 12.4 Advantages of High-Strength Bolts 392 12.5 Snug-Tight, Pretensioned, and Slip-Critical Bolts 392 12.6 Methods for Fully Pretensioning High-Strength Bolts 396 12.7 Slip-Resistant Connections and Bearing-Type Connections 398 12.8 Mixed Joints 399 12.9 Sizes of Bolt Holes 400 12.10 Load Transfer and Types of Joints 401 12.11 Failure of Bolted Joints 404 12.12 Spacing and Edge Distances of Bolts 405 12.13 Bearing-Type Connections-Loads Passing Through Center of Gravity of Connections 408 12.14 Slip-Critical Connections-Loads Passing Through Center of Gravity of Connections 419 12.15 Problems for Solution 423 CHAPTER 13 Eccentrically Loaded Bolted Connections and Historical Notes on Rivets 430 13.1 Bolts Subjected to Eccentric Shear 430 13.2 Bolts Subjected to Shear and Tension (Bearing-Type Connections) 444 13.3 Bolts Subjected to Shear and Tension (Slip-Critical Connections) 447 13.4 Tension Loads on Bolted Joints 448 13.5 Prying Action 451 13.6 Historical Notes on Rivets 454 13.7 Types of Rivets 455 13.8 Strength of Riveted Connections-Rivets in Shear and Bearing 457 13.9 Problems for Solution 461 CHAPTER 14 Welded Connections 469 14.1 General 469 14.2 Advantages of Welding 470 14.3 American Welding Society 471 14.4 Types of Welding 471 14.5 Prequalified Welding 475 14.6 Welding Inspection 475 14.7 Classification of Welds 478