STRUCTURAL DESIGN IN WOOD STRUCTURAL DESIGN IN WOOD Judith J. Stalnaker, Ph.D., P.E. University of Colorado at Denver and Ernest C. Harris, Ph.D., P.E. University of Colorado at Denver ~ Springer Science+Business Media, LLC Copyright © 1989 by Springer Science+B usiness Media New York Originally published by Van Nostrand Reinhold in 1989 Softcover reprint of the hardcover I st edition 1989 Library of Congress Catalog Card Number 88-20842 ISBN 978-1-4684-9998-8 ISBN 978-1-4684-9996-4 (eBook) DOI 10.1007/978-1-4684-9996-4 All rights reserved. No part of this work covered by the copyright hereon may be reproduced or used in any form or by any means-graphic, electronic, or mechanical, including photocopying, recording, taping, or information storage and retrieval systems-without written permission of the publisher. Van Nostrand Reinhold 115 Fifth Avenue New York, NY 10003 Chapman and Hall 2-6 Boundary Row London, SE1 8HN, England Thomas Nelson Australia I 02 Dodds Street South Melbourne 3205 Victoria, Australia Nelson Canada 1120 Birchmount Road Scarborough, Ontario M1K 5G4, Canada 16 15 14 13 12 II 10 9 8 7 6 5 4 3 Library of Congress Cataloging-in-Publication Data Stalnaker, Judith J. Structural design in wood. Includes index. I. Building, Wooden. 2. Structural design. I. Harris, Ernest C. II. Title. TA666.S67 1989 624.1 '84 88-20842 ISBN 978-1-4684-9998-8 -- VNR STRUCTURAL ENGINEERING SERIES -- Structural Engineering Theory STRUCTURES: FUNDAMENTAL THEORY AND BEHAVIOR by Richard Gutkowski STRUCTURAL DYNAMICS. 2nd Ed .. by Mario P.az MICROCOMPUTER-AIDED ENGINEERING: STRUCTURAL DYNAMICS by Mario P.az EARTHQUAKE RESISTANT BUILDING DESIGN AND CONSTRUCTION, 2nd Ed., by Norman Green SEISMIC DESIGN FOR BUILDINGS HANDBOOK edited by Farzad Naeim Steel Design STEEL DESIGN FOR ENGINEERS AND ARCHITECTS by Rene Amon, Bruce Knobloch and Atanu Mazumder Concrete Design HANDBOOK OF CONCRETE ENGINEERING by Mark Fintel STRUCTURAL DESIGN GUIDE TO THE ACI BUILDING CODE, 3rd Ed., by P.aul F. Rice, EdwardS. Hoffman, David P. Gustafson and Albert J. Gouwens TORSION OF REINFORCED CONCRETE by T. Hsu MODERN PRESTRESSED CONCRETE, 3rd Ed., by James R. Libby Masonry SIMPLIFIED MASONRY SKILLS by R. Kreh Wood MECHANICS OF WOOD AND WOOD COMPOSITES by Jozsef Bodig and Benjamin Jayne STRUCTURAL USE OF WOOD IN ADVERSE ENVIRONMENTS edited by Robert W. Meyer and Robert M. Kellogg STRUCTURAL DESIGN IN WOOD by Judith J. Stalnaker and Ernest C. Harris Tall Buildings DEVELOPMENTS IN TALL BUILDINGS by the Council on Tall Buildings ADVANCES IN TALL BUILDINGS by the Council on Tall Buildings SECOND CENTURY OF THE SKYSCRAPER by the Council on Tall Buildings Other Structures-Related Books ICE INTERACTION WITH OFFSHORE STRUCTURES by A.B. Cammaert and D.B. Muggeridge FOUNDATION ENGINEERING HANDBOOK by Hans Winterkorn and H. Y. Fang FOUNDATION ENGINEERING FOR DIFFICULT SUBSOIL CONDITIONS by Leonardo Zeevaert ADVANCED DAM ENGINEERING edited by Robert Jansen TUNNEL ENGINEERING HANDBOOK by John Bickel and T.R. Kuesel SURVEYING HANDBOOK edited by Russell Brinker and Roy Minnick Preface Why another textbook on the design of wood sets this book apart is its inclusion of "struc structures? In many years of teaching structural tural planning." Most textbooks show only the design in wood, the authors have used virtually selection of member proportions or number of every textbook available, as well as using only connectors in a joint to satisfy a given, com a code and no textbook at all. The textbooks pletely defined situation. This book, on the used have included both the old and the rela other hand, shows the thinking process needed tively modem; some have been fairly good, but to determine whether or not the member is re in our opinion each has deficiencies. Some quired in the first place. Following this, the books have too few solved examples. Others spacing and continuity of the member are de omit important material or have an arrange cided, its loads are determined, and finally its ment making them difficult to use as formal shape and size are selected. teaching tools. By writing this book, we intend We believe that illustrating structural plan to correct such deficiencies. ning as well as detailed member and connec The prime purpose of this book is to serve as tion design is of considerable value in helping a classroom text for the engineering or archi the student make the transition from the often tecture student. It will, however, also be useful simplistic classroom exercises to problems of to designers who are already familiar with de the real world. Problems for solution by the sign in other materials (steel, concrete, ma student follow the same idea. The first prob sonry) but need to strengthen, refresh, or up lems in each subject are the usual textbook-type date their capability to do structural design in problems, but in most chapters these are fol wood. Design principles for various structural lowed by problems requiring the student to materials are similar, but there are significant make structural planning decisions as well. The differences. This book shows what they are. student may be required, given a load source, The book has features that the authors be to find the magnitude of the applied loads and lieve set it apart from other books on wood decide upon a grade of wood. Given a floor structural design. One of these is an abundance plan, the student may be required to determine of solved examples. Another is its treatment of a layout of structural members. The authors loads. This book will show how actual member have used most of the problems in their classes, loads are computed. The authors have found so the problems have been tested. that students, more often than not, have diffi The book presents many of the design ex culty recognizing how load is transferred from amples in the form of "computation sheets," one member to another-for example, how to solutions in the form of actual design office proceed from a specified intensity of floor live computations. This is intended to reinforce the load and type and thickness of floor material to instruction given in Chapter 1 regarding neat knowing the actual load per unit length reach ness and orderliness in design computations. ing the beam in question. Worked-out exam The book refers frequently to two codes-the ples and student homework problems will il National Design Specification for Wood Con lustrate the process. struction and the Uniform Building Code. Another significant feature that we believe Wherever possible, however, the basic princi- vii viii PREFACE pies behind code requirements are explained, been presented. They realize also that (I) be and where the authors are aware of code short cause of its position in the course, connection comings, that too is pointed out. We refer fre design is something most students learn about quently to code requirements in the belief that almost as an afterthought (as though the subject theory with no exposure to real life is not good is of lesser importance than the design of mem education. What is needed is balance between bers); and (2) structural failures are far more the theoretical and the practical (the latter is not frequent in the connections than in the mem a bad word). bers themselves. Further, design of members The authors have included an example of de can be done more effectively if the designer signing for shear using "two-beam" action, so considers how the member will be connected, that users of the book can better understand the before making a final selection of member size. NDS provisions on the subject. However, the With these ~houghts in mind, the authors pre authors do not recommend using "two-beam" sent the subject of connections before going on action for design. to the design of structural members. In general, the book assumes that the user Those who prefer to present the subject in will be familiar with structural analysis. In fact, the conventional sequence can merely go on to the authors intend that the book will reinforce Chapter 6, delaying the study of Chapter 5 until the principles of structural analysis using wood after Chapter 8 (glulam design). It should work as a vehicle. equally well with either sequence. The authors use the book in a three semester In the authors' beginning three-hour course hour beginning course and find that sufficient in timber structure design, Chapters 1 through material remains that a second course could be 7, 9, 10, 11, most of 8, and parts of 12, 13, taught from the same book. The prerequisite and 14 are included. for the first course should be mechanics of ma The book is written to stand alone. Our terials as a minimum, including the subjects of many instructors may find it beneficial to ask shear and moment diagrams, flexural deflec their students to purchase the National Design tions, and axial forces in truss members. A Specification for Wood Construction from the more rigourous course in structural analysis, Publications Department of the National Forest though desirable as a prerequisite, is not essen Products Association, 1250 Connecticut A venue tial. N.W., Washington, D.C. 20036. Chapter 5 (Connections-Nails, Screws, and Bolts) is intentionally in an unconventional po JUDITH J. STALNAKER sition. The authors realize that most books ERNEST C. HARRIS cover connections after member design has Denver, Colorado Contents Preface I vii 3. Production and Grading of Sawn Lumber I 33 1. Introduction I 1 3-1. Lumber Production I 33 1-1. Evolution of Timber Design I 1 3-2. Standard Sizes of Lumber I 33 1-2. Material Properties I 2 3-3. Finish Designations I 35 1-3. Types of Construction I 2 3-4. Cutting Patterns I 35 1-4. Hybrid Construction I 7 3-5. Drying I 37 1-5. Timber Bridges I 7 3-6. Lumber Grading 38 1-6. Notes to Students I 9 3-7. Types of Grading I 39 References I 10 3-8. Definitions I 40 3-9. Modem Grading Rules I 41 3-10. Example of Visual Grading of 2. Wood Structure and Properties I 11 Beams and Stringers I 41 2-1. Wood as a Structural 3-11. Grading Stamps I 42 Material I 11 3-12. Caution to Designer and 2-2. Problems in Use of Wood for Builder I 43 Structures I 11 3-13. Board Measure I 43 2-3. Advantages of Wood as a Example 3-1 I 44 Structural Material I 11 References I 44 2-4. Classification of Wood I 12 Problem I 44 2-5. Wood Structure I 14 2-6. Juvenile Wood I 17 4. Loads and Allowable Stresses I 45 2-7. Wood Axes I 18 2-8. Properties of Interest to the Part I. Loads I 45 Structural Designer I 18 4-1. General I 45 2-9. Factors Affecting Strength 21 4-2. Dead Loads I 46 2-10. Moisture Content I 21 Example 4-1 I 46 Example 2-1 I 22 Example 4-2 I 47 Example 2-2 I 23 Example 4-3 I 48 2-11. Specific Gravity I 23 4-3. Vertical Live Loads I 49 2-12. Time-Dependent Behavior of Example 4-4 I 50 Wood I 24 Example 4-5 I 52 2-13. Strength-Reducing Example 4-6 I 52 Characteristics I 26 Example 4-7 I 52 2-14. Thermal Properties of Example 4-8 I 52 Wood I 29 4-4. Wind Loads I 52 References I 30 4-5. Stability Under Wind Problems I 31 Loads I 54 ix x CONTENTS 4-6. Load Combinations I 55 References I 97 Example 4-9 I 55 Problems I 98 Example 4-10 I 57 6. Selecting Sawn-Timber Beams I 101 4-7. Seismic Loads I 57 Example 4-11 I 60 6-1. Introduction I 101 Part II. Allowable Stresses 60 6-2. Design for Flexure-Laterally 4-8. Allowable Stresses I 60 Supported Beams I 101 4-9. Establishing Basic Allowable Example 6-1 I 104 Stresses I 62 Example 6-2 I 104 4-10. Design Allowable Stresses I 64 Example 6-3 I 105 Example 4-12 I 66 Example 6-4 I 105 Example 4-13 I 67 Example 6-5 105 Example 4-14 I 67 6-3. Design for Flexure-Laterally Example 4-15 I 67 Unsupported Beams I 106 Example 4-16 I 68 Example 6-6 I 108 Example 4-17 I 68 Example 6-7 I 109 Example 4-18 I 69 Example 6-8 I 109 4-11. Reliability-Based Design I 70 6-4. Design of Beams for References I 71 Shear I 109 Problems I 71 Example 6-9 I 113 Example 6-10 I 113 Example 6-11 I 114 5. Connections-Nails, Screws, and Example 6-12 I 114 Bolts I 74 Example 6-13 I 115 5-1. Connection Design I 74 Example 6-14 I 115 5-2. General Principles I 74 6-5. Deflection I 115 5-3. Nails and Spikes I 76 Example 6-15 I 118 Example 5-1 I 79 Example 6-16 I 118 Example 5-2 I 80 Example 6-17 I 118 Example 5-3 I 80 Example 6-18 I 119 Example 5-4 I 80 6-6. Design for Bearing I 119 Example 5-5 I 80 Example 6-19 I 121 Example 5-6 I 80 Example 6-20 I 121 5-4. Staples I 81 Example 6-21 I 121 5-5. Lag Screws I 81 6-7. Floor System Design I 121 Example 5-7 I 84 Example 6-22 I 122 Example 5-8 I 85 References I 125 Example 5-9 I 86 Problems I 125 5-6. Wood Screws I 87 7. Selecting Sawn-Timber Compression and 5-7. Bolted Connections I 87 Tension Members I 129 Example 5-10 I 92 Example 5-11 I 92 7-1. Wood Columns I 129 Example 5-12 I 93 7-2. Column Design I 131 Example 5-13 I 95 Example 7-1 I 134 Example 5-14 I 95 Example 7-2 I 135 Example 5-15 I 95 7-3. Round and Tapered 5-8. Bolts Loaded at an Angle to the Columns I 135 Bolt Axis I 96 Example 7-3 I 136 Example 5-16 I 97 Example 7-4 I 136 CONTENTS xi 7-4. Spaced Columns I 136 8-13. Three-Hinged Arches I 181 Example 7-5 I 139 Example 8-14 I 182 7-5. Built-Up Columns I 140 8-14. Glulam Columns I 183 Example 7-6 I 141 References I 184 7-6. Beam Columns I 141 Problems I 186 Example 7-7 I 143 Example 7-8 I 144 9. Bolts, Timber Connectors, and Special Example 7-9 I 145 Weldments I 190 Example 7-10 I 145 9-1. Bolt Groups Subject to 7-7. Columns or Beam-Columns with Moment I 190 Initial Curvature I 146 Example 9-1 I 191 7-8. Tension Members I 147 9-2. Connections with Moment-Bolts Example 7-11 I 147 in Tension and Shear I 193 7-9. Combined Tension and Bending Example 9-2 I 194 149 9-3. Stitch Bolts I 195 References I 149 9-4. Joist and Beam Hangers and Problems I 150 Framing Anchors I 195 9-5. Special Weldments I 196 Example 9-3 I 199 8. Glued Laminated Members I 152 Example 9-4 I 201 8-1. Glulams I 152 Example 9-5 I 203 8-2. Advantages of Glulams over Sawn 9-6. Shear Plates and Split Timbers I 153 Rings I 204 Example 8-1 I 154 9-7. Shear Plates I 205 8-3. Glulam Production I 155 9-8. Split Rings I 206 8-4. Standard Widths I 158 Example 9-6 I 206 8-5. Limits of Curvature I 159 Example 9-7 I 207 8-6. Allowable Stresses and Example 9-8 I 207 Modifications I 159 Example 9-9 I 208 Example 8-2 I 161 9-9. Spiked Grids and Grid Example 8-3 I 162 Plates I 209 8-7. Suggested Design 9-10. Nailer Plates and Toothed Procedure I 162 Plates I 210 Example 8-4 I 162 9-11. Drift Pins and Dowels I 210 Example 8-5 I 163 References I 211 Example 8-6 I 164 Problems I 211 8-8. Biaxial Bending I 165 10. Timber Trusses I 213 Example 8-7 I 165 8-9. Cantilever Beam Systems I 166 10-1. Wood Truss Types 213 Example 8-8 I 168 10-2. Light-Frame Trusses, Example 8-9 I 168 Analysis I 216 Example 8-10 I 170 Example 10-1 I 219 8-10. Curved Glulams 170 10-3. Light-Frame Trusses, Member Example 8-11 173 Design I 221 Example 8-12 174 10-4. Light-Frame Trusses, Connection 8-11. Tapered Glulams I 177 Design I 223 Example 8-13 I 180 Example 10-2 I 225 8-12. Members Both Tapered and 10-5. Bracing and Erection of Light Curved I 181 Frame Trusses I 228