DOCSLIB.ORG

Guide to Design Criteria for Bolted and Riveted Joints Second Edition

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Guide to Design Criteria for Bolted and Riveted Joints Second Edition Guide to Design Criteria for Bolted and Riveted Joints Second Edition Geoffrey L. Kulak John W. Fisher John H. A. Struik Published by: AMERICAN INSTITUTE OF STEEL CONSTRUCTION, Inc. One East Wacker Drive, Suite 3100, Chicago, IL 60601 Copyright (2001) by the Research Council on Structural Connections. All rights reserved. Original copyright (1987) by John Wiley & Sons, Inc. transferred to RCSC. Reproduction or translation of any part of this work beyond that permitted by Section 107 or 108 of the 1976 United States Copyright Act without the permission of the copyright owner is unlawful. Requests for permission or further information should be addressed to RCSC c/o AISC, One East Wacker Drive, Suite 3100, Chicago, IL 60601. Library of Congress Cataloging in Publication Data: Fisher, John W., 193 1Guide to design criteria for bolted and riveted joints. “A Wiley-lnterscience publication.” Bibliography: p. Includes index. 1. Bolted joints. 2. Riveted joints. I. Kulak, Geoffrey. II. Struik, John H. A., 1942- III. Title. TA492.B63F56 1987671.5 86-22390 ISBN 0-471-83791-1 (for Wiley copyright) ISBN 1-56424-075-4 (for RCSC copyright) Printed in the United States of America 10 9 8 7 6 Foreword Since the first edition of this book was published in 1974, numerous international studies on the strength and performance of bolted connections have been conducted. Ln the same period, the Research Council on Structural Connections has developed two new specifications for structural joints using ASTM A325 or A490 bolts, one based on allowable stress principles and the other on a load factor and resistance design philosophy. In addition, the Research Council has approved and published “A Test Method to Determine the Slip Coefficient for Coatings used in Bolted Joints.” This second, updated, edition has been prepared and approved by the Research Council. Formed in 1947 and formerly known as the Research Council on Riveted and Bolted Structural Connections, the Research Council on Structural Connections is a nonprofit technical body composed of consulting engineers, educational institutions trade associations and government agencies, and individual members. Its membership is classified according to interest either as producers, users, or general interest, and its purpose is to promote technical information and the knowledge of economical, efficient and safe practices related to the design and installation of bolted structural connections. The Research Council’s Specifications have been endorsed by the Industrial Fasteners Institute and endorsed and published by the American Institute of Steel Construction, and they form the basis of the technical requirements of other national standards. Research Council on Structural Connections Preface The impetus for the preparation of a second edition of the Guide to Design Criteria for Bolted and Riveted Joints has been the enthusiastic reception of the original version and the continued citation for over a decade of that book as a source of information regarding the design of bolted connections. There certainly has been no other single reference in this area that has been so accepted by designers, teachers, students, and specification writers. Of course, a great deal of research into the behavior of bolted connections has been conducted since the publication of the original Guide. Indeed, that publication itself identified areas of concern and areas in which information was lacking, and it thereby stimulated research. The success of the original Guide and the amount of significant research that has been done since its publication indicated that a revised and updated version was desirable. The authors are grateful to the Research Council on Structural Connections for supporting the preparation Of a second edition and for underwriting the costs involved. Many council members offered suggestions, and the efforts of the council were coordinated by M. I. Gilmor of the Canadian Institute of Steel Construction. Geoffrey Kulak also particularly wishes to express thanks to Professor J. -C. Badoux, Director of ICOM (Institute de la Construction Mdtallique) at École Polytechnique Federale de Lausanne in Switzerland. The majority of the revisions contained in the second edition were prepared while that author was a visiting professor at the Institute. Readers of the original Guide will find that the second edition follows the same framework. After introductory chapters treating the historical background of high- strength bolts and rivets, the behavior of individual fasteners is introduced. This is followed by descriptions of the behavior of fasteners in the various types of connections that are encountered in structural engineering practice. Throughout the book, new data have been used to update the information originally presented or to present thoughts in areas that were not covered at all in the earlier edition. There has been a great deal of new work for the authors to draw on. For example, there have been significant improvements in our knowledge of the behavior of slip-resistance connections, fatigue of bolted and riveted connections, beam-to-column connections, and so on. The authors are grateful to researchers throughout the world who have shared their results so willingly. GEOFFREY L. KULAK JOHN W. FISHER JOHN H. A. STRUIK Edmonton, Alberta, Canada Bethlehem, Pennsylvania January 1987 vii Preface to First Edition This book provides a state-of-the-art summary of the experimental and theoretical studies undertaken to provide an understanding of the behavior and strength of riveted and bolted structural joints. Design criteria have been developed on the basis of this information and should be beneficial to designers, teachers, students, and specification- writing bodies. The book is intended to provide a comprehensive source of information on bolted and riveted structural joints as well as an explanation of their behavior under various load conditions. Design recommendations are provided for both allowable stress design and load factor design. In both cases, major consideration is given to the fundamental behavior of the joint and its ultimate capacity. The work on this manuscript was carried out at Fritz Engineering Laboratory, Lehigh University, Bethlehem, Pa. The Research Council on Riveted and Bolted Structural Joints sponsored the project from its inception in 1969. The work has been guided by the Councils Committee on Specifications under the chairmanship of Dr. Theodore R. Higgins. Other members of the committee include: R. S. Belford, E. Chesson, Jr., M. F. Godfrey, F. E. Graves, R. M. Harris, H. A. Krentz, F. R. Ling, W. H. Munse, W. Pressler, E. J. Ruble, J. L. Rumpf, T. W. Spilman, F. Stahl, and W. M. Thatcher. The authors are grateful for the advice and guidance provided by the committee. Many helpful suggestions were made during the preparation of the manuscript. Sincere appreciation is also due the Research Council on Riveted and Bolted Structural Joints and Lehigh University for supporting this work. A book of this magnitude would not have been possible without the assistance of the many organizations who have sponsored research on riveted and bolted structural joints at Fritz Engineering Laboratory. Much of the research on the behavior of riveted and bolted structural joints that was conducted at Fritz Engineering Laboratory provided background for this study and was drawn on extensively. Those sponsoring this work include the American Institute of Steel Construction, the Pennsylvania Department of Transportation, the Research Council on Riveted and Bolted Structural Joints, the United States Department of Transportation-Federal Highway Administration, and the Louisiana Department of Transportation. The authors are particularly grateful for the advice provided by Dr. Theodore R. Higgins and Dr. Geoffrey L. Kulak. Many helpful suggestions were provided that greatly improved the manuscript and design recommendations. ix x Preface to First Edition The manuscript was typed by Mrs. Charlotte Yost, and her assistance with the many phases of the preparation of the manuscript is appreciated. Acknowledgment is also due Mary Ann Yost for her assistance with the preparation of the various indexes provided in this book and other resource material. Many organizations have given permission to reproduce graphs, tables, and photographs. This permission is appreciated and credit is given at the appropriate place. JOHN W. FISHER JOHN H. A. STRUIK Bethlehem, Pennsylvania July 1973 Contents 1. Introduction 1 1.1 Purpose and Scope, 1 1.2 Historical Notes, 1 1.3 Types and Mechanical Properties of Structural Fasteners, 3 2. General Provisions 9 2.1 Structural Steels, 9 2.2 Types of Connections, 12 2.3 Loads, 16 2.4 Factor of Safety—Load Factor Design, 17 2.5 Bolted and Riveted Shear Splices, 18 2.6 Fatigue, 20 2.7 Fracture, 22 3. Rivets 27 3.1 Rivet Types, 27 3.2 Installation of Rivets, 27 3.3 Behavior of Individual Fasteners, 29 3.3.1 Rivets Subjected to Tension, 29 3.3.2 Rivets Subjected to Shear, 30 3.3.3 Rivets Subjected to Combined Tension and Shear, 31 3.4 Basis for Design Recommendations, 33 3.4.1 Rivets Subjected to Tension, 33 3.4.2 Rivets Subjected to Shear, 33 3.4.3 Rivets Subjected to Combined Tension and Shear, 33 xi xii Contents 4. Bolts 35 4.1 Bolt Types, 35 4.2 Behavior of Individual Fasteners, 39 4.2.1 Bolts Subjected to Tension, 39 4.2.2 Bolts Subjected to Shear, 44 4.2.3 Bolts Subjected to Combined Tension and Shear, 50 4.3 Installation of High-Strength Bolts, 52 4.4 Relaxation, 61 4.5 Reuse of
Load more

Recommended publications
  • Analysis and Strengthening of Carpentry Joints 1. Introduction 2
    Generated by Foxit PDF Creator © Foxit Software Branco, J.M., Descamps, T., Analysis and strengthening http://www.foxitsoftware.comof carpentry joints. Construction andFor Buildingevaluation Materials only. (2015), 97: 34–47. http://dx.doi.org/10.1016/j.conbuildmat.2015.05.089 Analysis and strengthening of carpentry joints Jorge M. Branco Assistant Professor ISISE, Dept. Civil Eng., University of Minho Guimarães, Portugal Thierry Descamps Assistant Professor URBAINE, Dept. Structural Mech. and Civil Eng., University of Mons Mons, Belgium 1. Introduction Joints play a major role in the structural behaviour of old timber frames [1]. Current standards mainly focus on modern dowel-type joints and usually provide little guidance (with the exception of German and Swiss NAs) to designers regarding traditional joints. With few exceptions, see e.g. [2], [3], [4], most of the research undertaken today is mainly focused on the reinforcement of dowel-type connections. When considering old carpentry joints, it is neither realistic nor useful to try to describe the behaviour of each and every type of joint. The discussion here is not an extra attempt to classify or compare joint configurations [5], [6], [7]. Despite the existence of some classification rules which define different types of carpentry joints, their applicability becomes difficult. This is due to the differences in the way joints are fashioned depending, on the geographical location and their age. In view of this, it is mandatory to check the relevance of the calculations as a first step. This first step, to, is mandatory. A limited number of carpentry joints, along with some calculation rules and possible strengthening techniques are presented here.
    [Show full text]
  • [email protected]
    BOLTING Basics, Tips & Best Practices g... urin Feat SmartBolts® Direct Tension Indicating Fasteners™ Address: 202 Perry Parkway, Suite 7 Gaithersburg, MD 20877 United States Phone: +1 (240) 631-7246 Fax: +1 (240) 750-6025 Email: [email protected] URL: www.smartbolts.com www.stressindicators.com Stress Indicators Incorporated is a solutions-driven engineering and manufacturing firm based in Maryland, USA. Formed in 1992, we provide innovative Visual Indication Systems™ solutions for customers worldwide. Stress Indicators Incorporated invented and developed SmartBolts® technology and commercialized the products to enable broad industry acceptance. All SmartBolts® are manufactured from quality fasteners at our USA facility. Disclaimer While we try to make sure that all data/information posted in this report is accurate at all times, we are not responsible for typographical and other errors that may appear. Data/Information is subject to change without notice. Stress Indicators assumes no responsibility or liability for any damages incurred directly or indirectly as a result of any data errors, omissions, or discrepancies. BOLTING Basics, Tips & Best Practices Table of Contents Introduction ................................................................................................................................................. 4 Part One: Basics of Specifying a Bolt Step One: Specifying the Basics of a Fastener .......................................................................................... 6 Selecting a Head Type .............................................................................................................................
    [Show full text]
  • Fasteners Set the Industry's Highest Standards for Design, Ease of Use, and Reliability
    Keeping your belt up and running SINCE 1907 HEAVY-DUTY MECHANICAL BELT FASTENING SYSTEMS A comprehensive line of mechanical belt fastening systems and belt conveyor maintenance tools that increase uptime and output. Around the world, the most respected name in belt conveyor solutions is Flexco. YOUR PARTNER IN The reason is simple. Flexco belt splicing products have earned the reputation for unsurpassed quality and performance in the most demanding material handling PRODUCTIVITY applications on earth. Our fasteners set the industry's highest standards for design, ease of use, and reliability. The knowledgeable advice and proven solutions we provide our customers help keep conveyor efficiency high and conveyor operation costs low. QUICK FACTS OVER 100 YEARS OF SUCCESS ABOUT FLEXCO • Flexco is a U.S.-based company and HAS BEEN BUILT has been in the belt industry since 1907. BY FOCUSING ON OUR • We have subsidiary locations in Australia, Chile, China, Germany, India, Mexico, Singapore, South Africa, and CUSTOMERS the United Kingdom to service and support customers in more than 150 countries around the world. We have learned to understand our customers' • We have more than 1800 distributor industries and challenges and to respond to their partners throughout the world—we changing needs. partner with the best distributors in We are constantly driving technology and design and every market we serve around the world to ensure our customers have strive to become the leader in belt conveyor solutions that ready access to our products, services, maximize uptime, productivity, and safety. and expert resources. We value industry relationships and believe that together, with a team of industry experts, our customers will • As a company, we focus on training and development and maintaining a receive greater value.
    [Show full text]
  • Fastener Identification Guide • 4.13 KM • Printed in the USA
    HEAD STYLES Hex Cap Screw Bugle Hex cap screws feature a washer face on the Button Washer bearing surface, a chamfered point, and tighter body tolerances than hex bolts. Pan Binding Undercut Hex Bolt Similar to hex cap screw, hex bolts do not require a washer face or a pointed end and have a greater tolerance range in the body. Round Head Fillister Socket Head Cap Screw Socket heads feature an internal hexagonal drive DRIVES socket and close tolerances for precision assembly. Flat 82° Cross Recess Button Head Socket Cap Screw Type I FASTENER (Phillips) Button heads feature a dome shaped head, though Flat 100° this feature reduces the tensile capacity. Cross Recess Flat Head Socket Cap Screw Type IA Flat heads feature an 82° countersunk head for Flat Undercut (Pozidriv®) IDENTIFICATION flush connections. Like the button heads, this feature reduces the tensile capacity. Cross Recess Type II (Frearson) Low Head Socket Cap Screw Indented Hex Low heads are similar to standard socket heads, but with a shorter head for applications where clearance Cross Recess Square GUIDE is an issue. This head configuration also reduces the Combo strength capacity. Indented Hex Washer (Quadrex®) NUTS Carriage Bolt A round head bolt with a square neck under the Slotted head. These must be tightened with a nut. Serrated Hex Finished Hex Nuts: Hex Coupling Nuts: Washer Hexagonal shaped nuts with internal screw Designed to join two externally threaded Plow Bolt threads. Finished hex nuts are one of the most objects, usually threaded rod, together. Combination Similar to a carriage bolt, these have a flat head common nuts used.
    [Show full text]
  • Threaded Fasteners
    Threaded Fasteners Introduction If you are designing and building a Formula SAE vehicle, threaded fasteners will likely be used to join the various components and systems together and allow the vehicle to function as a unified machine. The reliability of your vehicle is key to realize your potential at the competition. Even though threaded fasteners have been in use for hundreds of years and are in products that we use every day, their performance is dependent on a wide range of factors. This chapter covers some of the main factors that can influence reliability and is intended as an aid in joint design, fastener selection, and installation. The first portion of this chapter covers several design and installation factors that can work together to improve the reliability of your vehicle’s bolted joints. These topics include, the importance of generating and maintaining clamp load, and how clamp load, along with joint stiffness, can work together to prevent self-loosening and improve fatigue performance. The second portion of this chapter reviews how installation method and torque are related to clamp load, and also includes a comparison between common fastener types to aid in selection. The chapter concludes with a short tutorial showing how to obtain Mil Spec information on fasteners and similar hardware. Disclaimer – Multiple factors on each component in a bolted joint affect its performance. Additionally, service requirements for every joint differ. Each joint must be evaluated and tested for its ability to perform the desired function. The information in this chapter provides general background and does not represent how a specific design or piece of hardware will perform.
    [Show full text]
  • Inspection of Wooden Vessels
    Guidance on Inspection, Repair, and Maintenance of Wooden Hulls ENCLOSURE (1) TO NVIC 7-95 COMPILED BY THE JOINT INDUSTRY/COAST GUARD WOODEN BOAT INSPECTION WORKING GROUP August 1995 TABLE OF CONTENTS ACKNOWLEDGEMENTS A-1 LIST OF FIGURES F-1 GLOSSARY G-1 CHAPTER 1. DESIGN CONSIDERATIONS A. Introduction 1-1 B. Acceptable Classification Society Rules 1-1 C. Good Marine Practice 1-1 CHAPTER 2. PLAN SUBMITTAL GUIDE A. Introduction 2-1 B. Plan Review 2-1 C. Other Classification Society Rules and Standards 2-1 D. The Five Year Rule 2-1 CHAPTER 3. MATERIALS A. Shipbuilding Wood 3-1 B. Bending Woods 3-1 C. Plywood. 3-2 D. Wood Defects 3-3 E. Mechanical Fastenings; Materials 3-3 F. Screw Fastenings 3-4 G. Nail Fastenings 3-5 H. Boat Spikes and Drift Bolts 3-6 I. Bolting Groups 3-7 J. Adhesives 3-7 K. Wood Preservatives 3-8 CHAPTER 4. GUIDE TO INSPECTION A. General 4-1 B. What to Look For 4-1 C. Structural Problems 4-1 D. Condition of Vessel for Inspection 4-1 E. Visual Inspection 4-2 F. Inspection for Decay and Wood Borers 4-2 G. Corrosion & Cathodic Protection 4-6 H. Bonding Systems 4-10 I. Painting Galvanic Cells 4-11 J. Crevice Corrosion 4-12 K. Inspection of Fastenings 4-12 L. Inspection of Caulking 4-13 M. Inspection of Fittings 4-14 N. Hull Damage 4-15 O. Deficiencies 4-15 CHAPTER 5. REPAIRS A. General 5-1 B. Planking Repair and Notes on Joints in Fore and 5-1 Aft Planking C.
    [Show full text]
  • Mass Timber Connections
    WoodWorks Connection Design Workshop Bernhard Gafner, P.Eng, MIStructE, Dipl. Ing. FH/STV [email protected] Adam Gerber, M.A.Sc. [email protected] Disclaimer: This presentation was developed by a third party and is not funded by WoodWorks or the Softwood Lumber Board. “The Wood Products Council” This course is registered is a Registered Provider with with AIA CES for continuing The American Institute of professional education. As Architects Continuing such, it does not include Education Systems (AIA/CES), content that may be Provider #G516. deemed or construed to be an approval or endorsement by the AIA of any material of Credit(s) earned on construction or any method completion of this course will or manner of handling, be reported to AIA CES for using, distributing, or AIA members. Certificates of dealing in any material or Completion for both AIA product. members and non-AIA __________________________________ members are available upon Questions related to specific materials, methods, and services will be addressed request. at the conclusion of this presentation. Description For engineers new to mass timber design, connections can pose a particular challenge. This course focuses on connection design principles and analysis techniques unique to mass timber products such as cross-laminated timber, glued-laminated timber and nail-laminated timber. The session will focus on design options for connection solutions ranging from commodity fasteners, pre- engineered wood products and custom-designed connections. Discussion will also include a review of timber mechanics and load transfer, as well as considerations such as tolerances, fabrication, durability, fire and shrinkage that are relevant to structural design.
    [Show full text]
  • Woodworking Joints.Key
    Woodworking making joints Using Joints Basic Butt Joint The butt joint is the most basic woodworking joint. Commonly used when framing walls in conventional, stick-framed homes, this joint relies on mechanical fasteners to hold the two pieces of stock in place. Learn how to build a proper butt joint, and when to use it on your woodworking projects. Basic Butt Joint The simplest of joints is a butt joint - so called because one piece of stock is butted up against another, then fixed in place, most commonly with nails or screws. The addition of glue will add some strength, but the joint relies primarily upon its mechanical fixings. ! These joints can be used in making simple boxes or frames, providing that there will not be too much stress on the joint, or that the materials used will take nails or screws reliably. Butt joints are probably strongest when fixed using glued dowels. Mitered Butt Joint ! A mitered butt joint is basically the same as a basic butt joint, except that the two boards are joined at an angle (instead of square to one another). The advantage is that the mitered butt joint will not show any end grain, and as such is a bit more aesthetically pleasing. Learn how to create a clean mitered butt joint. Mitered Butt Joint The simplest joint that requires any form of cutting is a miter joint - in effect this is an angled butt joint, usually relying on glue alone to construct it. It requires accurate 45° cutting, however, if the perfect 90° corner is to result.
    [Show full text]
  • Teaching with Midwest's Boomilever
    Teaching with Midwest’s Boomilever 1st Edition A “Hands-On” Laboratory Adaptable to Grades 6 - 12 Written by Bob Monetza Introduction This Teacher’s Guide is designed to introduce model building of cantilevered structures to teach principles of physics and engineering design in hands-on exercises, culminating in a classroom competition of creative design. The Boomilever project is based on a competitive Science Olympiad event. The information and materials presented with this kit are similar to the “Boomilever” event in the Science Olympiad competition program and may be a used as a starting point to prepare students to develop competitive structures. Note that rules published by Science Olympiad or any other organization are not reproduced here and are subject to change. Rules presented in this Guide do not substitute for official rules at sanctioned competitions; check the rules in use at formal competitions for differences. Midwest Products Co., Inc. grants permission for any reproduction or duplication of this manual for teacher and student use, but not for sale. ©2007, Midwest Products Co., Inc. 400 S. Indiana St. | PO Box 564 | Hobart, IN 46342 | (800) 348-3497 www.midwestproducts.com -- Table of Contents . Introduction .............................................................................................................................. 3 - 5 2. Construction of an Example Boomilever ................................................................................... 6 - 20 2. Problem Statement 2.2 Example Design and Construction: 2.2.. Materials and Tools 2.2.2. Step-by Step Construction Instructions 2.3 Testing 2.4 Evaluation 3. Boomilever Design Notes ........................................................................................................ 2 - 33 3. Compression Boomilever Design 3.2 Tension Boomilever Design 3.3 Attachment Base 3.4 Joint Design 3.5 Materials 3.5. Wood 3.5.2 Glue 3.6 Craftsmanship 3.7 Data Collection 3.8 Construction Jig 4.
    [Show full text]
  • Fastener Guide
    Experts in supplying Vendor Managed fasteners and industrial Inventory Programs products to manufacturers and sub-contract On-Site Parts assemblers. Kitting Department 763.535.0400 763.535.0400 Table of Contents Standard Fasteners.................................................................. 3 Hex Bolt Sizes and Thread Pitches Size Chart.............................................................. 4 Standard US Machine Screw Size Chart....................................................................... 7 Sheet Metal Screw Size Chart....................................................................................... 8 Shoulder Bolt Size Chart................................................................................................ 9 Socket Button Head Size Chart.................................................................................... 11 Socket Cap Size Chart................................................................................................. 12 Socket Flat Head Size Chart........................................................................................ 15 US Nuts Size Chart...................................................................................................... 17 SAE Flat Washer Size Chart........................................................................................ 20 USS Flat Washer Size Chart........................................................................................ 21 Screw Eye Size Chart.................................................................................................
    [Show full text]
  • Introduction to Carpentry Tools and Joints
    INTRODUCTION TO CARPENTRY TOOLS 1. Try Square 2. Steel Rule 3. Marking Guage 4. Coping Saw 5. Tenon Saw 6. Penon Saw 7. Ironjack Plane 8. Benchwise 1. Try Square This is used to mark lines at 90 degrees to a straight edge. It is used to mark out lines square to the face edge and face side. It may also be used to check if edges are straight. If the try square is placed on the edge of the material and held up to a light, any light shining through between the material and the try square blade indicates that the edge of the material is not straight. 2. Steel Rule A steel rule is a very accurate marking and measuring tool. The steel is thin and the markings on the rule are very fine. The measurements are in millimetres on one edge and inches on the other. The steel rule can also be used as a straight edge to check if materials or edges of materials are straight. The measurements on the steel rule go all the way to the end unlike the plastic ruler. This is because the rule may be used to measure inside pipes. It may also be used to measure diameters and circumferences of pipes and tubes accurately. The end of the rule with the measurements to the edge is called the zero end. By: Harish Gupta Page 1 3. Marking Guage The marking gauge is used on wood.It is used to mark straight lines parallel to a straight edge.The marking tool has an adjustable stock (the stock slides up and down the stem) and is set using a steel rule.
    [Show full text]
  • Basic Box Making
    W ENJOY THIS SELECTION FROM Basic Box Making taunton’s Basic Box Making D o u g S t o w e To purchase Basic Box Making, make your selection now: • ebook version • traditional version BUY NOW! BUY NOW! A Lap-Cornered Box HE BOX SEEN HERE is built with quilted maple sides and a spalted maple Tlift lid. While making this box, you can choose your degree of involve- ment with handtools: The joints can be cut primarily with the table- saw then simply cleaned up with a chisel, or you can go to the other extreme and cut the joints entirely by hand using a Japanese dozuki saw or backsaw. Either technique or a combination thereof can be used to build an attractive box and record your emergence as a true craftsman. I particularly like boxes where the joinery is exposed so that you can tell exactly how the design is held together. With this design, even a quick glance at a distance allows the viewer to say, “I get it. I see how that works.” With this basic design, you can choose from an infinite range of variables to express your own creativity (see “Design Options” on p. 94). 80 A lap-cornered box 1 4 in. 5 1 Cutting the exposed join- 9 ⁄ ⁄2 in. ery on this lap-cornered design is a good way to hone and showcase 5⁄8 in. your handtool skills. The box seen here features quilted maple sides and a spalted maple top. 31⁄2 in. 5 1 1 ⁄2 ⁄2 in.
    [Show full text]