Understanding Aircraft Structures John Cutler Fourth Edition revised by Jeremy Liber © John Cutler 1981,1992,1999 © John Cutler and Jeremy Liber 2005 Editorial offices: Blackwell Publishing Ltd,9600 Garsington Road,Oxford OX4 2DQ,UK Tel:+44 (0)1865 776868 Blackwell Publishing Inc.,350 Main Street,Malden,MA 02148-5020,USA Tel:+1 781 388 8250 Blackwell Publishing Asia Pty Ltd,550 Swanston Street,Carlton,Victoria 3053,Australia Tel:+61 (0)3 8359 1011 The right of the Author to be identified as the Author of this Work has been asserted in accordance with the Copyright,Designs and Patents Act 1988. All rights reserved.No part of this publication may be reproduced,stored in a retrieval system,or transmitted,in any form or by any means,electronic,mechanical,photocopying,recording or otherwise,except as permitted by the UK Copyright,Designs and Patents Act 1988,without the prior permission of the publisher. First published in Great Britain by Granada Publishing 1981 Second edition published by Blackwell Scientific Publications 1992 Third edition published by Blackwell Science Ltd 1999 Fourth edition published by Blackwell Publishing Ltd 2005 ISBN-10:1-4051-2032-0 ISBN-13:978-1-4051-2032-6 Library of Congress Cataloging-in-Publication Data Cutler,John. Understanding aircraft structures / John Cutler.–4th ed./rev.by Jeremy Liber. p. cm. Includes bibliographical references. ISBN-13:978-1-4051-2032-6 (alk.paper) ISBN-10:1-4051-2032-0 (alk.paper) 1. Airframes. I. Liber,Jeremy. II. Title. TL671.6.C88 2005 629.134¢31–dc22 2005048077 A catalogue record for this title is available from the British Library Set in 10 on 12 pt Times by SNP Best-set Typesetter Ltd.,Hong Kong Printed and bound in India by Replika Press Pvt Ltd,Kundli The publisher’s policy is to use permanent paper from mills that operate a sustainable forestry policy, and which has been manufactured from pulp processed using acid-free and elementary chlorine-free practices.Furthermore,the publisher ensures that the text paper and cover board used have met acceptable environmental accreditation standards. For further information on Blackwell Publishing,visit our website: www.blackwellpublishing.com Preface The fourth edition of Understanding Aircraft Structures builds,naturally enough,on the firm foundations of the earlier editions in aiming to keep up to date with an evolving industry.Whilst the fundamentals of how air- craft are constructed change only relatively slowly, the aerospace world as a whole tends to change at a more noticeable pace and many of these changes impinge upon the realm of aircraft structures.The major change since publication of the last edition has been in the regulatory environ- ment:all of the national European aviation regulators have been subor- dinated beneath a new European Union body, the European Aviation Safety Agency (EASA).This change is reflected in the chapter describing how to apply for approval of an aircraft modification and, to a lesser extent,in the section on quality and airworthiness. The broad range of subjects which support,and interact with,the work of the aircraft structures designer is covered in greater detail than before and the opportunity has been taken to provide a ‘round up’ of the key points at the end of each chapter.In their own studies the authors have found that this kind of review at the end of a chapter greatly helps the learning process. Finally,in recent years we have seen the European Airbus organisation surpass the great Boeing Company in terms of numbers of aircraft sold. However,the American aircraft industry remains the dominant force in the world of aviation.Its influence is such that,probably,the majority of the industry continues to work in imperial rather than SI units.For this reason,and after much soul-searching,it has been decided to retain both imperial and SI units in this book. Contents Preface ix Chapter 1 Introduction 1 Chapter 2 History 3 2.1 Outline 3 2.2 Wire-braced structures 4 2.3 Semi-monocoque structures 9 2.4 Sandwich structures 14 2.5 Review of the key points 15 Chapter 3 Parts of the Aircraft 29 3.1 Terms connected with flight 29 3.2 Terms connected with control 31 3.3 Terms connected with high-lift devices 32 3.4 Terms associated with the shape and dimensions of the aircraft 32 3.5 Review of the key points 37 Chapter 4 Loads on the Aircraft 38 4.1 General flight forces 38 4.2 Acceleration loads 44 4.3 Further aerodynamic loads 48 4.4 Other loads 50 4.5 Further load factors 51 4.6 Loads acting on the whole aircraft 53 4.7 Review of the key points 55 4.8 References 56 Chapter 5 The Form of Structures 57 5.1 Structure relative to aircraft design 57 5.2 Historic form of structure 57 5.3 General form of structure 59 5.4 The basic load systems in structures 59 5.5 The forms of stress in materials 63 5.6 Bending and torsion 72 5.7 Compression 85 vi Contents 5.8 The whole structure 87 5.9 Review of the key points 87 5.10 References 88 Chapter 6 Materials 89 6.1 Choice of materials 89 6.2 Material properties 92 6.3 Smart structures (and materials) 101 6.4 Cost as a property of a material 103 6.5 Heat treatment 105 6.6 Reference number for materials 106 6.7 Review of the key points 109 6.8 References 110 Chapter 7 Processes 112 7.1 Introduction 112 7.2 Manufacturing 112 7.3 Jointing 119 7.4 Review of the key points 123 7.5 References 123 Chapter 8 Corrosion and Protective Treatments 124 8.1 Nature of corrosion 124 8.2 Causes of corrosion 126 8.3 Protection against corrosion 128 8.4 Review of the key points 132 8.5 Reference 132 Chapter 9 Detail Design 133 9.1 Sheet-metal components 133 9.2 Machined components and large forgings 136 9.3 Notching and stress raisers 139 9.4 Rivets and bolts 144 9.5 Joggling 152 9.6 Clips or cleats 154 9.7 Stringer/frame intersections 155 9.8 Lugs 156 9.9 The ‘stiff path’ 157 9.10 Review of the key points 157 Chapter 10 Composite Materials in Aircraft Structures 159 10.1 What are composites? 159 10.2 The strength of composite materials 161 10.3 Types of structures 162 10.4 Joining composites 164 10.5 Fibres 167 10.6 Resins 169 10.7 Working safely with composites 171 10.8 Review of the key points 172 Contents vii Chapter 11 Quality and Airworthiness 173 11.1 Quality assurance and quality control 173 11.2 Control 174 11.3 Procedures and systems 175 11.4 Further notes on quality control functions 177 11.5 Airworthiness engineering 179 11.6 Continued airworthiness 180 11.7 Review of the key points 181 11.8 References 181 Chapter 12 Stressing 182 12.1 Introduction 182 12.2 The stressman’s work 183 12.3 Stressing methods 187 12.4 Stress reports 190 12.5 Review of the key points 193 12.6 References 194 Chapter 13 Presentation of Modifications and Repairs 195 13.1 Definitions 195 13.2 The essential paperwork associated with modifications 197 13.3 Review of the key points 201 13.4 Conclusion 201 13.5 References 202 Appendices 203 Index 209 Chapter 1 Introduction The aim of this book is to present the principles of aircraft structures to the interested reader in a manner that is both clear and thorough whilst avoiding the necessity for complex mathematical formulae.No previous knowledge of the field is assumed,only the desire to know more. Like most industries, aviation has various specialist fields which are often considered to be ‘black arts’ by the uninitiated;the work of the air- craft structures analyst,or stressman,falls into this category.However,as with most disciplines,given a little curiosity and some application the basic principles may be easily understood,at which point much of the mystery disappears. There are many people involved in the engineering side of the aircraft industry,such as draughtsmen,fitters or licensed engineers,who deal with aircraft structures in their daily lives, yet may have only an incomplete understanding of why aircraft are designed as they are.For those people, and others with enquiring minds, reading this book will not make them stressmen.It will,however,give them a qualitative understanding of the general principles of aircraft structures, allowing them to ask informed questions. The book is written in such a way that individual chapters may be read independently of each other if a topic is of particular interest to the reader. However, taken together they provide a logical progression and offer a thorough introduction to the subject. The book begins by giving an historical perspective,presenting a brief outline of the evolution of aircraft structures from the earliest flying machines to the present day.The one major change in philosophy made by aircraft structures designers is described.After this the basic shape and main structural elements of the aeroplane are defined,whilst introducing the fundamental reason why an aircraft requires a structure at all;that is to support the various loads applied to it.Subsequent chapters explain the form which that structure takes in order to efficiently carry those loads, the materials that are employed to make it and the processes involved in its construction.There follows an introduction to the principles of corro- sion protection and there is a distillation of much ‘rule of thumb’ and ‘good engineering practice’ so essential to the sound detail design of air- craft structures.The regulatory and quality environment within which the 2 Understanding Aircraft Structures aviation industry functions is outlined.Later chapters allow an insight into the work of the stressman and describe,in broad terms,the justification and documentation necessary to gain approval for aircraft modifications. For anybody intending to become an aircraft structures specialist (stressman)Understanding Aircraft Structureswill provide a firm founda- tion upon which to build and will provide explanations of phenomena which may not be easily found in more formal textbooks.Those who are simply looking for a broad appreciation of the subject will also find all that they require in this book. Chapter 2 History 2.1 Outline In this chapter we will book at the general development of aircraft struc- tures over the short period of their history.As with most subjects,knowl- edge of the steps which led to the present position is a great help in understanding current problems;later in the book there are more detailed comments concerning structures as they are now. Flying machines obviously changed enormously over the 70 years from the Wright Brothers Flyer at Kittyhawk to Apollo on the Moon, and a fighter ace of 1918 flew a very different aircraft from that flown by his suc- cessor today,so a review of the whole development of flying would be a large task. However, there are many different branches of science and engineering which make up aeronautics as a whole and when these are looked at separately, the problem of dealing with them becomes more manageable. The main divisions of aeronautical engineering are (a) the science, which deals with the airflow round the aircraft;(b) the power-plant engi- neering;(c) the avionics,that is the radios and navigation aids;(d) the air- frame engineering, where the airframe includes hydraulic and electrical systems,flying and engine controls,interior furnishings and cargo systems; and (e) the section which concerns this book,which is the structure.All these divisions and subdivisions have developed at different rates.Power plants (engines) for instance have moved with two great strides,and many years of continuing short but rapid steps. Before the Wright Brothers could make their first successful aeroplane,the power plant engineers had to make their first stride and invent an engine which was light and pow- erful.The next stride was the invention of the jet engine but,in between, the power of piston engines increased nearly 200 times in just 40 years, from 12hp (horse power) to over 2000hp,with only a ten times increase of weight.As we shall see,structures have made only one major funda- mental jump forward,but that was sufficient to change the whole charac- ter and appearance of aircraft. 4 Understanding Aircraft Structures 2.2 Wire-braced structures If we look at the aircraft in Fig.2.1 we can have no doubt about the form of its construction.The wings and the fore and aft structures carrying the other covered surfaces were all made of rectangular frames which were prevented from collapsing (or parallelogramming) by wires stretched from corner to corner.Although the methods were not original,there were two imaginative pieces of structural thinking here. Firstly, the idea that two wings,one above the other,would make a lighter,stronger structure than the type of wing arrangement suggested by bird flight and,secondly, the idea that a rectangle could be held in shape with two light wires rather than with one much heavier diagonal member,like the structure of a farm gate.At this stage,and for the next 30 years,the major structural material was wood;at first bamboo and later mainly spruce,a lightweight timber with very straight grain and medium strength. Strangely enough, balsa wood,which means so much to the model aircraft enthusiast,was not used during this period but has been used sometimes since then as a filler,or core material,in flooring panels for large aircraft.Wire bracing continued to be used as a major feature of aircraft construction for many years. Figures 2.2 and 2.3 illustrate its extensive use on early fighters and Fig.2.4 shows it still in evidence into the era of metal aircraft. (Note: these particular aircraft are illustrated as they show a progression of designs for the same manufacturer:Sopwith Aviation Co.,which became Hawker in 1920.) 2.2.1 Biplane structures Biplane structures (Figs 2.1–2.3) dominated aircraft design for many years and,for certain particular requirements,such as aerobatic aircraft or agri- cultural crop sprayers,they still appear from time to time.The structural advantage of the arrangement is that the combination of upper and lower wing, the interplane vertical members (struts) and the wire bracing forms a deep,light member which is very rigid and resistant to bending and twisting. 2.2.2 The change to metal construction The biplane era lasted until the middle of the 1930s,by which time wooden construction was being replaced by metal.The similarity of construction between the biplanes in Figs 2.2 and 2.3 is obvious but the main fuselage members of the later aircraft are steel tubes, as are the wing spars. Although wood was still being used very extensively at the time of the Hawker Fury, by the time that the Hurricane was produced (see Fig. 2.4(a)),the change to metal was almost complete.In spite of this change, the structures were still wire braced, and the principles of structural thinking behind the Sopwith Camel of 1917 and the Hurricane of 1935 showed some distinct similarities.Although the structures designer had