About the Authors Omri Rand is a Professor of Aerospace Engineering at the Technion – Israel Institute of Technology. He has been involved in research on theoretical modeling and analysis in the area of anisotropic elasticity for the last fifteen years, he is the author of many journal papers and conference presentations in this area. Dr. Rand has been extensively active in composite rotor blade analysis, and established many well recognized analytical and numerical approaches. He teaches graduate courses in the area of anisotropic elasticity, serves as the Editor-in-Chief of Science and Engineering of Composite Materials,as a reviewer for leading professional journals, and as a consultant to various research and development organizations. Vladimir Rovenski is a Professor of Mathematics and a well known researcher in the area of Riemannian and computational geometry. He is a corresponding member of the Natural Science Academy of Russia, a member of the American Mathematical Society, and serves as a reviewer of Zentralblatt für Mathematik. He is the author of many journal papers and books, including Foliations on Riemannian Manifolds and Submanifolds (Birkhäuser, 1997), and Geometry of Curves and Surfaces with MAPLE (Birkhäuser, 2000). Since 1999, Dr. Rovenski has been a senior scientist at the faculty of Aerospace Engineering at the Technion – Israel Institute of Technology, and a lecturer at Haifa University. Omri Rand Vladimir Rovenski Analytical Methods in Anisotropic Elasticity with Symbolic Computational Tools Birkha¨user Boston • Basel • Berlin OmriRand VladimirRovenski Technion—IsraelInstituteofTechnology Technion—IsraelInstituteofTechnology FacultyofAerospaceEngineering FacultyofAerospaceEngineering Haifa32000 Haifa32000 Israel Israel AMSSubjectClassifications:74E10,74Bxx,74Sxx,65C20,65Z05,68W30,74-XX,74A10,74A40,74Axx,74Fxx, 74Gxx,74H10,74Kxx,74N15,68W05,65Nxx,35J55(Primary);74-01,74-04,65-XX,68Uxx,68-XX(Secondary) LibraryofCongressCataloging-in-PublicationData Rand,Omri. Analyticalmethodsinanisotropicelasticity:withsymboliccomputationaltools/Omri Rand,VladimirRovenski. p.cm. Includesbibliographicalreferencesandindex. ISBN0-8176-4372-2(alk.paper) 1.Elasticity.2.Anisotropy.3.Anisotropy—Mathematicalmodels.4.Inhomogeneous materials.I.Rovenskii,VladimirY,1953-II.Title QA931.R362004 (cid:1) 531.382–dc22 2004054558 ISBN-100-8176-4272-2 Printedonacid-freepaper. 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(HP) 987654321 SPIN10855936 www.birkhauser.com Tomyfamily, Ora, Shahar, Taland Boaz, OmriRand Tomyteacher, ProfessorVictorToponogov, VladimirRovenski Preface Priortothecomputerera,analyticalmethodsinelasticityhadalreadybeendevelopedandim- proveduptoimpressivelevels.Relevantmathematicaltechniqueswereextensivelyexploited, contributingsignificantlytotheunderstandingofphysicalphenomena.Inrecentdecades,nu- merical computerized techniques have been refined and modernized, and have reached high levelsofcapabilities,standardizationandautomation.Thistrend,accompaniedbyconvenient andhighresolutiongraphicalvisualizationcapability,hasmadeanalyticalmethodslessattrac- tive,andtheamountofeffortdevotedtothemhasbecomesubstantiallysmaller.Yet,withsome tenacity,thetremendousadvancesincomputerizedtoolshaveyieldedvariousmatureprograms forsymbolicmanipulation.Suchtoolshaverevivedmanyabandonedanalyticalmethodologies byeasingthetediouseffortthatwaspreviouslyrequired,andbyprovidingadditionalcapabil- itiestoperformcomplexderivationprocessesthatwereonceconsideredimpractical. Generallyspeaking,itiswellrecognizedthatanalyticalsolutionsshouldbeappliedtorela- tivelysimpleproblems,whilenumericaltechniquesmayhandlemorecomplexcases.However, itisalsoagreedthatanalyticalsolutionsprovidebetterinsightandimprovedunderstandingof theinvolvedphysicalphenomena,andenableaclearrepresentationoftheroletakenbyeachof theproblemparameters.Nowadays,analyticalandnumericalmethodsareconsideredascom- plementary: that is, while analytical methods provide the required understanding, numerical solutionsprovideaccuracyandthecapabilitytodealwithcaseswherethegeometryandother characteristicsimposerelativelycomplexsolutions. Nevertheless,fromapracticalpointofview,analyticsolutionsarestillconsideredas“art”, whilenumericalcodes(suchascodesthatarebasedonthefinite-elementmethod)seemtooffer a“straightforward”solutionforanytypeandgeometryofanewproblem.Oneofthereasons forthisviewemergesfromthevarietyoftechniquesthatareusedforanalyticalsolutions.For example,onehastheoptiontoselecteitherthedeformationfieldorthestressfieldtoconstruct theinitialsolutionhypothesis,or,onehastheoptiontoformulatethegoverningequationsusing differential equilibrium, or by employing more integral energy methodologies for the same task.Hence, themainobstacletousinganalytical approaches seemstobethefactthatmany researchersandengineerstendtobelievethat,asfarasanalyticsolutionsareconsidered,each problem is associated with a specific solution type and that adifferent solution methodology hastobetailoredforeverynewproblem. In light of the above, the objective of this book is twofold. First, it brings together and refreshes the fundamentals of anisotropic elasticity and reviews various mathematical tools and analytical solution trails that are encountered in this area. Then, it presents a collection viii Preface of classical and advanced problems in anisotropic elasticity that encompasses various two- dimensional problems and different types of three-dimensional beam models. The book in- cludesmodelsofvariousmathematicalcomplexityandphysicalaccuracylevels,andprovides thetheoreticalbackgroundforcompositematerialanalysis.Oneofthemostadvancedformu- lationspresentedisacompleteanalyticalmodelandsolutionschemeforanarbitrarilyloaded non-homogeneousbeamstructureofgenericanisotropy. All classic and modern analytic solutions are derived using symbolic computational tech- niques. Emphasis is put on the basic principles of the analytic approach (problem statement, settingofsimplifyingassumptions,satisfyingthefieldandboundaryconditions,proofofsolu- tion,etc.),andtheirimplementationusingsymboliccomputationaltools,sothatthereaderwill beabletoemploytherelevantapproachtonewproblemsthatfrequentlyarise.Discussionsare devotedtothephysicalinterpretationofthepresentedmathematicalsolutions. From a format point of view, the book provides the background and mathematical formu- lation for each problem or topic. The main steps of the analytical solution and the graphical resultsarediscussedaswell,whilethecompletesystemofsymboliccodes(writteninMaple) areavailableontheencloseddisc. A unique characteristic of this book is the fact that the entire analytical derivation and all solution expressions are symbolically proved by suitable (computerized) codes. Hence, the chancefor(human)errorortypographicalmistakeiseliminated.Thesymbolicworksheetsare therefore absolute and firm testimony to the exactness of the presented expressions. For that reason, the specific solutions included in the text should be viewed as illustrative examples only,whilethesolutionexactnessanditsgenericapplicabilityareprovedsymbolicallyinthe mostgenericmanner. Thebookisaimedatgraduateandseniorundergraduatestudents,professors,engineers,ap- pliedmathematicians,numericalanalysisexperts,mechanicsresearchersandcompositemate- rialsscientists. Chapterdescription: Thefirstpartofthebook(Chapters1–4)containsthefundamentalsofanisotropicelasticity. Thesecondpart(Chapters5–10)isdevotedtovariousbeamanalysesandcontainsrecentand advancedmodelsdevelopedbytheauthors. Chapter1addressesfundamentalissuesofanisotropicelasticityandanalyticalmethodolo- gies.Itprovidesareviewofdeformationmeasuresandstrainingenericorthogonalcurvilinear coordinates, and reaches the complete nonlinear compatibility equations in such systems. It then introduces fundamental stress measures and the associated equilibrium equations. Later on,energytheoremsandvariationalanalysesarederived,followedbyageneraldiscussionof analyticalmethodologiesandtypicalsolutiontrails. Chapter2reviewsthemathematicalrepresentationofgeneralanisotropicmaterials,includ- ingthespecialcasesofMonoclinic,Orthotropic,Tetragonal,TransverselyIsotropic,Cubicand Isotropicmaterials.Later,transformationsbetweencoordinatesystemsofthecomplianceand stiffnessmatrices(ortensors)arepresented.Thechapteralsoaddressesissuessuchasplanes ofelasticsymmetry,principaldirectionsofanisotropyandnon-Cartesiananisotropy. Chapter 3 defines two-dimensional homogeneous and non-homogeneous domain topolo- gies,andpresentsvariousplanedeformationproblemsandanalyses,includingdetailedformu- lationofplane-strain/stressandplane-shearstates.Thederivationyieldsformaldefinitionsof generalizedNeumann/Dirichletandbiharmonicboundaryvalueproblems(BVPs).Thechapter Preface ix alsoaddressesCoupled-PlaneBVPformaterialsofgeneralanisotropy.Alongthesamelines, theclassicalanisotropiclaminatedplatetheoryisthenpresented. Chapter4presentsvarioussolutionmethodologiesfortheBVPsderivedinChapter3,and establishes solution schemes that facilitate applications presented later on. Explicit analytic expressionsforlow-orderexact/conditionalpolynomialsolutions,andapproximatehigh-order polynomialsolutionsinahomogeneoussimplyconnecteddomainarederivedandillustrated. A formulation based on complex potentials is also thoroughly derived and demonstrated by Fourierseriessolutions. Chapter5reviewssomebasicaspectsandgeneraldefinitionsofanisotropicbeamanalysis, approximate analysis techniques and relevant literature. It discusses the associated coupling characteristicsatboththematerialandstructurallevels. Chapter6presentsananalysisofgeneralanisotropicbeamsthatmaybeviewedasalevel- based extension of the classical Lekhnitskii formulation, and is capable of handling beams ofgeneralanisotropyandcross-sectiongeometrythatundergogenericdistributionofsurface, body-forceandtiploading.ThederivationisfoundedontheBVPsdeducedinChapter3,and despite its complexity, it provides a clear insight into the associated structural behavior and couplingmechanisms. Chapter 7 contains a closed-form formulation for uncoupled monoclinic homogeneous beams.Itfirstpresentssolutionsfortiploads,andthenagenericformulationforaxiallynon- uniform distribution of surface and body loads. Later on, analysis and examples of beams of cylindricalanisotropyarepresented. TheentirereasoningoftheapproachinthischapterisfoundedonSt.Venant’ssemi-inverse method of solution and may be considered as dual (though less generic) to the method pre- sentedinChapter6. Chapter 8 is focused on problems in various non-homogeneous domains. It first reviews generic formulations of plane BVPs, and then extends the analysis of Chapter 7 to the case ofmonoclinicnon-homogeneousbeamsundertiploading,whichisfoundedonextendingthe classicaldefinitionoftheauxiliaryproblemsofplanedeformationtotheanisotropiccase.The discussionencompassesthedeterminationoftheprincipalaxisofextension,principalplanes of bending and shear center. The chapter also presents a generalization of the derivation in Chapter7tothecaseofuncouplednon-homogeneousbeamsthatundergogenericdistributed loading. Chapter9discussescoupledsolidmonoclinicbeams.Theanalysispresentsanapproximate modelthatprovidesinsightintoandfundamentalunderstandingofthecouplingmechanisms withinanisotropicbeamsatthestructurallevel.Themodelalsosuppliesasimplifiedbutrela- tivelyaccuratetoolforquantitativeestimationofcoupledbeambehavior. Inaddition, the chapter presents anexact, level-based solutionscheme forcoupled beams. The derivation employs a series of properly interconnected solution levels and reaches the exactsolutioninaniterativemanner. Chapter10 handlescoupledthin-wallmonoclinicbeamsinasimilar(approximate)manner to Chapter 9. The analysis encompasses beams having either multiply connected domain (“closed”)orsimplyconnecteddomain(“open”)cross-sections. Chapter11presentsinstructionsforthesymbolicandillustrativeprogramsincludedinthis book(implementedinMaple). x Preface GeneralStyleClarificationNotes: (cid:1) (1) As a general rule, we use a “tilde” (e.g. A), for “temporary” variables that have no meaningfulrole,andareintroducedforthesakeofclarificationandanalyticconvenience.Such variablesarevalid“locally”withintheimmediateparagraphsinwhichtheyappearin.Hence, ifsuchanotationisrepeatedelsewhere,itstandsforadifferent“local”meaning;likewise,the superscript()(cid:1)mayhavedifferentmeaningsinvariouscontexts. (2) Duetothedependencyofmostinvolvedfunctionsonmanyparameters,bothordinary andpartialderivatives,sayd()/dαor∂()/∂α,areabbreviatedas(),α.Similarly,d2()/dα2 or∂2()/∂α2,areabbreviatedas(),αα. (3) Integralsappearinashortnotationbyomittingtheexplicitindicationoftheintegration variables.Twoexamplesareanintegrationalongaclosedloopwithacircumferentialcoordi- (cid:2) (cid:2) (cid:1) (cid:1) nate,s,i.e., Fds,whichiswrittensimplyas F,andtheareaintegrationinthexy-plane, (cid:3)(cid:3) ∂Ω (cid:3)(cid:3) ∂Ω (cid:1) (cid:1) i.e., Fdxdy,whichiswrittenas F. Ω Ω (4) Within the equation notation, e.g. (1.3), the first digits stand for the chapter in which it appears, while (1.15a) is an example for an equation in a group of (sub-)equations. By a notationlike(1.9a:b)werefertothesecondequationofagroupofequations thatappearsin onelinethatiscollectivelydenoted(1.9a). (5) WithintheSection,Program,Remark,Example, FigureandTablenotation,e.g.S.1.2, P.1.2, Remark 1.2, Example 1.2, Fig. 1.2, Table 1.2, the first digit stands for the chapter in whichitappears. Acknowledgements We wish to acknowledge the great help of Dr. Michael Kazar (Kezerashvili) who had a unique role in exposing us to some great contributions to this science made by the Eastern academiadiscussedinChapters7,8. WearealsothankfultothePh.D.studentMichaelGrebshteinwhomadeatremendouscon- tributiontotherigor,theanalyticaluniformityandthesymbolicverificationofthederivation inChapters4,7,8. WewarmlythankAnnKostant,ExecutiveEditorofMathematicsandPhysicsatBirkha¨user Boston,forhersupportduringthepublishingprocess. OmriRand VladimirRovenski Haifa,Israel