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Mathematical and Computational Analyses of Cracking Formation: Fracture Morphology and Its Evolution in Engineering Materials and Structures PDF

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Mathematics for Industry 2 Yoichi Sumi Mathematical and Computational Analyses of Cracking Formation Fracture Morphology and Its Evolution in Engineering Materials and Structures Mathematics for Industry Volume 2 Forfurthervolumes: http://www.springer.com/series/13254 EditorinChief MasatoWakayama(KyushuUniversity,Japan) Scientific Board Members RobertS.Anderssen(CommonwealthScientificandIndustrialResearch Organisation,Australia) PhilipBroadbridge(LaTrobeUniversity,Australia) JinCheng(FudanUniversity,China) MoniqueChyba(UniversityofHawai‘iatMaNnoa,USA) Georges-HenriCottet(JosephFourierUniversity,France) JoséAlbertoCuminato(UniversityofSãoPaulo,Brazil) Shin-IchiroEi(HokkaidoUniversity,Japan) YasuhideFukumoto(KyushuUniversity,Japan) JonathanR.M.Hosking(IBMT.J.WatsonResearchCenter,USA) AlejandroJofré(UniversityofChile,Chile) KerryLandman(TheUniversityofMelbourne,Australia) RobertMcKibbin(MasseyUniversity,NewZealand) GeoffMercer(AustralianNationalUniversity,Australia)(Deceased,2014) JillPipher(BrownUniversity,USA) KonradPolthier(FreeUniversityofBerlin,Germany) W.H.A.Schilders(EindhovenUniversityofTechnology,TheNetherlands) ZuoweiShen(NationalUniversityofSingapore,Singapore) Kim-ChuanToh(NationalUniversityofSingapore,Singapore) NakahiroYoshida(TheUniversityofTokyo,Japan) Aims& Scope The meaning of “Mathematics for Industry” (sometimes abbreviated as MI or MfI) is differentfromthatof“MathematicsinIndustry”(orof“IndustrialMathematics”).Thelatter is restrictive: it tends to be identified with the actual mathematics that specifically arises in the daily management and operation of manufacturing. The former, however, denotes a new research field in mathematics that may serve as a foundation for creating future technologies. This concept was born from the integration and reorganization of pure and appliedmathematicsinthepresentdayintoafluidandversatileformcapableofstimulating awarenessoftheimportanceofmathematicsinindustry,aswellasrespondingtotheneeds of industrial technologies. The history of this integration and reorganization indicates that thisbasicideawillsomedayfindincreasingutility.Mathematicscanbeakeytechnologyin modernsociety. The series aims to promote this trend by (1) providing comprehensive content on applicationsofmathematics,especiallytoindustrytechnologiesviavarioustypesofscientific research,(2)introducingbasic,useful,necessaryandcrucialknowledgeforseveralapplica- tionsthroughconcretesubjects,and(3)introducingnewresearchresultsanddevelopments for applications of mathematics in the real world. These points may provide the basis for opening a new mathematics-oriented technological world and even new research fields of mathematics. Yoichi Sumi Mathematical and Computational Analyses of Cracking Formation Fracture Morphology and Its Evolution in Engineering Materials and Structures 123 YoichiSumi SystemsDesignforOcean-Space YokohamaNationalUniversity Yokohama,Japan ISSN2198-350X ISSN2198-3518(electronic) ISBN978-4-431-54934-5 ISBN978-4-431-54935-2(eBook) DOI10.1007/978-4-431-54935-2 SpringerTokyoHeidelbergNewYorkDordrechtLondon LibraryofCongressControlNumber:2014935235 ©SpringerJapan2014 Thisworkissubjecttocopyright.AllrightsarereservedbythePublisher,whetherthewholeorpartof thematerialisconcerned,specificallytherightsoftranslation,reprinting,reuseofillustrations,recitation, broadcasting,reproductiononmicrofilmsorinanyotherphysicalway,andtransmissionorinformation storageandretrieval,electronicadaptation,computersoftware,orbysimilarordissimilarmethodology nowknownorhereafterdeveloped.Exemptedfromthislegalreservationarebriefexcerptsinconnection with reviews or scholarly analysis or material supplied specifically for the purpose of being entered and executed on a computer system, for exclusive use by the purchaser of the work. Duplication of this publication or parts thereof is permitted only under the provisions of the Copyright Law of the Publisher’slocation,initscurrentversion,andpermissionforusemustalwaysbeobtainedfromSpringer. PermissionsforusemaybeobtainedthroughRightsLinkattheCopyrightClearanceCenter.Violations areliabletoprosecutionundertherespectiveCopyrightLaw. Theuseofgeneraldescriptivenames,registerednames,trademarks,servicemarks,etc.inthispublication doesnotimply,evenintheabsenceofaspecificstatement,thatsuchnamesareexemptfromtherelevant protectivelawsandregulationsandthereforefreeforgeneraluse. While the advice and information in this book are believed to be true and accurate at the date of publication,neithertheauthorsnortheeditorsnorthepublishercanacceptanylegalresponsibilityfor anyerrorsoromissionsthatmaybemade.Thepublishermakesnowarranty,expressorimplied,with respecttothematerialcontainedherein. Printedonacid-freepaper SpringerispartofSpringerScience+BusinessMedia(www.springer.com) Preface This book focuses attention on the pattern formation and the evolution of crack propagation in engineering materials and structures, where efforts are made to bridge mathematical analyses of cracks based on singular integral equations to computationalsimulation of engineeringdesign. The aim of this book is not only forstructuralengineerstounderstandthebasicbackgroundsofanalyses,butalsofor thosemajoringinmathematicstoseehowsuchmathematicalsolutionsareevaluated in industrial applications. Brittle crack propagation and fatigue crack growth are consideredasthemechanismsofcrackpropagation,andtheyareinvestigatedbased on the Griffith–Irwin theory for the former, while the latter is examined by the repeated tension–compressionyielding behaviorincluding the contactmechanism of plastic wake left behind a crack tip. This monograph consists of four parts: elasticity, fracture, morphology, and design. The first two parts provide the basis of the analysis for the discussions on the fracture morphology and its numerical simulation which may lead to a simulation-based fracture control in engineering structures. In Part I, the basic elasticity theory is summarized for two-dimensionalelastic solids.Thedisplacementvectorandstraintensor,thestresstensorandAiry’sstress function,and the relationbetweenstress and strain tensorsare first introducedfor ahomogeneousisotropicelasticbody.Then,theelasticboundary-valueproblemis defined,andsomefundamentalsolutionsaregiveninChapter1.Stressconcentra- tion problemsare investigatedin Chapter 2, where the stress concentrationdue to anexternalforceandtostructuraldiscontinuitiessuchascircularandellipticholes aresolvedbyusingAiry’sstressfunctionandthecomplexpotentials.InChapter3, crackproblemsare solvedby the complexpotentialmethod,and the elastic stress singularitiesnearacracktipareidentified.Also,theanalyticalstructureofthestress fieldisexaminedbyamethodofeigen-functionexpansionnearacracktip. InPartII,analysesaremadeforbrittlefractureandfatiguecrackpropagation.In Chapter4,brittlefractureisanalyzedbasedontheGriffith–Irwintheory,wherethe effectsofplasticdeformationareexaminedbyconsideringthestripyieldingmodel, J-integral,andstabilityofslowcrackgrowth.Fatiguecrackgrowthisdiscussedin v vi Preface Chapter 5, in which Paris’ law is introduced. Then, the effective stress intensity range proposed by Elber based on the crack closure concept and the repeated tensile plasticity range proposed by Toyosada are discussed. The effects of stress ratio and load sequence are analyzed based on a recently developedcrack growth model.Fatigueandfractureareessentialforthestructuralintegrityofengineering structures, so that the results in this part are relevant to the design codes for the preventionofunstablefracturefollowingfatiguecrackgrowth. InPartIIIweinvestigatemorphology,i.e.,theformationofsingleandmultiple crack paths in brittle fracture and fatigue. In Chapter 6, morphologicalaspects of crack propagation are discussed focusing attention on the pattern formation of a systemofquasi-staticallygrowingstraightcracks,whichexhibitsstablebifurcation phenomena, i.e., every other growing crack is arrested at a certain crack length, resultinginaself-similarpatternformationofmultiplecracks.Then,inChapter7, we discuss a kinked and curved crack by applying the first-order perturbation method, in which crack path prediction in brittle solids is analyzed based on a crack path criterion that includes some aspects of crack path stability. The first- orderperturbationis then appliedto a system ofkinkedand curvedcracksforthe simulationofcurvedorwavycrackpropagationinbrittle solids.InChapter8,the perturbationmethodis extendedto the secondorderin examiningthe behaviorof brittle fracture along butt-weld, where the residual stress and the degradation of fracture toughness due to welding may play essential roles coupled with curved crackpaths.InChapter9,fatiguecrackpathsareinvestigatedwithregardtocrack pathcriteria,theeffectsofbiaxialstress,andwelding. InPartIV,weconsidersimulation-basedfracturecontroldesign.Itiswellknown that the simulation of the formation of brittle or fatigue cracks is essential for the precise evaluation of fracture modes and fracture processes, so that several numerical simulation systems have been developed based on the finite element method, meshless method, and/or boundary element method. In Chapter 10, a numerical simulation system is introduced for the path prediction of a system of through-the-thickness cracks and their remaining life assessment for fatigue crack propagation in three-dimensional plate structures. The method is based on astep-by-stepfinite-elementanalysis.Crackpathsarepredictedbytheperturbation methodapplyingthelocalsymmetrycriterion,whichgivesahigher-order(curved) approximation of each incremental crack extension as described in Chapters 7, 8, and 9. The finite element re-zoning is automatically carried out, so that user intervention is minimized to generate a very robust mesh during the entire crack propagationprocess. In Chapter 11, several design concepts are discussed for the prevention of fatigue and fracture in engineering structures, i.e., safe-life design, fail-safe design, and damage-tolerant design. To further improve the structural designagainstfracture,questionshavebeenraisedaboutwhetheronemaycontrol thecrackpropagationphenomenato acertainextentbasedonfracturemechanics, even though fatigue cracks initiate and then propagate. Attempts in this direction aresoughtbypreciselyidentifyingpotentiallycriticallocationsandtheassociated failure modes of structural details, predicting crack propagation lives considering theeffectof retardationdueto loadsequenceandresidualstresses, andpredicting Preface vii crack paths and shapes during crack propagation. This kind of design concept is sometimes called fracture control design, which is discussed in details based on illustrativeapplicationstomarinestructures. The results presented in Parts III and IV and some parts of Part II were based on the work with my former advisers and my graduate students. I must express myspecialthankstomyformeracademicadviserswhohavetaughtmemechanics and worked together on crack problems: Professor Yoshiyuki Yamamoto, The University of Tokyo; Professor Sia Nemat-Nasser, University of California, San Diego; Professor Leon M. Keer, Northwestern University; and Professor Hiroshi Itagaki,YokohamaNationalUniversity.Also,Iwishtoexpressmythankstoallthe peoplewhohavehelpedmeduringthecourseofmyresearch:myformerstudents Teppei Okawa, Yasunori Kagohashi, Chen Yang, Wang Zhinong, Mu Yang, Yuan Kuilin,ShigetoshiHayashi,KazuhiroHirota,KazutoshiOhashi,SatoshiFunabashi, andTakenobuInoue,aswellasmyfriendsYasumiKawamura,MasashiMohri,and ShunichiMichiyama. IgivemythankstoSaoriOgawaforherskillfultypinganddrawingsinadigital environment and her secretarial work in various aspects for a couple of years. I express my gratitude to my family: Katsuko, my wife, and Haruko, Naoko, and Mariko,mydaughters,fortheirlong-timeunderstandingandpatiencewithme. Finally, I acknowledgethe Ministry ofEducation,Culture, Sports,Science and Technology(MEXT),JapanSocietyforthePromotionofScience(JSPS),andJapan ShipTechnologyResearchAssociation(JSTRA)forthesupportofmyresearchin theareaoffracturemechanicsofmarinestructures. Yokohama YoichiSumi December2013 Contents PartI Elasticity 1 ElasticBoundary-ValueProblems........................................ 3 1.1 Displacement,Strain,andCompatibilityCondition................ 3 1.2 StressandEquilibriumConditions.................................. 5 1.3 Stress–StrainRelationship........................................... 6 1.4 StressFunction....................................................... 8 1.5 ElasticBoundary-ValueProblem.................................... 9 1.6 SolutionBasedonaPolarCoordinateSystem...................... 11 References.................................................................... 16 2 StressConcentrationProblems ........................................... 17 2.1 MechanismsandSolutionMethodsofStressConcentration....... 17 2.2 AConcentratedForceActingattheTipofaWedge ............... 18 2.3 AxisymmetricSolution .............................................. 20 2.4 StressConcentrationCausedbyaCircularHole ................... 22 2.5 StressConcentrationFactor.......................................... 24 2.6 EllipticHoleinTension.............................................. 25 References.................................................................... 30 3 AnalysisofTwo-DimensionalCracks .................................... 31 3.1 StressFieldAroundaCrack......................................... 31 3.2 Williams’ExpansionataCrackTip................................. 36 3.3 MethodofMuskhelishviliforaStraightCrack..................... 40 3.3.1 SolutionofaStraightCrackofLength2a ................ 40 3.3.2 SolutionofaSemi-InfiniteStraightCrack SubjectedtoaForceCouple ............................... 43 References.................................................................... 44 ix

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This book is about the pattern formation and the evolution of crack propagation in engineering materials and structures, bridging mathematical analyses of cracks based on singular integral equations, to computational simulation of engineering design. The first two parts of this book focus on elastic
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