LEADER 00000cam a2200649Mi 4500 001 ocn938434735 003 OCoLC 005 20211008041809.0 006 m o d 007 cr ||||||||||| 008 140722s2015 enk o 001 0 eng d 019 957737395|a958083969|a1117869556|a1166991661 020 9781316156438|q(electronic book) 020 1316156435|q(electronic book) 020 9781316691908|q(electronic book) 020 131669190X|q(electronic book) 020 1107096766 020 9781107096769 020 |z9781107096769|q(hardback) 035 (OCoLC)938434735|z(OCoLC)957737395|z(OCoLC)958083969 |z(OCoLC)1117869556|z(OCoLC)1166991661 040 UAB|beng|erda|epn|cUAB|dYDXCP|dOCLCO|dOCLCF|dOCLCQ|dN$T |dIDEBK|dOCLCQ|dEBLCP|dYDX|dDEBBG|dIDB|dNRC|dOCLCQ|dLEAUB |dUKAHL|dOCLCQ|dLVT|dOCLCQ|dLUN|dOCLCQ|dK6U|dOCLCO 049 RIDW 050 4 TA409|b.M336 2015 072 7 TEC|x009000|2bisacsh 072 7 TEC|x035000|2bisacsh 082 04 620.1/126|223 090 TA409|b.M336 2015 100 1 Maiti, Surjya Kumar,|0https://id.loc.gov/authorities/names /n2015013424|eauthor. 245 10 Fracture Mechanics :|bFundamentals and Applications / |cSurjya Kumar Maiti. 264 1 Cambridge :|bCambridge University Press,|c2015. 300 1 online resource (295 pages) 336 text|btxt|2rdacontent 337 computer|bc|2rdamedia 338 online resource|bcr|2rdacarrier 347 text file|2rdaft 500 Title from publisher's bibliographic system (viewed on 09 Feb 2016). 505 0 Cover; Fracture Mechanics; Title; Copyright; Dedication; Contents; List of Figures; List of Tables; Preface; 1 Introduction; 1.1 Introduction; 1.2 Linear Elastic Fracture Mechanics; 1.3 Elastic Plastic or Yielding Fracture Mechanics; 1.4 Mixed Mode Fracture; 1.5 Fatigue Crack Growth; 1.6 Computational Fracture Mechanics; 1.7 Scope of the Book; References; 2 Linear Elastic Fracture Mechanics; 2.1 Introduction; 2.2 Calculation of Theoretical Strength; 2.3 Griffth's Explanation Based on Stress Concentration; 2.4 Griffth's Theory of Brittle Fracture; 2.4.1 Irwin-Orowan Modifcation. 505 8 2.5 Stress Intensity Factor (SIF) Approach2.5.1 Relationship between G and K; 2.6 Concepts of Strain Energy and Potential Energy Release Rates; 2.6.1 Crack Extension Under Load Control (Soft Loading); 2.6.2 Crack Extension Under Displacement Control (Hard Loading); 2.7 Irwin Plastic Zone Size Correction; 2.8 Dugdale-Barenblatt Model for Plastic Zone Size; 2.9 Crack-Tip Plastic Zone Shape; 2.9.1 Mode I Plastic Zone; 2.9.2 Plane Strain Constraint; 2.9.3 Mode II and Mode III Plastic Zones; 2.10 Triaxiality at Crack Front; 2.11 Thickness Dependence of Fracture Toughness Kc. 505 8 2.12 Design ApplicationsAPPENDIX 2.1 Stress Intensity Factors for Various Configurations; Exercise; References; 3 Determination of Crack-Tip Stress Field; 3.1 Introduction; 3.2 Airy Stress Function Approach; 3.3 Kolosoff-Muskhelishvili Potential Formulation; 3.4 Examples of Analytic and Stress Functions; 3.5 Westergaard Stress Function Approach; 3.5.1 Mode I Crack-Tip Field; 3.5.2 Mode II Crack-Tip Field; 3.6 Mode III Solution; 3.7 Williams' Eigenfunction Expansion for Mode I; 3.8 Williams' Eigenfunction Expansion for Mode II and Mixed Mode; Exercise; References. 505 8 4 Crack Opening Displacement, J Integral, and Resistance Curve4.1 Introduction; 4.2 Crack Opening Displacement; 4.3 Special Integrals; 4.4 Rice's Path-Independent Integral J; 4.5 J As Potential Energy Release Rate; 4.6 Graphical Representation of J for Non-linear Elastic Case; 4.7 Resistance Curve; 4.8 Stability of Crack Growth; Exercise; References; 5 Determination of Stress Intensity Factors; 5.1 Introduction; 5.2 Analytical Methods; 5.2.1 Boundary Collocation Method; 5.2.2 Green's Function Approach; 5.2.3 Method of Superposition; 5.2.4 Weight Function Method. 505 8 5.3 Numerical Technique: Finite Element Method5.3.1 Displacement and Stress-Based Methods for Extraction of SIFs; 5.3.2 Energy-based Methods for Determination of SIFs; 5.4 FEM-Based Calculation of G Associated with Kinking of Crack; 5.5 Other Numerical Methods; 5.6 Experimental Methods; 5.6.1 Strain Gauge Technique; 5.6.2 Photoelasticity; Exercise; References; 6 Mixed Mode Brittle Fracture; 6.1 Introduction; 6.2 Theory based on Potential Energy Release Rate; 6.3 Maximum Tangential Stress Criterion; 6.4 Maximum Tangential Principal Stress Criterion; 6.5 Strain Energy Density Criterion. 520 Fracture mechanics studies the development and spreading of cracks in materials. The study uses two techniques including analytical and experimental solid mechanics. The former is used to determine the driving force on a crack and the latter is used to measure material's resistance to fracture. The text begins with a detailed discussion of fundamental concepts including linear elastic fracture mechanics (LEFM), yielding fracture mechanics, mixed mode fracture and computational aspects of linear elastic fracture mechanics. It explains important topics including Griffith theory of brittle crack propagation and its Irwin and Orowan modification, calculation of theoretical cohesive strength of materials through an atomic model and analytical determination of crack tip stress field. This book covers MATLAB programs for calculating fatigue life under variable amplitude cyclic loading. The experimental measurements of fracture toughness parameters KIC, JIC and crack opening displacement (COD) are provided in the last chapter. 590 eBooks on EBSCOhost|bEBSCO eBook Subscription Academic Collection - North America 650 0 Fracture mechanics.|0https://id.loc.gov/authorities/ subjects/sh85051154 650 7 Fracture mechanics.|2fast|0https://id.worldcat.org/fast/ 933536 650 7 TECHNOLOGY & ENGINEERING|xEngineering (General)|2bisacsh 650 7 TECHNOLOGY & ENGINEERING|xReference.|2bisacsh 655 0 Electronic books. 655 4 Electronic books. 776 08 |iErscheint auch als:|nDruck-Ausgabe|aMaiti, Surjya Kumar. Fracture Mechanics .|tFundamentals and Applications 856 40 |uhttps://rider.idm.oclc.org/login?url=https:// search.ebscohost.com/login.aspx?direct=true&scope=site& db=nlebk&AN=1196930|zOnline ebook via EBSCO. Access restricted to current Rider University students, faculty, and staff. 856 42 |3Instructions for reading/downloading the EBSCO version of this ebook|uhttp://guides.rider.edu/ebooks/ebsco 901 MARCIVE 20231220 948 |d20211213|cEBSCO|tEBSCOebooksacademic NEW Oct-Nov 5018 |lridw 994 92|bRID