A Teaching Essay on Residual Stresses and Eigenstrains.
Residual stresses are an important subject in materials science and engineering that has implications across disciplines, from quantum dots to human teeth, from aeroengines to automotive surface finishing. Although a number of monographs exist, no resource is available in the form of a book to serve...
Clasificación: | Libro Electrónico |
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Autor principal: | |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Saint Louis :
Elsevier Science,
2017.
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Temas: | |
Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Front Cover; A Teaching Essay on Residual Stresses and Eigenstrains; A Teaching Essay on Residual Stresses and EigenstrainsAlexander M. KorsunskyUniversity of Oxford; Copyright; Contents; Biography; Preface; 1
- Introduction and Outline; 2
- Elastic and Inelastic Deformation and Residual Stress; 2.1 DEFORMATION AND STRAIN; 2.2 STRESS; 2.3 EQUATIONS OF EQUILIBRIUM; 2.4 FORMULATION AND SOLUTION OF PROBLEMS IN CONTINUUM MECHANICS; 2.5 STRAIN ENERGY DENSITY; 2.6 CONTRACTED NOTATION; 2.7 ELASTIC ISOTROPY; 2.8 ELASTIC CONSTANTS; 2.9 UNIFORM DEFORMATION; 2.10 THERMOELASTICITY.
- 2.11 PLANE STRESS AND PLANE STRAIN2.12 FUNDAMENTAL RESIDUAL STRESS SOLUTIONS AND THE NUCLEI OF STRAIN; 2.13 THE RELATIONSHIP BETWEEN RESIDUAL STRESSES AND EIGENSTRAINS; 3
- Simple Residual Stress Systems; 3.1 ADDITIVITY OF TOTAL STRAIN; 3.2 CONSTRAINED ELASTIC-PLASTIC BAR LOADED AT A POINT ALONG ITS LENGTH; 3.3 ELASTOPLASTIC COMPOSITES: UNIFORM STRESS (REUSS) AND STRAIN (VOIGT); 3.4 ON THE COMPOSITE MECHANICS OF POLYCRYSTALS; 3.5 THE RAMBERG-OSGOOD STRESS-STRAIN RELATIONSHIP; 3.6 CONTINUUM PLASTICITY; 4
- Inelastic Bending of Beams.
- 4.1 SLENDER RODS: COLUMNS, BEAMS, AND SHAFTS. SAINT-VENANT'S PRINCIPLE4.2 INELASTIC BEAM BENDING; 4.3 DIRECT PROBLEM: RESIDUAL STRESS IN A PLASTICALLY BENT BEAM; 4.4 CASE: RESIDUAL STRESSES DUE TO SURFACE TREATMENT; 4.5 CASE: RESIDUAL STRESSES IN COATINGS AND THIN LAYERS; 5
- Plastic Yielding of Cylinders; 5.1 INELASTIC EXPANSION OF A THICK-WALLED TUBE; 5.2 CASE: AUTOFRETTAGED TUBES AND COLD-EXPANDED HOLES; 5.3 CASE: QUENCHING OF A SOLID CYLINDER; 6
- The Eigenstrain Theory of Residual Stress; 6.1 GENERALIZATION; 6.2 THE EIGENSTRAIN CYLINDER; 6.3 THE EIGENSTRAIN SPHERE.
- 6.4 ESHELBY ELLIPSOIDAL INCLUSIONS6.5 NUCLEI OF STRAIN; 7
- Dislocations; 7.1 DISLOCATIONS; 7.2 SCREW DISLOCATION: ANTIPLANE SHEAR SOLUTION; 7.3 EDGE DISLOCATION: PLANE STRAIN SOLUTION; 7.4 DISLOCATION PHENOMENOLOGY: FORCES, DIPOLES, INITIATION, AND ANNIHILATION; 7.5 THE DYNAMICS OF DISLOCATION MOTION; 7.6 DISLOCATION DYNAMICS EXAMPLES; Reference; 8
- Residual Stress "Measurement"; 8.1 CLASSIFICATION; 8.2 LAYER REMOVAL AND CURVATURE MEASUREMENT; 8.3 HOLE DRILLING; 8.4 THE CONTOUR METHOD; 8.5 PHYSICAL METHODS; 8.6 METHOD OVERVIEW AND SELECTION.
- 9
- Microscale Methods of Residual Stress Evaluation9.1 PECULIARITIES OF RESIDUAL STRESS EVALUATION AT THE MICROSCALE; 9.2 MICROFOCUS X-RAY DIFFRACTION METHODS; 9.3 ELECTRON DIFFRACTION METHODS; 9.4 SPECTROSCOPIC METHODS; 9.5 INTRODUCTION TO FIB-DIC MICROSCALE RESIDUAL STRESS ANALYSIS AND ERROR ESTIMATION; 9.6 FIB-DIC MILLING GEOMETRIES; 9.6.1 Surface Slotting; 9.6.2 Hole Drilling; 9.6.3 Microscale Ring-Core Milling; 9.6.4 H-bar Milling; 9.7 ERROR ESTIMATION AND PROPAGATION IN FIB-DIC RESIDUAL STRESS ANALYSIS; 9.7.1 DIC Error Estimation; 9.7.2 DIC Outlier Removal.