Cargando…

Practical residual stress measurement methods /

"This comprehensive collection of practical residual stress measurement techniques is written by world-renowned experts in their respective fields. It provides the reader with the information needed to understand key concepts and to make informed technical decisions. Fully illustrated throughou...

Descripción completa

Detalles Bibliográficos
Clasificación:	Libro Electrónico
Otros Autores:	Schajer, Gary S. (Editor )
Formato:	Electrónico eBook
Idioma:	Inglés
Publicado:	Chichester, West Sussex, United Kingdom : Wiley, 2013.
Temas:	Residual stresses. Contraintes résiduelles. internal stress. TECHNOLOGY & ENGINEERING > Quality Control. Residual stresses
Acceso en línea:	Texto completo

Tabla de Contenidos:

Machine generated contents note: 1.1. Introduction / Gary S. Schajer / Clayton 0. Ruud
1.1.1. Character and Origin of Residual Stresses / Gary S. Schajer / Clayton 0. Ruud
1.1.2. Effects of Residual Stresses / Clayton 0. Ruud / Gary S. Schajer
1.1.3. Residual Stress Gradients / Clayton 0. Ruud / Gary S. Schajer
1.1.4. Deformation Effects of Residual Stresses / Clayton 0. Ruud / Gary S. Schajer
1.1.5. Challenges of Measuring Residual Stresses / Gary S. Schajer / Clayton 0. Ruud
1.1.6. Contribution of Modern Measurement Technologies / Clayton 0. Ruud / Gary S. Schajer
1.2. Relaxation Measurement Methods / Clayton 0. Ruud / Gary S. Schajer
1.2.1. Operating Principle / Gary S. Schajer / Clayton 0. Ruud
1.3. Diffraction Methods / Clayton 0. Ruud / Gary S. Schajer
1.3.1. Measurement Concept / Clayton 0. Ruud / Gary S. Schajer
1.3.2. X-ray Diffraction / Clayton 0. Ruud / Gary S. Schajer
1.3.3. Synchrotron X-ray / Gary S. Schajer / Clayton 0. Ruud
1.3.4. Neutron Diffraction / Clayton 0. Ruud / Gary S. Schajer
1.4. Other Methods / Gary S. Schajer / Clayton 0. Ruud
1.4.1. Magnetic / Clayton 0. Ruud / Gary S. Schajer
1.4.2. Ultrasonic / Clayton 0. Ruud / Gary S. Schajer
1.4.3. Thermoelastic / Gary S. Schajer / Clayton 0. Ruud
1.4.4. Photoelastic / Clayton 0. Ruud / Gary S. Schajer
1.4.5. Indentation / Gary S. Schajer / Clayton 0. Ruud
1.5. Performance and Limitations of Methods / Clayton 0. Ruud / Gary S. Schajer
1.5.1. General Considerations / Clayton 0. Ruud / Gary S. Schajer
1.5.2. Performance and Limitations of Methods / Gary S. Schajer / Clayton 0. Ruud
1.6. Strategies for Measurement Method Choice / Clayton 0. Ruud / Gary S. Schajer
1.6.1. Factors to be Considered / Clayton 0. Ruud / Gary S. Schajer
1.6.2. Characteristics of Methods / Gary S. Schajer / Clayton 0. Ruud
References / Gary S. Schajer / Clayton 0. Ruud
2.1. Introduction / Philip S. Whitehead / Gary S. Schajer
2.1.1. Introduction and Context / Gary S. Schajer / Philip S. Whitehead
2.1.2. History / Philip S. Whitehead / Gary S. Schajer
2.1.3. Deep Hole Drilling / Philip S. Whitehead / Gary S. Schajer
2.2. Data Acquisition Methods / Philip S. Whitehead / Gary S. Schajer
2.2.1. Strain Gages / Philip S. Whitehead / Gary S. Schajer
2.2.2. Optical Measurement Techniques / Philip S. Whitehead / Gary S. Schajer
2.3. Specimen Preparation / Philip S. Whitehead / Gary S. Schajer
2.3.1. Specimen Geometry and Strain Gage Selection / Philip S. Whitehead / Gary S. Schajer
2.3.2. Surface Preparation / Philip S. Whitehead / Gary S. Schajer
2.3.3. Strain Gage Installation / Philip S. Whitehead / Gary S. Schajer
2.3.4. Strain Gage Wiring / Philip S. Whitehead / Gary S. Schajer
2.3.5. Instrumentation and Data Acquisition / Philip S. Whitehead / Gary S. Schajer
2.4. Hole Drilling Procedure / Philip S. Whitehead / Gary S. Schajer
2.4.1. Drilling Cutter Selection / Philip S. Whitehead / Gary S. Schajer
2.4.2. Drilling Machines / Philip S. Whitehead / Gary S. Schajer
2.4.3. Orbital Drilling / Philip S. Whitehead / Gary S. Schajer
2.4.4. Incremental Measurements / Philip S. Whitehead / Gary S. Schajer
2.4.5. Post-drilling Examination of Hole and Cutter / Philip S. Whitehead / Gary S. Schajer
2.5. Computation of Uniform Stresses / Philip S. Whitehead / Gary S. Schajer
2.5.1. Mathematical Background / Philip S. Whitehead / Gary S. Schajer
2.5.2. Data Averaging / Philip S. Whitehead / Gary S. Schajer
2.5.3. Plasticity Effects / Philip S. Whitehead / Gary S. Schajer
2.5.4. Ring Core Measurements / Philip S. Whitehead / Gary S. Schajer
2.5.5. Optical Measurements / Philip S. Whitehead / Gary S. Schajer
2.5.6. Orthotropic Materials / Philip S. Whitehead / Gary S. Schajer
2.6. Computation of Profile Stresses / Philip S. Whitehead / Gary S. Schajer
2.6.1. Mathematical Background / Philip S. Whitehead / Gary S. Schajer
2.7. Example Applications / Philip S. Whitehead / Gary S. Schajer
2.7.1. Shot-peened Alloy Steel Plate
Application of the Integral Method / Philip S. Whitehead / Gary S. Schajer
2.7.2. Nickel Alloy Disc
Fine Increment Drilling / Philip S. Whitehead / Gary S. Schajer
2.7.3. Titanium Test-pieces
Surface Processes / Philip S. Whitehead / Gary S. Schajer
2.7.4. Coated Cylinder Bore
Adaptation of the Integral Method / Gary S. Schajer / Philip S. Whitehead
2.8. Performance and Limitations of Methods / Philip S. Whitehead / Gary S. Schajer
2.8.1. Practical Considerations / Philip S. Whitehead / Gary S. Schajer
2.8.2. Common Uncertainty Sources / Philip S. Whitehead / Gary S. Schajer
2.8.3. Typical Measurement Uncertainties / Philip S. Whitehead / Gary S. Schajer
References / Philip S. Whitehead / Gary S. Schajer
3.1. Introduction and Background / David J. Smith
3.2. Basic Principles / David J. Smith
3.2.1. Elastic Analysis / David J. Smith
3.2.2. Effects of Plasticity / David J. Smith
3.3. Experimental Technique / David J. Smith
3.4. Validation of DHD Methods / David J. Smith
3.4.1. Tensile Loading / David J. Smith
3.4.2. Shrink Fitted Assembly / David J. Smith
3.4.3. Prior Elastic-plastic Bending / David J. Smith
3.4.4. Quenched Solid Cylinder / David J. Smith
3.5. Case Studies / David J. Smith
3.5.1. Welded Nuclear Components / David J. Smith
3.5.2. Components for the Steel Rolling Industry / David J. Smith
3.5.3. Fibre Composites / David J. Smith
3.6. Summary and Future Developments / David J. Smith
Acknowledgments / David J. Smith
References / David J. Smith
4.1. Measurement Principle / Michael R. Hill
4.2. Residual Stress Profile Calculation / Michael R. Hill
4.3. Stress Intensity Factor Determination / Michael R. Hill
4.4. Practical Measurement Procedures / Michael R. Hill
4.5. Example Applications / Michael R. Hill
4.6. Performance and Limitations of Method / Michael R. Hill
4.7. Summary / Michael R. Hill
References / Michael R. Hill
5.1. Introduction / Adrian T. DeWald / Michael B. Prime
5.1.1. Contour Method Overview / Adrian T. DeWald / Michael B. Prime
5.1.2. Bueckner's Principle / Michael B. Prime / Adrian T. DeWald
5.2. Measurement Principle / Michael B. Prime / Adrian T. DeWald
5.2.1. Ideal Theoretical Implementation / Michael B. Prime / Adrian T. DeWald
5.2.2. Practical Implementation / Michael B. Prime / Adrian T. DeWald
5.2.3. Assumptions and Approximations / Michael B. Prime / Adrian T. DeWald
5.3. Practical Measurement Procedures / Michael B. Prime / Adrian T. DeWald
5.3.1. Planning the Measurement / Michael B. Prime / Adrian T. DeWald
5.3.2. Fixturing / Michael B. Prime / Adrian T. DeWald
5.3.3. Cutting the Part / Michael B. Prime / Adrian T. DeWald
5.3.4. Measuring the Surfaces / Michael B. Prime / Adrian T. DeWald
5.4. Residual Stress Evaluation / Michael B. Prime / Adrian T. DeWald
5.4.1. Basic Data Processing / Michael B. Prime / Adrian T. DeWald
5.4.2. Additional Issues / Michael B. Prime / Adrian T. DeWald
5.5. Example Applications / Michael B. Prime / Adrian T. DeWald
5.5.1. Experimental Validation and Verification / Michael B. Prime / Adrian T. DeWald
5.5.2. Unique Measurements / Michael B. Prime / Adrian T. DeWald
5.6. Performance and Limitations of Methods / Michael B. Prime / Adrian T. DeWald
5.6.1. Near Surface (Edge) Uncertainties / Michael B. Prime / Adrian T. DeWald
5.6.2. Size Dependence / Michael B. Prime / Adrian T. DeWald
5.6.3. Systematic Errors / Michael B. Prime / Adrian T. DeWald
5.7. Further Reading On Advanced Contour Method Topics / Adrian T. DeWald / Michael B. Prime
5.7.1. Superposition For Additional Stresses / Michael B. Prime / Adrian T. DeWald
5.7.2. Cylindrical Parts / Michael B. Prime / Adrian T. DeWald
5.7.3. Miscellaneous / Michael B. Prime / Adrian T. DeWald
5.7.4. Patent / Adrian T. DeWald / Michael B. Prime
Acknowledgments / Adrian T.
DeWald / Michael B. Prime
References / Michael B. Prime / Adrian T. DeWald
6.1. Introduction / I. Cevdet Noyan / Conal E. Murray
6.2. Measurement of Lattice Strain / I. Cevdet Noyan / Conal E. Murray
6.3. Analysis of Regular do, vs. sin2* Data / Conal E. Murray / I. Cevdet Noyan
6.3.1. Dolle-Hauk Method / Conal E. Murray / I. Cevdet Noyan
6.3.2. Winholtz-Cohen Least-squares Analysis / Conal E. Murray / I. Cevdet Noyan
6.4. Calculation of Stresses / Conal E. Murray / I. Cevdet Noyan
6.5. Effect of Sample Microstructure / Conal E. Murray / I. Cevdet Noyan
6.6. X-ray Elastic Constants (XEC) / I. Cevdet Noyan / Conal E. Murray
6.6.1. Constitutive Equation / I. Cevdet Noyan / Conal E. Murray
6.6.2. Grain Interaction / Conal E. Murray / I. Cevdet Noyan
6.7. Examples / Conal E. Murray / I. Cevdet Noyan
6.7.1. Isotropic, Biaxial Stress / Conal E. Murray / I. Cevdet Noyan
6.7.2. Triaxial Stress / I. Cevdet Noyan / Conal E. Murray
6.7.3. Single-crystal Strain / Conal E. Murray / I. Cevdet Noyan
6.8. Experimental Considerations / I. Cevdet Noyan / Conal E. Murray
6.8.1. Instrumental Errors / Conal E. Murray / I. Cevdet Noyan
6.8.2. Errors Due to Counting Statistics and Peak-fitting / I. Cevdet Noyan / Conal E. Murray.
Note continued: 11.6. Examples and Applications / Drew V. Nelson
11.7. Performance and Limitations / Drew V. Nelson
References / Drew V. Nelson.

Practical residual stress measurement methods /

Ejemplares similares