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9780415310000

Introduction To The Characterization Of Residual Stress By Neutron Diffraction

by ;
  • ISBN13:

    9780415310000

  • ISBN10:

    0415310008

  • Edition: 1st
  • Format: Hardcover
  • Copyright: 2005-02-28
  • Publisher: CRC Press

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Summary

Over the past 25 years the field of neutron diffraction for residual stress characterization has grown tremendously, and has matured from the stage of trial demonstrations to provide a practical tool with widespread applications in materials science and engineering. While the literature on the subject has grown commensurately, it has also remained fragmented and scattered across various journals and conference proceedings.For the first time, this volume presents a comprehensive introduction to stress measurement using neutron diffraction. It discusses all aspects of the technique, from the basic physics, the different neutron sources and instrumentation, to the various strategies for lattice strain measurement and data interpretation. These are illustrated by practical examples. This book represents a coherent unified treatment of the subject, written by well-known experts. It will prepare students, engineers, and other newcomers for their first neutron diffraction experiments and provide experts with a definitive reference work.

Table of Contents

Introduction
1(24)
Residual Stress: Friend or Foe?
1(1)
Historical Development of Stress Measurement by Diffraction
2(4)
Laboratory X-Ray Diffraction
3(2)
Synchrotron X-Ray Diffraction
5(1)
Neutron Diffraction
5(1)
Special Characteristics of Neutron Strain Measurement
6(4)
Nature and Origin of Residual Stress
10(7)
Macrostresses and Microstresses
11(3)
Measurement of Macrostresses and Microstresses
14(1)
Diffraction Techniques
15(1)
Other Measurement Techniques
16(1)
Effects of Residual Stress
17(8)
Static Loading
17(1)
Fatigue Loading
18(3)
References
21(4)
Fundamentals of Neutron Diffraction
25(40)
Introduction
25(2)
Scattering and Absorption of Neutrons and X-Rays by Atoms
27(7)
Neutron Scattering
27(3)
Coherent Scattering Cross-Section
30(1)
Incoherent Scattering Cross-Section
30(1)
Absorption Cross-Section
31(1)
Tabulation of Neutron Cross-Sections
32(1)
X-Ray Scattering
32(2)
Neutron Diffraction from Crystalline Solids
34(21)
Crystal Lattice
35(2)
Diffraction from Crystal Lattice Planes
37(2)
Observation of Diffraction Peaks
39(1)
Reciprocal Lattice Approach to Diffraction Theory
40(1)
Reciprocal Lattice
40(1)
Neutron Coherent Elastic Cross-Section
41(5)
Lattice Plane Spacings
46(1)
Orthogonal Crystal Structures
47(1)
Hexagonal Structures
48(1)
Lower Symmetry Structures
48(1)
Diffracted Intensity
49(3)
Scattering from Engineering Materials
52(1)
Scattering from Elements
52(1)
Scattering from Alloys
52(1)
Application to Titanium Alloys
53(1)
Macroscopic Cross-Section
53(1)
Elements
53(1)
Alloys
54(1)
Penetration of Neutron Beams
55(1)
Effects of Lattice Vibrations
56(2)
Extinction, Texture, and Multiple Scattering
58(7)
Extinction
58(1)
Texture
59(1)
Multiple Scattering
60(3)
References
63(2)
Diffraction Techniques and Instrument Design
65(84)
Neutron Sources
65(13)
Steady-State Reactor Neutron Source
66(1)
Moderation
67(2)
Neutron Guide Tubes
69(4)
Neutron Lenses
73(1)
Time-Pulsed Neutron Source
73(4)
Safety
77(1)
Diffractometers for Strain Measurement
78(22)
Reactor-Based Continuous Beam Instrument for Strain Measurement
79(1)
Basic Instrument
79(4)
Instrument Construction
83(1)
Monochromator and Choice of Wavelength
84(4)
Collimation
88(1)
Apertures and Beam Area Definition
89(2)
Shielding
91(1)
Time-Pulsed Beam Instrument for Strain Measurement
92(1)
Time-Pulsed Neutron Beams on Reactors
92(1)
Time-Pulsed Neutron Beams from Pulsed Sources
93(3)
Instruments on a Spallation Source
96(3)
Collimation
99(1)
Neutron Detectors
100(3)
Position-Sensitive Detectors and Detector Arrays
101(2)
The Instrumental Resolution
103(5)
Continuous Beam Instrument
104(3)
Time-Pulsed Beam Instrument
107(1)
Instrument Gauge Volumes
108(6)
Instrument Reference Point
109(1)
Gauge Volume
109(1)
Nominal Gauge Volume
110(1)
Instrumental Gauge Volume
111(3)
Definition of Instrumental Gauge Volume When Using a Position-Sensitive Detector
114(1)
Sampled Gauge Volume and Effective Measurement Position
114(22)
Sampled Gauge Volume
114(2)
Effects of Beam Attenuation in Sample
116(3)
Geometric and Attenuation Shifts of Effective Centroid of Sampled Gauge Volume
119(1)
Sample Positioning
120(1)
Sample Positioning, Orientation, and Movement
120(3)
Mounting the Sample
123(3)
Anomalous Angular Shifts Due to Surface Effects
126(5)
Corrections for Anomalous Angle Shifts
131(3)
Minimizing Anomalous Angle Shifts
134(2)
Specialized Instruments for Strain Measurement
136(13)
Triple-Axis Spectrometer
136(2)
Use of Horizontally Curved Silicon Crystals
138(2)
Specialized Time-of-Flight Techniques
140(2)
Transmission Techniques
142(2)
References
144(5)
Practical Aspects of Strain Measurement Using Neutron Diffraction
149(54)
Introduction
149(3)
Measurement of Diffraction Bragg Peak Profile
152(5)
Choosing an Appropriate Gauge Volume
152(1)
Choosing an Appropriate Reflection
153(1)
Elastic Regime
154(1)
Plastic Regime
154(1)
Avoidance of Anomalous Shifts of Angle Due to Bragg Edges
155(2)
Measurement of Many Peaks in a Diffraction Pattern
157(1)
Scanning the Diffraction Peak
157(1)
Analyzing Bragg Peak Profiles
157(7)
Expressions for Peak Profiles
159(1)
Symmetric Peaks from Continuous Source Diffractometers
159(2)
Asymmetric Peaks from Time-Pulsed Source Instruments
161(1)
Fitting a Profile to a Single Diffraction Peak
162(2)
Accuracy of Diffraction Peak Center Determination
164(18)
Accuracy of Fitted Parameters
164(1)
Uncertainty in Case of Negligible Background
164(2)
Effects of Background on Strain Uncertainty
166(3)
Systematic Uncertainties
169(1)
Time Required to Achieve a Given Accuracy in Peak Center Measurement
169(1)
Measuring at Positions Deep within a Sample
170(4)
Analytical and Empirical Studies of Scan Optimization
174(1)
Range of Scan
174(1)
Fitting a Sloping Background
175(2)
Weighting
177(1)
VAMAS Recommendations on Peak Fitting
178(3)
Strategy of Peak Fitting
181(1)
Sources of Background Counts
182(1)
Analysis of Complete Diffraction Profiles for Strain
182(1)
Strain-Free Reference
183(14)
Requirement
183(1)
Other Factors That Can Affect Lattice Spacing
184(2)
Measurement of Reference d0-Spacing
186(1)
Far-Field Reference
187(1)
Powders, Cubes, and Combs
188(4)
d0 Measurement Using X-Rays
192(1)
d0 Measurement by Neutron Transmission
192(4)
Imposing Stress Balance
196(1)
Reproducibility Tests
197(6)
Recording Measurement Details
199(1)
References
199(4)
Interpretation and Analysis of Lattice Strain Data
203(60)
Inferring Stresses from Lattice Strains
203(7)
Basic Continuum Relationship between Strain and Stress
203(3)
Diffraction-Specific Elastic Constants
206(1)
X-Ray Measurement of Stress
207(3)
Introduction to Mechanics of Crystallite Deformation
210(5)
Elastic Anisotropy of Single Crystals
215(7)
Elastic Anisotropy of Cubic Single Crystals
216(5)
Elastic Anisotropy of Hexagonal Crystals
221(1)
The Bulk Elastic Response of Polycrystals
222(5)
Voigt and Reuss Models for Macroscopic Bulk Properties
223(1)
Voigt Model for Bulk Properties
223(1)
Reuss Model for Bulk Properties
224(1)
Kroner Model for Macroscopic Bulk Properties
225(2)
hkl-Specific Response in a Polycrystal Undergoing Elastic Deformation
227(3)
Voigt and Reuss Models
227(1)
Voigt Model
227(1)
Reuss Model
227(1)
Kroner Model
228(2)
hkl-Specific Response in a Polycrystal Undergoing Plastic Deformation
230(24)
Elastoplastic Self-Consistent Models
233(1)
Implementation of EPSC Model
234(3)
Predicting Crystallographic Slip
237(2)
EPSC Predictions of Lattice Strains under Plastic Straining
239(3)
EPSC Predictions of Residual Intergranular Strains
242(2)
Analysis of Experimental Data
244(1)
Uniaxial Tensile Loading of Aluminum
244(2)
Uniaxial Tensile Loading of Stainless Steel
246(1)
Hexagonal Materials
246(2)
Cyclical Loading
248(1)
Rietveld Analysis of Diffraction Patterns
249(4)
Summary
253(1)
Analysis of Bragg Peak Broadening
254(9)
References
257(6)
Applications to Problems in Materials Science and Engineering
263(84)
Introduction
263(2)
Welded Structures
265(24)
Origin and Nature of Weld Stresses
266(2)
Comparison of Various Stress Measurement Techniques
268(6)
Challenges to Accurate Neutron Diffraction Measurement of Weldment Stresses
274(4)
Examples of Stress Measurement in Weldments
278(1)
Alumino-Thermic Welds
278(1)
Manual Metal Arc Repair Welds
279(2)
Electron Beam Welds
281(1)
Friction-Based Welds
281(6)
Future Directions for Neutron Diffraction Studies of Weldments
287(1)
Validation of Finite Element Models
287(1)
Postweld Heat Treatment
288(1)
Phase Transformations
288(1)
Strategies for Improved Lifetime
289(1)
Composites and Other Multiphase Materials
289(27)
Nature and Origins
289(2)
Mean Phase-Specific Microstresses
291(1)
Methods for Measurement of Stress in Composites
291(1)
Raman Spectroscopy
291(1)
Photoelasticity
291(1)
Diffraction Techniques
292(7)
Separation of Different Stress Contributions in Composites
299(2)
Elastic Mismatch Stresses
301(2)
Thermal Microstresses
303(3)
Particulate Composites
306(1)
Whisker Composites
307(2)
Continuous Fiber Composites
309(1)
Plastic Misfit Stresses
309(1)
Continuous Fiber Metal Matrix Systems
310(1)
Phase Transformation Stresses
311(1)
Microstress-Related Peak Broadening
312(2)
Future Directions for Neutron Diffraction Measurements of Composites
314(2)
Plastically Deformed Components and Materials
316(8)
Origin and Nature of Plastic Misfit Stresses
316(1)
Challenges to Accurate Neutron Diffraction Measurement of Stress in Plastically Deformed Components
316(1)
Examples of Stress Measurement in Plastically Deformed Materials
317(1)
Studies of Fundamental Aspects of Material Deformation
317(1)
Practical Example of Intergranular Stresses: Bent Monel Tube
318(2)
Stress in a Highly Textured Sample
320(2)
Intergranular Lattice Strain as an Indicator of Macroscopic Plastic Strain
322(2)
Future Directions for Neutron Diffraction Measurement of Stress in Plastically Deformed Components
324(1)
Near-Surface Stresses
324(9)
Origin and Nature of Near-Surface Stresses
325(1)
Challenges to Accurate Neutron Diffraction Measurement of Stress Near Surfaces
325(3)
Examples of Measurement of Stress Near Surfaces
328(1)
Machining Stresses
328(1)
Shot-Peening
329(1)
Carburized Layers
330(2)
Future Directions for Neutron Diffraction Measurement of Stress Near Surfaces
332(1)
In Situ and Through-Process or Life Studies
333(14)
Manufacturing Process Studies
334(2)
Heat Treatment
336(2)
Service Life Studies
338(2)
References
340(7)
The Future
347(2)
Symbols and Abbreviations 349(8)
Glossary 357(4)
Appendix 1 Note on Reactor Flux Spectrum 361(4)
Appendix 2 Relation between the Centroid of Sampled Gauge Volume and Translator Reading 365(4)
Appendix 3 Points for Consideration When Making a Neutron Diffraction Stress Measurement 369(10)
Appendix 4 Macroscopic Scattering Cross-Sections of All Elements 379(6)
Index 385

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