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Library | Item Barcode | Call Number | Material Type | Item Category 1 | Status |
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Summary
Summary
EMATs for Science and Industry comprises the physical principles of electromagnetic acoustic transducers (EMATs) and the applications to scientific and industrial ultrasonic measurements on materials. The text is arranged in four parts:
-PART I is intended to be a self-contained description of the basic elements of coupling mechanism along with practical designing of EMATs for various purposes. There are several implementations to compensate for the low transfer efficiency of the EMATs. Useful tips to make an EMAT are also presented.
-PART II describes the principle of electromagnetic acoustic resonance (EMAR), which makes the most of contactless nature of EMATs and is the most successful amplification mechanism for precise velocity and attenuation measurements.
-PART III applies EMAR to studying the physical acoustics. New measurements emerged on three major subjects; in situ monitoring of dislocation behavior, determination of anisotropic elastic constants, and acoustic nonlinearity evolution.
-PART IV deals with a variety of individual topics encountered in industrial applications, for which the EMATs are believed to the best solutions.
Table of Contents
Preface |
Introduction: Noncontact Ultrasonic Measurements |
Brief Historical Sketch of EMAT |
Electromagnetic Acoustic Resonance |
EMAR |
Part I Development of EMAT Techniques |
1 Coupling Mechanism |
1.1 Background |
1.2 Generation Mechanism |
1.3 Receiving Mechanisms |
1.4 Comparison with Measurements |
2 Available EMATS |
2.1 Bulk-Wave EMATs |
2.2 Longitudinal-Guided-Wave EMAT for Wires and Pipes |
2.3 PPM EMAT |
2.4 Meander-Line Coil SH-Wave EMAT |
2.5 SH-Wave EMAT for Chirp Pulse Compression |
2.6 Axial-Shear-Wave EMAT |
2.7 SH-Wave EMAT for Resonance in Bolt Head |
2.8 Rayleigh-Wave EMAT |
2.9 Line-Focusing EMAT |
2.10 Trapped-Torsional-Mode EMAT |
2.11 EMATs for High Temperature Measurements |
3 Brief Instruction To Build EMATs |
3.1 Coil |
3.2 Magnets |
3.3 Impedance Matching |
Part II Resonance Spectroscopy with EMATs -EMAR |
4 Principles of EMAR for Spectral Response |
4.1 Through-Thickness Resonance |
4.2 Spectroscopy with Analog Superheterodyne Processing |
4.3 Determination of Resonance Frequency and Phase Angle |
5 Free-Decay Measurement For Attenuation And Internal Friction |
5.1 Difficulty of Attenuation Measurement |
5.2 Isolation of Ultrasonic Attenuation |
5.3 Measurement of Attenuation Coefficient |
5.4 Correction for Diffraction Loss |
5.5 Comparison with Conventional Technique |
Part III Physical-Acoustics Studies |
6 In-Situ Monitoring Of Dislocation Mobility |
6.1 Dislocation-Damping Model for Low Frequencies |
6.2 Elasto-Plastic Deformation in Copper |
6.3 Point-Defect Diffusion toward Dislocations in Deformed Aluminum |
6.4 Dislocation Damping after Elastic Deformation in Al-Zn Alloy |
6.5 Recovery and Recrystallization in Aluminum |
7 Elastic Constants and Internal Friction of Advanced Materials |
7.1 Mode Control in Resonance Ultrasound Spectroscopy by EMAR |
7.2 Inverse Calculation for Cij and Qij-1 |
7.3 Monocrystal Copper |
7.4 Metal-Matrix Composites (SiCf/Ti-6Al-4V) |
7.5 Lotus-Type Porous Copper |
7.6 Ni-Base Superalloys |
7.7 Thin Films |
7.8 Piezoelectric Material (Langasite: La3Ga5SiO14) |
8 Nonlinear Acoustics |
Part IV Industrial Applications |
9 On-Line Texture Monitoring Of Steel Sheets |
9.1 Texture of Polycrystalline Metals |
9.2 Mathematical Expressions of Texture and Velocity Anisotropy |
9.3 Relation between ODCs and r-Values |
9.4 On-Line Monitoring with Magnetostrictive-Type EMATs |
10 Acoustoelastic Stress Measurements |
10.1 Nonlinear Elasticity |
10.2 Acoustoelastic Response of Solids |
10.3 Birefringence Acoustoelasticity |
10.4 Practical Stress Measurements with EMAR |
10.5 Monitoring Bolt Axial Stress |
11 Measurements On High-Temperature Steels |
11.1 Velocity Variation at High Temperatures |
11.2 Solidification-Shell Thickness of Continuous Casting Slabs |
11.3 Wall Thickness of Hot Seamless Steel Tubes |
12 Measurement Of Induction-Hardening Depth |
12.1 Sensing Modified Surface Layers |
12.2 Axial-Shear-Wave Resonance |
12.3 Linear Perturbation Scheme |
12.4 Inverse Evaluation of Case Depth |
13 Detection Of Flaw And Corrosion |
13.1 Crack Inspection of Railroad Wheels |
13.2 Gas-Pipeline Inspection |
13.3 Line-Focusing EMAT for Detecting Slit Defects |
14 Average Grain Size Of Steels |
14.1 Scattering of Ultrasonic Waves by Grains |
14.2 Fourth-Power Law |
14.3 Steel Specimens and Grain-Size Distribution |
14.4 Grain-Size Evaluation |
15 Remaining-Life Assessment Of Fatigued Metals |
15.1 Fatigue and Ultrasonic Measurements |
15.2 Zero-to-Tension Fatigue of Copper |
15.3 Rotating-Bending Fatigue of Low-Carbon Steels |
15.4 Tension-Compression Fatigue of Low-Carbon Steels |
16 Creep Damage Detection Of Steels |
16.1 Aging of Metals |
16.2 Creep and Dislocation Damping |
16.3 Interrelation with Microstructure |
References |
Index |