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Handbook of Borehole Acoustics and Rock Physics for Reservoir Characterization /
"The Handbook of Borehole Acoustics and Rock Physics for Reservoir Characterization combines in a single useful handbook the multidisciplinary domains of the petroleum industry, including the fundamental concepts of rock physics, acoustic logging, waveform processing, and geophysical applicatio...
| Clasificación: | Libro Electrónico |
|---|---|
| Autores principales: | , , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Amsterdam, Netherlands :
Elsevier,
[2018]
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| Edición: | First edition. |
| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Front Cover; Handbook of Borehole Acoustics and Rock Physics for Reservoir Characterization; Copyright; Contents; List of Tables; List of Figures; Preface; Acknowledgments; Chapter 1: Introduction; 1.1. General Introduction; 1.2. Understanding Isotropy; 1.3. Elasticity and Displacement; 1.3.1. Stress Tensor; 1.3.2. Strain Tensor; 1.3.3. Constitutive Equations of Linear Elasticity; 1.3.4. Isotropic Linear Elasticity; 1.4. Elastic Constants and Interrelation; 1.5. Equation of Motion in Isotropic Media; 1.5.1. Plane Wave in 3-D Space; 1.5.2. Simplified 1-D Wave Equation.
- 1.6. Equation of Motion in Anisotropic Media1.6.1. Generalized Plane Wave in Anisotropic Media; 1.6.2. Plane Wave in Transversely Isotropic Media; References; Chapter 2: Introduction to Wave Propagation; 2.1. Wave Propagation in Poroelastic Media; 2.1.1. Biot's High-Frequency Limit; 2.1.2. Biot's Low-Frequency Limit: Purely Elastic Wave; 2.1.3. Biot's Low-Frequency Limit: Viscoelastic Dissipation; Assumptions & Limitations: Biot's Theory; 2.2. Acoustic Dispersion and Critical Frequency; 2.2.1. Qualitative Discussion; 2.2.2. General Quantitative Solution; 2.2.2.1. Compressional wave.
- 2.2.2.2. Shear wave2.3. Geerstma-Smit Approximation; Assumptions Geerstma-Smit Approximation; 2.4. Gassmann's Theory of Fluid-Saturated Media; Assumptions & Limitations: Gassmann's Theory; 2.5. Biot's Theory and Gassmann's Prediction; 2.6. Wavetrain Propagation in a Borehole; 2.6.1. Snell's Law; 2.6.2. Acoustic Modes in a Borehole; 2.6.3. Leaky Modes; 2.6.4. Pseudo-Rayleigh Waves; References; Chapter 3: Borehole Acoustic Logging; 3.1. Acoustic Tool Principle (Monopole); 3.1.1. Single Transmitter Monopole Tool; Limitations of the Single Transmitter Monopole Tool.
- 3.1.2. Borehole Compensated SonicLimitations & Advantages of Monopole BHC Measurement; 3.1.3. Long-Spaced Sonic and BHC; Limitations & Advantages of LSS & BHC Measurements; 3.1.4. Array Sonic Tool; Limitations & Advantages of Array Sonic Measurement; 3.2. Waveforms in Monopole Tool; 3.2.1. Waveforms in a Fast Formation; 3.2.2. Waveforms in a Slow Formation; 3.3. The Tool Principle (Dipole Acoustic Tool); Limitations & Advantages of Dipole Sonic Measurement; 3.4. Further Tool Advancements; 3.4.1. Sonic Scanner; Limitations & Advantages of Sonic Scanner Measurement.
- 3.4.2. Quadrupole Sonic LWD ToolLimitations & Advantages of Sonic Quadrupole Measurement; 3.4.3. Seismic While Drilling; 3.5. Borehole Waveform Processing; 3.5.1. First-motion Detection; 3.5.2. Semblance Correlation; 3.5.3. Slowness-Time-Coherence; 3.5.3.1. STC concept; 3.5.3.2. Dispersion (bias) correction; 3.5.3.3. Dispersion correction: weighted spectral average concept; 3.5.4. Dispersive Processing; 3.5.4.1. Flexural dispersion characteristics; 3.5.4.2. Dispersive analog of STC; 3.5.4.3. Dispersive STC (DSTC); 3.5.5. QC Techniques; 3.5.5.1. Slowness-frequency projection.