Wave Propagation in Drilling, Well Logging and Reservoir Applications.
Wave propagation is central to all areas of petroleum engineering, e.g., drilling vibrations, MWD mud pulse telemetry, swab-surge, geophysical ray tracing, ocean and current interactions, electromagnetic wave and sonic applications in the borehole, but rarely treated rigorously or described in truly...
Clasificación: | Libro Electrónico |
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Autor principal: | |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Hoboken :
Wiley,
2014.
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Colección: | Advances in Petroleum Engineering.
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Temas: | |
Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Cover; Half Title page; Title page; Copyright page; Dedication; Preface; Acknowledgements; Chapter 1: Overview and Fundamental Ideas; 1.1 The Classical Wave Equation; 1.2 Functional Representation; 1.3 Separation of Variables and Eigenfunction Expansions; 1.4 Standing Versus Propagating Waves; 1.5 Laplace Transforms; 1.6 Fourier Transforms; 1.7 External Forces Versus Boundary Conditions; 1.8 Point Force and Dipole Wave Excitation; 1.9 First-Order Partial Differential Equations; 1.10 References; Chapter 2: Kinematic Wave Theory; 2.1 Whitham's Theory in Nondissipative Media*
- 2.2 Simple Attenuation Modeling2.3 KWT in Homogeneous Dissipative Media; 2.4 High-Order Kinematic Wave Theory; 2.5 Effect of Low-Order Nonuniformities; 2.6 Three-Dimensional Kinematic Wave Theory; 2.7 References; Chapter 3: Examples from Classical Mechanics; 3.1 Example 3-1. Lateral Vibration of Simple Beams; 3.2 Example 3-2. Acoustic Waves in Waveguides; 3.3 Example 3-3. Gravity-Capillary Waves in Deep Water; 3.4 Example 3-4. Fluid-Solid Interaction
- Waves on Elastic Membranes; 3.5 Example 3-5. Problems in Hydrodynamic Stability; 3.6 References.
- Chapter 4: Drillstring Vibrations: Classic Ideas and Modern Approaches4.1 Typical Downhole Vibration Environment; 4.2 Axial Vibrations; 4.3 Lateral Bending Vibrations; 4.4 Torsional and Whirling Vibrations; 4.5 Coupled Axial, Torsional and Lateral Bending Vibrations; 4.6 References; Chapter 5: Mud Acoustics in Modern Drilling; 5.1 Governing Lagrangian Equations; 5.2 Governing Eulerian Equations; 5.3 Transient Finite Difference Modeling; 5.4 Swab-Surge Modeling; 5.5 MWD Mud Pulse Telemetry; 5.6 Recent MWD Developments; 5.7 References; Chapter 6: Geophysical Ray Tracing.
- 6.1 Classical Wave Modeling- Eikonal Methods and Ray Tracing6.2 Format's Principle of Least Time (via Calculus of Variations); 6.3 Fermat's Principle Revisited Via Kinematic Wave Theory; 6.4 Modeling Wave Dissipation; 6.5 Ray Tracing Over Large Space-Time Scales; 6.6 Subtle High-Order Effects; 6.7 Travel-Time Modeling; 6.8 References; Chapter 7: Wave and Current Interaction in the Ocean; 7.1 Wave Kinematics and Energy Summary.; 7.2 Sources of Hydrodynamic Loading; 7.3 Instabilities Due to Heterogeneity; 7.4 References.
- Chapter 8: Borehole Electromagnetics
- Diffusive and Propagation Transients8.1 Induction and Propagation Resistivity; 8.2 Conductive Mud Effects in Wireline and MWD Logging; 8.3 Longitudinal Magnetic Fields; 8.4 Apparent Anisotropic Resistivities for Electromagnetic Logging Tools in Horizontal Wells; 8.5 Borehole Effects
- Invasion and Eccentricity; 8.6 References; Chapter 9: Reservoir Engineering
- Steady, Diffusive and Propagation Models; 9.1 Buckley-Leverett Multiphase Flow; 9.2 References; Chapter 10: Borehole Acoustics
- New Approaches to Old Problems.
- 10.1 Stoneley Waves in Permeable Wells
- Background.