London ; New York : Routledge, 1996

0-415-17205-5

XIII, 199 p. : ill. ; 24 cm

Experience of Archaeology

930.1

Archeologia greca

Inglese

Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2023]

©2023

1-119-72991-2

1-119-72784-7

1 online resource (380 pages)

622.338

Hydrocarbon reservoirs - Analysis

Rocks - Permiability

Petroleum - Migration

Fluid dynamics

Inglese

Includes bibliographical references and index.

Cover -- Title Page -- Copyright Page -- Contents -- List of Contributors -- Preface -- Introduction -- Chapter 1 Unconventional Reservoirs: Advances and Challenges -- 1.1  Background -- 1.2  Advances -- 1.2.1  Wettability -- 1.2.2  Permeability -- 1.3  Challenges -- 1.3.1  Multiscale Systems -- 1.3.2  Hydrocarbon Production -- 1.3.3  Recovery Factor -- 1.3.4  Unproductive Wells -- 1.4  Concluding Remarks -- References -- Part I Pore-Scale Characterizations -- Chapter 2 Pore-Scale Simulations and Digital Rock Physics -- 2.1  Introduction -- 2.2  Physics of Pore-Scale Fluid Flow in Unconventional Rocks -- 2.2.1  Physics of Gas Flow -- 2.2.1.1  Gas Slippage and Knudsen Layer Effect -- 2.2.1.2  Gas Adsorption/Desorption and Surface Diffusion -- 2.2.2  Physics of Water Flow -- 2.2.3  Physics of Condensation -- 2.3  Theory of Pore-Scale Simulation Methods -- 2.3.1  The Isothermal Single-Phase Lattice Boltzmann Method -- 2.3.1.1  Bhatnagar-Gross-Krook (BGK) Collision Operator -- 2.3.1.2  The Multi-Relaxation Time (MRT)-LB Scheme -- 2.3.1.3  The Regularization Procedure -- 2.3.2  Multi-phase Lattice Boltzmann Simulation Method -- 2.3.2.1  Color-Gradient Model -- 2.3.2.2  Shan-Chen Model -- 2.3.3  Capture Fluid Slippage at the Solid Boundary -- 2.3.4  Capture the Knudsen Layer/Effective Viscosity -- 2.3.5  Capture the Adsorption/Desorption and Surface Diffusion Effects -- 2.3.5.1  Modeling of Adsorption in LBM -- 2.3.5.2  Modeling of Surface Diffusion Via LBM -- 2.4  Applications -- 2.4.1  Simulation of Gas Flow in Unconventional Reservoir Rocks -- 2.4.1.1  Gas Slippage -- 2.4.1.2  Gas Adsorption -- 2.4.1.3  Surface Diffusion of Adsorbed Gas -- 2.4.2  Simulation of Water Flow in Unconventional Reservoir Rocks -- 2.4.3  Simulation of Immiscible Two-Phase Flow -- 2.4.4  Simulation of Vapor Condensation -- 2.4.4.1  Model Validations.

2.4.4.2  Vapor Condensation in Two Adjacent Nano-Pores -- 2.5  Conclusion -- References -- Chapter 3 Digital Rock Modeling: A Review -- 3.1  Introduction -- 3.2  Single-Scale Modeling of Digital Rocks -- 3.2.1  Experimental Techniques -- 3.2.1.1  Imaging Technique of Serial Sectioning -- 3.2.1.2  Laser Scanning Confocal Microscopy -- 3.2.1.3  X-Ray Computed Tomography Scanning -- 3.2.2  Computational Methods -- 3.2.2.1  Simulated Annealing -- 3.2.2.2  Markov Chain Monte Carlo -- 3.2.2.3  Sequential Indicator Simulation -- 3.2.2.4  Multiple-Point Statistics -- 3.2.2.5  Machine Learning -- 3.2.2.6  Process-Based Modeling -- 3.3  Multiscale Modeling of Digital Rocks -- 3.3.1  Multiscale Imaging Techniques -- 3.3.2  Computational Methods -- 3.3.2.1  Image Superposition -- 3.3.2.2  Pore-Network Integration -- 3.3.2.3  Image Resolution Enhancement -- 3.3.2.4  Object-Based Reconstruction -- 3.4  Conclusions and Future Perspectives -- Acknowledgments -- References -- Chapter 4 Scale Dependence of Permeability and Formation Factor: A Simple Scaling Law -- 4.1  Introduction -- 4.2  Theory -- 4.2.1  Funnel Defect Approach -- 4.2.2  Application to Porous Media -- 4.3  Pore-network Simulations -- 4.4  Results and Discussion -- 4.5  Limitations -- 4.6  Conclusion -- Acknowledgment -- References -- Part II Core-Scale Heterogeneity -- Chapter 5 Modeling Gas Permeability in Unconventional Reservoir Rocks -- 5.1  Introduction -- 5.1.1  Theoretical Models -- 5.1.2  Pore-Network Models -- 5.1.3  Gas Transport Mechanisms -- 5.1.4  Objectives -- 5.2  Effective-Medium Theory -- 5.3  Single-Phase Gas Permeability -- 5.3.1  Gas Permeability in a Cylindrical Tube -- 5.3.2  Pore Pressure-Dependent Gas Permeability in Tight Rocks -- 5.3.3  Comparison with Experiments -- 5.3.4  Comparison with Pore-Network Simulations -- 5.3.5  Comparaison with Lattice-Boltzmann Simulations.

5.4  Gas Relative Permeability -- 5.4.1  Hydraulic Flow in a Cylindrical

Pore -- 5.4.2  Molecular Flow in a Cylindrical Pore -- 5.4.3  Total Gas Flow in a Cylindrical Pore -- 5.4.4  Gas Relative Permeability in Tight Rocks -- 5.4.5  Comparison with Experiments -- 5.4.6  Comparison with Pore-Network Simulations -- 5.5  Conclusions -- Acknowledgment -- References -- Chapter 6 NMR and Its Applications in Tight Unconventional Reservoir Rocks -- 6.1  Introduction -- 6.2  Basic NMR Physics -- 6.2.1  Nuclear Spin -- 6.2.2  Nuclear Zeeman Splitting and NMR -- 6.2.3  Nuclear Magnetization -- 6.2.4  Bloch „Equations’and NMR Relaxation -- 6.2.5  Simple NMR Experiments: Free Induction Decay and CPMG Echoes -- 6.2.6  NMR Relaxation of a Pure Fluid in a Rock Pore -- 6.2.7  Measured NMR CPMG Echoes in a Formation Rock -- 6.2.8  Inversion -- 6.2.8.1  Regularized Linear Least Squares -- 6.2.8.2  Constrains of the Resulted NMR Spectrum in Inversion -- 6.2.9  Data from NMR Measurement -- 6.3  NMR Logging for Unconventional Source Rock Reservoirs -- 6.3.1  Brief Introduction of Unconventional Source Rocks -- 6.3.2  NMR Measurement of Source Rocks -- 6.3.2.1  NMR Log of a Source Rock Reservoir -- 6.3.3  Pore Size Distribution in a Shale Gas Reservoir -- 6.4  NMR Measurement of Long Whole Core -- 6.4.1  Issues of NMR Instrument for Long Sample -- 6.4.2  HSR-NMR of Long Core -- 6.4.3  Application Example -- 6.5  NMR Measurement on Drill Cuttings -- 6.5.1  Measurement Method -- 6.5.1.1  Preparation of Drill Cuttings -- 6.5.1.2  Measurements -- 6.5.2  Results -- 6.6  Conclusions -- References -- Chapter 7 Tight Rock Permeability Measurement in Laboratory: Some Recent Progress -- 7.1  Introduction -- 7.2  Commonly Used Laboratory Methods -- 7.2.1  Steady-State Flow Method -- 7.2.2  Pressure Pulse-Decay Method -- 7.2.3  Gas Research Institute Method.

7.3  Simultaneous Measurement of Fracture and Matrix Permeabilities from Fractured Core Samples -- 7.3.1  Estimation of Fracture and Matrix Permeability from PPD Data for’Two’Flow’Regimes -- 7.3.2  Mathematical Model -- 7.3.3  Method Validation and Discussion -- 7.4  Direct Measurement of Permeability-Pore Pressure Function -- 7.4.1  Knudsen Diffusion, Slippage Flow, and Effective Gas Permeability -- 7.4.2  Methodology for Directly Measuring Permeability-Pore Pressure Function -- 7.4.3  Experiments -- 7.5  Summary and Conclusions -- References -- Chapter 8 Stress-Dependent Matrix Permeability in Unconventional Reservoir Rocks -- 8.1  Introduction -- 8.2  Sample Descriptions -- 8.3  Permeability Test Program -- 8.4  Permeability Behavior with Confining Stress Cycling -- 8.5  Matrix Permeability Behavior -- 8.6  Concluding Remarks -- Acknowledgments -- References -- Chapter 9 Assessment of Shale Wettability from Spontaneous Imbibition Experiments -- 9.1  Introduction -- 9.2  Spontaneous Imbibition Theory -- 9.3  Samples and Analytical Methods -- 9.3.1  SI Experiments -- 9.3.2  Barnett Shale from United States -- 9.3.3  Silurian Longmaxi Formation and Triassic Yanchang Formation Shales from China -- 9.3.4  Jurassic Ziliujing Formation Shale from China -- 9.4  Results and Discussion -- 9.4.1  Complicated Wettability of Barnett Shale Inferred Qualitatively from SI Experiments -- 9.4.1.1  Wettability of Barnett Shale -- 9.4.1.2  Properties of Barnett Samples and Their Correlation to Wettability -- 9.4.1.3  Low Pore Connectivity to Water of Barnett Samples -- 9.4.2  More Oil-Wet Longmaxi Formation Shale and More Water-Wet Yanchang Formation Shale -- 9.4.2.1  TOC and Mineralogy -- 9.4.2.2  Pore Structure Difference Between Longmaxi and Yanchang Samples -- 9.4.2.3  Water and Oil Imbibition Experiments.

9.4.2.4  Wettability of Longmaxi and Yanchang Shale Samples Deduced from SI Experiments -- 9.4.3  Complicated Wettability of Ziliujing Formation Shale -- 9.4.3.1  TOC and Mineralogy -- 9.4.3.2  Pore

Structure -- 9.4.3.3  Water and Oil Imbibition Experiments -- 9.4.3.4  Wettability of Ziliujing Formation Shale Indicated from SI Experiments and its Correlation to Shale Pore Structure and Composition -- 9.4.4  Shale Wettability Evolution Model -- 9.5  Conclusions -- Acknowledgments -- References -- Chapter 10 Permeability Enhancement in Shale Induced by Desorption -- 10.1  Introduction -- 10.1.1  Shale Mineralogical Characteristics -- 10.1.2  Flow Network -- 10.1.2.1  Bedding-Parallel Flow Network -- 10.1.2.2  Bedding-Perpendicular Flow Paths -- 10.2  Adsorption in Shales -- 10.2.1  Langmuir Theory -- 10.2.2  Competing Strains in Permeability Evolution -- 10.2.2.1  Poro-Sorptive Strain -- 10.2.2.2  Thermal-Sorptive Strain -- 10.3  Permeability Models for Sorptive Media -- 10.3.1  Strain Based Models -- 10.4  Competing Processes during Permeability Evolution -- 10.4.1  Resolving Competing Strains -- 10.4.2  Solving for Sorption-Induced Permeability Evolution -- 10.5  Desorption Processes Yielding Permeability Enhancement -- 10.5.1  Pressure Depletion -- 10.5.2  Lowering Partial Pressure -- 10.5.3  Sorptive Gas Injection -- 10.5.4  Desorption with Increased Temperature -- 10.6  Permeability Enhancement Due to Nitrogen Flooding -- 10.7  Discussion -- 10.8  Conclusion -- References -- Chapter 11 Multiscale Experimental Study on Interactions Between Imbibed Stimulation Fluids and Tight Carbonate Source Rocks -- 11.1  Introduction -- 11.2  Fluid Uptake Pathways -- 11.2.1  Experimental Methods -- 11.2.1.1  Materials -- 11.2.1.1.1  Rock Sample -- 11.2.1.2  Experimental Procedure.

11.2.1.2.1  3D Microscale Visualization of Thin-Section Rock Sample in As-Received State.