| Description |
1 online resource |
| Contents |
Cover -- Half Title -- Title -- Copyright -- Contents -- Preface -- Authors -- Chapter 1 Petroleum Reservoir Fluids -- 1.1 Reservoir Fluid Constituents -- 1.2 Properties of Reservoir Fluid Constituents -- 1.3 Phase Envelopes -- 1.4 Classification of Petroleum Reservoir Fluids -- 1.5 Shale Fluids -- References -- Chapter 2 Sampling, Quality Control, and Compositional Analyses -- 2.1 Fluid Sampling -- 2.2 Quality Control of Fluid Samples -- 2.2.1 Bottom Hole/Wellhead Samples -- 2.2.2 Separator Samples -- 2.2.2.1 Quality Control of Separator Gas -- 2.2.2.2 QC of Separator Liquid |
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2.3 Hoffmann Plot -- 2.4 Compositional Analyses -- 2.4.1 Gas Chromatography -- 2.4.1.1 Preparation of Oil Mixtures -- 2.4.1.2 Preparation of Gas Condensate Mixtures -- 2.4.1.3 Gas Chromatograph -- 2.4.2 TBP Analysis -- 2.4.2.1 Molecular Weight from Freezing Point Depression -- 2.5 Reservoir Fluid Composition from Bottom Hole Sample -- 2.6 Reservoir Fluid Composition from Separator Samples -- 2.7 Mud-Contaminated Samples -- References -- Chapter 3 PVT Experiments -- 3.1 Routine PVT Experiments -- 3.1.1 Constant Mass Expansion Experiment -- 3.1.1.1 Oil Mixtures -- 3.1.1.2 Gas Condensate Mixtures |
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3.1.1.3 Dry Gases -- 3.1.2 Differential Liberation Experiment -- 3.1.3 Constant-Volume Depletion Experiment -- 3.1.4 Separator Test -- 3.1.5 Viscosity Experiment -- 3.1.6 Material Balance Tests -- 3.1.7 Measurement of Gas Z-Factors -- 3.2 EOR PVT Experiments -- 3.2.1 Solubility Swelling Test -- 3.2.2 Equilibrium Contact Experiment -- 3.2.3 Multi-Contact Experiment -- 3.2.4 Slim Tube Experiment -- 3.2.5 Gas Revaporization Experiment -- References -- Chapter 4 Equations of State -- 4.1 van der Waals Equation -- 4.2 Redlich-Kwong Equation -- 4.3 Soave-Redlich-Kwong Equation |
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4.4 Peng-Robinson Equation -- 4.5 Peneloux Volume Correction -- 4.6 Other Cubic Equations of State -- 4.7 Fugacity Coefficients -- 4.8 Nonclassical Mixing Rules -- 4.9 PC-SAFT Equation -- 4.10 GERG-2008 Equation of State -- 4.11 Span-Wagner Equation -- 4.12 Other Equations of State -- 4.13 Postscript on the Role of Cubic Equations in the Oil Industry -- References -- Chapter 5 C7+ Characterization -- 5.1 Classes of Components -- 5.1.1 Defined Components to C6 -- 5.1.2 C7+ Fractions -- 5.1.3 Plus Fraction -- 5.2 Binary Interaction Coefficients -- 5.3 Lumping -- 5.4 Delumping |
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5.5 Mixing of Multiple Fluids -- 5.6 Characterizing of Multiple Compositions to the Same Pseudocomponents -- 5.7 Heavy Oil Compositions -- 5.7.1 Biodegraded Oils -- 5.8 PC-SAFT Characterization Procedure -- References -- Chapter 6 Flash and Phase Envelope Calculations -- 6.1 Pure Component Vapor Pressures from Cubic Equations of State -- 6.2 Mixture Saturation Points from Cubic Equations of State -- 6.3 Flash Calculations -- 6.3.1 Stability Analysis -- 6.3.2 Solving the Flash Equations -- 6.3.3 Multiphase PT-Flash -- 6.3.4 Three Phase PT-Flash with a Pure Water Phase |
| Summary |
"Developed in conjunction with several oil companies using experimental data for real reservoir fluids, Phase Behavior of Petroleum Reservoir Fluids introduces industry standard methods for modeling the phase behavior of petroleum reservoir fluids at different stages in the process. Keeping mathematics to a minimum, this book discusses sampling, characterization, compositional analyses, and equations of state used to simulate various pressure-volume-temperature (PVT) properties of reservoir fluids. Updated throughout, this third edition: reflects advances in the field including shale gas, updates cubic and non-cubic equations and between classical and non-classical mixing rules, experimental techniques for modeling of asphaltene precipitation, and water formation and hydrate inhibitors, and provides practical knowledge essential for achieving optimal design and cost-effective operations in a petroleum processing plant. The book offers engineers working in the energy sector a solid understanding of the phase behavior of the various fluids present in a petroleum reservoir"-- Provided by publisher |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Karen Schou Pedersen earned a PhD in liquid physics at the Technical University of Denmark. Her work with liquids at a fundamental level continued in positions as a research associate at the University of Edinburgh and at the nuclear research center Institute Laue-Langevin, Grenoble, France. She founded Calsep A/S in 1982, worked for Calsep as a senior principal consultant until 2022, and was responsible for software development and projects within reservoir fluid modeling and flow assurance. She is the author of more than 60 publications on the phase behavior of oil and gas mixtures. Her current position is Senior Principal Consultant at Kapexy Aps, a company specializing in reservoir fluid modeling. Peter Lindskou Christensen earned a PhD at the Technical University of Denmark. In the 1980s, he was employed at Risø National Laboratories in Denmark, where he was responsible for PVT modeling for use in reservoir simulation studies. For a 10-year period in the 1990s, he was an associate professor at the Technical University of Denmark and taught thermodynamics, unit operations, and oil and gas technology. After leaving the university, he became a senior principal consultant at Calsep A/S, where he developed new techniques for matching experimental PVT data and was engaged in several fluid modeling projects. Peter is today a senior consultant at Kapexy Aps. Jawad Azeem Shaikh earned an MSc in petroleum technology at the University of Pune in India. His current position is Sales Director and Principal Consultant of Calsep FZ LLC in Dubai where he has been responsible for several projects carried out in collaboration with the local oil industry within the design of enhanced oil recovery studies, equation of state modeling, and reservoir fluid communication. Before joining Calsep, he was an advanced studies supervisor for Core Laboratories International BV in Abu Dhabi. His job functions at Core Laboratories included technical support to field engineers to carry out fluid sampling as well as project coordination and data evaluation within PVT, compositional, and enhanced oil recovery projects. He has authored several papers and articles on sampling, PVT lab work, fluid communication, and equation of state modeling |
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Description based on print version record and CIP data provided by publisher; resource not viewed |
| Subject |
Petroleum reserves -- Mathematical models
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Petroleum -- Geology -- Mathematical models
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Phase rule and equilibrium.
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Thermodynamic equilibrium.
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Heavy oil.
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Hydrocarbons.
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Hydrocarbons
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SCIENCE / Chemistry / Industrial & Technical
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Heavy oil
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Hydrocarbons
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Petroleum -- Geology -- Mathematical models
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Petroleum reserves -- Mathematical models
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Phase rule and equilibrium
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Thermodynamic equilibrium
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| Form |
Electronic book
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| Author |
Christensen, Peter L. (Peter Lindskou), author.
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Shaikh, Jawad Azeem, author.
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| LC no. |
2023031174 |
| ISBN |
9780429457418 |
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0429457413 |
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9781040002094 |
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1040002099 |
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9780429854668 |
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0429854668 |
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9780429854644 |
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0429854641 |
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