| Description |
1 online resource |
| Series |
Energy policies, politics and prices |
| Contents |
ENHANCED OIL RECOVERY: METHODS, ECONOMIC BENEFITS AND IMPACTS ON THE ENVIRONMENT; ENHANCED OIL RECOVERY: METHODS, ECONOMIC BENEFITS AND IMPACTS ON THE ENVIRONMENT; Library of Congress Cataloging-in-Publication Data; Contents; Preface; Chapter 1: Enhanced Oil Recovery: Growth, Economic and Environmental Benefits and Risks; Abstract; 1. Introduction; 2. Oil Production from CO2-EOR; 3. Literature Review; 4. Commodity Futures and Spot Markets; 4.1. T-West Texas Intermediate Light Sweet Crude Future; 4.2. ICE EUA Futures; 5. Net Present Value of Investment; 6. Investment Risk |
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7. The Real Option ApproachConclusion; Acknowledgments; References; Chapter 2: Contributions of the Chemical Industry to Enhanced Oil Recovery; Abstract; Introduction; Chemical Enhanced Oil Recovery; Key Contributions of Chemical Industry; Conclusion; References; Chapter 3: Research of SC-CO2 in Improving the Recovery of Heavy Oil; Abstract; 1. Study on the Solubility of CO2 in Ultra-Heavy Oil; 1.1. Experiment Apparatus; 1.2. Test Sample; 1.3. Test Conditions; 1.4. Results and Discussion; 1.4.1. The Properties of CO2 Dissolved in the Degassing and Dehydration Oil |
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1) Confirm the highest solution of CO2 in the ultra-heavy oil in the Z411-P2 well2) Confirm the volume factor of the CO2 dissolved in the ultra-heavy oil; 3) Determine the density of the ultra-heavy oil after dissolving CO2; 4) Determine the viscosity of the extra-heavy oil after dissolving CO2; 1.4.2. The Dissolved CO2 Characteristics of Different Water Degassed Oils; 2. CO2-Crude Oil Interfacial Tension Experiment; 2.1. Experimental Medicine; 2.2. Experimental Apparatus; 2.3. Experimental Procedure; 2.4. Experimental Results and Analysis; 3. CO2 Core Displacement Experiment |
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3.1. Experimental Objective3.2. Experimental Drug; 3.3. Experimental Apparatus and Flow Chart; 3.4. Experimental Core Data; 3.5. Experimental Procedure; 3.6. Experimental Results and Analysis; Chapter 4: Synthesis and Assessment of a Novel AM-Co-AMPS Polymer for Enhanced Oil Recovery (EOR); Abstract; 1. Introduction; 2. Experimental; 2.1. Material; 2.2. Polymerization Processes; 2.3. Polymerization Initiator; 3. Sample Preparation and Aging; 3.1. All of the Polymers Examined in This Paper Were; Prepared As Solutions; 3.2. Determination of Apparent Viscosity; 4. Result and Discussion |
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4.1. Optimization of Polymerization Processes4.2. IR Characterization of AM-co-AMPS Polymer; 4.3. Polymer Rheology; 4.4. Polymer Viscosity As a Function of Temperature; 4.5. Polymer Stability Tests at 90 ; Conclusion; References; Chapter 5: Improved Oil Recovery vs. Enhanced Oil Recovery; National Research Tomsk Polytechnic University, ; Institute of Petroleum Geology and Geophysics, ; SB RAS, Novosibirsk, Russia; Abstract; Introduction; Geofluid-Dynamical Aspects. Critical Threshold of Perturbation; Seismic-Geophysical Method. Dynamic-Fluid Models (DFM) |
| Summary |
Significant quantities of oil can be extracted using Enhanced Oil Recovery (EOR) methods. One of the main methods of this type is CO2-EOR, which also has a positive impact on the environment as it results in the practically permanent storage of CO2, the main greenhouse gas (GHG). When its use is economically viable, the technology for extracting oil using CO2 (CO2-EOR) enables significant quantities of oil to be obtained and at the same time, provides storage for large volumes of CO2. It thus brings in both financial profits and environmental benefits if the oil extracted is used instead of cr |
| Notes |
Includes index |
|
Print version record |
| Subject |
Secondary recovery of oil.
|
|
TECHNOLOGY & ENGINEERING -- Mining.
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Secondary recovery of oil
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| Form |
Electronic book
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| Author |
Knight, Alicia, 1976- editor.
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| LC no. |
2020687693 |
| ISBN |
9781634639439 |
|
163463943X |
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