Details
Gas Injection for Disposal and Enhanced Recovery
Advances in Natural Gas Engineering 1. Aufl.
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180,99 € |
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| Verlag: | Wiley |
| Format: | EPUB |
| Veröffentl.: | 02.09.2014 |
| ISBN/EAN: | 9781118938577 |
| Sprache: | englisch |
| Anzahl Seiten: | 400 |
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Beschreibungen
<p>This is the fourth volume in a series of books focusing on natural gas engineering, focusing on two of the most important issues facing the industry today: disposal and enhanced recovery of natural gas. This volume includes information for both upstream and downstream operations, including chapters on shale, geological issues, chemical and thermodynamic models, and much more.</p> <p>Written by some of the most well-known and respected chemical and process engineers working with natural gas today, the chapters in this important volume represent the most cutting-edge and state-of-the-art processes and operations being used in the field. Not available anywhere else, this volume is a must-have for any chemical engineer, chemist, or process engineer working with natural gas.</p> <p>There are updates of new technologies in other related areas of natural gas, in addition to disposal and enhanced recovery, including sour gas, acid gas injection, and natural gas hydrate formations. <i>Advances in Natural Gas Engineering</i> is an ongoing series of books meant to form the basis for the working library of any engineer working in natural gas today. Every volume is a must-have for any engineer or library.</p>
<p><b>Section 1: Data and Correlations<br /> <br /> 1</b> <b>Densities of Carbon Dioxide-Rich Mixtures Part I: Comparison with Pure CO</b><b>2</b> <b>1</b><br /> <i>Erin L. Roberts and John J. Carroll<br /> <br /> </i>1.1 Introduction 1<br /> <br /> 1.2 Density 2<br /> <br /> 1.3 Literature Review 2<br /> <br /> 1.4 Calculations 4<br /> <br /> 1.5 Discussion 19<br /> <br /> 1.6 Conclusion 27<br /> <br /> References 27<br /> <br /> <b>2 Densities of Carbon Dioxide-Rich Mixtures Part II: Comparison with Thermodynamic Models 29<br /> </b><i>Erin L. Roberts and John J. Carroll<br /> <br /> </i>2.1 Introduction 29<br /> <br /> 2.2 Literature Review 30<br /> <br /> 2.3 Calculations 30<br /> <br /> 2.4 Lee Kesler 31<br /> <br /> 2.5 Benedict-Webb- Rubin (BWR) 37<br /> <br /> 2.6 Peng-Robinson 43<br /> <br /> 2.7 Soave-Redlich-Kwong 49<br /> <br /> 2.8 AQUAlibrium 54<br /> <br /> 2.9 Discussion 60<br /> <br /> 2.10 Conclusion 62<br /> <br /> References 63<br /> <br /> <b>3 On Transferring New Constant Pressure Heat Capacity Computation Methods to Engineering Practice 65<br /> </b><i>Sepideh Rajaeirad and John M. Shaw<br /> <br /> </i>3.1 Introduction 65<br /> <br /> 3.2 Materials and Methods 66<br /> <br /> 3.3 Results and Discussion 67<br /> <br /> 3.4 Conclusions 70<br /> <br /> References 70<b><br /> <br /> </b><b>4 Developing High Precision Heat Capacity Correlations for Solids, Liquids and Ideal Gases 73<br /> </b><i>Jenny Boutros and John M. Shaw<br /> <br /> </i>4.1 Introduction 73<br /> <br /> 4.2 Databases and Methods 75<br /> <br /> 4.3 Results and Discussion 77<br /> <br /> 4.4 Conclusion 77<br /> <br /> References 77<br /> <br /> <b>5 Method for Generating Shale Gas Fluid Composition from Depleted Sample 79<br /> </b><i>Henrik Sorensen, Karen S. Pedersen and Peter L. Christensen<br /> <br /> </i>5.1 Introduction 79<br /> <br /> 5.2 Theory of Chemical Equilibrium Applied to Reservoir Fluids 80<br /> <br /> 5.3 Reservoir Fluid Composition from a Non-Representative Sample 83<br /> <br /> 5.4 Numerical Examples 87<br /> <br /> 5.5 Discussion of the Results 94<br /> <br /> 5.6 Conclusions 96<br /> <br /> 5.7 Nomenclature 97<br /> <br /> Greek letters 97<br /> <br /> Sub and super indices 97<br /> <br /> References 98<br /> <br /> <b>6 Phase Equilibrium in the Systems Hydrogen Sulfi de + Methanol and Carbon Dioxide + Methanol 99<br /> </b><i>Marco A. Satyro and John J. Carroll<br /> <br /> </i>6.1 Introduction 100<br /> <br /> 6.2 Literature Review 101<br /> <br /> 6.3 Modelling With Equations Of State 102<br /> <br /> 6.4 Summary 107<br /> <br /> 6.5 Nomenclature 108<br /> <br /> Greek 109<br /> <br /> Subscripts 109<br /> <br /> References 109<br /> <br /> <b>7 Vapour-Liquid Equilibrium, Viscosity and Interfacial Tension Modelling of Aqueous Solutions of Ethylene Glycol or Triethylene Glycol in the Presence of Methane, Carbon Dioxide and Hydrogen Sulfide 111<br /> </b><i>Shu Pan, Na Jia, Helmut Schroeder, Yuesheng Cheng, Kurt A.G. Schmidt and Heng-Joo Ng<br /> <br /> </i>7.1 Introduction 111<br /> <br /> 7.2 Results and Discussion 112<br /> <br /> 7.3 Conclusions 122<br /> <br /> 7.4 Nomenclature 122<br /> <br /> 7.5 Acknowledgement 125<br /> <br /> References 124<br /> <br /> Appendix 7.A 125<br /> <br /> <b>Section 2: Process Engineering<br /> <br /> </b><b>8 Enhanced Gas Dehydration using Methanol Injection in an Acid Gas Compression System 129<br /> </b><i>M. Rafay Anwar, N. Wayne McKay and Jim R. Maddocks<br /> <br /> </i>8.1 Introduction 129<br /> <br /> 8.2 Methodology 130<br /> <br /> 8.3 CASE I: 100 % CO2 132<br /> <br /> 8.4 CASE II: 50 Percent CO2, 50 Percent H2S 140<br /> <br /> 8.5 CASE III: Enhanced Oil Recovery Composition 142<br /> <br /> 8.6 Conclusion 150<br /> <br /> 8.7 Additional Notes 151<br /> <br /> References 151<br /> <br /> <b>9 Comparison of the Design of CO</b><b>2</b><b>-capture Processes using Equilibrium and Rate Based Models 153<br /> </b><i>A.R.J. Arendsen, G.F. Versteeg, J. van der Lee,R. Cota and M.A. Satyro<br /> <br /> </i>9.1 Introduction 155<br /> <br /> 9.2 VMG Rate Base 155<br /> <br /> 9.3 Rate Based Versus Equilibrium Based Models 157<br /> <br /> 9.4 Process Simulations 162<br /> <br /> 9.5 Conclusions 173<br /> <br /> References 174<br /> <br /> <b>10 Post-Combustion Carbon Capture Using Aqueous Amines: A Mass-Transfer Study 177<br /> </b><i>Ray A. Tomcej<br /> <br /> </i>10.1 Introduction 178<br /> <br /> 10.2 Mass Transfer Basics 179<br /> <br /> 10.3 Factors Infl uencing Mass Transfer 182<br /> <br /> 10.4 Examples 188<br /> <br /> 10.5 Summary 190<br /> <br /> References 191<br /> <br /> <b>11 BASF Technology for CO</b><b>2</b> <b>Capture and Regeneration 193<br /> </b><i>Sean Rigby, Gerd Modes, Stevan Jovanovic, John Wei, Koji Tanaka, Peter Moser and Torsten Katz<br /> <br /> </i>11.1 Introduction 195<br /> <br /> 11.2 Materials and Methods 197<br /> <br /> 11.3 Results 206<br /> <br /> 11.4 Conclusions 223<br /> <br /> 11.5 Acknowledgements and Disclaimer 225<br /> <br /> References 226<br /> <br /> <b>12 Seven Deadly Sins of Filtration and Separation Systems in Gas Processing Operations 227<br /> </b><i>David Engel and Michael H. Sheilan<br /> <br /> </i>12.1 Gas Processing and Contamination Control 228<br /> <br /> 12.2 The Seven Deadly Sins of Filtration and Separation Systems in Gas Processing Operations 231<br /> <br /> 12.3 Concluding Remarks 240<br /> <br /> <b>Section 3: Acid Gas Injection<br /> <br /> </b><b>13 Development of Management Information System of Global Acid Gas Injection Projects 243<br /> </b><i>Qi Li, Guizhen Liu and Xuehao Liu<br /> <br /> </i>13.1 Background 243<br /> <br /> 13.2 Architecture of AGI-MIS 244<br /> <br /> 13.3 Data management 246<br /> <br /> 13.4 Data mining and information visualization 248<br /> <br /> 13.5 Interactive program 251<br /> <br /> 13.6 Conclusions 252<br /> <br /> 13.7 Acknowledgements 252<br /> <br /> References 253<br /> <br /> <b>14 Control and Prevention of Hydrate Formation and Accumulation in Acid Gas Injection Systems During Transient Pressure/Temperature Conditions 255<br /> </b><i>Alberto A. Gutierrez and James C. Hunter<br /> <br /> </i>14.1 General Agi System Considerations 255<br /> <br /> 14.2 Composition And Properties Of Treated Acid Gases 256<br /> <br /> 14.3 Regulatory And Technical Restraints On Injection Pressures 258<br /> <br /> 14.4 Phase Equilibria, Hydrate Formation Boundaries And Prevention Of Hydrate Formation In Agi Systems 259<br /> <br /> 14.5 Formation, Remediation And Prevention Of Hydrate Formation During Unstable Injection Conditions – Three Case Studies 263<br /> <br /> 14.6 Discussion And Conclusions 272<br /> <br /> References 273<br /> <br /> <b>15 Review of Mechanical Properties Related Problems for Acid Gas Injection 275<br /> </b><i>Qi Li, Xuehao Liu, Lei Du and Xiaying Li<br /> <br /> </i>15.1 Introduction 276<br /> <br /> 15.2 Impact Elements 276<br /> <br /> 15.3 Coupled Processes 285<br /> <br /> 15.4 Failure Criteria 286<br /> <br /> 15.5 Conclusions 286<br /> <br /> 15.6 Acknowledgements 287<br /> <br /> References 287<br /> <br /> <b>16 Comparison of CO</b><b>2</b> <b>Storage Potential in Pyrolysed Coal Char of different Coal Ranks 293<br /> </b><i>Pavan Pramod Sripada, MM Khan, Shanmuganathan Ramasamy, VajraTeji Kanneganti, Japan Trivedi and Rajender Gupta<br /> <br /> </i>16.1 Introduction 294<br /> <br /> 16.2 Apparatus, Methods, & Materials 295<br /> <br /> 16.3 Results And Discussion 298<br /> <br /> 16.4 Conclusion 302<br /> <br /> References 302<br /> <br /> <b>Section 4: Carbon Dioxide Storage<br /> <br /> </b><b>17 Capture of CO</b><b>2</b> <b>and Storage in Depleted Gas Reservoirs in</b> <b>Alberta as Gas Hydrate 305<br /> </b><i>Duo Sun, Nagu Daraboina, John Ripmeester and Peter Englezos<br /> <br /> </i>17.1 Experimental 306<br /> <br /> 17.2 Results And Discussion 307<br /> <br /> 17.3 Conclusions 310<br /> <br /> Reference 310<br /> <br /> <b>18 Geological Storage of CO</b><b>2</b> <b>as Hydrate in a McMurray Depleted Gas Reservoir 311<br /> </b><i>Olga Ye. Zatsepina, Hassan Hassanzadeh and Mehran Pooladi-Darvish<br /> <br /> </i>18.1 Introduction 312<br /> <br /> 18.2 Fundamentals 313<br /> <br /> 18.3 Reservoir 314<br /> <br /> 18.4 Sensitivity Studies 322<br /> <br /> 18.5 Long-term storage 326<br /> <br /> 18.6 Summary and conclusions 327<br /> <br /> 18.7 Acknowledgements 329<br /> <br /> References 329<br /> <br /> <b>Section 5: Reservoir Engineering<br /> <br /> </b><b>19 A Modified Calculation Method for the Water Coning Simulation Mode in Oil Reservoirs with Bottom Water Drive 331<br /> </b><i>Weiyao Zhu, Xiaohe Huang and Ming Yue<br /> <br /> </i>19.1 Introduction 331<br /> <br /> 19.2 Mathematical Model 332<br /> <br /> 19.3 Solution 334<br /> <br /> 19.4 Results and Discussion 335<br /> <br /> 19.5 Conclusions 336<br /> <br /> 19.6 Nomenclature 336<br /> <br /> References 337<br /> <br /> <b>20 Prediction Method on the Multi-scale Flow Patterns and the Productivity of a Fracturing Well in Shale Gas Reservoir 339<br /> </b><i>Weiyao Zhu, Jia Deng and M.A. Qian<br /> <br /> </i>20.1 Introduction 340<br /> <br /> 20.2 Multi-scale flow state analyses of the shale gas reservoirs 340<br /> <br /> 20.3 Multi-scale seepage non-linear model in shale gas reservoir 343<br /> <br /> 20.4 Productivity prediction method of fracturing well 348<br /> <br /> 20.5 Production Forecasting 351<br /> <br /> 20.6 Conclusions 354<br /> <br /> 20.7 Acknowledgements 354<br /> <br /> References 355<br /> <br /> <b>21 Methane recovery from natural gas hydrate in porous sediment using gaseous CO</b><b>2</b><b>, liquid CO</b><b>2</b><b>, and CO</b><b>2</b> <b>emulsion 357<br /> </b><i>Sheng-li Li, Xiao-Hui Wang, Chang-Yu Sun,Qing-Yuan and Guang-Jin Chen<br /> <br /> </i>21.1 Introduction<br /> <br /> 21.2 Experiments 359<br /> <br /> 21.3 Results and Discussion 361<br /> <br /> 21.4 Conclusion 368<br /> <br /> 21.5 Acknowledgements 369<br /> <br /> References 369<br /> <br /> <b>Section 6: Hydrates<br /> <br /> </b><b>22 On the Role of Ice-Solution Interface in Heterogeneous Nucleation of Methane Clathrate Hydrates 371<br /> </b><i>PaymanPirzadeh and Peter G. Kusalik<br /> <br /> </i>22.1 Introduction 371<br /> <br /> 22.2 Method Summary 373<br /> <br /> 22.3 Results and Discussion 373<br /> <br /> 22.4 Summary 378<br /> <br /> References 379<br /> <br /> <b>23 Evaluating and Testing of Gas Hydrate Anti-Agglomerants in (Natural Gas + Diesel Oil + Water) Dispersed System 381<br /> </b><i>Chang-Yu Sun, Jun Chen, Ke-Le Yan, Sheng-Li Li,</i> <i>Bao-ZiPeng and Guang-Jin Chen<br /> <br /> </i>23.1 Introduction 381<br /> <br /> 23.2 Experimental Apparatus And Analysis 382<br /> <br /> 23.3 Results And Discussion 382<br /> <br /> 23.4 Conclusion 385<br /> <br /> <b>Section 7: Biology<br /> <br /> </b><b>24 “Is That a Bacterium in Your Trophosome, or Are You</b> <b>Just Happy to See Me?” - Hydrogen Sulfide, Chemosynthesis, and the Origin of Life 387<br /> </b><i>Neil Christopher Griffin<br /> <br /> </i>24.1 Introducing the extremophiles 387<br /> <br /> 24.2 Tempted by the guts of another 388<br /> <br /> 24.3 Chemosynthesis 101 389<br /> <br /> 24.4 Chemosynthetic bacteria and the origins of life 391<br /> <br /> References 392<br /> <br /> <b>Index 399</b></p>
<p><strong>Ying (Alice) Wu</strong> is currently the President of Sphere Technology Connection Ltd. (STC) in Calgary, Canada. From 1983 to 1999 she was an Assistant Professor and Researcher at Southwest Petroleum Institute (now Southwest Petroleum University, SWPU) in Sichuan, China. She received her MSc in Petroleum Engineering from the SWPU and her BSc in Petroleum Engineering from Daqing Petroleum University in Heilongjiang, China. <p><strong>John J. Carroll</strong>, PhD, PEng is the Director, Geostorage Process Engineering for Gas Liquids Engineering, Ltd. in Calgary, Canada. Dr. Carroll holds bachelor and doctoral degrees in chemical engineering from the University of Alberta, Edmonton, Canada, and is a registered professional engineer in the provinces of Alberta and New Brunswick in Canada.?His fist book, <em>Natural Gas Hydrates: A Guide for Engineers</em>, is now in its second edition, and he is the author or co-author of 50 technical publications and about 40 technical presentations. <p><strong>Qi Li,</strong> PhD, is the Professor of CCS Research Group at Institute of Rock and Soil Mechanics at the Wuhan Branch of the Chinese Academy of Sciences. He is a geoscientist with expertise in the fields of hydrogeology and engineering mechanics. Professor Li's research is currently focused in the CCS field include mechanical stability of disposal reservoirs, multiphase flow, coupled processes, and risk monitoring. He also involved some research projects using laboratory and numerical tools to design novel subsurface disposal processes and on disposal site monitoring systems on different temporal and spatial scales.
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