Hoboken, N.J., : John Wiley and Sons

Salem, Mass., : Scrivener Pub., c2012

1-118-51115-8

1-283-64539-4

1-118-51113-1

1-118-51109-3

1 online resource (296 p.)

Advances in Natural Gas Engineering

WuYing, MSc.

CarrollJohn J. <1958->

ZhuWeiyao

665.7/3

Natural gas

Gas wells

Oil wells

Oil field flooding

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Sour Gas and Related Technologies; Contents; Preface; Introduction; Part 1: Data: Experiments and Correlation; 1. Equilibrium Water Content Measurements for Acid Gas at High Pressures and Temperatures; 1.1 Introduction; 1.2 Experimental; 1.3 Recent Results and Modelling; 1.3.1 Partitioning of Hydrogen Sulfide (H2S Solubility in Water); 1.3.2 Partitioning of Water (Water Content in H2S); 1.3.3 Discussion of Results; 1.4 Conclusions; References; 2. Comparative Study on Gas Deviation Factor Calculating Models for CO2 Rich Gas Reservoirs; 2.1 Introduction; 2.2 Deviation Factor Correlations

2.2.1 Empirical Formulas2.2.1.1 Dranchuk-Purvis-Robinsion (DPR) Model; 2.2.1.2 Dranchuk-Abu-Kassem (DAK) Model; 2.2.1.3 Hall-Yarborough (HY) Model; 2.2.1.4 Beggs and Brill (BB) Model; 2.2.1.5 Sarem Model; 2.2.1.6 Papay Model; 2.2.1.7 Li Xiangfang (LXF) Model; 2.2.1.8 Zhang Guodong Model; 2.2.2 Correction Methods; 2.2.2.1 Guo

Xuqiang Method; 2.2.2.2 Carr-Kobayshi-Burrows Correction Method; 2.2.2.3 Wiehert-Aziz Correction Method [16]; 2.3 Model Optimization; 2.4 Conclusions; References; 3. H2S Viscosities and Densities at High-Temperatures and Pressures; 3.1 Introduction; 3.2 Experimental

3.3 Results and Discussion3.4 Conclusions and Outlook; 3.5 Acknowledgement; References; 4. Solubility of Methane in Propylene Carbonate; 4.1 Introduction; 4.2 Results and Discussion; 4.3 Nomenclature; 4.4 Acknowledgement; References; Part 2: Process; 5. A Holistic Look at Gas Treating Simulation; 5.1 Introduction; 5.2 Clean Versus Dirty Solvents: Heat Stable Salts; 5.2.1 CO2 Removal Using MEA, and MDEA Promoted With Piperazine; 5.2.2 Piperazine-promoted MDEA in an Ammonia Plant; 5.2.3 Post-combustion CO2 Capture; 5.2.4 LNG Absorber; 5.3 Summary

6. Controlled Freeze ZoneTM Commercial Demonstration Plant Advances Technology for the Commercialization of North American Sour Gas Resources6.1 Introduction - Gas Demand and Sour Gas Challenges; 6.2 Acid Gas Injection; 6.3 Controlled Freeze ZoneTM - Single Step Removal of CO2 and H2S; 6.4 Development Scenarios Suitable for Utilizing CFZTM Technology; 6.5 Commercial Demonstration Plant Design & Initial Performance Data; 6.6 Conclusions and Forward Plans; Bibliography; 7. Acid Gas Dehydration - A DexProTM Technology Update; 7.1 Introduction; 7.2 Necessity of Dehydration; 7.3 Dehydration Criteria

7.4 Acid Gas - Water Phase Behaviour7.5 Conventional Dehydration Methods; 7.5.1 Desiccant Adsorption; 7.5.2 Desiccant Absorption; 7.5.3 Separation Based Processes; 7.5.4 Avoidance Based Processes; 7.5.5 Thermodynamic/Refrigerative Based Processes; 7.6 Development of DexPro; 7.7 DexPro Operating Update; 7.8 DexPro Next Steps; 7.9 Murphy Tupper - 2012 Update; 7.10 Acknowledgements; 8. A Look at Solid CO2 Formation in Several High CO2 Concentration Depressuring Scenarios; 8.1 Introduction; 8.2 Methodology; 8.3 Thermodynamic Property Package Description; 8.4 Model Configuration; 8.5 Results

8.6 Discussion

Carbon dioxide has been implicated in the global climate change, and CO2 sequestration is a technology being explored to curb the anthropogenic emission of CO2 into the atmosphere. The injection of CO2 for enhanced oil recovery (EOR) has the duel benefit of sequestering the CO2 and extending the life of some older fields. This volume presents some of the latest information on these processes covering physical properties, operations, design, reservoir engineering, and geochemistry for AGI and the related technologies.