| Description |
1 online resource (1146) |
|
text txt rdacontent |
|
computer c rdamedia |
|
online resource cr rdacarrier |
| Note |
Print version record. |
| Summary |
Fundamentals of Gas Lift Engineering: Well Design and Troubleshooting discusses the important topic of oil and gas reservoirs as they continue to naturally deplete, decline, and mature, and how more oil and gas companies are trying to divert their investments in artificial lift methods to help prolong their assets. While not much physically has changed since the invention of the King Valve in the 1940s, new developments in analytical procedures, computational tools and software, and many related technologies have completely changed the way production engineers and well operators face the daily design and troubleshooting tasks and challenges of gas lift, which can now be carried out faster, and in a more accurate and productive way, assuming the person is properly trained. This book fulfills this training need with updates on the latest gas lift designs, troubleshooting techniques, and real-world field case studies that can be applied to all levels of situations, including offshore. Making operational and troubleshooting techniques central to the discussion, the book empowers the engineer, new and experienced, to analyze the challenge involved and make educated adjustments and conclusions in the most economical and practical way. Packed with information on computer utilization, inflow and outflow performance analysis, and worked calculation examples made for training, the book brings fresh air and innovation to a long-standing essential component in a well's lifecycle. |
| Note |
Includes index. |
| Contents |
Title page; Table of Contents; Copyright; Dedication; Acknowledgments; Chapter 1: Gas properties; Abstract; 1.1. Equation of state; 1.2. Gas viscosity; 1.3. Solubility of natural gas in water; 1.4. Solubility of water vapor in natural gas; 1.5. Hydrates; 1.6. Specific heat ratio; Chapter 2: Single-phase flow; Abstract; 2.1. Single-phase gas flow; 2.2. Single-phase liquid flow; Chapter 3: Multiphase flow; Abstract; 3.1. Qualitative aspects; 3.2. General quantitative aspects in multiphase flow; 3.3. Examples of correlations and mechanistic models developed for vertical upward multiphase flow. |
|
3.4. Horizontal multiphase flow3.5. Unified models; 3.6. Fluid flow through annular cross-sections; Chapter 4: Single and multiphase flow through restrictions; Abstract; 4.1. Gas flow through restrictions; 4.2. Liquid flow through restrictions; 4.3. Multiphase flow through restrictions; Chapter 5: Total system analysis applied to gas lift design; Abstract; 5.1. Determination of the depth of the operating point of injection; 5.2. Examples of the effect that different gas lift system's components or fluid properties might have on the liquid production of a well on gas lift. |
|
5.3. Calculation examplesChapter 6: Gas lift equipment; Abstract; 6.1. Gas lift valves and latches; 6.2. Gas lift mandrels; 6.3. Wireline equipment; 6.4. Types of completions for gas lift installations; Chapter 7: Gas lift valve mechanics; Abstract; 7.1. Force-balance equations for the different types of gas lift valves; 7.2. Calculation of the nitrogen pressure at different conditions; 7.3. Determination of the port and bellows areas; 7.4. Examples of Problems Using the Force-Balance Equations for Designing and Troubleshooting Gas Lift Installations. |
|
Chapter 8: Gas flow through gas lift valvesAbstract; 8.1. Use of the Thornhill-Craver equation for gas lift valves; 8.2. Mathematical models for the dynamic behavior of gas lift valves; 8.3. Use of chokes installed downstream of the seat; 8.4. Use of chokes installed upstream of the seat; 8.5. Orifice valves with special geometry seats; Chapter 9: Design of continuous gas lift installations; Abstract; 9.1. Determination of the operating injection point depth, target injection gas flow rate, and the liquid flow rate the well can produce. |
|
9.2. Gas lift mandrel spacing procedures and valve design calculations9.3. Stability check of the gas lift design; 9.4. Examples of gas lift designs; Chapter 10: Design of intermittent gas lift installations; Abstract; 10.1. Description of the production cycle; 10.2. General fundamentals and implementation guidance for intermittent gas lift; 10.3. Types of completions for intermittent gas lift; 10.4. Description of pilot valves; 10.5. Types of control of the surface gas injection; 10.6. Intermittent gas lift design for simple type completions; 10.7. Design of accumulation chambers. |
| Subject |
Oil wells -- Gas lift.
|
|
Pétrole -- Puits -- Allčgement de la colonne d'huile au gaz.
|
|
TECHNOLOGY & ENGINEERING -- Mining.
|
|
Oil wells -- Gas lift
|
| Other Form: |
Print version: Hernandez, Ali. Fundamentals of Gas Lift Engineering : Well Design and Troubleshooting. Saint Louis : Elsevier Science, ©2016 9780128041338 |
| ISBN |
0128041463 (electronic bk.) |
|
9780128041468 (electronic bk.) |
|
9780128041338 |
|
0128041331 |
| Standard No. |
AU@ 000061151126 |
|
CHBIS 010796208 |
|
CHNEW 001013427 |
|
CHVBK 40393673X |
|
DEBSZ 482469420 |
|
GBVCP 879391987 |
|
UKMGB 017756254 |
|
