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| The course aims to provide fundamental of reservoir gas flow and emphasize the importance of flow regime |
| and non-Darcy flow on test design and interpretation for new wells and for the possibility of improving the |
| performance of older wells. Student will calculate and determine the effect of each system component on |
| total well performance, which permits optimum sizing of tubing, flowline, separator, and compressor. |
| Formation damage, gas well de-watering, hydrate formation, water influx, and abnormal reservoir pressure |
| problems are reviewed as well as field gas processing. |
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| Production, reservoir, and facilities engineers and others involved in gas production, transportation, and |
| storage including field supervisors |
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| - Gas property (real gas behavior, equation of state, phase behavior |
| - Reservoir performance (well test, stabilized inflow performance, turbulence and skin |
| effect, perforation effect, abnormal pressure effect, deliverability) |
| - Flow in pipe and restriction (pressure loss, multiphase flow, flow regimes, hold-up |
| correlation, tubing and flowline size effect) |
| - Liquid loading effect and liquid removal method |
| - Type and selection of compressor |
| - Concept and design of flow metering |
| - Gas condensate reservoir |
| - Gas cycling |
| - Hydrate formation |
| - Nodal analysis |
| - Water coning prevention |
| - Gas well production optimization |
| - Gas Processing |
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| As requested |
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