| 论文简介 |
Liquid loading from condensed fluids will cause the gas to flow intermittently, sharply reduce the production, which may completely stops. However, the currently existing gas well deliquification technologies are not competitive due to the large volume and extremely high operation expenses. The approach is thus proposed in this paper by establishing the liquid atomization through a supersonic nozzle in high-speed gas environments. The natural-gas condensate and water are therefore pushed into a moving stream of gas where they are broken up into small droplets and flushed away. This approach is especially suited for low-pressure and low-yielding wells. Numerical and experimental studies are firstly performed to determine the optimal nozzle structure. The exit velocity can reach 5–6 times the speed of sound. As expected, the magnitude of the gas velocity determines the droplet size, which ranges from 10 lm to 50 lm in most circumstances and is far less than the minimum threshold for being discharged. A year-long field test on three producing gas wells is conducted to validate the applicability of this method, the water and condensates build-up are removed completely to maintain the long-term stability and productivity in gas production. Also, this method enables to extend the useful life of equipment, reduce downtime and maximize the production capabilities. |
(创新港)
