Abstract:

A new annular supersonic nozzle was designed for natural gas dehydration based on the principle of conservation of angular momentum. Corresponding mathematical and physical models were established. The flow characteristics of natural gas in the annular supersonic nozzle were numerically simulated with the RNG k-εturbulence model. The results showed that natural gas expanded to supersonic velocity，resulting in a low temperature in the annular nozzles. The Mach number could reach 1.85 at a low temperature of －70 ℃ at the nozzle exit. The swirling motion was generated by the vanes located at the entrance of the nozzle，leading to a centrifugal field of about 640 000g. Water could be condensed and removed from natural gas under the combined effects of low temperature and strong centrifugal field. The strong swirling flow could be obtained in the annular nozzle as a result of the central body. When the swirling flow passed through the nozzle，the expansion characteristics of the nozzle was weakened，which was different from the common Laval nozzle.