Se flow experimenality and strong manage efficiency; umbrella. Via the experimentsSe flow experimenality and sturdy

Se flow experimenality and strong manage efficiency; umbrella. Via the experiments
Se flow experimenality and sturdy control performance; umbrella. Through the experiments dynamic tal device based on the phase isolation collection it may intuitively observe the around the fluid. the gas ater two-phase and oil as ater multiphase flow, we verified the feasibility of your DGLS instrument’s gas iquid separation. We also observed the dynamic response law, and determined a reasonable structure and separation efficiency for the DGLS. This laid six.three. Experiment Research on Oil as ater Multiphase Flow the foundation for the subsequent structural design of the instrument and its large-scale application in oilfield output profile logging. The goal in the dynamic experiment will be to confirm the feasibility from the So that you can C6 Ceramide Biological Activity investigate the DGSL’s separation impact, we performed dynamic experimenliquid separation efficiency measurement. Figure 13 shows the multiphase f tal calibration of your turbine flowmeter under various gas-phase flows in oil as ater mental device based on the phase isolation collection umbrella. By way of the e three-phase flow. In the experiment, the gas flow was five m3 /d, ten m3 /d, and 15 m3 /d, the oil ater liquid flow ranged from 1 m3 /d to 60 m3 /d, and the water holdup ranged from 50 to 100 .Simulated wellboreOilGasSeparateSeparatedevice.Appl. Sci. 2021, 11,on the DGLS instrument’s gas iquid separation. We also obs law, and determined a reasonable structure and separation e Collecting laid the foundation for the subsequent structural style of t umbrella 17 of 21 scale application in oilfield output profile logging.Collecting Figure 13. DGLS multiphase flow experiment device.umbrellaIn order to investigate the DGSL’s separation effect, we performed dyna mental calibration of your turbine flowmeter below distinctive gas-phase flows water three-phase flow. In the experiment, the gas flow was five m3/d, 10 m3/d, a the oil ater liquid flow ranged from 1 m3/d to 60 m3/d, and the water hol from 50 to 100 . Figure 14 shows the turbine flowmeter’s response characteristic curve w flow is 5m3/d. The horizontal axis represents the total liquid flow, and the represents themultiphase flow experiment device. turbine flowmeter’s response frequency. The turbine respons Figure 13. DGLS Figurewith DGLS multiphase liquidexperiment device. response chara 13. the improve in total flow flow, as well as the output increases Figure 14 curve gas not change/d.shows the turbine flowmeter’s response Hydroxyflutamide custom synthesis characteristicand thewhen theaxis 3 with water holdup. In addition, the curve shows a very good phenomen flow is 5m The horizontal axis represents the total liquid flow, vertical ship. This shows that the DGLS isolates the gas and separation effect, we In order flowmeter’s response frequency. The turbine response frequency represents the turbine to investigate the DGSL’s liquid phases.increases using the boost in total liquid flow, as well as the output response characteristics mental calibration of your turbine flowmeter below diverse do not alter with water holdup. In addition, the curve shows a fantastic phenomenon partnership. This shows that the DGLS In the experiment, the gas flow was water three-phase flow. isolates the gas and liquid phases.70 the oil ater liquid flow ranged from 1 m3/d to 60 m3/d, an Water L from 50 to 100 . ( GL ) Water holdup 100 60 Water holdup 90 ( Figure 14 shows GL ) turbine flowmeter’s response chara the Water holdup 80 ( GL ) 50 Water holdup 70 ( GL ) flow is 5m3/d. The horizontal axis represents the total liqui Water holdup 60 (.