Study of Flow Field Characteristics During the Impact of a High-pressure Gas Jet on a Bulk-loaded Liquid

A visual experiment platform for high-pressure gas jet impacting the bulk-loaded liquid was designed and built in order to investigate the real law of the interaction between the high-pressure gas jet and the liquid medium during the liquid-balance launch of rocket launcher. The experiments of singl...

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Bibliographic Details
Published in:Journal of physics. Conference series 2023-01, Vol.2437 (1), p.12020
Main Authors: Wang, Jian, Jiang, Kun, Cheng, Shenshen, Wang, Hao
Format: Article
Language:English
Subjects:
displacement equation
gas cavity
Gas jets
Gas temperature
High pressure
Liquid flow
Liquid-balance launch
Physics
pressure fluctuation
Rocket launchers
Temperature
Turbulent mixing
visual experiment platform
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Summary:A visual experiment platform for high-pressure gas jet impacting the bulk-loaded liquid was designed and built in order to investigate the real law of the interaction between the high-pressure gas jet and the liquid medium during the liquid-balance launch of rocket launcher. The experiments of single-phase gas jet injection and the high-pressure gas jet at different temperatures impacting the bulk-loaded liquid were carried out, and the effects of gas temperature on the characteristics of the gas-liquid flow field have been revealed. The results show that the turbulent mixing between the high-pressure gas jet and the liquid medium leads to the appearance of pressure fluctuations in the gas chamber connected to the nozzle. The higher the gas temperature, the greater the amplitude of the pressure fluctuations. Under the impact of high-pressure gas jet, a gas cavity with an arc-shaped head is formed inside the bulk-loaded liquid. The higher the gas temperature, the faster and more unstable the development of the gas cavity and the flow field. The displacement equation of the gas cavity confirms to the first-order exponential decay function, and the error between the fitting value of the established mathematical model and the measured value is within 2%.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/2437/1/012020