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In this piece, geometry of dually fluid contained in is considered introducing a speedy jet at a location onto fluid at rest. With introducing the jet, simulations are carried out after constructing geometry with suitable meshing. Refinement is done at jet ways. Surface of target fluid at rest socked and at a velocity magnitude the fluid in container hid the jet. Reappearance of jet is seen and bubble is drawn. The influence is investigated in regard of relation between the surface dip generated and variation of jet velocity. There are many narrow down actions which can be observed.

Jet, air, bubble, computational fluid dynamics, jet-air-gas, simulations.

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How to Cite
KHOKHAR, Z. H. (2019). SPEEDY GAS ONTO TARGET FLUID AT REST. Journal of Basic and Applied Research International, 25(6), 290-294. Retrieved from https://ikprress.org/index.php/JOBARI/article/view/4797
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McKelvey KN, Yieh HN, Zakanycz S and Brodkey RS. Turbulent motion, mixing and kinetics in a chemical reactor configuration. AIChE Journal. 1975;21(6):1165-1176.

Morchain J, Maranges C and Fonade C. CFD modelling of a two-phase jet aerator under influence of a crossflow. Water Research. 2000;34(13):3460-3472.

Chilton TH, Genereaux RP. The mixing of gases for reaction. AIChE Transaction. 1930; 25:102-122.

Johnson DA, Wood PE. Self‐sustained oscillations in opposed impinging jets in an enclosure. The Canadian Journal of Chemical Engineering. 2000;78(5):867-875.

Kresta SM, Wood PE. Prediction of the three‐dimensional turbulent flow in stirred tanks. AIChE Journal. 1991;37(3):448-460.

Lin CH, O'Brien EE. Turbulent shear flow mixing and rapid chemical reactions: An analogy. Journal of Fluid Mechanics. 1974; 64(01):195-206.

Spedding PL, Woods GS, Raghunathan RS, Watterson JK. Vertical two-phase flow: Part II: experimental semi-annular flow and hold-up. Chemical Engineering Research and Design. 1998;76(5):620-627.

Nguyen AV, Evans GM. Computational fluid dynamics modelling of gas jets impinging onto liquid pools. Applied Mathematical Modelling. 2006;30(11):1472-1484.

Ersson M, Tilliander A, Jonsson L, Jönsson P. A mathematical model of an impinging air jet on a water surface. ISIJ International. 2008; 48(4):377-384.

Farhangi MM, Passandideh-Fard M, Bagherian B. Bubble rise and departure from a viscous liquid free surface. In ASME. International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers. 2008;1893-1900.

Chen WY, An YR, Jiang N, Yuan QH. May. Study on numerical simulation of single-phase injection device flow flied. In Information and Computing Science, 2009. ICIC'09. Second International. IEEE. 2009; 4:358-361.

Hirt CW, Nichols BD. Volume of fluid (VOF) method for the dynamics of free boundaries. Journal of Computational Physics. 1981;39(1): 201-225.

Manninen M, Taivassalo V, Kallio S. On the mixture model for multiphase flow. Valtion teknillinen tutkimuskeskus; 1996.

Huang S. Numerical simulation of oil water hydrocyclone using reynolds stress model for Eulerian multiphase flows. The Canadian Journal of Chemical Engineering. 2005;83(5): 829-834.