«Previous Article|Table of Contents|Next Article»

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]

Issue:

2023年06期

Page:

46-54

Research Field:

目次

Publishing date:

Info

Title:

Numerical simulation of the influence of single jet obliquely impinging against wall

Author(s):

DAI Qingwen¹;  YANG Jianwen²;  YANG Bin¹;  WANG Ying¹

1.Shanghai Key Laboratory of Multiphase Flow and Heat Transfer in Power Engineering,School of Energy and Power Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China; 2.Xi'an Aerospace Propulsion Institute, Xi'an 710100, China

Keywords:

liquid rocket engine;  oblique jet impinging;  liquid film;  numerical simulation;  gas-liquid flow

PACS:

V434+.14

DOI:

-

Abstract:

In order to investigate the morphological variation rule of liquid film after oblique cylindrical jet impinging on solid surface, a multiphase flow model named Volume of Fluid Phase Model(VOF)was adopted and combined with the polyhedral hybrid grid.The geometric characteristic parameters variations of the liquid film after the jet impacting on the wall obliquely under different working conditions were analyzed, and the key characteristics of the liquid film spreading under different working conditions were obtained.The results show that after the jet dashing against the solid surface obliquely, the wall pressure gradually decreases from the edge of the liquid film to the central axis.As the jet velocity increases, the pressure on the wall near the impinging point increases, while the pressure on the liquid film collection area decreases.At the same time, the liquid film has the maximum velocity, which occurs near the impact point, and the minimum velocity appears near the confluence point of the hydraulic jump zone.As the jet aperture increases, the area of the maximum velocity and minimum velocity region of the spreading liquid film scales up obviously.

References:

[1] AHMED M,ASHGRIZ N,TRAN H N.Break-up length and spreading angle of liquid sheets formed by splash plate nozzles[J].Journal of Fluids Engineering,2009,131(1):1.
[2] 韩红伟,王艺杰.液体火箭发动机混合比影响因素研究[J].导弹与航天运载技术,2022(1):36-40.
[3] DRAKE M C,FANSLER T D,SOLOMON A S,et al.Piston fuel films as a source of smoke and hydrocarbon emissions from a wall-controlled spark-ignited direct-injection engine[J].Transactions of the ASABE,2003,112:762-783.
[4] LI Y Y,ZHANG C H,YU W,et al.Effects of rapid burning characteristics on the vibration of a common-rail diesel engine fueled with diesel-methanol dual-fuel[J].Fuel,2016,170:176-184.
[5] GUHA A,BARRON R M,BALACHANDAR R.An experimental and numerical study of water jet cleaning process[J].Journal of Materials Processing Technology,2011,211(4):610-618.
[6] BHAGAT R K,WILSON D I.Flow in the thin film created by a coherent turbulent water jet impinging on a vertical wall[J].Chemical Engineering Science,2016,152:606-623.
[7] WILSON D I,LE B L,DAO H D A,et al.Surface flow and drainage films created by horizontal impinging liquid jets[J].Chemical Engineering Science,2012,68(1):449-460.
[8] ARNOLD R,SUSLOV D,HAIDN O J.Circumferential film cooling effectiveness in a LOx/H₂ subscale combustion chamber[J].Journal of Propulsion and Power,2009,25(3):760-770.
[9] KIBAR A.Experimental and numerical investigations of the impingement of an oblique liquid jet onto a superhydrophobic surface:Energy transformation[J].Fluid Dynamics Research,2016,48(1):015501.
[10] KIBAR A,KARABAY H,YIG^ˇIT K S,et al.Experimental investigation of inclined liquid water jet flow onto vertically located superhydrophobic surfaces[J].Experiments in Fluids,2010,49(5):1135-1145.
[11] GOOD R,NOLLET B.Fluid film distribution investigation for liquid film cooling application[C]//53rd AIAA/SAE/ASEE Joint Propulsion Conference.Reston,Virginia:AIAA,2017.
[12] 唐亮,胡锦华,刘计武,等.倾斜射流撞壁实验研究及液膜几何参数建模[J].航空学报,2020,41(12):124061.
[13] 林庆国,杨成虎,刘犇.射流角度和壁面曲率对撞壁液膜的影响[J].国防科技大学学报,2013,35(2):17-21.
[14] WANG R X,HUANG Y,FENG X,et al.Semi-empirical model for the engine liquid fuel sheet formed by the oblique jet impinging onto a plate[J].Fuel,2018,233:84-93.
[15] HASSON D,PECK R E.Thickness distribution in a sheet formed by impinging jets[J].AIChE Journal,1964,10(5):752-754.
[16] WATSON E J.The radial spread of a liquid jet over a horizontal plane[J].Journal of Fluid Mechanics,1964,20(3):481-499.
[17] INAMURA T,YANAOKA H,TOMODA T.Prediction of mean droplet size of sprays issued from wall impingement injector[J].AIAA Journal,2004,42(3):614-621.
[18] YANG L J,LI P H,FU Q F.Liquid sheet formed by a Newtonian jet obliquely impinging on pro/hydrophobic surfaces[J].International Journal of Multiphase Flow,2020,125:103192.
[19] YANG L J,ZHAO F,FU Q F,et al.Liquid sheet formed by impingement of two viscous jets[J].Journal of Propulsion and Power,2014,30(4):1016-1026.
[20] GRADECK M,KOUACHI A,DANI A,et al.Experimental and numerical study of the hydraulic jump of an impinging jet on a moving surface[J].Experimental Thermal and Fluid Science,2006,30(3):193-201.
[21] FARD M,ASHGRIZ N,MOSTAGHIMI J.A numerical model for flow simulation in spray nozzles[C]//42nd AIAA Aerospace Sciences Meeting and Exhibit.Reston,Virginia:AIAA,2004.
[22] 林庆国.空间轨控发动机高效燃烧室仿真与试验研究[D].长沙:国防科学技术大学,2015.
[23] 邱添.液体射流冲击平板数值模拟研究[D].天津:中国民航大学,2020.
[24] 徐文,高新妮,胡保林,等.离心式喷嘴一次破碎与二次雾化的数值模拟[J].火箭推进,2022,48(4):13-20.
XU W,GAO X N,HU B L,et al.Numerical simulation of primary breakup and secondary atomization for centrifugal nozzle[J].Journal of Rocket Propulsion,2022,48(4):13-20.
[25] HIRT C W,NICHOLS B D.Volume of fluid(VOF)method for the dynamics of free boundaries[J].Journal of Computational Physics,1981,39(1):201-225.
[26] 唐亮,王凯,李文龙,等.倾斜射流撞壁铺展的数值仿真[J].航空学报,2023,44(4):141-153.
[27] KATE R P,DAS P K,CHAKRABORTY S.Hydraulic jumps due to oblique impingement of circular liquid jets on a flat horizontal surface[J].Journal of Fluid Mechanics,2007,573:247-263.
[28] 唐亮,李平,周立新,等.倾斜射流撞壁形成的液膜外形的理论建模[J].推进技术,2021,42(2):327-334.

Memo

Memo:

-

Common functions

Last Update: 1900-01-01