Experimental Study on Impinging Velocimetry of Gel Simulants Based on PIV

Journal of Propulsion Technology ›› 2014, Vol. 35 ›› Issue (4): 565-569.

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Experimental Study on Impinging Velocimetry of Gel Simulants Based on PIV

School of Mechanical Engineering, Nanjing University of Science and Technology,Nanjing 210094, China;School of Mechanical Engineering, Nanjing University of Science and Technology,Nanjing 210094, China;School of Mechanical Engineering, Nanjing University of Science and Technology,Nanjing 210094, China;School of Mechanical Engineering, Nanjing University of Science and Technology,Nanjing 210094, China

Published:2021-08-15

基于PIV的凝胶模拟液撞击雾化速度场实验研究

陈杰, 封锋, 马虎, 武晓松

南京理工大学机械学院, 江苏南京 210094;南京理工大学机械学院, 江苏南京 210094;南京理工大学机械学院, 江苏南京 210094;南京理工大学机械学院, 江苏南京 210094

作者简介:陈杰(1985—),男,硕士生,研究领域为固体火箭发动机。E-mail:liangzichen@hotmail.com
基金资助:
航天科技创新基金(CASC201103)。

Abstract

Abstract: In order to study the atomization of gelled propellant, the effects with different pressure drop and impinging angle on atomization of impinging injector with gelled propellant were studied by a Time-Resolved Particle Image Velocimetry (TR-PIV), in which the injection impinging angles were 45°,60°,75°,90°and 120°,the pressures drop ranged from 0.4MPa to 0.8MPa. The experimental results indicate that the distribution of atomization velocity is symmetry by the impinging axis and has one peak.The further from the strike spot, the smaller the atomization velocity and more uniform.The effective impinging speed of gel propellant is improved by increasing impinging angle and pressure drop.That is because the liquid kinetic energy converted to the energy of liquid broken is enhanced, and the atomization quality is improved. Finally, the gel propellant prepared in laboratory can be fully atomized when the effective impinging velocity is above 27.9m/s. 

Key words: Gel propellant; Time-resolved particle image velocimetry; Injector; Effective impinging velocity; Atomization

摘要： 为了更好研究凝胶推进剂的雾化,采用时间分辨粒子图像测速(TR-PIV), 研究了不同撞击角度(45°,60°,75°,90°和120°)和射流压差(0.4MPa~0.8MPa)对凝胶推进剂雾化速度的影响。实验结果表明:雾化液滴速度对于撞击轴线呈单峰对称分布,距离撞击点越远,雾化液滴速度越小且分布越均匀；增大撞击角和增大射流压差都可提高凝胶推进剂有效撞击速度,即增加撞击后液体动能转换液体破碎所需的能量,雾化质量提高；当有效撞击速度大于27.9m/s时,实验室配置的凝胶推进剂可充分雾化。 

关键词: 凝胶推进剂;时间分辨粒子图像测速;喷注器;有效撞击速度;雾化 

CHEN Jie,FENG Feng,MA Hu,WU Xiao-song. Experimental Study on Impinging Velocimetry of Gel Simulants Based on PIV[J]. Journal of Propulsion Technology, 2014, 35(4): 565-569.

陈杰,封锋,马虎,武晓松. 基于PIV的凝胶模拟液撞击雾化速度场实验研究[J]. 推进技术, 2014, 35(4): 565-569.

References

[1] Chojnacki K T, Feikema D A.Atomization Studies of Gelled Liquids[R].AIAA 94-2773.
[2] Chojnacki K T, Feikema D A.Atomization Studies of Gelled Bipropellant Simulants Using Planar Laser Induced Fluorescence[R].AIAA 95-2423.
[3] Chojnacki K T,Feikema D A.Study of Non-Newtonian Liquid Sheets Formed by Impinging Jets[R].AIAA 97-3335.
[4] Ciezki H, Robers A, Schneider G.Investigation of the Spray Behavior of Gelled Jet-a1Fuels Using an Air Blast and an Impinging Jet Atomizer[R].AIAA 2002-3601.
[5] Kampen J, Alberio F, Ciezki H.Spray and Combustion Characteristics of Aluminized Gelled Fuels with an Impinging Jet Injector[J].Aerospace Science and Technology, 2007,1(1):77-83.
[6] Nusca M, Mathis N, Michaels S.Modeling Hypergolic Ignition in the Army's Impinging Stream Vortex Engine Including Injection Throttling.[R]．AIAA 2007-5443.
[7] Rahimi S, Hasan D, Peretz A.Development of Laboratory-Scale Gel Propulsion Technology[J]．Journal of Propulsion and Power, 2004,0(8):93-100.
[8] Kampen J, Alberio F, Ciezki H.Spray and Combustion Characteristics of Aluminized Gelled Fuels with an Impinging Jet Injector[J]．Aerospace Science and Technology , 2007,1(1):77-83.
[9] 魏锦洲,王占学．两股互击式喷嘴雾化数值模拟研究[J]．机械设计与制造,2009,8:130-132.
[10] 孙纪国,王钰,沈赤兵,等．一种40撞击角双股自击式喷嘴试验[J]．推进技术,2002,3(3):207-209.(SUN Ji-guo,WANG Yu,SHEN Chi-bing,et al.Experimental for a Like-Doublet Injector with 40Impingement Angle[J].Journal of Propulsion Technology,2002,3(3):207-209.)
[11] 韩亚伟,强洪夫,刘虎．双股液体射流撞击雾化的SPH方法数值模拟[J].工程力学,2013,0(3):17-23.
[12] 强洪夫,韩亚伟,王广,等．幂律型流体雾化SPH方法数值分析[J]．推进技术,2013,4(2):240-247.(QIANG Hong-fu,HAN Ya-wei,WANG Guang.et al.Numerical Anslysis of Atomization Process of Liquid with Power Law Model Based on SPH Method[J].Journal of Propulsion Technology,2013,4(2):240-247.)
[13] Yang Li-jun, Fu Qing-fei.Break of a Power-Law Liquid Sheet Formed by an Impinging Jet Injector[J]．International Journal of Multiphase Flow,2012,(39) :37-44.
[14] 蔡锋娟,张蒙正．凝胶推进剂雾化研究现状及问题[J]．推进技术,2010,6(4):24-30.(CAI Feng-juan,ZHANG Meng-zheng．Status and Problems of Gelled Propellant Atomizaition Research[J]．Journal of Propulsion Technology, 2010,6(4):24-30.)
[15] 张蒙正,杨伟东,王玫．双股互击式喷嘴雾凝胶水雾化特性试验[J]．推进技术,2008,9(1):22-25.( ZHANG Meng-zheng,YANG Wei-dong,WANG Mei.Test of Unlike Impinging Injector Atomization Characteristic with Gelled Water[J].Journal of Propulsion Technology, 2008,9(1):22-25.)
[16] 谢伟亮,王红涛．汽轮机低压排气缸内流场的PIV实验研究[J]．实验流体力学2011,5:64-69.

Experimental Study on Impinging Velocimetry of Gel Simulants Based on PIV

基于PIV的凝胶模拟液撞击雾化速度场实验研究

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