垂直上升弹状流中弹状氢气泡运动速度

宋建军; 杜小平; 赵继广

垂直上升弹状流中弹状氢气泡运动速度

1.
装备指挥技术学院研究生院,北京 101416
2.
装备指挥技术学院装备采办系,北京 101416
3.
装备指挥技术学院航天装备系,北京 101416

基金项目: 预研基金(20094104002, 20104106007); 国家高技术研究发展计划(2008AA1088)

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出版历程
- 收稿日期: 2011-07-22
- 刊出日期: 2012-07-28

Rising velocity of Taylor hydrogen bubble in upward vertical slug flow

1.
The Graduate University of Academy of Equipment,Beijing 101416,China
2.
The Equipment Acquisition Department of Academy of Equipment, Beijing 101416,China
3.
The Aerospace Equipment Department of Academy of Equipment,Beijing 101416,China

摘要

摘要: 针对垂直管路内气液两相流实验化困难的问题,运用建模仿真的方法建立了竖直管路中弹状流气泡的运动模型,模拟了弹状氢气泡在垂直管路的上升过程,并对其运动速度进行了研究.仿真结果表明:在静置的竖直管道内,充分发展的弹状氢气泡的速度基本上以0.2265m/s的速度匀速上升;弹状氢气泡在流动液氢中运动时,其速度模型中的速度系数与流体的速度有关,当雷诺数从220上升到6400时,其系数的值从1.83下降到1.14;在未充分发展的弹状流系统中,气泡间距对气泡速度分布有着影响,其上升速度随着气泡间距的减小而增大.
- 弹状流气泡 /
- 液氢 /
- 弹状流 /
- 上升速度 /
- 数值模拟
Abstract: Aiming at the difficulties of gas-liquid flow experiment in the vertical pipe,the modeling and simulation methods were conducted to investigate the dynamic model of slug flow and the rising velocity of Taylor hydrogen bubble in upward vertical slug flow.Simulation results show that the velocity of the developed Taylor hydrogen bubble is 0.2265m·s^-1.In flowing liquid,the velocity coefficient is insensitive to the liquid Reynolds number.As the Reynolds number based on the liquid velocity,the Reynolds number increases from 220 to 6400,and the velocity coefficient decreases from 1.83 to 1.14.In developing Taylor bubble,the rising velocity increases with the shortening distance between consecutive bubbles.
- Taylor bubble /
- liquid hydrogen /
- slug flow /
- rising velocity /
- numerical simulation

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参考文献(16)

[1]	张华,李满峰,巨永林,等.倾斜管中低温两相弹状流特性实验研究[J].低温技术,2009,38(4):9-16. ZHANG Hua,LI Manfeng,JU Yonglin,et al.Experimental study on the cryogenic two-phase slug flow characteristic in inclined pipes[J].Cryogenics,2009,38(4):9-16.(in Chinese)
[2]	李祥东,汪荣顺.垂直低温推进剂管路中弹状泡形成数值模拟[J].哈尔滨工程大学学报,2009,30(2):198-203. LI Xiangdong,WANG Rongshun.Numerical simulation of slug bubble formation in a vertical cryogenic propellant pipe[J].Journal of Harbin Engineering University,2009,30(2):198-203.(in Chinese)
[3]	Morgan S K,Brady H F.Elimination of the geysering effect in missiles[J].Advance in Cryogenic Engineering,1962,7(1):206-213.
[4]	Murphy D W.An experimental investigation of geysering in vertical tubes[J].Advance in Cryogenic Engineering,1965,10(6):353-359.
[5]	Burkhalter J E,Richard H S.Investigations of geysering in vertical tubes[J].Journal of Spacecraft,1968,5(7):854-857.
[6]	Brennen C E.Cavitation and bubble dynamics[M].New York:Oxford University,1995.
[7]	Taylor G I,Davies R M.The mechanics of large bubbles rising through extended liquids and through liquid in tubes[J].Proc.R.Soc.Lond.Ser.,1949,200(10):375-390.
[8]	Moissis R,Griffith P.Entrance effect in two phase slug flow[J].Journal of Heat Transfer,1962,84(9):29-39.
[9]	Nicklin D J,Wilkes M A,Davidson J F.Two-phase flow in vertical tubes[J].Transactions of the Institution of Chemical Engineers,1962,40(1):61-68.
[10]	Hirt C W,Nichols B D.Volume of fluid method for the dynamics of free boundary[J].Journal of Compute Phys.,1981,93(5):201-225.
[11]	Brackbill J U,Kothe D B,Zemach C.A continuum method for modeling surface tension[J].J. Compute Phys.,1992,100(9):335-354.
[12]	Polonsky S,Barnea D,Shemer L.Averaged and time-dependent characteristics of the motion of an elongated bubble in a vertical pipe[J].International Journal of Multiphase Flow,1999,25(3):795-812.
[13]	Takatoshi T,Mitsuo M.The coalescence mechanism of multiple slug bubbles[J].Journal of Nuclear Science and Technology,1999,36(8):671-682.
[14]	Taitel Y,Barnea D,Dukler A E.Modeling flow pattern transition for steady upward gas-liquid flow in vertical tubes[J].General Chemical Engineering Journal,1980,26(3):345-354.
[15]	夏国栋,周芳德,胡明胜.垂直管中气液两相弹状流液弹长度分布[J].化工学报,1997,48(6):729-735. XIA Guodong,ZHOU Fangde,HU Mingsheng.Liquid slug length distribution of gas-liquid two-phase slug flow in a vertical tube[J].Journal of Chemical Industry and Engineering,1997,48(6):729-735.(in Chinese)
[16]	张亮.垂直输送管路中低温液体的间歇泉现象研究及自然循环分析 .上海:上海交通大学,2004. ZHANG Liang.Research of geysering phenomenon and the natural recirculation in the vertical cryogenic transfer pipe .Shanghai:Shanghai Jiaotong University,2004.(in Chinese)