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深宽比对微通道内气液二相流空隙率的影响 被引量:3

Influence of aspect ratio on void fraction of gas-liquid two-phase flow in microchannels
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摘要 微通道内气液二相流的空隙率对管路内热质传递具有重要影响。利用高速摄像仪对4种不同深宽比的矩形截面微通道内空气-水二相流的流型进行实时观测和记录,对二相流型图进行了分析和计算,得到了不同流型时的空隙率。4种微通道尺寸(深度×宽度)分别为100μm×200μm,100μm×400μm,100μm×800μm,100μm×2 000μm。结果表明:对于弹状流,空隙率随着微通道截面深宽比的减小而降低,当流型为液环流时,空隙率随着微通道截面深宽比的减小而增加。在实验基础上,将截面深宽比作为参数提出了一个新的空隙率预测模型,计算结果显示:模型能对矩形截面微通道内气液二相流动空隙率进行很好的预测。 The void fraction of gas-liquid two-phase flow in microchannels is of vital importance in heat and mass transfer processes.A high-speed camera was utilized for real-time observation and recordation of air-water two-phase flow patterns in rectangular cross-section microchannels with four different aspect ratios,and the void fractions under different flow regimes were obtained by analyzing and calculating the flow pattern images.Four microchannels with different dimensions of 100 μm × 200 μm,100 μm× 400 μm,100 μm × 800 μm and 100 μm× 2 000 μm in depth and width were used.The results show that the void fraction decreases in the slug flow pattern while increases in the annular flow pattern with the decreasing of aspect ratios.A new correlation of void fraction prediction was proposed with the aspect ratio as a variable,and the present model shows good predicting accuracy.
作者 马友光 季喜燕 朱春英
机构地区 天津大学化工学院化学工程联合国家重点实验室
出处 《化学工程》 CAS CSCD 北大核心 2010年第11期35-38,共4页 Chemical Engineering(China)
基金 国家自然科学基金资助项目(20876107) 化学工程国家重点实验室开放课题(SKL-ChE-08B06)
关键词 矩形截面微通道 空隙率 深宽比 气液二相流 rectangular cross-section microchannels void fraction aspect ratio gas-liquid two-phase flow
分类号 TQ021.4 [化学工程]
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参考文献22

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同被引文献67

  • 1赵建福,K S Gabriel.微重力条件下90°弯管气液两相流型研究[J].工程热物理学报,2004,25(5):801-803. 被引量:4
  • 2KASHID M N, KOWALINSKI W, RENKEN A, et al. Analytical method to predict two-phase flow pattern in horizontal micro-capillaries [ J ]. Chemical Engineering Science, 2012, 74(28): 219-232.
  • 3FU T, MA Y, FUNFSCHILLING D, et al. Breakup dy- namics of slender bubbles in non-newtonian fluids in mi- crofluidic flow-focusing devices [ J ]. AIChE Journal, 2012, 58( 11 ) : 3560-3567.
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  • 5KASHID M N, RENKEN A, KIWI-MINSKER L. Influ- ence of flow regime on mass transfer in different types of mieroehannels[Jl. Industrial and Engineering Chemistry Research, 2011, 50( 11 ): 6906-6914.
  • 6AUBIN J, FERRANDO M, JIRICNY V. Current methods for characterizing mixing and flow in microchannels J . Chemical Engineering Science, 2010, 65 (6): 2065- 2093.
  • 7ZHANG Q, YONG Y, MAO Z, et al. Experimental de- termination and numerical simulation of mixing time in a gas-liquid stirred tank [ J ]. Chemical Engineering Sci- ence, 2009, 64(12) : 2926-2933.
  • 8CUBAUD T, HO C. Transport of bubbles in square mi- crochannels[ J 1- Physics of Fluids, 2004, 16 (12) : 4575-4585.
  • 9LI J, PETERSON G P. Boiling nucleation and two-phase flow patterns an forced liquid flow in microchannels [ J .International Journal of Heat and Mass Transfer, 2005, 48(23/24) : 4797-4810.
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引证文献3

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化学工程
2010年 第11期

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