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宽矩形硅微通道中流动冷凝的流型 被引量:4

Flow pattern of condensation in wide rectangular silicon microchannels
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摘要 对水力直径90.6μm、宽深比9.668的矩形硅微通道中的流动冷凝过程进行了可视化研究。研究发现,宽矩形硅微通道中的冷凝,沿程主要有珠状-环状复合流、喷射流和弹状-泡状流等流型。在珠状-环状复合流区,冷凝液膜可覆盖通道竖直侧壁,而在通道长边上,仍然为珠状凝结。喷射流位置随着入口蒸气Reynolds数的增大而延后,通道截面形状对流动冷凝不稳定性也存在很大影响。喷射流之后为弹状-泡状流,弹状气泡沿程逐渐缩短,并在表面张力的作用下收缩成圆球形气泡。冷凝通道的平均传热系数将随着入口蒸气Reynolds数的增大而增大。 Visualization experiments were conducted to study the condensation flow in rectangular silicon microchannels with hydraulic diameter of 90.6 μm and width/depth ratio of 9. 668. In such wide rectangular microchannels, droplet-annular compound flow, injection flow and slug-bubbly flow were observed. In the droplet-annular compound flow regime, the vertical wall of the channel was completely covered by the condensate film. But on the long sidewall of the channel, droplet condensation still existed. The occurrence of injection flow would be postponed with increasing inlet vapor Reynolds number. And it was confirmed that the cross-section shape of the microchannel had a significant effect on the instability of condensation flow. Slug-bubbly flow occurred after injection flow. Along the condensation stream, the slug would contract into round bubble due to surface tension. The average heat transfer coefficient of the channel increased with increasing inlet vapor Reynolds number.
作者 李鑫 陈永平 吴嘉峰 施明恒
机构地区 东南大学能源与环境学院
出处 《化工学报》 EI CAS CSCD 北大核心 2009年第5期1080-1086,共7页 CIESC Journal
基金 "十一五"国家科技支撑计划重点项目(2008BAJ12B02) 国家自然科学基金项目(50806012)~~
关键词 冷凝 矩形微通道 流型 condensation rectangular microchannels flow pattern
分类号 TK124 [动力工程及工程热物理—工程热物理]
  • 相关文献

参考文献15

  • 1Chen Y P, Shi M H, Cheng P, Peterson G P. Condensation in microchannels. Nanoscale Microscale Thermophys. Eng., 2008, 12 (2): 117- 143 被引量:1
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  • 3Du X Z, Zhao T S. Analysis of film condensation heat transfer inside a vertical micro tube with consideration of the meniscus draining effect. Int. J. Heat Mass Transfer, 2003, 46 (24): 4669 -4679 被引量:1
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  • 6陈永平,吴嘉峰,施明恒,张程宾,肖春梅.矩形微通道中环状冷凝的三维数值模拟[J].化工学报,2008,59(8):1923-1929. 被引量:4
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二级参考文献23

  • 1Suder K. Blockage Development in a Transonic Axial Compressor Rotor. ASME 97-GT-394, 1997 被引量:1
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  • 9陈永平,肖春梅,施明恒,吴嘉峰.微通道冷凝研究的进展与展望[J].化工学报,2007,58(9):2153-2160. 被引量:13
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共引文献5

同被引文献25

引证文献4

二级引证文献6

化工学报
2009年 第5期

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