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微管道中压力驱动液体流动特性的数值模拟研究 被引量:3

Numerical simulation and charactertics study of pressure-driven flow in microtubes
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摘要 MEMS系统的飞速发展让人们对微尺度领域的研究产生了极大的兴趣。对压力驱动下蒸馏水流过直径20μm微管道的流量-压力、流速-压力特性进行了数值模拟研究。结果表明,在该仿真条件下,蒸馏水的流动规律基本符合宏观条件下的Navier-Stokes和Hagen-Poiseuille方程。在仿真研究中还考虑了重力对流动特性的影响,结果发现,在微米尺度下,重力对流动的流量与速度的影响很小,几乎可以忽略不计。 Advances in fabrication methods in microelectromechanical systems(MEMS) have generated significant interest in the area of microscale heat transfer and fluid, flow.In this paper, The model of water flow through the microtube with diamter 20μm has been builded. The flow charactertics by different Pressure-driven has been researched and analyzed the pressure-mass flow rate and pressure-velocity relationship.Numerical simulations showed good agreement with the Navier-Stokes and Hagen-Poiseuille equation.The results also showed that gravity had hardly effect on flow charactertics in microscale and nearly can be neglected.
作者 凌智勇 庄志文 丁建宁 杨继昌 宋向前 朱爱军
机构地区 江苏大学机械工程学院
出处 《机械设计与制造》 北大核心 2007年第10期37-39,共3页 Machinery Design & Manufacture
关键词 微管道 压力 流动 数值模拟 Microtube Pressure--driven Flow Numerical simulation
分类号 TH137 [机械工程—机械制造及自动化]
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参考文献3

  • 1Mohamed G.Flow physics in MEMS[J],Mec.Ind.,2001(2):313-341.
  • 2TuckermanD.Heat Transfer Microstructures for Integrated Circuits[D],Ph.D.thesis.Stanford University,Dept.of Electrical Eng.,California.1984.
  • 3章梓雄,董曾南.粘性流体力学[M].北京:清华大学出版社,1988:41-43.

同被引文献43

  • 1高桂丽,李大勇,石德全.液体粘度测定方法及装置研究现状与发展趋势简述[J].化工自动化及仪表,2006,33(2):65-70. 被引量:39
  • 2Margulies M, Egholm M, Altman WE, et al. Genome sequencing in microfabricated high-density picolitre reactors [J]. Nature, 2005, 437 (7057): 376-380.
  • 3Mardis E R. The impact of next-generation sequencing technology on genetics [J]. Trends in Genetics, 2008, 24 (3): 133.
  • 4Ho Chetmg S, Sauret A, Fernandez-Nieves A, et al. Corrugated interfaces in multiphase core-annular flow [J]. Physics of Fluids, 2010, 22 (8): 082002.
  • 5Kim C, Chung S, Kim Y E , et al. Generation of core-shell microcapsules with three-dimensional focusing device for efficient formation of cell spheroid [J]. Lab Chip, 2011, 11 (2): 246-252.
  • 6Umbanhowar P B, Prasad V, Weitz D A. Monodisperse emulsion generation via drop break off in a coflowing stream [J]. Langmuir, 2000, 16 (2): 347-351.
  • 7Anna S L, Bontoux N, Stone H A. Formation of dispersions using "flow focusing" in microchannels [J]. Applied Physics Letters, 2003, 82 (3): 364-366.
  • 8Dreyfus R, Tabeling P, Willaime H. Ordered and disordered patterns in two-phase flows in microchannels [J]. Physical Review Letters, 2003, 90 (14): 144505.
  • 9Garstecki P, Gitlin I, DiLuzio W, et al. Formation of monodisperse bubbles in a microfluidic flow-focusing device [J]. Applied Physics Letters, 2004, 85 (13): 2649-2651.
  • 10Takeuchi S, Garsteeki P, Weibel D B, et al. An axisymmetric flow-focusing microfluidic device [J]. Advanced Materials, 2005, 17 (8): 1067-1072.

引证文献3

二级引证文献19

机械设计与制造
2007年 第10期

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