Mikrokanallarda taşınımla ısı geçişinin bir incelemesi

Micro ölçülerdeki ısı transferi alanındaki analitik yöntemler ve karmaşık ölçüm tekniklerine dair son 5 yıldaki büyük ilerleme; mikrokanal akışının anlaşılmasına büyük katkıda bulunmuş ve geleneksel teorik modellerin hangi durumlarda mikrokanal akışındaki tsı transfer davranışını doğru tahmin etmek için kullanılabileceğini belirlemede yardımcı olmuştu. Burada sunulan, sürmekte olan birçok araştırma projesine dair tartışmalarla birlikte son 5 yılda konu üzerine yayımlanan, ısı transferi ve mikrokanal akışını içeren, eserlerin bir özetidir. Teorik ve deneysel çalışmalar, hesap analizleri daha yenilikçi modelleme tekniklerinin bazılarının tanımı ve bunlara dair tüm önemli bulgular burada sunulmuş, karşılaştırılmış ve tartışılmıştır.

A review of convective heat transfer in microchannels

The tremendous progress over the past five years in sophisticated measurement techniques and analytical methodologies in the area of microscale heat transfer have greatly added to the understanding of the phenomena unique to microchannel flow and has helped to clarify those situations where conventional theoretical models can be used to accurately describe and predict the flow and heat transfer behavior in microchannel flows. Presented here is a review of the published literature from the past five years, along with discussions of several ongoing research projects involving microchannel flow and heat transfer. Theoretical and experimental studies, computational analyses, a description of some of the more innovative instrumentation techniques, and important findings from all of these are presented, compared and discussed.

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71.Steinke, M. E. and Kandlikar, S. G., "Control and effect of dissolved air in water during flow boiling in microchannels," International Journal of Heat and Mass Transfer, v 47, n 8-9, April, 2004, p 1925-1935.
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82.Li, H.Y., Tseng, F.G. and Pan, C., "Bubble dynamics in microchannels. Part II: Two parallel microchannels," International Journal of Heat and Mass Transfer, v 47, n 25, December, 2004, p 5591-5601.
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94.Yu, S. and Ameel, T.A., "Slip-flow heat transfer in rectangular microchannels," International Journal of Heat and Mass Transfer, v 44, n 22, Sep 18, 2001, p 4225-4234.
95.Yu, S. and Ameel, T. A., "Slip flow convection in isoflux rectangular microchannels," Journal of Heat Transfer, v 124, n 2, April, 2002, p 346-355.
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97.Sun, H. and Faghri, M., "Effect of surface roughness on nitrogen flow in a microchannel using the direct simulation Monte Carlo method," Numerical Heat Transfer; Part A: Applications, v 43, n 1, January, 2003, p 1-8.
98.Colin, S., Lalonde, P. and Caen, R., "Validation of a Second-Order Slip Flow Model in Rectangular Microchannels," Heat Transfer Engineering, v 25, n 3, April/May, 2004, p 23-30.
99.Raju, R. and Roy, S., "Hydrodynamic study of high speed flow and heat transfer through a microchannel," Journal of Thermophysics and Heat Transfer, v 19, n 1, January/March, 2005, p 106-113.
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102.Choi, H., Lee, D. and Maeng, J.S., "Computation of slip flow in microchannels using Langmuir slip condition," Numerical Heat Transfer; Part A: Applications, v 44, n 1, July, 2003, p 59-71.
103.Tso, C.P. and Mahulikar, S.P., "Combined evaporating meniscus-driven convection and radiation in annular microchannels for electronics cooling application," International Journal of Heat and Mass Transfer, v43, n 6, Jan, 2000, p 1007-1023.
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105.Turner, S. E., Lam, L. C., Faghri, M. and Gregory, O. J., "Experimental investigation of gas flow in microchannels," Journal of Heat Transfer, v 126, n 5, October, 2004, p 753-763.
106.Kohl, M.J., Abdel-Khalik, S.I., Jeter, S.M. and Sadowski, D.L., "An experimental investigation of microchannel flow with internal pressure measurements," International Journal of Heat and Mass Transfer, v48, n 8, April, 2005, p 1518-1533.
107.Murakami, Y. and Mikic, B. B., "Parametric investigation of viscous dissipation effects on optimized air cooling microchanneled heat sinks," Heat Transfer Engineering, v 24, n 1, January/February, 2003,p53-62.
108.Kim, S. J., "Methods for thermal optimization of microchannel heat sinks," Heat Transfer Engineering, v 25, n 1, January/February, 2004, p 37-49.
109.Nakayama, W. Ohba, Y. and Maeda, K., "The effects of geometric uncertainties on micro-channel heat transfer - A CFD study on the tilted-cover problem," Heat Transfer Engineering, v 25, n 1, January/February, 2004, p 50-60.
110.Eason, C., Dalton, T., Davies, M., O'Mathuna, C. and Slattery, O., "Direct comparison between five different microchannels, part 1: Channel manufacture and measurement," Heat Transfer Engineering, v 26, n 3, April, 2005, p 79-88.
111.Hrnjak, P., "Developing Adiabatic Two-phase Flow in Headers - Distribution Issue in Parallel Flow MicroChannel Heat Exchangers," Heat Transfer Engineering, v 25, n 3, April/May, 2004, p 61 -68.
112.Li, J., Peterson, G. P. and Cheng, P., "Three- Dimensional Analysis of Heat Transfer in a Micro Heat Sink with Single-phase Flow," Int'l. J. Heat and Mass Transfer, vol. 47,2004, p. 4215-4231.
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114.Li, J. and Peterson, G. P., "Boiling Nucleation and two- phase flow patterns in forced liquid flow in microchannels," International Journal of Heat and Mass Transfer, 2005 (in press).
115.Wang, Y.X. and Peterson, G. P., "Capillary Evaporation in Microchanneled Polymer Films," paper no. AIAA-2002-2767, 8th AMSE/AIAA Joint Thermophysicsand heat Transfer Conference, St. Louis, MO, 2002.
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117.McDaniels, D. and Peterson, G. P. (2001) "Investigation Polymer Based Micro Heat Pipes for Flexible Spacecraft Radiators," Proc. ASME Heat Transfer Division, HTD-Vol. 142, NewYork,NY.,2001.
118.Peterson, G. P. and Sobhan, C. B. "Applications of Microscale Phase Change Heat Transfer: Micro Heat Pipes and Micro Heat Spreaders," Handbook of Microelectromechanical Systems, Mohamed Gad-el-Hak (ed.), CRC Press Inc.,pp. 2nd Edition, 2005.
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ISSN: 1300-3402
Yayın Aralığı: Yılda 4 Sayı
Başlangıç: 1957
Yayıncı: TMMOB MAKİNA MÜHENDİSLERİ ODASI

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Mikrokanallarda taşınımla ısı geçişinin bir incelemesi

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Mikrokanallar ve kapiler borularda elektrokinetik olarak yönlendirilen akım

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