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makale • Son zamanlarda yüzey özellikleri ve yüzey ve akışkan etkileşimi ile sürtünme katsayısının azaltılabileceği görüşü ileri sürülmüştür. TEŞEKKÜR Bu makale Atatürk Üniversitesi Araştırma Fonu tarafından desteklenen 2005/12 nolu proje ve TÜBİTAK tarafından desteklenen 106M304 nolu proje kapsamında hazırlanmıştır. Yazarlar destekleri nedeniyle Atatürk Üniversitesi Araştırma Fonu ve TÜBİTAK'a teşekkür ederler. KAYNAKÇA 1. Morini L.G., Single-Phase Convective Heat Transfer in Microchannels: a Review of Experimental Results, Int. J. Thermal Sciences, 43 (2004) 631-651. 2. Kandlikar S.G., Grande W.J., Evaluations of Microchannel Flow Passages-Thermohdraulic Performance and Fabrication Technology, Heat Transfer Engineering, 24 (2003) 3-17. 3. Pfund D., Rector D., Shekarriz A., Popescu A., Welty J., Pressure Drop Measurements in a Microchannel, AIChE J. 46 (2000) 14961507. 4. Jeong Ho-E., Jeong Jae-T., Extended Greatz Problem Including Streamwise Conduction and Viscous Dissipation in Microchannel, Int. J. Heat and Mass Transfer, 49 (2006) 2151- 2157. 5. Kaplan H., Dölen M., Mikro-Elekro-Mekanik Sistemler (MEMS) Üretim Teknikleri, 11.Ulusal Makina Teorisi Sempozyumu, Gazi Üniversitesi, Mühendislik Fakültesi, 6 Eylül 2003. 6. Owhaib W., Palm B., Experimental Investigation of Single- Phase Convective Heat Transfer in Circular Microchannels, Exp. Thermal and Fluid science, 28 (2004) 105-110. 7. Gad-el-Hak M., The Fluid Mechanics of Microdevices-The Freeman Scholar Lecture, Journal of Fluids Eng. 121 (1999) 257-274. 8. Gad-el-Hak M., Differences Between Liquid and Gas Transport at the Microscale, Bulletin of the Polish Academy of Sciences Technical Sciences, 53 (2005) 301-316. 9. Bayraktar T, Pidugu S.B, Review: Characterization of liquid Flows in Microfluidic Systems, Int. J. Heat and Mass Transfer, 49 (2006) 815-824. 10. Sobhan C. B., Garimella S.V, A Comparative Analysis of Studies on Heat Transfer and Fluid flow in microchannels, Microscale Thermophysical Engineering, 5 (2001) 293-311. 11. Obot N.T., Toward a Better Understanding of Friction and Heat/mass Transfer in Microchannels-a Literature Review, Microscale Thermophysical Engineering, 6 (2002) 155-173. 32 Mühendis ve Makina Cilt : 48 Sayı: 570 12. Hetsroni G., Mosyak A., Pogrebnyak E., Yarin L.P., Fluid Flow in Micro-Channels, Int. J. Heat and Mass Transfer, 48 (2005) 19821998. 13. White F.M., Fluid Mechanic, McGraw-Hill, 1999. 14. Shah R.K., Sekulic D.P., Fundamentals of Heat Exchanger Design, John Willey Sons, Inc., Hoboken New Jersey, 2003. 15. Araki T., Kim M.S., Iwai H., Suzuki K., An Experimental Investigation of Gaseous Flow Characteristics in Microchannels, Microscale Thermophysical Engineering, 6 (2002) 117-130. 16. Shah R.K, London A.L, Laminar Flow Forced Convection in Ducts: A Source Book for Compact Heat Exchanger Analytical Data, Suppl. 1,Academic press, NewYork, 1978. 17. Morini G.L., Lorenzini M, Salvigini S., Friction Characteristics of Compressible Gas Flows In Microtubes, Exp. Thermal and Fluid science, 30 (2006) 733-744. 18. Hao P.F., He F., Zhu K.Q., Experimental Investigation of Water Flow in Smooth and Rough Microchannel, J. Micromechanics and Microengineering, 16 (2006) 1397-1402. 19. Rands C., Webb B.W, Maynes D., Characterization of Transition to Turbulence in Microchannels, Int. J. Heat and Mass Transfer, 49 (2006) 2924-2930. 20. Kohl M.J.,Abdel-Khalik S.I., Jeter S.M., Sadowsk, D.L., An Experimental Investigation of Microchannel Flow With Internal Pressure Measurements, Int. J. Heat and Mass Transfer, 48 (2005) 1518-1533. 21. Garimella S.V., Singhal V., Single-Phase Flow and Heat Transport and Pumping Considerations in Microchannel Heat Sink, Heat Transfer Engineering, 25 (2004) 15-25. 22. Ren L., Qu W., Li D., Interfacial Electro Kinetic Effect on Liquid Flow in Microchannels, Int. J. Heat and Mass Transfer, 44 (2001) 3125-3134. 23. Li Z, Du D, Guo Z, Experimental Study on Flow Characteristics of Liquid in Circular Microbes, Microscale Thermophysical Engineering, 7 (2003) 253-265. 24. Judy J, Maynes D, Webb B.W, Characterization of Frictional Pressure Drop For Liquid Flows Trough Micrchannels, Int. J. Heat and Mass Transfer, 45 (2002) 3477-3489. 25. Gao P., Person S.L., Marinet M.F., Scale Effects on Hydrodynamics and Heat Transfer in Two-Dimensional Mini and Microchannels, Int.J. Thermal Sciences, 41 (2002) 1017- 1027. 26. Hao P.F., He F., Zhu K.Q., Flow Characteristics in Trapezoidal Silicon Microchannel, J. Micromechanics and Microengineering, 15 (2005) 1362-1368.
27. Chen Y.T., Kang S.W., Tuh W.C., Hsiao T.H., Experimental Investigation of Fluid Flow and Heat Transfer in Microchannels, Tamkang Journal of Science and Engineering, 7 (2004) 11-16. 28. Qu W., Mudawar I., Experimental and Numerical Study of Pressure Drop and Heat Transfer in a Single-phase Microchannel Heat Sink, Int. J. Heat and Mass Transfer, 45 (2002) 2549-2565. 29. Hegab H.E, BariA,Ameel T, Friction and Convection Studies of R-134a in Microchannels Within the Transition and Turbulent Flow Regimes, Experimental Heat Transfer, 15 (2002) 124-259. 30. Liu D, Garimella S.V., Investigation of Liquid Flow in Microchannels, Journal of Thermophysics and Heat Transfer, 18 (2004) 65-72. 31. Baviere R., Marinet M.F., Le Person S., Bias Effect on Heat Transfer Measurmenrts in Microchannel Flows, Int. J. Heat and Mass Transfer, 49 (2006) 3325-23337. 32. Mala Gh. M., Li D., Flow Characteristics of Water in Microtubes, Int.J.Heat and Fluid Flow, 20 (1999) 142-148. 33. Brutin D., Tadrist L., Experimental Friction Factor of Liquid Flow in Microtubes, Physics oh Fluid, 15 (2003) 653-661. 34. Peng X.F., Peterson G.P., Convective Heat Transfer and Fluid Flow For Water Flow in Microchannel Structures, Int. J. Heat and Mass Transfer, 39 (1996) 2599-2608. 35. Wu P.Y., Little W.A., Measurement of Friction Factor For Gases in Very Fine Channels Used For Micro-miniature Joule- Thompson refrigenerators, Cryogenics, 24 (1983) 273-277. 36. Peng X.F., Peterson G.P., Wang B.X., Frictional Flow Characteristics of Water Flowing Through Rectangular Microchalles, Experimental Heat transfer, 7(1994) 249-264. 37. Hsieh S.S, Tsai H.H., Lin C.Y., Huang C.F., Chien C.M., Gas Flow in a Long Microchannel, Int. J. Heat and Mass Transfer, 47 (2004a) 3877-3887. 38. Choi S.B., Barron R.F., Warrington R.O., Fluid Flow and Heat Transfer in Microtubes, Micromechanical Sensors, Actuators, and Systems, DSC-Vol.32, pp. 123-134, ASME, NewYork, 1991. 39. Yu, D., Warrington, R.O., Barron, R., Ameel, T., An Experimental and Theoretical Investigation of Fluid Flow and Heat Transfer in Microtubes, in: Proceedings of ASME/JSME Thermal Engineering Joint Conf., Maui, HI, 1995, pp. 523530. 40. Lelea D., Nishio S., Takano K., The Experimental Research on Microtube Heat Transfer and Fluid Flow of Distilled Water, Int. J. Heat and Mass Transfer, 47 (2004) 2817-2830. 41. Celata G.P., Cumo M., Guglielmi, Zummo G., Experimental Investigation of Hydraulic and Single-phase Heat Transfer in makale 0.130-mm Capillary Tube, Microscale Thermophysical Engineering, 6 (2002) 85-97. 42. Pfalher J, .,Harley J., Bau H.H, Zemel J.N., Liquid Transport in Micron and Submicron Channels, Sensors Actuators A 2123 (1990) 431434. 43. Lee H.J., Lee S.Y., Pressure Drop Correlations For Two-phase Flow Within Horizontal Rectangular Channels With Small Heights, Int. J. Multiphase Flow, 27 (2001) 783-796. 44. Hwang Y.W., Kim M.S., The Pressure Drop in Microtubes and the Correlation Development, Int. J. Heat and Mass Transfer, 49 (2006) 1804-1812. 45. Harms T.M., Kazmierczak M.J., Gerner F.M, Developing Convective Heat Transfer in Deep Rectangular Microchannels, Int. J. Heat and Fluid Flow,20 (1999) 149-157. 46. Choi M., Cho K., Effect of the Aspect Ration of Rectangular Channels on the Heat Transfer and Hydrodynamics of Paraffin Slurry Flow, Int. J. Heat and Mass Transfer, 44 (2001) 55-61. 47. Jiang X.N., Zhou Z.Y., Yao J., Li Y., Ye X.Y., Micro-Fluid Flow in Microchannel, The 8th International Conference on Solid-State Sensors and Actuators, and Eurusensors IX. Stockholm, Sweden, 1995. 48. Kandlikar S.G., Schmitt D., Carrano A.L., Taylor J. B., Characterization of Surface Roughness Effects on Pressure Drop In Single-phase Flow İn Minichannels, Physics of Fluids, 17 (2005) 100606-1-11. 49. Qu W., Mala M., Li D., Pressure-Driven Water Flows in Trapezoidal Silicon Microchannels, Internat. J. Heat Mass Transfer 43 (2000) 353364. 50. Toh K.C., Chen X.Y., Chai J.C., Numerical Computation of Fluid Flow and Heat Transfer in Microchannels, Int. J. Heat and Mass Transfer, 45 (2002) 5133-5141. 51. Hsieh S.S, Tsai H.H., Lin C.Y., Huang C.F., Tsai H.H, Liquid Flow in a Micro-Channel, Journal of Micromechanics and Microengineering, 14 (2004b) 436-445. 52. Wu H.Y., Cheng P., Friction Factors in Smooth Trapezoidal Silicon Microchannels With Different Aspect Ratios, Internat. J. Heat Mass Transfer 46 (2003a) 25192525. 53. Wu H.Y., Cheng P, An Experimental Study of Convective Heat Transfer in Silicon Microchannels With Different Surface Conditions, Int. J. Heat and Mass Transfer, 46 (2003b) 2547- 2556. 54. Morini G.L., Spiga M., Tartarini P., The Rarefaction Effect on the Friction Factor of Gas Flow in Microchannels, Superlattices and Microstructures, 35 (2004) 587-599. 55. Xu B, Ooi K.T, Wong N.T., Experimental Investigation of Flow Friction for Liquid Flow in Microchannels, Int. Comm..Heat and Mass Transfer, 27 (2000) 1165-1176. Mühendis ve Makina Cilt : 48 Sayı: 570 33
Page 1 and 2: Mikro Kanallarda Basınç Düşüş
Page 3 and 4: Tablo 1 Devamı. Mikro Kanallarda T
Page 5 and 6: incelendiğinde eşitliklerin birbi
Page 7 and 8: Knudsen Sayısının Etkisi Gazlar
Page 9: yüksek olan SiO2 kaplanmış kanal

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