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Year 2016, , 51 - 60, 30.06.2016
https://doi.org/10.17350/HJSE19030000032

Abstract

References

  • Lee PS, Garimella SV, Liu D. Investigation of Heat Transfer in Rectangular Microchannels. International Journal of Heat and Mass Transfer 48 (2005) 1688-1704.
  • Asadi M, Xie G, Sunden B. A Review of Heat Transfer and Pressure Drop Characteristics of Single and Two-Phase Microchannels. International Journal of Heat and Mass Transfer 79 (2014) 34–53.
  • Morini GL. Single-Phase Convective Heat Transfer in Microchannels: a Review of Experimental Results. International Journal of Thermal Sciences 43 (2004) 631– 651.
  • Rosa P, Karayiannis TG, Collins MW. Single-Phase Heat Transfer in Microchannels: The Importance of scaling effects. Applied Thermal Engineering 29 (2009) 3447–3468.
  • Webb RL. Effect of Manifold Design on Flow Distribution in Parallel Micro-Channels. International Electronic Packaging Technical Conference and Exhibition 2 (2003) 527-535.
  • Kandlikar S, Garimella S, Li D, Colin S, King MR. Heat Transfer and Fluid Flow in Minichannels and Microchannels, Elsevier Ltd., Oxford, pp. 87-116, 2006.
  • Kakaç S, Yener Y. Convective Heat Transfer, Second edition CRC press, Washington, 1994.
  • Incropera F, Lavine A, DeWitt D. Fundamentals of Heat and Mass Transfer, Sixth Edition, New Jersey, 2007.
  • Altınöz M. Experimental Investigation of Single Phase Liquid Flow and Heat Transfer in Multiport Minichannels, Middle East Technical University, Ankara, 2013.
  • Holman JP. Experimental Methods for Engineers, Eighth edition McGraw-Hill, New York, pp. 64, 2012.
  • Dai B, Li M, Dang C, Ma Y, Chen Q. Investigation on Convective Heat Transfer Characteristics of Single Phase Liquid Flow in Multi-Port Micro-Channel Tubes. International Journal of Heat and Mass Transfer 70 (2014)114-118.
  • Shah RK, London AL. Laminar Flow Forced Convection in Ducts, Supplement 1 to Advances in Heat Transfer, New York Academic press, 1978.
  • Troniewski L, Ulbrich R. Two-Phase Gas-Liquid Flow in Rectangular Channels. Chemical Engineering Science, 39 (1984) 751-765.
  • Spiga M, Morini GL. A Symmetric Solution for Velocity Profile in Laminar Flow through Rectangular Ducts. International Community of Heat and Mass Transfer, 21 (1996) 283-296.
  • Pelevic N, van der Meer TH. Heat Transfer and Pressure Drop in Microchannels with Random Roughness. International Journal of Thermal Sciences 99 (2016) 125-135.
  • Kakac S, Shah RK, Aung W. Handbook of Single-Phase Convective Heat Transfer, JohnWiley and Sons Inc., New York, 1987.
  • Zhang J, Diao Y, Zhao Y, Zhang Y, Sun Q. Thermal-Hydraulic Performance of Multiport Microchannel Flat Tube with Sawtooth Fin Structure. International Journal of Thermal Sciences 84 (2014) 175-183.
  • Webb RL. Performance Evaluation Criteria for Use of Enhanced Heat Transfer Surfaces in Heat Exchanger Design. Internation Journal of Heat and Mass Transfer 24 (1981) 715-726.

Experimental Analysis of Laminar Flow and Heat Transfer in a Multi-Port Finned Minichannel

Year 2016, , 51 - 60, 30.06.2016
https://doi.org/10.17350/HJSE19030000032

Abstract

D ue to their high heat transfer rate, small scale channels have been a popular area of study for the past three decades, especially for heat exchangers. In this study, fluid flow and heat transfer in a multi-port finned minichannel with a rectangular cross section was investigated experimentally under the constant heat flux boundary condition. The minichannel, which has a length of 638 mm, consists of 16 ports, 14 of which are identical finned rectangular channels with a width of 2.10 mm and a height of 5.85 mm while the remaining two ports at the outer edges of the channel were considered to be identical with the other ports. Deionized water was used as the working fluid with Reynolds number ranging between 75 and 190 in a single port. In order to correctly evaluate local heat transfer and friction coefficient values, thermal entrance effects and varying thermo-physical properties of the working fluid were taken into consideration throughout the study. Local Nusselt number varying with dimensionless axial thermal length, friction factor and average Nusselt number values varying with Reynolds number, and temperature distribution along the wall were evaluated to study fluid flow and heat transfer of the finned minichannel. The results were compared to theoretical values and presented graphically. Local Nusselt number values indicated fairly good agreement with theory while friction factor was overestimated. This was considered to be due to the effect of fins. In addition, three correlations were suggested in order to evaluate friction factor, local Nusselt number and average Nusselt number for the minichannel in given ranges of parameters

References

  • Lee PS, Garimella SV, Liu D. Investigation of Heat Transfer in Rectangular Microchannels. International Journal of Heat and Mass Transfer 48 (2005) 1688-1704.
  • Asadi M, Xie G, Sunden B. A Review of Heat Transfer and Pressure Drop Characteristics of Single and Two-Phase Microchannels. International Journal of Heat and Mass Transfer 79 (2014) 34–53.
  • Morini GL. Single-Phase Convective Heat Transfer in Microchannels: a Review of Experimental Results. International Journal of Thermal Sciences 43 (2004) 631– 651.
  • Rosa P, Karayiannis TG, Collins MW. Single-Phase Heat Transfer in Microchannels: The Importance of scaling effects. Applied Thermal Engineering 29 (2009) 3447–3468.
  • Webb RL. Effect of Manifold Design on Flow Distribution in Parallel Micro-Channels. International Electronic Packaging Technical Conference and Exhibition 2 (2003) 527-535.
  • Kandlikar S, Garimella S, Li D, Colin S, King MR. Heat Transfer and Fluid Flow in Minichannels and Microchannels, Elsevier Ltd., Oxford, pp. 87-116, 2006.
  • Kakaç S, Yener Y. Convective Heat Transfer, Second edition CRC press, Washington, 1994.
  • Incropera F, Lavine A, DeWitt D. Fundamentals of Heat and Mass Transfer, Sixth Edition, New Jersey, 2007.
  • Altınöz M. Experimental Investigation of Single Phase Liquid Flow and Heat Transfer in Multiport Minichannels, Middle East Technical University, Ankara, 2013.
  • Holman JP. Experimental Methods for Engineers, Eighth edition McGraw-Hill, New York, pp. 64, 2012.
  • Dai B, Li M, Dang C, Ma Y, Chen Q. Investigation on Convective Heat Transfer Characteristics of Single Phase Liquid Flow in Multi-Port Micro-Channel Tubes. International Journal of Heat and Mass Transfer 70 (2014)114-118.
  • Shah RK, London AL. Laminar Flow Forced Convection in Ducts, Supplement 1 to Advances in Heat Transfer, New York Academic press, 1978.
  • Troniewski L, Ulbrich R. Two-Phase Gas-Liquid Flow in Rectangular Channels. Chemical Engineering Science, 39 (1984) 751-765.
  • Spiga M, Morini GL. A Symmetric Solution for Velocity Profile in Laminar Flow through Rectangular Ducts. International Community of Heat and Mass Transfer, 21 (1996) 283-296.
  • Pelevic N, van der Meer TH. Heat Transfer and Pressure Drop in Microchannels with Random Roughness. International Journal of Thermal Sciences 99 (2016) 125-135.
  • Kakac S, Shah RK, Aung W. Handbook of Single-Phase Convective Heat Transfer, JohnWiley and Sons Inc., New York, 1987.
  • Zhang J, Diao Y, Zhao Y, Zhang Y, Sun Q. Thermal-Hydraulic Performance of Multiport Microchannel Flat Tube with Sawtooth Fin Structure. International Journal of Thermal Sciences 84 (2014) 175-183.
  • Webb RL. Performance Evaluation Criteria for Use of Enhanced Heat Transfer Surfaces in Heat Exchanger Design. Internation Journal of Heat and Mass Transfer 24 (1981) 715-726.
There are 18 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Berk Cevrim This is me

Almila Guvenc Yazicioglu This is me

Sadik Kakac This is me

Publication Date June 30, 2016
Published in Issue Year 2016

Cite

Vancouver Cevrim B, Yazicioglu AG, Kakac S. Experimental Analysis of Laminar Flow and Heat Transfer in a Multi-Port Finned Minichannel. Hittite J Sci Eng. 2016;3(1):51-60.

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