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Heat Transfer Characteristics of Individual Row of Fin and Tube Heat Exchangers  

Chang Keun-Sun (Department of Mechanical Engineering, Sunmoon University)
Kweon Young-Chul (Department of Mechanical Engineering, Sunmoon University)
Kim Young-Jae (Department of Chemical Engineering, Sunmoon University)
Jeong Ji-Hwan (Department of Mechanical Engineering, Pusan National University)
Publication Information
International Journal of Air-Conditioning and Refrigeration / v.14, no.2, 2006 , pp. 49-56 More about this Journal
Abstract
Heat transfer performances of individual row of two-row fin and tube heat exchangers are experimentally investigated. Tested are four heat exchangers which are geometrically identical with the exception of fin shape, slit or louver, and that the fins between the first row and the second row are connected or separated. The tube diameter and fin spacing of the heat exchangers examined are 7mm and 1.4mm, respectively. All thermal fluid measurements are made using a psychrometric calorimeter. In order to evaluate air-side heat transfer coefficients of individual rows, tube-side water flow rates of individual rows are independently controlled such that the water-side temperature drops in each row remain at $5^{\circ}C$. Frontal air velocity varies in the range from 0.7m/s to 2.5m/s. Heat transfer coefficients are presented in terms of Colburn ${\jmath}-factor$. The results show that the heat transfer coefficient of the upstream row is larger than that for the downstream row at low Reynolds numbers.
Keywords
Fin-tube heat exchanger; Heat transfer coefficient; Tube row;
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1 Tasi, S. F. and Shew, T. W. H., 1998, Some physical insights into a two-row finned tube heat transfer, Computers & Fluids, Vol. 27, No.1, pp.29-46   DOI   ScienceOn
2 Rich, D. G., 1975, The effect of the number of tube rows on heat transfer performance of smooth plate fin-and-tube heat exchanger, ASHRAE Transactions, Vol. 81, Part 1, pp. 307-319
3 McAdams, W. H., 1954, Heat Transmission, McGraw Hill, New York, 3rd ed
4 Schmidt, T. E., 1949, Heat transfer calculations for extended surfaces, J. of the ASHRAE, Refrigerating Engineering, Vol.4, pp. 351-357
5 ASHRAE Standard 33-78, 1978, Methods of testing forced circulation air cooling and air heating coils, pp.33-78
6 Gnielinski, V., 1976, New equation for heat and mass transfer in turbulent pipe and channel flow, International Chemical Engineering, Vol. 16, No.2, pp.359-368
7 Sawai, S., Hayashi, T., Ohtake, Y. and Takei, T., 1969, Effects of mechanical bond between fin and tube on heat transfer, Refrigeration, Vol. 44, No. 502, pp.15-21
8 Saboya, F. E. M. and Sparrow, E. M., 1976, Transfer characteristics of two-row plate fin and tube heat exchanger configurations, Int. J. Heat and Mass Transfer, Vol. 19, pp. 41-49   DOI   ScienceOn