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Cooling Performance of a Counterflow Regenerative Evaporative Cooler with Finned Channels  

Moon, Hyun-Ki (Energy Mechanics Research Center, Korea Institute of Science & Technology)
Lee, Dae-Young (Energy Mechanics Research Center, Korea Institute of Science & Technology)
Publication Information
Korean Journal of Air-Conditioning and Refrigeration Engineering / v.20, no.7, 2008 , pp. 462-469 More about this Journal
Abstract
A regenerative evaporative cooler has been fabricated and tested for the evaluation of cooling performance. The regenerative evaporative cooler is a kind of indirect evaporative cooler comprised of multiple pairs of dry and wet channels. The air flowing through the dry channels is cooled without any change in the humidity and at the outlet of the dry channel a part of air is redirected to the wet channel where the evaporative cooling takes place. The regenerative evaporative cooler fabricated in this study consists of the multiple pairs of finned channels in counterflow arrangement. The fins and heat transfer plates were made of aluminum and brazed for good thermal connection. Thin porous layer coating was applied to the internal surface of the wet channel to improve surface wettability. The regenerative evaporative cooler was placed in a climate chamber and tested at various operation condition. The cooling performance is found greatly influenced by the evaporation water flow rate. To improve the cooling performance, the evaporation water flow rate needs to be minimized as far as the even distribution of the evaporation water is secured. At the inlet condition of $32^{\circ}C$ and 50%RH, the outlet temperature was measured at $22^{\circ}C$ which is well below the inlet wet-bulb temperature of $23.7^{\circ}C$.
Keywords
Regenerative evaporative cooler; Cooling effectiveness; Performance test; Evaporation water flow rate;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
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1 Maclaine-cross, I. L. and Banks, P. J., 1981, A general theory of wet surface heat exchangers and its application to regenerative evaporative cooling, J. of Heat Transfer, Vol. 103, pp. 579- 585   DOI
2 Stoitchkov, N. J. and Dimitrov, G. I., 1998, Effectiveness of crossflow plate heat exchanger for indirect evaporative cooling, Int. Journal of Refrigeration, Vol. 21, pp. 463-471   DOI   ScienceOn
3 Erens, P. J. and Dreyer, A. A., 1993, Modelling of indirect evaporative air coolers, Int. J. Heat Mass Transfer, Vol. 36, pp. 17-26   DOI   ScienceOn
4 Hsu, S. T., Lavan, Z. and Worek, W., 1989, Optimization of wet-surface heat exchangers, Energy, Vol. 14, pp. 757-770   DOI   ScienceOn
5 Lee, D.-Y., Lee, J. W., and Kang, B. H., 2005, Experimental study on the hydrophilic porous film coating for evaporative cooling enhancement, Int. Journal of Air-Conditioning and Refrigeration, Vol. 13, pp. 99-106
6 Choi, B. S., Hong, H., and Lee, D.-Y., 2008, Study on the counterflow regenerative evaporative cooler with finned channels, Korean Journal of Air-Conditioning and Refrigeration Engineering, Vol. 20, pp. 447-454   과학기술학회마을
7 Choo, H.-S., Lee, K.-S., and Lee, D.-Y., 2006, Effects of evaporation water flow rate on the performance of an indirect evaporative cooler, Korean Journal of Air-Conditioning and Refrigeration Engineering, Vol. 18, pp. 714-721   과학기술학회마을
8 Pescod, D., 1979, A heat exchanger for energy saving in an air conditioning plant, Trans. ASHRAE, Vol. 85, pp. 238-251