2008
DOI: 10.1016/j.applthermaleng.2007.12.006
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Numerical study of a novel counter-flow heat and mass exchanger for dew point evaporative cooling

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Cited by 201 publications
(80 citation statements)
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“…The temperature of the treated surface equals to the local wall temperature. 5) The thermal resistance of the wall separating the adjacent dry and wet channels is assumed to be negligible, namely ignore the temperature difference between the dry and wet sides of the wall (Zhao et al, 2008). 6) Air is treated as incompressible gas.…”
Section: Fig2 Physical Model Of the Corrugated Hmx For Computationmentioning
confidence: 99%
“…The temperature of the treated surface equals to the local wall temperature. 5) The thermal resistance of the wall separating the adjacent dry and wet channels is assumed to be negligible, namely ignore the temperature difference between the dry and wet sides of the wall (Zhao et al, 2008). 6) Air is treated as incompressible gas.…”
Section: Fig2 Physical Model Of the Corrugated Hmx For Computationmentioning
confidence: 99%
“…As a result of evaporation, the air in the wet channel absorbs heat from the product air flowing in the adjacent side. This process occurs multiple times in a short physical space within the exchanger, thus, resulting in progressively colder product air temperatures [107]. 19 Fig.…”
Section: Indirect Evaporative Coolersmentioning
confidence: 99%
“…19 Fig. 10 (a, b) schematics of DPEC and (c) psychometric process [97,107] The arrangement enables the temperatures of the product air to be cooled nearly to the dew-point temperature of the incoming working air, which is considerable lower than the wet bulb temperature (the achievable limit for direct evaporative cooling) [108].…”
Section: Indirect Evaporative Coolersmentioning
confidence: 99%
“…The performance of a 400 m 3 /h air flow rate cooler was analysed and showed that for inlet air temperatures higher than 24 C the model results accuracy were within 10%. Zhao et al [6] presented a numerical study of a counter flow Indirect Evaporative Cooler for sub-wet bulb temperature cooling. The authors suggested a range of design conditions to maximize the cooler performance including air velocity range, height of air passage, and length to height ratio of air flow ducts and found that the cooler can yield wet bulb effectiveness of up to 1.3.…”
Section: B Indirect Evaporative Cooling and Sub Wet Bulb Temperaturementioning
confidence: 99%