Experimental study of the optimal design and performance of a mixed-flow dew-point indirect evaporative cooler
Alessandra Urso, Eloy Velasco Gómez, A. González, Manuel Andrés Chicote, Francesco Nocera
Abstract
• A novel Dew Point Indirect Evaporative Cooler is designed in mixed flow configuration. • The use of wicking material on the wet side improves 1.45 times the cooling capacity. • Water distribution through outside nozzles increases the temperature drop over 1 °C. • The temperature drop per heat transfer surface area corresponds to published results. • Cooling capacity reaches 250 W in a compact 31 x 25 x 30.5 cm device. Evaporative cooling technologies represent a promising alternative to face the emerging cooling energy poverty, owing to their low production and operative costs. High performance can be achieved through more complex designs, such as dew point indirect evaporative cooling (DIEC) systems. Recent literature explores improvements on these systems, like flow configuration, materials, and water distribution. This study proposes a compact mixed-flow DIEC system made of polycarbonate plates covered with two possible wicking materials. Three water distribution systems are also studied. The prototypes are experimentally characterised by varying the inlet air temperature, humidity, volume flow, and working-to-intake air ratio. The best performing design is evaluated in terms of temperature drop, dew-point effectiveness, wet-bulb effectiveness, and cooling capacity. Results are consistent with those in the literature for equivalent heat transfer areas. The use of a wicking material improves the cooling capacity by up to 1.45. The type of material is less relevant, which enables to select the most economic and accessible option. External nozzles for water distribution offers temperature drops of more than 1 °C and better cooling capacities of approximately 100 W than inlet water distributors.