@article{NAVARRO2024121455,
title = {Numerical study of an ultrasonic spray atomiser as an evaporative cooler},
journal = {Applied Thermal Engineering},
volume = {236},
pages = {121455},
year = {2024},
issn = {1359-4311},
doi = {https://doi.org/10.1016/j.applthermaleng.2023.121455},
url = {https://www.sciencedirect.com/science/article/pii/S1359431123014849},
author = {P. Navarro and J. Ruiz and P. Martínez and M. Lucas},
keywords = {CFD, Cooling efficiency, Ultrasonic atomiser, Evaporative cooling},
abstract = {Pre-cooling the inlet air of an air conditioning condenser through evaporative cooling has proven highly effective in enhancing performance. Previous works focused on utilising an ultrasonic mist generator, obtaining promising results. However, the mist generator’s inability to control droplet distribution presents limitations. To address this, we propose the utilisation of an ultrasonic spray atomiser, which overcomes these constraints. Our main objective is to develop a numerical model for this innovative system. Experimental data from a wind tunnel facility were employed to validate the model. A parametric analysis was conducted, considering key variables in the cooling process: injected water mass flow rate, cooled area, and atomiser power consumption. Based on these variables, an optimisation analysis was performed, revealing that the optimal operating ranges for overall performance are water-to-air mass flow ratios below 1.8⋅10−3 for a relative humidity of 0.5, and below 8.1⋅10−4 for 0.7. Within these conditions, water spray is more evenly distributed throughout the control section, facilitating a homogeneous and efficient evaporative cooling process. The maximum evaporative coefficient of performance achieved across all simulations was 30.49. That is, this novel equipment surpasses the limitations of previous systems and its performance.}
}