Atmospheric water generator (AWG) is a device for producing water from humid air. The water is produced by cooling the air until below its dew point temperature. This study presents the optimization of a simple thermoelectric AWG device (S-TEAWG) for emergency purposes. The designed S-TEAWG consists of a thermoelectric module and condensation plate as a cooler and condensation surface, respectively. The plate is attached to the cold side of the thermoelectric module to enhance the contact surface area with the ambient air. The thermoelectric module with the dimension of 4 cm × 4 cm is operated at 12 V of voltage and 50 ^oC of hot side temperature. The device is installed vertically thus the condensates flow down naturally due to gravity. Various surface areas of vertical plates, from 0.01 m2 to 0.09 m2, are evaluated theoretically to obtain the maximum water production. The results show that the lower temperature of the vertical plate is achieved at a smaller surface area. However, the optimum surface area is obtained at 0.03 m2 with 60.9 ml/d of water production.

Ajiwiguna, T.A., Nugroho, R., Ismardi, A., Method for thermoelectric cooler utilization using manufacturer’s technical information. AIP Conference Proceedings, 1941, 2018.

Avhad, S., Dandekar, A., Chandak, A., Kajale, P., Gohel, N. S, Theoretical Analysis of Atmospheric Water Generator using Thermoelectric Cooler. Proceeding of the Yukhti, 2021.

Bundschuh, J., Kaczmarczyk, M., Ghaffour, N., Tomaszewska, B, State-of-the-art of renewable energy sources used in water desalination: Present and future prospects. Desalination, 508, 2021.

Cengel, Y.A, Heat transfer a practical approach, Mcgraw-Hill, 1997.

Engineering ToolBox, Convective Heat Transmission - Air Velocity and Air Flow Volume. https://www.engineeringtoolbox.com/convective-air-flow-d_1006.html, 2005.

Joshi, V.P., Joshi, V.S., Kothari, H.A., Mahajan, M.D., Chaudhari, M.B., Sant, K.D, Experimental Investigations on a Portable Fresh Water Generator Using a Thermoelectric Cooler. Energy Procedia, 109, 161–166, 2017.

Kadhim, T. J., Abbas, A. K., Kadhim, H.J, Experimental study of atmospheric water collection powered by solar energy using the Peltier effect. IOP Conference Series: Materials Science and Engineering, 671(1), 2020.

Lee, S., Song, S., Au, V., Moran, K.P, Constriction/spreading resistance model for electronics packaging. Proceedings of the 4th ASME/JSME Thermal Engineering Conference, 4, 199–206, 1995.

Nassrullah, H., Anis, S. F., Hashaikeh, R., Hilal, N, Energy for desalination: A state-of-the-art review. Desalination, 491, 2020.

Offir Inbar, Igal Gozlan, Stanislav Ratner, Yaron Aviv, Roman Sirota, Dror Avisar, Producing safe drinkingwater using an atmospheric water generator (AWG) in an urban environment, Water 12, 2940, 2020.

Qasim, M., Badrelzaman, M., Darwish, N. N., Darwish, N. A., Hilal, N, Reverse osmosis desalination: A state-of-the-art review. Desalination, 459(February), 59–104, 2019.

Ramya M, Roopa M. Atmospheric water generator using peltier device, International Journal of Engineering Research & Technology, 8(13), 182–185, 2020.

Shanshan, L., Wei, H., Dengyun, H., Song, L., Delu Chen, Xin Wu, Fusuo Xu, Sijia Li, Experiment analysis of portable atmospheric water generator by thermoelectric cooling method, Energy Procedia 142, 1609–1614, 2017.

Sri Suryaningsih, Nurhilal, O., Optimal design of an atmospheric water generator (AWG) based on the thermo-electric cooler (TEC) for drought in rural, AIP Conference Proceedings 1712, 030009, 2016.

Vas, A. C., Ibnu Masood, B., Ahamad, F., Portable atmospheric water generator, International Research Journal of Engineering and Technology, 1649–1652, 2020.