TY - JOUR
T1 - Efficient cooling of light-emitting diode via plasma-activated aerosols
AU - Low, Mary
AU - Hung, Yew M.
AU - Tan, Ming K.
N1 - Publisher Copyright:
© 2024 The Authors
PY - 2024/12
Y1 - 2024/12
N2 - Spray cooling is an effective method for rapidly absorbing excess heat from high-temperature surfaces. The performance of this method can be further enhanced by applying a thin layer of two-dimensional materials to the heated surface, which increases surface wettability and promotes the rapid permeation of aerosols into the coating. However, the durability of these coatings over extended periods remains a challenge. In this study, we investigate the enhancement of spray cooling performance using plasma-activated aerosols generated by a nozzle-based nebulizer; plasma-activated water (prior to nebulization) is produced using an atmospheric pressure plasma. Compared to deionized aerosols, plasma-activated aerosols have lower surface tension, which facilitates rapid evaporation when deposited on the heated surface. Specifically, we observe up to a 23% reduction in surface temperature when the heated surface (initially at 100 degree Celsius) is sprayed at a nebulization rate of 0.33 g/min with plasma-activated aerosols (having an electrical conductivity of 1.1 mS/cm), as opposed to deionized aerosols. When applied to the cooling of LED bulbs, this technique increases the heat transfer coefficient by up to 45%, leading to a 30% increase in illuminance. Plasma-activated water is easy to produce, making it a feasible and significant improvement over deionized water for spray cooling. Importantly, this approach does not require modifications to the existing spray cooling systems, such as those involving surface coatings.
AB - Spray cooling is an effective method for rapidly absorbing excess heat from high-temperature surfaces. The performance of this method can be further enhanced by applying a thin layer of two-dimensional materials to the heated surface, which increases surface wettability and promotes the rapid permeation of aerosols into the coating. However, the durability of these coatings over extended periods remains a challenge. In this study, we investigate the enhancement of spray cooling performance using plasma-activated aerosols generated by a nozzle-based nebulizer; plasma-activated water (prior to nebulization) is produced using an atmospheric pressure plasma. Compared to deionized aerosols, plasma-activated aerosols have lower surface tension, which facilitates rapid evaporation when deposited on the heated surface. Specifically, we observe up to a 23% reduction in surface temperature when the heated surface (initially at 100 degree Celsius) is sprayed at a nebulization rate of 0.33 g/min with plasma-activated aerosols (having an electrical conductivity of 1.1 mS/cm), as opposed to deionized aerosols. When applied to the cooling of LED bulbs, this technique increases the heat transfer coefficient by up to 45%, leading to a 30% increase in illuminance. Plasma-activated water is easy to produce, making it a feasible and significant improvement over deionized water for spray cooling. Importantly, this approach does not require modifications to the existing spray cooling systems, such as those involving surface coatings.
KW - Atmospheric pressure plasma
KW - Heat transfer coefficient
KW - LED
KW - Nozzle-based nebulizer
KW - Plasma-activated aerosols
KW - Spray cooling
UR - http://www.scopus.com/inward/record.url?scp=85200812197&partnerID=8YFLogxK
U2 - 10.1016/j.ijthermalsci.2024.109313
DO - 10.1016/j.ijthermalsci.2024.109313
M3 - Article
AN - SCOPUS:85200812197
SN - 1290-0729
VL - 206
JO - International Journal of Thermal Sciences
JF - International Journal of Thermal Sciences
M1 - 109313
ER -