Efficient cooling of light-emitting diode via plasma-activated aerosols

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Abstract

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.

Original languageEnglish
Article number109313
Number of pages10
JournalInternational Journal of Thermal Sciences
Volume206
DOIs
Publication statusPublished - Dec 2024

Keywords

  • Atmospheric pressure plasma
  • Heat transfer coefficient
  • LED
  • Nozzle-based nebulizer
  • Plasma-activated aerosols
  • Spray cooling

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