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Capillary container array structures for efficient, energy-saving, and sustainable evaporative cooling and humidification

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  • Wu, Xintao
  • Wen, Yating
  • Wang, Hongzhou
  • Sun, Zhiyuan
  • Huang, Zhandong
  • Wei, Jinjia

Abstract

Evaporative cooling is a widely employed method for air conditioning and heat dissipation, utilizing the phase transition of water to achieve simultaneous cooling and humidification. It relies on high-surface-area solid materials to enhance air-liquid contact upon wetting. However, these water-absorbing materials have drawbacks such as increased air resistance, degradation of water quality, and limited water retention capabilities. This study introduces a novel structure called the capillary container array (CCA) for effective humidification and cooling. The CCA structure overcomes the limitations of traditional methods by incorporating interconnected capillary containers with adjustable spacing and utilizing capillary forces to capture liquid droplets while minimizing the solid component. Compared to commercial paper-based wet curtains, the CCA structure offers significant advantages including strong water retention capabilities, high humidification performance, low air resistance and high pollution resistance. It increases water capacity by 6 times, humidification capacity by 8 %, and temperature drop by 2.2 °C. Moreover, it exhibits a 5-fold longer in water retention duration, a 30 % reduction in air pressure drop and a 3-fold increase in the performance coefficient, and maintains excellent water quality (<1 NTU) over prolonged operation. These advancements make the CCA structure highly promising for various applications in agriculture, industry and environmental conservation.

Suggested Citation

  • Wu, Xintao & Wen, Yating & Wang, Hongzhou & Sun, Zhiyuan & Huang, Zhandong & Wei, Jinjia, 2024. "Capillary container array structures for efficient, energy-saving, and sustainable evaporative cooling and humidification," Energy, Elsevier, vol. 309(C).
    • Handle: RePEc:eee:energy:v:309:y:2024:i:c:s0360544224029347
    DOI: 10.1016/j.energy.2024.133159
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