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一般的なプラスチックが、季節に合わせて建物を受動的に冷暖房する可能性(Common plastics could passively cool and heat buildings with the seasons)

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2024-06-27 プリンストン大学

プリンストン大学とUCLAの研究者たちは、建物の冷暖房をパッシブに制御するメカニズムを開発しました。2023年6月27日に発表されたこの研究では、特定の波長での放射熱の流れを制限するコーティングを使用することで、従来の建物の外装を超えるエネルギー節約と快適性が実現されました。これにより、夏は冷房、冬は暖房効果を持つ建物が可能になります。研究は、低コストで一般的な材料を用いて実現でき、特にエネルギー資源の少ない地域で有望です。この新技術は空調コストの削減や熱関連の健康被害の軽減に貢献する可能性があります。

<関連情報>

地球の輝きにおける放射冷却と体温調節 Radiative cooling and thermoregulation in the earth’s glow

Jyotirmoy Mandal,Jyothis Anand,Sagar Mandal,John Brewer,Arvind Ramachandran,Aaswath P. Raman
Cell Reports Physical Science  Published:June 27, 2024
DOI:https://doi.org/10.1016/j.xcrp.2024.102065

Graphical abstract

一般的なプラスチックが、季節に合わせて建物を受動的に冷暖房する可能性(Common plastics could passively cool and heat buildings with the seasons)

Highlights

  • A novel, passive radiative thermoregulation mechanism for walls and windows
  • Buildings lose narrowband heat to the sky but exchange broadband heat with the earth
  • Vertical LWIR emitters stay cooler than broadband ones in hot weather and warmer in cold
  • Thermoregulation by this simple and static design yields untapped energy savings

Summary

Efficient passive radiative cooling of buildings requires an unimpeded view of the sky. However, vertical facades of buildings mostly see terrestrial features that become broadband-radiative heat sources in the summer and heat sinks in the winter. The resulting summertime terrestrial heat gain by buildings negates or overwhelms their narrowband longwave infrared (LWIR) radiative cooling to space, while the wintertime terrestrial heat loss causes overcooling. We show that selective LWIR emitters on vertical building facades can exploit the differential transmittance of the atmosphere toward the sky and between terrestrial objects to achieve higher summertime cooling and wintertime heating than conventionally used broadband emitters. The impact of this novel and passive thermoregulation is comparable to that of painting dark roofs white and is achievable with both novel and commonplace materials. Our findings represent new and remarkable opportunities for materials design and untapped thermoregulation of entities ranging from buildings to human bodies.

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