Radiative Cooling and Thermoregulation of Vertical Facades with Micropatterned Directional Emitters

arXiv - PHYS - Applied Physics Pub Date : 2024-08-07 DOI:arxiv-2408.03512

Mathis Degeorges, Jyothis Anand, Nithin Jo Varghese, Jyotirmoy Mandal

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Abstract

We demonstrate a micropatterned directional emitter ({\mu}DE) with an ultrabroadband, azimuthally selective and tailorable emittance across the thermal wavelengths and over wide angles. The {\mu}DE can enable a novel and passive seasonal thermoregulation of buildings by reducing summertime terrestrial radiative heat gain, and wintertime loss. We show several types of {\mu}DE, such as metallic and white variants, made using low-cost materials and scalable manufacturing techniques that are already in large-scale use. Furthermore, we show that its directional emittance can be geometrically tailored to sky-view factors in different urban scenarios. Outdoor experiments show that {\mu}DEs stay up to 1.53{\deg}C cooler than traditional building envelopes when exposed to direct sunlight on summer days and up to 0.46{\deg}C warmer during winter nights. Additionally, {\mu}DEs demonstrate significant cooling powers of up to 40 Wm-2 in warm conditions and heating powers of up to 30 Wm-2 in cool conditions, relative to typical building envelopes. Building energy models show that {\mu}DEs can achieve all-season energy savings similar to or higher than those of cool roofs. Collectively, our findings show {\mu}DEs as highly promising for thermoregulating buildings.

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利用微图案定向发射器对垂直外墙进行辐射冷却和热调节

我们展示了一种微图案定向发射器（{\mu}DE），它具有多宽带、方位角选择性和可定制的热波长和广角发射率。这种{mu}DE可以通过减少夏季的地面辐射得热和冬季的地面辐射失热，对建筑物进行新颖的、被动的季节性温度调节。我们展示了几种类型的{\mu}DE，如金属和白色变体，它们都是利用低成本材料和可扩展的制造技术制成的，目前已在大规模使用。室外实验表明，{\mu}DE在夏日阳光直射下比传统建筑外墙温度低1.53摄氏度，在冬夜比传统建筑外墙温度高0.46摄氏度。此外，与典型的建筑围护结构相比，{\mu}DE 在温暖条件下的制冷能力高达 40 Wm-2，在凉爽条件下的制热能力高达 30 Wm-2。建筑节能模型显示，{\mu}DE可以实现与凉爽屋顶类似或更高的全年节能效果。总之，我们的研究结果表明{\mu}DEs在调节建筑物温度方面大有可为。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Applied Physics

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