TY - GEN
T1 - Surface generation of radiatively cooled building skin for desert climate
AU - Aviv, Dorit
AU - Wang, Zherui
AU - Meggers, Forrest
AU - Ida, Aletheia
N1 - Funding Information:
We would like to thank Sean Rucewicz, Eric Teitelbaum, Maryam Moradnejad, Junren Tan, and Jiewei Li for their contributions to this project, and Princeton University Office of Sustainability, Princeton Council on Science and Technology, University of Arizona (UA) Accelerate for Success (AFS) grant, and Penn Praxis at the University of Pennsylvania for providing funding for this research.
Publisher Copyright:
© Proceedings of the 40th Annual Conference of the Association for Computer Aided Design in Architecture: Distributed Proximities, ACADIA 2020. All rights reserved.
PY - 2020
Y1 - 2020
N2 - A radiatively cooled translucent building skin is developed for desert climates, constructed out of pockets of high heat-capacity liquids. The liquids are contained by a wavelength-selective membrane enclosure, which is transmissive in the infrared range of electromagnetic radiation but reflective in the shortwave range, and therefore prevents overheating from solar radiation and at the same time allows for passive cooling through exposure of its thermal mass to the desert sky. To assess the relationship between the form and performance of this envelope design, we develop a feedback loop between computational simulations, analytical models, and physical tests. We conduct a series of simulations and bench-scale experiments to determine the thermal behavior of the proposed skin and its cooling potential. Several materials are considered for their thermal storage capacity. Hydrogel cast into membrane enclosures is tested in real climate conditions. Slurry phase change materials (PCM) are also considered for their additional heat storage capacity. Challenges of membrane welding patterns and nonuniform expansion of the membrane due to the weight of the enclosed liquid are examined in both digital simulations and physical experiments. A workflow is proposed between the radiation analysis based on climate data, the form- finding simulations of the elastic membrane under the liquid weight, and the thermal storage capacity of the overall skin.
AB - A radiatively cooled translucent building skin is developed for desert climates, constructed out of pockets of high heat-capacity liquids. The liquids are contained by a wavelength-selective membrane enclosure, which is transmissive in the infrared range of electromagnetic radiation but reflective in the shortwave range, and therefore prevents overheating from solar radiation and at the same time allows for passive cooling through exposure of its thermal mass to the desert sky. To assess the relationship between the form and performance of this envelope design, we develop a feedback loop between computational simulations, analytical models, and physical tests. We conduct a series of simulations and bench-scale experiments to determine the thermal behavior of the proposed skin and its cooling potential. Several materials are considered for their thermal storage capacity. Hydrogel cast into membrane enclosures is tested in real climate conditions. Slurry phase change materials (PCM) are also considered for their additional heat storage capacity. Challenges of membrane welding patterns and nonuniform expansion of the membrane due to the weight of the enclosed liquid are examined in both digital simulations and physical experiments. A workflow is proposed between the radiation analysis based on climate data, the form- finding simulations of the elastic membrane under the liquid weight, and the thermal storage capacity of the overall skin.
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M3 - Conference contribution
AN - SCOPUS:85115669598
T3 - Proceedings of the 40th Annual Conference of the Association for Computer Aided Design in Architecture: Distributed Proximities, ACADIA 2020
SP - 66
EP - 73
BT - Technical Papers, Keynote Conversations
A2 - Slocum, Brian
A2 - Ago, Viola
A2 - Doyle, Shelby
A2 - Marcus, Adam
A2 - Yablonina, Maria
A2 - del Campo, Matias
PB - ACADIA
T2 - 40th Annual Conference of the Association for Computer Aided Design in Architecture: Distributed Proximities, ACADIA 2020
Y2 - 24 October 2020 through 30 October 2020
ER -