Weather-responsive adaptive shading through biobased and bioinspired hygromorphic 4D-printing

Cheng, Tiffany; Tahouni, Yasaman; Sahin, Ekin Sila; Ulrich, Kim; Lajewski, Silvia; Bonten, Christian; Wood, Dylan; Rühe, Jürgen; Speck, Thomas; Menges, Achim

Weather-responsive adaptive shading through biobased and bioinspired hygromorphic 4D-printing

Tiffany Cheng (), Yasaman Tahouni, Ekin Sila Sahin, Kim Ulrich, Silvia Lajewski, Christian Bonten, Dylan Wood, Jürgen Rühe, Thomas Speck and Achim Menges
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Tiffany Cheng: University of Stuttgart
Yasaman Tahouni: University of Stuttgart
Ekin Sila Sahin: University of Stuttgart
Kim Ulrich: University of Freiburg
Silvia Lajewski: University of Stuttgart
Christian Bonten: University of Stuttgart
Dylan Wood: University of Stuttgart
Jürgen Rühe: University of Freiburg
Thomas Speck: University of Freiburg
Achim Menges: University of Stuttgart

Nature Communications, 2024, vol. 15, issue 1, 1-13

Abstract: Abstract In response to the global challenge of reducing carbon emissions and energy consumption from regulating indoor climates, we investigate the applicability of biobased cellulosic materials and bioinspired 4D-printing for weather-responsive adaptive shading in building facades. Cellulose is an abundantly available natural material resource that exhibits hygromorphic actuation potential when used in 4D-printing to emulate motile plant structures in bioinspired bilayers. Three key aspects are addressed: (i) examining the motion response of 4D-printed hygromorphic bilayers to both temperature and relative humidity, (ii) verifying the responsiveness of self-shaping shading elements in lab-generated conditions as well as under daily and seasonal weather conditions for over a year, and (iii) deploying the adaptive shading system for testing in a real building facade by upscaling the 4D-printing manufacturing process. This study demonstrates that hygromorphic bilayers can be utilized for weather-responsive facades and that the presented system is architecturally scalable in quantity. Bioinspired 4D-printing and biobased cellulosic materials offer a resource-efficient and energy-autonomous solution for adaptive shading, with potential contributions towards indoor climate regulation and climate change mitigation.

Date: 2024
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DOI: 10.1038/s41467-024-54808-8

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