Biologically inspired compliant building façade systems with tunable heat transfer capabilities

Item

Title
Biologically inspired compliant building façade systems with tunable heat transfer capabilities
Description
Energy consumption for building thermoregulation is a major contributor to the environmental impact of
our built environment. Building envelope systems that actively tune their heat transfer rate in response to
environmental stimuli and leverage the free energy the exterior environment has to offer, thus represent a
promising solution to make building thermoregulation more energy efficient.
This dissertation investigates the means and methods to develop façade systems that tune heat flow by
drawing inspiration from nature and leveraging the unique properties of compliant materials. The research
encompasses a wide range of highly complementary fields including thermodynamics, materials science,
and soft actuators, all of which are framed within the context of employing nature’s design rules for tuning
heat transfer and generating motion.
From these interdisciplinary investigations, two novel thermoregulatory concepts are presented in the
form of mechanically actuated designs made from the optically transparent elastomer
polydimethylsiloxane (PDMS). Inspired by the chromatophores in coleoid cephalopod skin, the first
example is a novel infrared light-modulating technology constructed from a PDMS film with a thin gold
surface coating. Inspired by the cutaneous cardiovascular system in endothermic homeotherms, the second
example consists of a PDMS-based vascular device that modulates conductive and convective heat
transfer. Through both experimental projects, the work investigated how to translate biological design
principles into our own concepts for tunable systems, how to fabricate these systems, how they can be
actuated, how to evaluate their performance, and where and how to apply them in our building envelopes
to benefit building thermoregulation. To achieve these goals, the research encompasses an extensive
literature review of the biological precedents, iterative and functional prototyping, and performance
analysis through numerical modeling and experimentation.
The results from these efforts demonstrate how the new concepts provide opportunities for optimizing
heat transfer and utilizing freely available solar energy and wind, and consequently, significantly reducing
energy use for building thermoregulation. Fundamentally, the work demonstrates how a design strategy
that integrates science, technology, and design creates new design opportunities for façade systems with
tunable heat transfer.
Creator
Tomholt, Lara
Subject
biologically inspired
compliant
energy efficiency
facade
thermoregulation
tunable
Architecture
Sustainability
Design
Contributor
Picon, Antoine
Malkawi, Ali
Weaver, James C.
Date
2023-02-07T03:56:28Z
2022
2023-02-06
2022-11
2023-02-07T03:56:28Z
Type
Thesis or Dissertation
text
Format
application/pdf
application/pdf
Identifier
Tomholt, Lara. 2022. Biologically inspired compliant building façade systems with tunable heat transfer capabilities. Doctoral dissertation, Harvard Graduate School of Design.
29397395
https://nrs.harvard.edu/URN-3:HUL.INSTREPOS:37374200
0000-0002-1304-5094
Language
en
Item sets
Graduate School of Design