Architected Porosity: Foam 3D Printing for Lightweight and Insulating Building Elements
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Date
2023
Publication Type
Doctoral Thesis
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yes
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Abstract
Porous materials are ubiquitous. They make the bones of birds lightweight for flight and one of the oldest staple foods of humankind, bread, easy to digest. Distributing nothing inside something unleashes transformative powers and fascinates designers and engineers alike. In construction, different porosities are conventionally combined by pressing, bolting, or gluing materials together to make building parts lighter, thermally insulating, and endow them with additional properties. In contrast, this thesis asks what architectures would become possible when building with varying porosities in one holistic materialization process: large-scale 3D printing of foams. The most press- ing environmental challenges of the construction industry are addressed by proposing a design and manufacturing framework. This framework enables the creation of lightweight and insulating structures that require less material, resulting in a lower carbon footprint and reduced operational energy require- ments for heating buildings.
The cumulative thesis is comprised of four main publications: an opening review defining the research field, followed by three consecutive milestones advancing the main research objectives on a small, medium, and large scale. A robotic 3D printing setup is prototyped, subsequently scaled, and refined in alignment with the material development. Computational design strategies are explored and developed for building part geometries and print path infill schemes. These methods are tested in three real-scale prototypes for architectural applications. By combining digital fabrication technologies and state-of-the-art material science, this interdisciplinary research explores the unknown design potential of foams for innovative building components and envisions a more environmentally friendly and sustainable construction culture.
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published
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ETH Zurich
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Subject
Digital fabrication; Construction automation; 3D Printing; construction 3D printing; Design for Additive Manufacturing (DfAM); Computational design
Organisational unit
09566 - Dillenburger, Benjamin / Dillenburger, Benjamin
Notes
Funding
ETH-01 19-2 - 3D printing of functional graded inorganic foam (ETHZ)