Samenvatting
This paper presents four key developments that are leading to the scalability of the fabrication processes of mycelium material. We develop a biological and digital fabrication pipeline for (1) growing large mycelium composite blocks, (2) on-site robotic wire-cutting, (3) using mycelium materials as a multi-functional formwork, and (4) implementing the self-healing of fungal organisms. The purpose of the research is to investigate the processing approaches, variable material handling and materials properties of large biohybrid (composed of biological and non-biological material) foam blocks. The robotic tool provides the freedom to shape and structure this novel biological material and opens the possibility of making unique architectural modules. For the first time, mycelium materials are robotically wire-cut in situ, which results in two demonstrators. Departing from an application-based intention, we test the compatibility of thermal insulating mycelium formwork with a concrete slab. As such, we combine two different materials with hybrid physical and architectural properties. Additionally, we investigated the self-healing and living properties of mycelium components after robotic implementation. The combination of microbiological systems and fibrous substrates creates a unique class of bioactive composite materials, with potential applications at in the construction sector.
| Originele taal-2 | English |
|---|---|
| Artikelnummer | 122732 |
| Tijdschrift | Construction and Building Materials |
| Volume | 283 |
| DOI's | |
| Status | Published - 10 mei 2021 |
Bibliografische nota
Funding Information:This research was made possible thanks to the funding of the SB Fellowship of the Research Foundation Flanders [grant number 1S36417N (E.E.) and 1SA9721N (A.V.W)]. The work was supplementary supported by an FWO long term travel grant [grant number V442219N] which financed my research stay at the Centre for Information Technology and Architecture (CITA), the Royal Danish Academy of Fine Arts Schools of Architecture, Design and Conservation. The robotic wire-cutting setup was developed and performed by Asbjørn Søndergaard at Odico Formwork Robotics Aps, (Odense, Denmark). The authors would also like to thank Jon Wedersøe Strunge for introducing us to Odico and for the conceptualization. We want to thank Daniel Debondt and Gabriel Van den Nest, the technical staff of MEMC research group of the Vrije Universiteit Brussel for supporting with the concrete casting process. We also thank Vendula Ficelová and Joost Brancart of FYSC research group for supporting with the SEM images.
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