Growing living and multifunctional mycelium composites for large-scale formwork applications using robotic abrasive wire-cutting

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 multifunctional 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. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This paper presents four key developments that are leading to the scalability of the fabrication processes of mycelium material, focusing on biological and digital fabrication pipeline, robotic wire-cutting, multifunctional formwork using mycelium materials, and self-healing of fungal organisms. The research aims to investigate the processing approaches, material handling, and properties of large biohybrid foam blocks, which combine different materials with hybrid physical and architectural properties. The integration of microbiological systems and fibrous substrates creates a unique class of bioactive composite materials with potential applications in the construction sector.