As emphasised by several EU initiatives, including the European Green Deal and the New European Bauhaus, reducing the construction industry’s impact on the global climate demands a drastic cut in CO2 emissions and raw material consumption, especially from concrete. A promising strategy is to design materially efficient structures that resist loads primarily through their geometry, following the principle of resistance through form.
Although modern digital design tools make it easy to design and analyse lightweight shell structures, their potential often remains untapped due to the difficulty of constructing complex double-curved concrete geometries. Conventional formwork methods, relying on single-use timber or milled foam, are wasteful, labour-intensive, and costly.
Fabric tensile formworks have gained attention for their structural efficiency and minimal material use. Among these, knitted textiles offer exceptional potential: they can be specified at the stitch level, enabling continuous double-curved formworks with tailored mechanical properties. This flexibility supports targeted meta-material designs and optimised fabrication. However, designing 3D knitted formworks that meet precise structural and functional requirements is a challenging task. It requires complex structural modelling and extensive prototyping, as their non-homogeneous behaviour is less predictable than that of woven textiles.
FlexiForm challenges these limitations by combining computational structural design and optimisation, digital fabrication, and automated construction into a unified workflow. This will enable the production of innovative, lightweight stay-in-place textile formworks using 3D knitting. 3D knitting is an innovative technique that enables the creation of seamless textiles with a wide range of custom knitting architectures. These knitted textile formworks will enable the straightforward construction of innovative, sustainable double-curved concrete shell structures that excel in material efficiency, mechanical functionality, embodied carbon reduction, reliability, and cost-effectiveness. In the future, we plan to expand this approach to include other materials, such as bio-based materials, which can pave the way for construction without relying on traditional cement.