A team from the Digital Building Technologies department at ETH Zurich and renewable insulation company FenX have created a 3D-printable foam alternative to concrete. The temporary or permanent foam is made from recycled waste, and can be printed in unique shapes that are lighter and are have better insulation properties than normal concrete. A prototype is described by DBT as following the geometry of a 2m by 1.3m ribbed slab with point supports in each corner, with the foam following lines that mimic the principal stress pattern. The prototype requires 24 formwork elements in 12 unique shapes. After installation, the printed foam can be reused in similar applications or recycled.Building geometrically complex formwork for concrete elements that are optimized for resource-efficiency is often wasteful and labor intensive. FoamWork explores how foam 3D printing (F3DP) can be used to produce unique shapes for functional stay-in-place or temporary and recyclable formwork in concrete casting. The resulting mineral composite elements can save up to 70% concrete, are lighter, and feature improved insulation properties. The printable mineral foams based on recycled waste are developed at ETH Zürich in collaboration with FenX AG.A prototype demonstrates this approach with the generic geometry of a 2 x 1.3m ribbed slab with point supports in every corner. The rib layout follows the isostatic lines derived from the principal stress pattern. The resulting geometry requires 24 formwork elements in 12 unique shapes.All foam elements are fabricated with a robotic foam 3D printing (F3DP) setup. They are placed manually inside a conventional timber perimeter formwork before casting ultra-high-performance fiber-reinforced concrete (UHPFRC). After curing, the timber formwork is removed from the prototype and the structural building element is completed.This novel fabrication approach is envisioned to significantly impact the responsible and sustainable consumption of resources and energy in the building industry. It enables the manufacturing of geometrically complex foam elements that were previously unfeasible and wasteful to produce with conventional methods. The foam shapes produced with F3DP can be used as stay-in-place applications or removed and recycled for printing the next formwork.
A team from the Digital Building Technologies department at ETH Zurich and renewable insulation company FenX have created a 3D-printable foam alternative to concrete. The temporary or permanent foam is made from recycled waste, and can be printed in unique shapes that are lighter and are have better insulation properties than normal concrete. A prototype is described by DBT as following the geometry of a 2m by 1.3m ribbed slab with point supports in each corner, with the foam following lines that mimic the principal stress pattern. The prototype requires 24 formwork elements in 12 unique shapes. After installation, the printed foam can be reused in similar applications or recycled.Building geometrically complex formwork for concrete elements that are optimized for resource-efficiency is often wasteful and labor intensive. FoamWork explores how foam 3D printing (F3DP) can be used to produce unique shapes for functional stay-in-place or temporary and recyclable formwork in concrete casting. The resulting mineral composite elements can save up to 70% concrete, are lighter, and feature improved insulation properties. The printable mineral foams based on recycled waste are developed at ETH Zürich in collaboration with FenX AG.A prototype demonstrates this approach with the generic geometry of a 2 x 1.3m ribbed slab with point supports in every corner. The rib layout follows the isostatic lines derived from the principal stress pattern. The resulting geometry requires 24 formwork elements in 12 unique shapes.All foam elements are fabricated with a robotic foam 3D printing (F3DP) setup. They are placed manually inside a conventional timber perimeter formwork before casting ultra-high-performance fiber-reinforced concrete (UHPFRC). After curing, the timber formwork is removed from the prototype and the structural building element is completed.This novel fabrication approach is envisioned to significantly impact the responsible and sustainable consumption of resources and energy in the building industry. It enables the manufacturing of geometrically complex foam elements that were previously unfeasible and wasteful to produce with conventional methods. The foam shapes produced with F3DP can be used as stay-in-place applications or removed and recycled for printing the next formwork.