Integrated Fiber Forms – Functionally Integrated Slab Systems through Additive Manufacturing and Natural Fiber Reinforcement

Conference Paper

Authors

  • Bruno Knychalla additive tectonics GmbH
  • Christian Wiesner additive tectonics GmbH
  • Patrick Sonnleitner additive tectonics GmbH
  • Magdalena Kowalczyk Autodesk (United Kingdom) image/svg+xml
  • Allin Groom Autodesk (United Kingdom) image/svg+xml
  • Peter Storey Autodesk B.V

DOI:

https://doi.org/10.52825/ocp.v7i.2766

Keywords:

Particle-Bed AM, 3D Printing, Concrete Printing, Selective Cement Activation, Fibre Winding, Formwork, Geopolymer, Hybrid Construction

Abstract

Today’s structural floor systems are labour-intensive to install and constrained to prismatic shapes, relying on formwork that leads to material waste and elevated carbon emissions. This research introduces a particlebed 3D-printed, stay-in-place formwork produced from upcycled wood-aggregate. The formwork defines the geometry of the slab and also sequesters biogenic carbon, provides acoustic dampening, and enables complex, performance-optimised geometries. Instead of conventional steel reinforcement, robotically wound natural fibre cords are applied and anchored to dedicated winding points integrated directly into the printed formwork. Combined with cast geopolymer concrete, this approach eliminates the risk of corrosion and significantly reduces embodied carbon. Because the formwork remains in place, no dismantling or disposal is required, resulting in substantial reductions in labour and construction waste. The system’s topology-optimised geometry accommodates embedded utility conduits, removing the need for suspended ceilings and maximising usable space. The result is a lightweight, trade-friendly floor system that is both functionally and environmentally advanced. Its feasibility has been demonstrated at full architectural scale through a 1:1 prototype.

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Cover for Visions and Strategies for Reinforcing Additively Manufactured Constructions 2025

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Published

2025-12-12

How to Cite

Knychalla, B., Wiesner, C., Sonnleitner, P., Kowalczyk, M., Groom, A., & Storey, P. (2025). Integrated Fiber Forms – Functionally Integrated Slab Systems through Additive Manufacturing and Natural Fiber Reinforcement: Conference Paper. Open Conference Proceedings, 7. https://doi.org/10.52825/ocp.v7i.2766

Conference Proceedings Volume

Vol. 7 (2025): Visions and Strategies for Reinforcing Additively Manufactured Constructions 2025

Section

Contributions to the symposium "Visions and Strategies for Reinforcing Additively Manufactured Constructions 2025"

License

Copyright (c) 2025 Bruno Knychalla, Christian Wiesner, Patrick Sonnleitner, Magdalena Kowalczyk, Allin Groom, Peter Storey

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Received 2025-05-28
Accepted 2025-09-26
Published 2025-12-12