Datum
2022-03-25Metadata
Zur Langanzeige
Aufsatz
3DWoodWind: robotic winding processes for material-efficient lightweight veneer components
Zusammenfassung
Winding processes are known from fiber composite technology for highly resistance lightweight components for aviation. These fiber-based processes work predominantly with synthetic composites made of carbon or glass fibers. For the construction industry, these additive processes are very promising and resource-efficient building processes, but they are still hardly used in timber construction despite the very high level of digitalization and technical development. The 3DWoodWind research project uses a continuous strip of thin veneer as a sustainable alternative as its application material. Its natural fibers are intact, continuous, and tensile. In the project, three-dimensional winding processes were developed for material-efficient hollow profile lightweight components made of wood. We describe the material system, composed of suitable combinations of veneers and adhesives, and develop computational design methods for filament layout and robotic fabrication methods. We also show an open-source prototype development method, necessary for efficient prototyping. Through several fabrication case studies, we demonstrate the capabilities of the production process, and investigate suitable architectural applications. These hollow lightweight components could save large amounts of material in timber construction and serve as a substitute for concrete or steel components in the future. We conclude by discussing possible applications in the construction industry and future research possibilities.
Zitierform
In: Construction Robotics Volume 6 / Issue 1 (2022-03-25) , S. 39-55 ; eissn:2509-8780Förderhinweis
Gefördert im Rahmen des Projekts DEALZitieren
@article{doi:10.17170/kobra-202206016278,
author={Göbert, Andreas and Deetman, Arjen and Rossi, Andrea and Weyhe, Ole and Eversmann, Philipp},
title={3DWoodWind: robotic winding processes for material-efficient lightweight veneer components},
journal={Construction Robotics},
year={2022}
}
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2022-08-16T09:24:52Z 2022-08-16T09:24:52Z 2022-03-25 doi:10.17170/kobra-202206016278 http://hdl.handle.net/123456789/14058 Gefördert im Rahmen des Projekts DEAL eng Namensnennung 4.0 International http://creativecommons.org/licenses/by/4.0/ robotic fabrication digital design timber construction additive manufacturing winding 004 600 3DWoodWind: robotic winding processes for material-efficient lightweight veneer components Aufsatz Winding processes are known from fiber composite technology for highly resistance lightweight components for aviation. These fiber-based processes work predominantly with synthetic composites made of carbon or glass fibers. For the construction industry, these additive processes are very promising and resource-efficient building processes, but they are still hardly used in timber construction despite the very high level of digitalization and technical development. The 3DWoodWind research project uses a continuous strip of thin veneer as a sustainable alternative as its application material. Its natural fibers are intact, continuous, and tensile. In the project, three-dimensional winding processes were developed for material-efficient hollow profile lightweight components made of wood. We describe the material system, composed of suitable combinations of veneers and adhesives, and develop computational design methods for filament layout and robotic fabrication methods. We also show an open-source prototype development method, necessary for efficient prototyping. Through several fabrication case studies, we demonstrate the capabilities of the production process, and investigate suitable architectural applications. These hollow lightweight components could save large amounts of material in timber construction and serve as a substitute for concrete or steel components in the future. We conclude by discussing possible applications in the construction industry and future research possibilities. open access Göbert, Andreas Deetman, Arjen Rossi, Andrea Weyhe, Ole Eversmann, Philipp doi:10.1007/s41693-022-00067-2 Holzindustrie Effizienz Nachhaltigkeit Robotik 3D-Technologie publishedVersion eissn:2509-8780 Issue 1 Construction Robotics 39-55 Volume 6 false
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