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Print-Path Design for Inclined-Plane Robotic 3D Printing of Unreinforced Concrete (2022-09)

10.1007/978-3-031-13249-0_16

Bhooshan Shajay,  Bhooshan Vishu, Megens Johannes, Casucci Tommaso,  van Mele Tom,  Block Philippe
Contribution - Proceedings of the Design Modelling Symposium, pp. 188-197

Abstract

The paper details the computational toolkit for print-path synthesis and execution that was used in the physical realisation of an arched, bifurcating, unreinforced masonry footbridge spanning 16 m, composed of 53 3D-printed concrete blocks. The printed concrete filaments ofevery block were placed in layers that are orthogonal to the expected, compressive force flow, resulting in the need for nonparallel, inclined print-path planes, thus also resulting in non-uniform print-layer heights. In addition, the bridge’s global structural logic of stereotomic masonry necessitated the precise coordination of the interface planes be- tween blocks. Approximately 58 km of print path, distributed over 7800 inclined layers, were generated and coordinated such that the resulting print paths meet printing-related criteria such as good spatial coherence, minimum and maximum layer thickness, infill patterns etc.We describe a schema based on Function Representation (FRep) for inclined-plane print-path generation, and its full implementation for practical and large-batch production. We also implement specific extensions to generate the infill print paths typically needed in 3D concrete printing.

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8 Citations

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BibTeX 
@inproceedings{bhoo_bhoo_mege_casu.2023.PPDfIPR3PoUC,
  author            = "Shajay Bhooshan and Vishu Bhooshan and Johannes Megens and Tommaso Casucci and Tom van Mele and Philippe Block",
  title             = "Print-Path Design for Inclined-Plane Robotic 3D Printing of Unreinforced Concrete",
  doi               = "10.1007/978-3-031-13249-0_16",
  year              = "2023",
  pages             = "188--197",
  booktitle         = "Proceedings of the Design Modelling Symposium: Towards Radical Regeneration",
  editor            = "Christoph Gengnagel and Olivier Baverel and Giovanni Betti and Mariana Popescu and Mette Ramsgaard Thomsen and Jan Wurm",
}
Formatted Citation

S. Bhooshan, V. Bhooshan, J. Megens, T. Casucci, T. van Mele and P. Block, “Print-Path Design for Inclined-Plane Robotic 3D Printing of Unreinforced Concrete”, in Proceedings of the Design Modelling Symposium: Towards Radical Regeneration, 2023, pp. 188–197. doi: 10.1007/978-3-031-13249-0_16.

Bhooshan, Shajay, Vishu Bhooshan, Johannes Megens, Tommaso Casucci, Tom van Mele, and Philippe Block. “Print-Path Design for Inclined-Plane Robotic 3D Printing of Unreinforced Concrete”. In Proceedings of the Design Modelling Symposium: Towards Radical Regeneration, edited by Christoph Gengnagel, Olivier Baverel, Giovanni Betti, Mariana Popescu, Mette Ramsgaard Thomsen, and Jan Wurm, 188–97, 2023. https://doi.org/10.1007/978-3-031-13249-0_16.