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Reinforcement Lattices for 3DCP (2022-07)

A Fabrication Method Based on Ruled Surfaces

10.1201/9781003023555-33

 Anton Ana-Maria,  Reiter Lex,  Skevaki Eleni,  Dillenburger Benjamin
Contribution - Structures and Architecture, pp. 268-276

Abstract

3D Concrete Printing (3DCP) is one of the most used digital fabrication processes with concrete. As a technology, 3DCP promises an economy of resources by creating optimized geometries that require no formwork. But, before material reduction can be achieved, the 3DCP should be comparable in mechanical performance with conventionally reinforced concrete. Existing literature already acknowledges the difficulty of adding reinforcement compatible with 3DCP. Even if several reinforcement strategies for 3DCP are reported, the direct implementation of conventional rebar in 3DCP remains limited. The presented work shows how the geometric freedom for 3DCP enables the efficient placement of continuous and straight rebar in a lattice that activates both loading orientations. The presented prototypes reduce the overall concrete use. The material reduction is achieved by creating a hollow structural element in which the printed concrete acts as formwork for the infill and as a simple guide for reinforcement. This design strategy simultaneously simplifies the assembly of an elaborate reinforcement cage and utilizes linear, readily available, and cheap rebar.

20 References

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7 Citations

  1. Kamhawi Abdallah, Meibodi Mania (2024-09)
    Techniques and Strategies in Extrusion-Based 3D Concrete Printing of Complex Components to Prevent Premature Failure
  2. Jipa Mihail-Andrei, Anton Ana-Maria, Gebhard Lukas, Dillenburger Benjamin (2024-09)
    The Nubian Slab:
    3D Concrete Printed Stay-in-Place Formwork for Vaulted Slabs
  3. Soto Alejandro, Gebhard Lukas, Anton Ana-Maria, Dillenburger Benjamin et al. (2024-09)
    Structural Testing Campaign for a 30 m Tall 3D Printed Concrete Tower
  4. Zimmermann Stefan, Griego Danielle, Flatt Robert (2024-09)
    Visualizing Defects of Concrete 3D Printed Structures with Augmented Reality Based on Machine Learning-Driven Image-Analysis
  5. Anton Ana-Maria, Lin Che, Skevaki Eleni, Wang Mingyang et al. (2024-04)
    Tor Alva:
    A 3D Concrete Printed Tower
  6. Raza Saim, Triantafyllidis Zafiris, Anton Ana-Maria, Dillenburger Benjamin et al. (2024-01)
    Seismic Performance of Fe-SMA Pre-Stressed Segmental Bridge Columns with 3D Printed Permanent Concrete Formwork
  7. Mata-Falcón Jaime, Gebhard Lukas, Lee Minu, Bischof Patrick (2023-10)
    Advances in Structural Applications of Digital Fabrication With Concrete

BibTeX 
@inproceedings{anto_reit_skev_dill.2022.RLf3,
  author            = "Ana-Maria Anton and Lex Reiter and Eleni Skevaki and Benjamin Dillenburger",
  title             = "Reinforcement Lattices for 3DCP: A Fabrication Method Based on Ruled Surfaces",
  doi               = "10.1201/9781003023555-33",
  year              = "2022",
  pages             = "268--276",
  booktitle         = "Structures and Architecture: A Viable Urban Perspective?",
  editor            = "Paulo Jorge Sousa Cruz and Marie Frier Hvejsel",
}
Formatted Citation

A.-M. Anton, L. Reiter, E. Skevaki and B. Dillenburger, “Reinforcement Lattices for 3DCP: A Fabrication Method Based on Ruled Surfaces”, in Structures and Architecture: A Viable Urban Perspective?, 2022, pp. 268–276. doi: 10.1201/9781003023555-33.

Anton, Ana-Maria, Lex Reiter, Eleni Skevaki, and Benjamin Dillenburger. “Reinforcement Lattices for 3DCP: A Fabrication Method Based on Ruled Surfaces”. In Structures and Architecture: A Viable Urban Perspective?, edited by Paulo Jorge Sousa Cruz and Marie Frier Hvejsel, 268–76, 2022. https://doi.org/10.1201/9781003023555-33.