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Advancing Construction in Existing Contexts (2024-09)

Prospects and Barriers of 3D Printing with Mobile Robots for Building Maintenance and Repair

10.1016/j.cemconres.2024.107656

 Dörfler Kathrin,  Dielemans Gido,  Leutenegger Stefan,  Jenny Ercan,  Pankert Johannes,  Sustarevas Julius,  Lachmayer Lukas,  Raatz Annika,  Lowke Dirk
Journal Article - Cement and Concrete Research, Vol. 186, No. 107656

Abstract

Mobile robots for 3D printing applications are ready to transition from factory floors to building sites. Their remarkable flexibility and adaptability support a variety of deposition-based 3D printing technologies that utilise materials ranging from concrete and earth for extrusion, spraying, or shotcreting to metals for processes like Wire Arc Additive Manufacturing. Not confined to new constructions alone, their mobility enables utilisation in corrective building maintenance, restoration, revitalisation, and repair. Their ability to cooperate with one another allows for deployment in multi-robot settings, offering scalability in speed by their number. Despite their promising potential, mobile 3D printing robots also encounter numerous technological challenges. These include ensuring the mechanical properties of printed structures meet required building codes, designing robust mechanical systems for large-scale construction projects, and integrating these systems seamlessly with existing architectural planning tools. Moreover, enhancing the precision and robustness of these robots through advanced sensing and control technologies is critical for their effective application in building manufacturing. With this paper, we detail selected current research trajectories and give insights into current challenges, open questions, and key prospects associated with mobile 3D printing robots for on-site construction within existing environments. To enrich the discussion, insights into potential architectural application scenarios for revitalising, repairing, and strengthening building structures are provided. The complex, interdisciplinary nature of these challenges underscores the need for a collaborative approach in advancing the field of mobile 3D printing technology.

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BibTeX 
@article{dorf_diel_leut_jenn.2024.ACiEC,
  author            = "Kathrin Dörfler and Gido Dielemans and Stefan Leutenegger and Ercan Selen Jenny and Johannes Pankert and Julius Sustarevas and Lukas Lachmayer and Annika Raatz and Dirk Lowke",
  title             = "Advancing Construction in Existing Contexts: Prospects and Barriers of 3D Printing with Mobile Robots for Building Maintenance and Repair",
  doi               = "10.1016/j.cemconres.2024.107656",
  year              = "2024",
  journal           = "Cement and Concrete Research",
  volume            = "186",
  pages             = "107656",
}
Formatted Citation

K. Dörfler, “Advancing Construction in Existing Contexts: Prospects and Barriers of 3D Printing with Mobile Robots for Building Maintenance and Repair”, Cement and Concrete Research, vol. 186, p. 107656, 2024, doi: 10.1016/j.cemconres.2024.107656.

Dörfler, Kathrin, Gido Dielemans, Stefan Leutenegger, Ercan Selen Jenny, Johannes Pankert, Julius Sustarevas, Lukas Lachmayer, Annika Raatz, and Dirk Lowke. “Advancing Construction in Existing Contexts: Prospects and Barriers of 3D Printing with Mobile Robots for Building Maintenance and Repair”. Cement and Concrete Research 186 (2024): 107656. https://doi.org/10.1016/j.cemconres.2024.107656.