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In-Process Reinforcement Method for 3D-Printed Concrete Layers (2026-04)

10.1016/j.autcon.2026.106958

Modi Chaman,  Kumar Manish, Chopperla Krishna
Journal Article - Automation in Construction, Vol. 187, No. 106958

Abstract

State-of-the-art methods for reinforcement of 3D printed concrete layers require manual intervention, cause poor bonding between concrete and reinforcement, or result in a disrupted concrete flow. This paper presents an automated reinforcement method. A printhead bifurcates the incoming concrete flow and merges the two streams near a tapered outlet, while a fiber mesh is fed from an integrated spool and embedded within the printed layer. Mesh reinforced concrete was printed along linear and curved paths. A greater path radius helped reduce out-of-plane distortion in the mesh (and concrete) along curvilinear paths. Compaction due to tapering in the printhead reduced amount of voids near mesh, and increased green strength and mesh pull-out force in the fresh state. Cubes extracted from printed beams exhibited strength comparable to mould-cast specimens. The presence of fiber mesh substantially enhanced the deformability of printed beams.

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0 Citations

BibTeX 
@article{modi_kuma_chop.2026.IPRMf3PCL,
  author            = "Chaman Modi and Manish Kumar and Krishna Siva Teja Chopperla",
  title             = "In-Process Reinforcement Method for 3D-Printed Concrete Layers",
  doi               = "10.1016/j.autcon.2026.106958",
  year              = "2026",
  journal           = "Automation in Construction",
  volume            = "187",
  pages             = "106958",
}
Formatted Citation

C. Modi, M. Kumar and K. S. T. Chopperla, “In-Process Reinforcement Method for 3D-Printed Concrete Layers”, Automation in Construction, vol. 187, p. 106958, 2026, doi: 10.1016/j.autcon.2026.106958.

Modi, Chaman, Manish Kumar, and Krishna Siva Teja Chopperla. “In-Process Reinforcement Method for 3D-Printed Concrete Layers”. Automation in Construction 187 (2026): 106958. https://doi.org/10.1016/j.autcon.2026.106958.