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3D Concrete Printing Using Computational Fluid Dynamics (2024-04)

Modeling of Material-Extrusion with Slip-Boundaries

10.1016/j.jmapro.2024.03.042

 el Abbaoui Khalid,  al Korachi Issam,  el Jai Mostapha,  Šeta Berin,  Mollah Md.
Journal Article - Journal of Manufacturing Processes, Vol. 118, pp. 448-459

Abstract

This paper investigates the role of slip boundary conditions in computational fluid dynamics modeling of material extrusion and layer deposition during 3D concrete printing. The mortar flow governed by the Navier-Stokes equations was simulated for two different slip boundary conditions at the extrusion nozzle wall: no-slip and free-slip. The simulations were conducted with two constitutive models: a generalized Newtonian fluid model and an elasto-viscoplastic fluid model. The cross-sectional shapes of up to three printed layers were compared to the experimental results from literature for different geometrical- and speed-ratios. The results reveal that employing free-slip boundary conditions at the extrusion nozzle wall improves layer-mimicking quality for both constitutive models, indicating the presence and importance of a lubricating layer of fine particles at the concrete-solid wall interface. This enhanced performance is primarily due to the observed decrease in extrusion pressure that minimizes layer height- and width-deviations compared to the experimental prints. Furthermore, the free-slip boundary conditions play an important role in predicting the multilayer prints, its deformation and groove shapes.

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BibTeX 
@article{abba_kora_jai_seta.2024.3CPUCFD,
  author            = "Khalid El Abbaoui and Issam Al Korachi and Mostapha El Jai and Berin Šeta and Md. Tusher Mollah",
  title             = "3D Concrete Printing Using Computational Fluid Dynamics: Modeling of Material-Extrusion with Slip-Boundaries",
  doi               = "10.1016/j.jmapro.2024.03.042",
  year              = "2024",
  journal           = "Journal of Manufacturing Processes",
  volume            = "118",
  pages             = "448--459",
}
Formatted Citation

K. E. Abbaoui, I. A. Korachi, M. E. Jai, B. Šeta and M. T. Mollah, “3D Concrete Printing Using Computational Fluid Dynamics: Modeling of Material-Extrusion with Slip-Boundaries”, Journal of Manufacturing Processes, vol. 118, pp. 448–459, 2024, doi: 10.1016/j.jmapro.2024.03.042.

Abbaoui, Khalid El, Issam Al Korachi, Mostapha El Jai, Berin Šeta, and Md. Tusher Mollah. “3D Concrete Printing Using Computational Fluid Dynamics: Modeling of Material-Extrusion with Slip-Boundaries”. Journal of Manufacturing Processes 118 (2024): 448–59. https://doi.org/10.1016/j.jmapro.2024.03.042.