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Slow Penetration for Characterizing Concrete for Digital Fabrication (2022-04)

10.1016/j.cemconres.2022.106802

 Reiter Lex,  Wangler Timothy,  Roussel Nicolas,  Flatt Robert
Journal Article - Cement and Concrete Research, Vol. 157

Abstract

Digital fabrication processes with concrete require a specific yield stress evolution after placing. This paper shows that this goal can be achieved with displacement controlled continuous slow penetration methods, and gives a model understanding and specific suggestions for measurement. It is found that the force recorded in continuous and point-wise penetration tests with a conical tool moving at a slow rate scales linearly and over multiple decades with independent measurements of yield stress carried out using uniaxial compression and vane test. A model adapted from soil-mechanical stability predicts the bearing capacity factor that relates the penetration force to yield stress. The experimental value agrees with the predicted one for an undrained/plastic material. The measurements indicate a yield stress validity range of 1–200 kPa and as low as 0.1 kPa with consideration of depth dependency. This range is the one of greatest interest for structural build-up in digital fabrication during production.

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BibTeX 
@article{reit_wang_rous_flat.2022.SPfCCfDF,
  author            = "Lex Reiter and Timothy Paul Wangler and Nicolas Roussel and Robert Johann Flatt",
  title             = "Slow Penetration for Characterizing Concrete for Digital Fabrication",
  doi               = "10.1016/j.cemconres.2022.106802",
  year              = "2022",
  journal           = "Cement and Concrete Research",
  volume            = "157",
}
Formatted Citation

L. Reiter, T. P. Wangler, N. Roussel and R. J. Flatt, “Slow Penetration for Characterizing Concrete for Digital Fabrication”, Cement and Concrete Research, vol. 157, 2022, doi: 10.1016/j.cemconres.2022.106802.

Reiter, Lex, Timothy Paul Wangler, Nicolas Roussel, and Robert Johann Flatt. “Slow Penetration for Characterizing Concrete for Digital Fabrication”. Cement and Concrete Research 157 (2022). https://doi.org/10.1016/j.cemconres.2022.106802.