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2D Stationary Computational Printing of Cement-Based Pastes with Time-Dependent Rheology (2023-04)

10.1016/j.matpr.2023.03.544

Salam Mohammad Abdul,  Biernacki Joseph
Journal Article - Materials Today: Proceedings

Abstract

Additive manufacturing is rapidly emerging as a potentially transformative technology for the construction industry. Many technical hurdles, however, are yet unresolved including the formulation of robust, standardized cement-based printing pastes. To hasten the development of rheologically sound materials for printing, a combined experimental and computational approach has been taken. A new, efficient strategy for computational printing was recently introduced. The new method, 2-D Stationary Computational Printing (2D-SCP), has been shown to map well to experimental print outcomes. Here, the 2D-SCP strategy was extended to include time-dependent rheological effects due to hydration-related structuration. The time-domain rheological properties of cement-based printing pastes were determined from experimentally measured static yield stress values. As a benchmark, a tubular form was used for printed objects. The numerical models were then validated by comparing the polished sections of the printed objects with that produced using the 2D-SCP model. The importance of structural build-up and related rheological changes i.e. static yield stress, on 3D printing of the experimental cement pastes was quantified. The obtained results show high fidelity between 2D-SCP prints and experimental objects. This newly developed computational printing strategy can assist in targeting optimal paste design for 3D printing applications.

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1 Citations

  1. Zat Tuani, Schuster Sílvio, Schmitt Duarte Ester, Freitas Daudt Natália et al. (2025-03)
    Rheological Properties of High-Performance Concrete Reinforced with Microfibers and Their Effects on 3D Printing Process

BibTeX 
@article{sala_bier.2023.2SCPoCBPwTDR,
  author            = "Abdul Salam Mohammad and Joseph J. Biernacki",
  title             = "2D Stationary Computational Printing of Cement-Based Pastes with Time-Dependent Rheology",
  doi               = "10.1016/j.matpr.2023.03.544",
  year              = "2023",
  journal           = "Materials Today: Proceedings",
}
Formatted Citation

A. S. Mohammad and J. J. Biernacki, “2D Stationary Computational Printing of Cement-Based Pastes with Time-Dependent Rheology”, Materials Today: Proceedings, 2023, doi: 10.1016/j.matpr.2023.03.544.

Mohammad, Abdul Salam, and Joseph J. Biernacki. “2D Stationary Computational Printing of Cement-Based Pastes with Time-Dependent Rheology”. Materials Today: Proceedings, 2023. https://doi.org/10.1016/j.matpr.2023.03.544.