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Influence of the Amount of Mineral Additive on the Rheological Properties and the Carbon Footprint of 3D-Printed Concrete Mixtures (2026-01)

10.3390/buildings16030490

Kligys Modestas,  Girskas Giedrius, Baltuškiene Daiva
Journal Article - Buildings, Vol. 16, Iss. 3, No. 490

Abstract

Rheology plays an important role in the 3D concrete printing technology, because it directly governs the flowability and shape retention of the material, impacting both the printing process and the final quality of the obtained structure. Local raw materials such as Portland cement, washed sand, and tap water were used for the preparation of 3D-printed concrete mixtures. The solid-state polycarboxylate ether with an anti-foaming agent was used as superplasticizer. The Portland cement was partially replaced (by volume) with a natural zeolite additive in amounts ranging from 0% to 9% in 3D-printed concrete mixtures. A rotational rheometer with coaxial cylinders was used in this research for the determination of rheological characteristics of prepared 3D-printed concrete mixtures. The Herschel–Buckley model was used to approximate experimental flow curves and assess rheological parameters such as yield stress, plastic viscosity, and shear-thinning/thickening index. The additional experiments and calculations, such as water bleeding test and evaluation of the carbon footprint of 3D-printed concrete mixtures, were performed in this work. The replacement of Portland cement with natural zeolite additive positively influenced rheological and stability-related properties of 3D-printed concrete mixtures. Natural zeolite additive consistently reduced water bleeding, enhanced yield stress under increasing shear rates, and lowered plastic viscosity, thereby improving flowability and mixture transportation during the 3D printing process. As the shear-thinning/thickening index remained stable (indicating non-thixotropic behavior in most cases), higher amounts of natural zeolite additive introduced slight thixotropy (especially under decreased shear rates). These changes contributed to better shape retention, layer stability, and the ability to print taller and narrower structures without collapse, making natural zeolite additive suitable for use in the optimized processes of 3D concrete printing. A significant decrease in total carbon footprint (from 3% to 19%) was observed in 3D-printed concrete mixtures with an increase in the mentioned amounts of natural zeolite additive, compared to the mixture without this additive.

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BibTeX 
@article{klig_girs_balt.2026.IotAoMAotRPatCFo3PCM,
  author            = "Modestas Kligys and Giedrius Girskas and Daiva Baltuškiene",
  title             = "Influence of the Amount of Mineral Additive on the Rheological Properties and the Carbon Footprint of 3D-Printed Concrete Mixtures",
  doi               = "10.3390/buildings16030490",
  year              = "2026",
  journal           = "Buildings",
  volume            = "16",
  number            = "3",
  pages             = "490",
}
Formatted Citation

M. Kligys, G. Girskas and D. Baltuškiene, “Influence of the Amount of Mineral Additive on the Rheological Properties and the Carbon Footprint of 3D-Printed Concrete Mixtures”, Buildings, vol. 16, no. 3, p. 490, 2026, doi: 10.3390/buildings16030490.

Kligys, Modestas, Giedrius Girskas, and Daiva Baltuškiene. “Influence of the Amount of Mineral Additive on the Rheological Properties and the Carbon Footprint of 3D-Printed Concrete Mixtures”. Buildings 16, no. 3 (2026): 490. https://doi.org/10.3390/buildings16030490.