Skip to content

High-Alumina Cementitious Materials for Binder-Jetting 3D Printing (2024-12)

Exploring Suitable Mixing-Ratio and Curing-Solution for Improving Mechanical Properties and Hydration-Reaction

10.1016/j.jobe.2024.111598

 Liu Junxing,  Li Peiqi,  Piao Taiyan, Im Sumin, Bae Sungchul
Journal Article - Journal of Building Engineering, Vol. 99, No. 111598

Abstract

In recent years, binder jetting 3D printing (BJ3DP) technology has attracted growing attention in construction materials. Although ordinary Portland cement (OPC) is one of the most widely used building materials, its slow hydration reaction limits its effectiveness in BJ3DP. In contrast, calcium aluminate cement (CAC) undergoes a rapid hydration reaction, achieving sufficient strength at an early stage, which is advantageous for BJ3DP applications. Nevertheless, there is still limited research on the suitability of cementitious materials for BJ3DP. Therefore, this work aimed to identify the optimal material mixing proportions and suitable post-processing solutions for BJ3DP by comprehensively evaluating the flowability of the dry materials, print bed characteristics, print quality, and mechanical strength of the printed specimens. The results showed that replacing 40 % of ordinary Portland cement with calcium aluminate cement optimized the flowability of the dry mixture, allowing for the production of specimens with favorable print quality. Furthermore, at this optimal ratio, the printed specimen’s compressive strength achieved 12.7 MPa after curing in Na2SiO3 solution for 28 d, representing a 42.6 % increase in compressive strength compared with the specimens cured in water. Simultaneously, the compressive strength of the printed samples increased by 57.7 % compared to our previous results and showed a further 10 % increase under the same curing condition (water curing). Based on these findings, we proposed a novel composition ratio for high-alumina cementitious materials in BJ3DP, consisting of a 60 % OPC and 40 % CAC mix, along with post-treatment of the printed samples using a Na2SiO3 solution. This study broadens the range of cementitious materials suitable for BJ3DP and demonstrates the feasibility of Na2SiO3 as an effective post-treatment solution, providing a theoretical foundation for future research and practical applications of high-alumina cementitious materials.

23 References

  1. Bai Gang, Wang Li, Ma Guowei, Sanjayan Jay et al. (2021-03)
    3D Printing Eco-Friendly Concrete Containing Under-Utilised and Waste Solids as Aggregates
  2. Das Arnesh, Reiter Lex, Mantellato Sara, Flatt Robert (2022-10)
    Early-Age Rheology and Hydration-Control of Ternary Binders for 3D Printing Applications
  3. Hosseini Ehsan, Zakertabrizi Mohammad, Korayem Asghar, Xu Guanzhong (2019-03)
    A Novel Method to Enhance the Inter-Layer Bonding of 3D Printing Concrete:
    An Experimental and Computational Investigation
  4. Ingaglio Joseph, Fox John, Naito Clay, Bocchini Paolo (2019-02)
    Material-Characteristics of Binder-Jet 3D Printed Hydrated CSA Cement with the Addition of Fine Aggregates
  5. Jo Jun, Jo Byung, Cho Woohyun, Kim Jung-Hoon (2020-03)
    Development of a 3D Printer for Concrete Structures:
    Laboratory Testing of Cementitious Materials
  6. Liu Xiongfei, Wang Nan, Zhang Yi, Ma Guowei (2024-02)
    Optimization of Printing Precision and Mechanical Property for Powder-Based 3D Printed Magnesium Phosphate Cement Using Fly-Ash
  7. Lowke Dirk, Dini Enrico, Perrot Arnaud, Weger Daniel et al. (2018-07)
    Particle-Bed 3D Printing in Concrete Construction:
    Possibilities and Challenges
  8. Lowke Dirk, Mai (née Dressler) Inka, Keita Emmanuel, Perrot Arnaud et al. (2022-02)
    Material-Process Interactions in Particle-Bed 3D Printing and the Underlying Physics
  9. Lowke Dirk, Talke Daniel, Mai (née Dressler) Inka, Weger Daniel et al. (2020-05)
    Particle-Bed 3D Printing by Selective Cement-Activation:
    Applications, Material and Process Technology
  10. Ma Guowei, Hu Tingyu, Wang Fang, Liu Xiongfei et al. (2023-02)
    Magnesium Phosphate Cement for Powder-Based 3D Concrete Printing:
    Systematic Evaluation and Optimization of Printability and Printing Quality
  11. Moelich Gerrit, Kruger Jacques, Combrinck Riaan (2021-09)
    Modelling the Inter-Layer Bond Strength of 3D Printed Concrete with Surface Moisture
  12. Na Okpin, Kim Kangmin, Lee Hyunjoo, Lee Hyunseung (2021-05)
    Printability and Setting-Time of CSA Cement with Na2SiO3 and Gypsum for Binder-Jetting 3D Printing
  13. Rehman Asif, Sglavo Vincenzo (2021-08)
    3D Printing of Portland-Cement-Containing Bodies
  14. Shahid Mursaleen, Sglavo Vincenzo (2024-03)
    Binder-Jetting 3D Printing of Binary Cement-Siliceous Sand Mixture
  15. Shakor Pshtiwan, Chu Shaohua, Puzatova (nee Sharanova) Anastasiia, Dini Enrico (2022-01)
    Review of Binder-Jetting 3D Printing in the Construction Industry
  16. Shakor Pshtiwan, Nejadi Shami, Paul Gavin (2019-11)
    Investigation into the Effect of Delays Between Printed Layers on the Mechanical Strength of Inkjet 3DP Mortar
  17. Shakor Pshtiwan, Nejadi Shami, Paul Gavin, Gowripalan Nadarajah (2023-04)
    Effects of Different Orientation-Angle, Size, Surface-Roughness, and Heat-Curing on Mechanical Behavior of 3D Printed Cement-Mortar with and without Glass-Fiber in Powder-Based 3DP
  18. Shakor Pshtiwan, Nejadi Shami, Paul Gavin, Sanjayan Jay (2019-12)
    Dimensional Accuracy, Flowability, Wettability, and Porosity in Inkjet 3DP for Gypsum and Cement Mortar Materials
  19. Shakor Pshtiwan, Sanjayan Jay, Nazari Ali, Nejadi Shami (2017-02)
    Modified 3D Printed Powder to Cement-Based Material and Mechanical Properties of Cement Scaffold Used in 3D Printing
  20. Wang Xingjian, Naito Clay, Fox John, Bocchini Paolo (2024-02)
    Impact of Mix Proportions on Particle-Bed 3D Printed Concrete Properties
  21. Xia Ming, Nematollahi Behzad, Sanjayan Jay (2018-09)
    Compressive Strength and Dimensional Accuracy of Portland Cement Mortar Made Using Powder-Based 3D Printing for Construction Applications
  22. Xia Ming, Nematollahi Behzad, Sanjayan Jay (2019-02)
    Development of Powder-Based 3D Concrete Printing Using Geopolymers
  23. Xia Ming, Nematollahi Behzad, Sanjayan Jay (2019-09)
    Post-Processing Techniques to Enhance Strength of Portland Cement Mortar Digitally Fabricated Using Powder-Based 3D Printing Process

0 Citations

BibTeX 
@article{liu_li_piao_im.2025.HACMfBJ3P,
  author            = "Junxing Liu and Peiqi Li and Taiyan Piao and Sumin Im and Sungchul Bae",
  title             = "High-Alumina Cementitious Materials for Binder-Jetting 3D Printing: Exploring Suitable Mixing-Ratio and Curing-Solution for Improving Mechanical Properties and Hydration-Reaction",
  doi               = "10.1016/j.jobe.2024.111598",
  year              = "2025",
  journal           = "Journal of Building Engineering",
  volume            = "99",
  pages             = "111598",
}
Formatted Citation

J. Liu, P. Li, T. Piao, S. Im and S. Bae, “High-Alumina Cementitious Materials for Binder-Jetting 3D Printing: Exploring Suitable Mixing-Ratio and Curing-Solution for Improving Mechanical Properties and Hydration-Reaction”, Journal of Building Engineering, vol. 99, p. 111598, 2025, doi: 10.1016/j.jobe.2024.111598.

Liu, Junxing, Peiqi Li, Taiyan Piao, Sumin Im, and Sungchul Bae. “High-Alumina Cementitious Materials for Binder-Jetting 3D Printing: Exploring Suitable Mixing-Ratio and Curing-Solution for Improving Mechanical Properties and Hydration-Reaction”. Journal of Building Engineering 99 (2025): 111598. https://doi.org/10.1016/j.jobe.2024.111598.