Skip to content

Early-Age Rheology and Hydration-Control of Ternary Binders for 3D Printing Applications (2022-10)

10.1016/j.cemconres.2022.107004

Das Arnesh,  Reiter Lex,  Mantellato Sara,  Flatt Robert
Journal Article - Cement and Concrete Research, Vol. 162

Abstract

Achieving and controlling the desired strength build-up is important for 3D concrete printing. In this paper, we investigate the possibility of using calcium aluminate cement (CAC) as an accelerator for Ordinary Portland Cement (OPC) for 3D extrusion printing. Both ternary and binary cement systems were studied whereby for the former, the third component was a calcium sulfate source (C\(). Experiments are conducted on mixes both in presence and absence of retarders. They focus on hydration progress, evolution of rheological properties and microstructural development. It is concluded that CAC-C\) can be effectively used as an accelerator to achieve the desired rates of strength build-up. Additionally, it is shown that strength build-up has is directly related to CAC dosage, irrespective of the presence of retarders. Based on microstructure characterization results, AFt and AH3 are found to be formed in the first hour after acceleration and responsible for the observed strength build-up.

14 References

  1. Buswell Richard, Silva Wilson, Bos Freek, Schipper Roel et al. (2020-05)
    A Process Classification Framework for Defining and Describing Digital Fabrication with Concrete
  2. Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
    3D Printing Using Concrete-Extrusion:
    A Roadmap for Research
  3. Khalil Noura, Aouad Georges, Cheikh Khadija, Rémond Sébastien (2017-09)
    Use of Calcium-Sulfoaluminate-Cements for Setting-Control of 3D Printing Mortars
  4. Khan Mohammad, Sanchez Florence, Zhou Hongyu (2020-04)
    3D Printing of Concrete:
    Beyond Horizons
  5. Khoshnevis Behrokh (2003-11)
    Automated Construction by Contour Crafting:
    Related Robotics and Information Technologies
  6. Lloret-Fritschi Ena, Shahab Amir, Linus Mettler, Flatt Robert et al. (2014-03)
    Complex Concrete Structures:
    Merging Existing Casting Techniques with Digital Fabrication
  7. Marchon Delphine, Kawashima Shiho, Bessaies-Bey Hela, Mantellato Sara et al. (2018-05)
    Hydration- and Rheology-Control of Concrete for Digital Fabrication:
    Potential Admixtures and Cement-Chemistry
  8. Mechtcherine Viktor, Bos Freek, Perrot Arnaud, Silva Wilson et al. (2020-03)
    Extrusion-Based Additive Manufacturing with Cement-Based Materials:
    Production Steps, Processes, and Their Underlying Physics
  9. Reiter Lex, Wangler Timothy, Anton Ana-Maria, Flatt Robert (2020-05)
    Setting-on-Demand for Digital Concrete:
    Principles, Measurements, Chemistry, Validation
  10. Reiter Lex, Wangler Timothy, Roussel Nicolas, Flatt Robert (2018-06)
    The Role of Early-Age Structural Build-Up in Digital Fabrication with Concrete
  11. Reiter Lex, Wangler Timothy, Roussel Nicolas, Flatt Robert (2022-04)
    Slow Penetration for Characterizing Concrete for Digital Fabrication
  12. Roussel Nicolas (2018-05)
    Rheological Requirements for Printable Concretes
  13. Schutter Geert, Lesage Karel, Mechtcherine Viktor, Nerella Venkatesh et al. (2018-08)
    Vision of 3D Printing with Concrete:
    Technical, Economic and Environmental Potentials
  14. Wangler Timothy, Lloret-Fritschi Ena, Reiter Lex, Hack Norman et al. (2016-10)
    Digital Concrete:
    Opportunities and Challenges

24 Citations

  1. Zhang Xin, Xu Xinglong, Liu Xianda, Sun Junbo et al. (2026-01)
    Enhancing Electromagnetic Wave Absorption in 3D-Printed Concrete with Superabsorbent Polymers for High Performance
  2. Xu Bin, Sun Zhaoyang, Sun Ming, Chen Binmeng (2025-09)
    Realizing Rheological Manipulation by Adjusting Initiator Concentrations for In-Situ Polymerization:
    Towards 3D Concrete Printing Applications
  3. Li Qiyan, Su Anshuang, Gao Xiaojian (2025-06)
    Improvement of Interlayer Performance of 3D Printable Magnesium Oxysulfate Cement-Based Materials by Carbonation Curing
  4. Tao Yaxin, Zhang Yi, Mohan Manu, Dai Xiaodi et al. (2025-05)
    Waste-Derived Aggregates in 3D Printable Concrete:
    Current Insights and Future Perspectives
  5. Silveira Júnior Jairon, Sakata Rafael, Onghero Lucas, Matos Paulo et al. (2025-03)
    Al-Anodizing Waste as a Supplementary Cementitious Material for 3D-Printed Portland Cement
  6. Das Arnesh, Wenger Cedric, Walpen Lukas, Flatt Robert (2025-02)
    Early-Age Hydration of Accelerated Low-Carbon Cements for Digital Fabrication
  7. Liu Junxing, Li Peiqi, Piao Taiyan, Im Sumin et al. (2024-12)
    High-Alumina Cementitious Materials for Binder-Jetting 3D Printing:
    Exploring Suitable Mixing-Ratio and Curing-Solution for Improving Mechanical Properties and Hydration-Reaction
  8. Wang Qingwei, Han Song, Liu Qi, Yang Junhao et al. (2024-12)
    Research on the 3D Printing Process and Filament Shape of Cementitious Materials in Low Gravity
  9. Márquez Álvaro, Varela Hugo, Barluenga Gonzalo (2024-12)
    Rheology and Early-Age Evaluation of 3D Printable Cement-Limestone-Filler-Pastes with Nano-Clays and Methylcellulose
  10. Wang Qingwei, Han Song, Yang Junhao, Li Ziang et al. (2024-11)
    Optimizing Printing and Rheological Parameters for 3D Printing with Cementitious Materials
  11. Sun Zhaoyang, Zhao Yuyang, Hou Dongshuai, Li Zongjin et al. (2024-11)
    Rheology-Control of Cement-Paste by In-Situ Polymerization for 3D Printing Applications
  12. Mahmoudi Matineh, Wangler Timothy, Flatt Robert (2024-09)
    Robustness of Digital Concrete:
    Effects of Temperature, Accelerator Type and Dosage
  13. Prihar Arjun, Gupta Shashank, Esmaeeli Hadi, Moini Mohamadreza (2024-08)
    Tough Double-Bouligand Architected Concrete Enabled by Robotic Additive Manufacturing
  14. Perrot Arnaud, Jacquet Yohan, Caron Jean-François, Mesnil Romain et al. (2024-08)
    Snapshot on 3D Printing with Alternative Binders and Materials:
    Earth, Geopolymers, Gypsum and Low-Carbon Concrete
  15. Wangler Timothy, Tao Yaxin, Das Arnesh, Mahmoudi Matineh et al. (2024-08)
    Aluminate 2K Systems in Digital Concrete:
    Process, Design, Chemistry, and Outlook
  16. Jakob Cordula, Rudolph Jennifer, Wolf Julian, Neubauer Jürgen (2024-06)
    Hydration of a Two-Component CSA-OPC-Mix-Timing of Component Blending & Setting-on-Demand
  17. Birru Bizu, Rehman Atta, Kim Jung-Hoon (2024-06)
    Comparative Analysis of Structural Build-Up in One-Component Stiff and Two-Component Shotcrete-Accelerated Set-on-Demand Mixtures for 3D Concrete Printing
  18. Wangler Timothy, Vangen Kathrina, Burger Joris, Flatt Robert (2024-05)
    Digital Fabrication Material-Processing-Strategy for Bespoke Low-Clinker Mass-Concrete Components
  19. Tao Yaxin, Mohan Manu, Rahul Attupurathu, Schutter Geert et al. (2024-02)
    Hydration and Microstructure of Calcium-Sulfoaluminate-Portland-Cement Binder Systems for Set-on-Demand Applications
  20. Ambily Parukutty, Kaliyavaradhan Senthil, Sebastian Shilpa, Shekar Deepadharshan (2023-12)
    Mixing Approach for 3D Printable Concrete:
    Method of Addition and Optimization of Superplasticizer Dosage
  21. Chen Yu, Rahmani Hossein, Schlangen Erik, Çopuroğlu Oğuzhan (2023-11)
    An Approach to Develop Set-on-Demand 3D Printable Limestone-Calcined-Clay-Based Cementitious Materials Using Calcium-Nitrate
  22. Zhu Binrong, Wang Yufei, Sun Junbo, Wei Yang et al. (2023-10)
    An Experimental Study on the Influence of Waste-Rubber-Particles on the Compressive, Flexural and Impact Properties of 3D Printable Sustainable Cementitious Composites
  23. Olczyk Norbert, Skibicki Szymon, Gierszewska Natalia (2023-08)
    3D Printed Mortar with High Alumina-Cement as Alternative Solution for Standard Materials Used for 3D Printing
  24. Rehman Atta, Melesse Birru, Kim Jung-Hoon (2023-02)
    Set-on-Demand 3D Concrete Printing Construction and Potential Outcome of Shotcrete-Accelerators on Its Hardened Properties

BibTeX 
@article{das_reit_mant_flat.2022.EARaHCoTBf3PA,
  author            = "Arnesh Das and Lex Reiter and Sara Mantellato and Robert Johann Flatt",
  title             = "Early-Age Rheology and Hydration-Control of Ternary Binders for 3D Printing Applications",
  doi               = "10.1016/j.cemconres.2022.107004",
  year              = "2022",
  journal           = "Cement and Concrete Research",
  volume            = "162",
}
Formatted Citation

A. Das, L. Reiter, S. Mantellato and R. J. Flatt, “Early-Age Rheology and Hydration-Control of Ternary Binders for 3D Printing Applications”, Cement and Concrete Research, vol. 162, 2022, doi: 10.1016/j.cemconres.2022.107004.

Das, Arnesh, Lex Reiter, Sara Mantellato, and Robert Johann Flatt. “Early-Age Rheology and Hydration-Control of Ternary Binders for 3D Printing Applications”. Cement and Concrete Research 162 (2022). https://doi.org/10.1016/j.cemconres.2022.107004.