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Hydration Re-Initiation of Borated CSA Systems with a Two-Stage Mixing Process (2022-06)

An Application in Extrusion-Based Concrete 3D Printing

10.1016/j.cemconres.2022.106870

 Mohan Manu,  Rahul Attupurathu,  Tao Yaxin,  de Schutter Geert,  van Tittelboom Kim
Journal Article - Cement and Concrete Research, Vol. 159

Abstract

Enhanced structural build-up and strength development are crucial for various construction processes, especially in extrusion-based concrete 3D printing. However, controlling the stiffening process could be quite challenging as there are conflicting requirements during the pumping and deposition phase. We present a study to enhance the structural build-up of a calcium sulfoaluminate (CSA) cement-based system using a two-stage mixing method. A borated CSA cement mixture having a long open time (> two hours) was intermixed near the nozzle/print head of the 3D printer with a mixture of limestone and calcium hydroxide having an indefinite open time. The hydration and the early-age mechanical behaviour of the different combinations of these two mixtures were investigated by isothermal calorimetry, XRD analysis, unconfined compression tests, and ultrasonic pulse wave velocity tests. The results indicate that in the presence of calcium hydroxide, the borated phase (ulexite) covering the ye'elimite and being responsible for the long open time, rapidly destabilizes and the hydration reaction reinitiates. The hydration progresses rapidly, resulting in enhanced pore segmentation and a rapid increase in mechanical properties (compressive strength and elastic modulus), significantly faster than what is reported for conventional 3D printable concrete. Finally, a 1.5 m tall column was printed with this two-stage mixing method in a time period of <10 min – demonstrating the feasibility of the developed mixture for 3D printing applications.

23 References

  1. Chen Mingxu, Yang Lei, Zheng Yan, Huang Yongbo et al. (2020-04)
    Yield-Stress and Thixotropy-Control of 3D Printed Calcium-Sulfoaluminate Cement Composites with Metakaolin Related to Structural Build-Up
  2. Gosselin Clément, Duballet Romain, Roux Philippe, Gaudillière-Jami Nadja et al. (2016-03)
    Large-Scale 3D Printing of Ultra-High-Performance Concrete:
    A New Processing Route for Architects and Builders
  3. Khalil Noura, Aouad Georges, Cheikh Khadija, Rémond Sébastien (2017-09)
    Use of Calcium-Sulfoaluminate-Cements for Setting-Control of 3D Printing Mortars
  4. Mai (née Dressler) Inka, Freund Niklas, Lowke Dirk (2020-01)
    The Effect of Accelerator Dosage on Fresh Concrete Properties and on Inter-Layer Strength in Shotcrete 3D Printing
  5. 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
  6. Mohan Manu, Rahul Attupurathu, Dam Benjamin, Zeidan Talina et al. (2022-02)
    Performance Criteria, Environmental Impact and Cost-Assessment for 3D Printable Concrete Mixtures
  7. Mohan Manu, Rahul Attupurathu, Schutter Geert, Tittelboom Kim (2021-01)
    Early-Age Hydration, Rheology and Pumping Characteristics of CSA Cement-Based 3D Printable Concrete
  8. Mohan Manu, Rahul Attupurathu, Schutter Geert, Tittelboom Kim (2020-10)
    Extrusion-Based Concrete 3D Printing from a Material Perspective:
    A State of the Art Review
  9. Mohan Manu, Rahul Attupurathu, Tittelboom Kim, Schutter Geert (2020-10)
    Rheological and Pumping Behavior of 3D Printable Cementitious Materials with Varying Aggregate Content
  10. Panda Biranchi, Lim Jian, Tan Ming (2019-02)
    Mechanical Properties and Deformation Behavior of Early-Age Concrete in the Context of Digital Construction
  11. Perrot Arnaud, Rangeard Damien, Pierre Alexandre (2015-02)
    Structural Build-Up of Cement-Based Materials Used for 3D Printing-Extrusion-Techniques
  12. Qian Ye, Schutter Geert (2018-06)
    Enhancing Thixotropy of Fresh Cement-Pastes with Nano-Clay in Presence of Polycarboxylate-Ether Superplasticizer (PCE)
  13. Rahul Attupurathu, Mohan Manu, Schutter Geert, Tittelboom Kim (2021-10)
    3D Printable Concrete with Natural and Recycled Coarse Aggregates:
    Rheological, Mechanical and Shrinkage Behavior
  14. Rahul Attupurathu, Santhanam Manu (2020-02)
    Evaluating the Printability of Concretes Containing Lightweight Coarse Aggregates
  15. Rahul Attupurathu, Santhanam Manu, Meena Hitesh, Ghani Zimam (2018-12)
    3D Printable Concrete:
    Mixture-Design and Test-Methods
  16. Reiter Lex, Wangler Timothy, Anton Ana-Maria, Flatt Robert (2020-05)
    Setting-on-Demand for Digital Concrete:
    Principles, Measurements, Chemistry, Validation
  17. Roussel Nicolas (2018-05)
    Rheological Requirements for Printable Concretes
  18. Schutter Geert, Lesage Karel, Mechtcherine Viktor, Nerella Venkatesh et al. (2018-08)
    Vision of 3D Printing with Concrete:
    Technical, Economic and Environmental Potentials
  19. Tao Yaxin, Rahul Attupurathu, Lesage Karel, Yuan Yong et al. (2021-02)
    Stiffening Control of Cement-Based Materials Using Accelerators in In-Line Mixing Processes:
    Possibilities and Challenges
  20. Vantyghem Gieljan, Corte Wouter, Steeman Marijke, Boel Veerle (2019-07)
    Density-Based Topology-Optimization for 3D Printable Building Structures
  21. Wolfs Robert, Bos Freek, Salet Theo (2018-06)
    Correlation Between Destructive Compression Tests and Non-Destructive Ultrasonic Measurements on Early-Age 3D Printed Concrete
  22. Wolfs Robert, Bos Freek, Salet Theo (2018-02)
    Early-Age Mechanical Behaviour of 3D Printed Concrete:
    Numerical Modelling and Experimental Testing
  23. Yuan Qiang, Zhou Dajun, Huang Hai, Peng Jianwei et al. (2020-06)
    Structural Build-Up, Hydration and Strength Development of Cement-Based Materials with Accelerators

28 Citations

  1. Zhang Jiao-Long, Yuan Yong, Fatoyinbo Imoleayo, Zhou Lujie et al. (2025-11)
    3D-Printable Mortars Incorporating Municipal Solid Waste Incineration Bottom Ash:
    Linking Hydration to Extrudability and Mechanical Performance
  2. Lin Xing-Tao, Xu Shuhao, Chen Xiangsheng (2025-08)
    Optimization of Building Structures Based on Additive Manufacturing:
    A Review
  3. Tao Yaxin, Wang Li, Wangler Timothy, Lesage Karel et al. (2025-05)
    A (P)Review:
    Adhesion of Printcrete for Tunnel Structures
  4. Ali Shah Syed, Zhang Shipeng, Xuan Dongxing, Poon Chi (2025-04)
    Development of a Novel Mixing Strategy for Set-on-Demand Printing of One-Part Geopolymer Using Municipal Solid Waste Incineration Bottom Ash and Blast Furnace Slag
  5. Kaszyńska Maria, Skibicki Szymon (2024-11)
    Sustainable Development Approach for 3D Concrete Printing
  6. Sheng Zhaoliang, Zhu Binrong, Cai Jingming, Han Jinsheng et al. (2024-09)
    Influence of Waste-Glass-Powder on Printability and Mechanical Properties of 3D Printing Geopolymer Concrete
  7. Mohan Manu, Tao Yaxin, Schutter Geert, Tittelboom Kim (2024-09)
    Influence of Temperature Variations on the Performance of Two-Component 3D Printable Mixtures
  8. Tao Yaxin, Tittelboom Kim, Rahul Attupurathu, Wangler Timothy et al. (2024-09)
    Static Mixing for Set-on-Demand of Digital Concrete
  9. Huseien Ghasan, Tan Shea, Saleh Ali, Lim Nor et al. (2024-08)
    Test-Procedures and Mechanical Properties of Three-Dimensional Printable Concrete Enclosing Different Mix-Proportions:
    A Review and Bibliometric Analysis
  10. Tao Yaxin, Schutter Geert, Tittelboom Kim (2024-07)
    CFD Simulation of Twin-Pipe Pumping Process for 3D Concrete Printing
  11. Lyu Qifeng, Wang Yalun, Dai Pengfei (2024-05)
    Multilayered Plant-Growing Concrete Manufactured by Aggregate-Bed 3D Concrete Printing
  12. Zaid Osama, Ouni Mohamed (2024-04)
    Advancements in 3D Printing of Cementitious Materials:
    A Review of Mineral Additives, Properties, and Systematic Developments
  13. Zhang Yi, Ren Qiang, Dai Xiaodi, Tao Yaxin et al. (2024-03)
    A Potential Active Rheology-Control Approach for 3D Printable Cement-Based Materials:
    Coupling of Temperature and Viscosity-Modifiers
  14. Sun Yubo, Mohan Manu, Tao Yaxin, Zhang Yi et al. (2024-02)
    A Conceptual Design of Two-Stream Alkali-Activated Materials
  15. 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
  16. Zhou Wen, Zhu He, Hu Wei-Hsiu, Wollaston Ryan et al. (2024-02)
    Low-Carbon, Expansive Engineered Cementitious Composites (ECC) In the Context of 3D Printing
  17. Tao Yaxin, Zhang Yi, Schutter Geert, Tittelboom Kim (2024-01)
    Interfacial Bonding of 3D Printable Concrete with Chemically Reactive Coating for Automatic Repair
  18. 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
  19. Gao Huaxing, Chen Yuxuan, Chen Qian, Yu Qingliang (2023-11)
    Thermal and Mechanical Performance of 3D Printing Functionally Graded Concrete:
    The Role of SAC on the Rheology and Phase Evolution of 3DPC
  20. Miranda Luiza, Jovanović Balša, Lesage Karel, Schutter Geert (2023-10)
    Geometric Conformability of 3D Concrete Printing Mixtures from a Rheological Perspective
  21. Tao Yaxin, Mohan Manu, Rahul Attupurathu, Schutter Geert et al. (2023-10)
    Influence of Rheology on Mixing Homogeneity and Mechanical Behavior of Twin-Pipe 3D Printable Concrete
  22. Wang Chaofan, Chen Bing, Vo Thanh, Rezania Mohammad (2023-07)
    Mechanical Anisotropy, Rheology and Carbon Footprint of 3D Printable Concrete:
    A Review
  23. Tu Haidong, Wei Zhenyun, Bahrami Alireza, Kahla Nabil et al. (2023-06)
    Recent Advancements and Future Trends in 3D Printing Concrete Using Waste-Materials
  24. Tao Yaxin, Dai Xiaodi, Schutter Geert, Tittelboom Kim (2023-06)
    Set-on-Demand of Alkali-Activated Slag Mixture Using Twin-Pipe Pumping
  25. Tao Yaxin, Rahul Attupurathu, Mohan Manu, Schutter Geert et al. (2023-05)
    Enhancing Mechanical Performance of Twin-Pipe Printable Concrete Using a Binary Binder System
  26. Mohan Manu, Rahul Attupurathu, Stappen Jeroen, Cnudde Veerle et al. (2023-05)
    Assessment of Pore-Structure Characteristics and Tortuosity of 3D Printed Concrete Using Mercury-Intrusion-Porosimetry and X-Ray Tomography
  27. Tao Yaxin, Mohan Manu, Rahul Attupurathu, Schutter Geert et al. (2023-02)
    Development of a Calcium Sulfoaluminate-Portland Cement Binary System for Twin-Pipe 3D Concrete Printing
  28. Tao Yaxin, Mohan Manu, Rahul Attupurathu, Yuan Yong et al. (2022-08)
    Stiffening Controllable Concrete Modified with Redispersible Polymer Powder for Twin-Pipe Printing

BibTeX 
@article{moha_rahu_tao_schu.2022.HRIoBCSwaTSMP,
  author            = "Manu K. Mohan and Attupurathu Vijayan Rahul and Yaxin Tao and Geert de Schutter and Kim van Tittelboom",
  title             = "Hydration Re-Initiation of Borated CSA Systems with a Two-Stage Mixing Process: An Application in Extrusion-Based Concrete 3D Printing",
  doi               = "10.1016/j.cemconres.2022.106870",
  year              = "2022",
  journal           = "Cement and Concrete Research",
  volume            = "159",
}
Formatted Citation

M. K. Mohan, A. V. Rahul, Y. Tao, G. de Schutter and K. van Tittelboom, “Hydration Re-Initiation of Borated CSA Systems with a Two-Stage Mixing Process: An Application in Extrusion-Based Concrete 3D Printing”, Cement and Concrete Research, vol. 159, 2022, doi: 10.1016/j.cemconres.2022.106870.

Mohan, Manu K., Attupurathu Vijayan Rahul, Yaxin Tao, Geert de Schutter, and Kim van Tittelboom. “Hydration Re-Initiation of Borated CSA Systems with a Two-Stage Mixing Process: An Application in Extrusion-Based Concrete 3D Printing”. Cement and Concrete Research 159 (2022). https://doi.org/10.1016/j.cemconres.2022.106870.