Skip to content

Rheological and Mechanical Properties of 3D Printable Alkali-Activated Slag Mixtures with Addition of Nano Clay (2023-02)

10.1016/j.cemconcomp.2023.104995

 Dai Xiaodi,  Tao Yaxin,  van Tittelboom Kim,  de Schutter Geert
Journal Article - Cement and Concrete Composites, Vol. 139

Abstract

Alkali-activated slag mixture (AAS) is seen as a prospective option to replace Portland cement for threedimensional (3D) printing to reduce carbon emission. This paper investigates the use of nano clay and adjusting SiO2/Na2O (Ms value) of an alkaline solution to meet the demands for the additive manufacturing process, such as pumpability and buildability. Results showed that the use of nano clay can considerably improve the structural build-up of AAS mixtures. The dynamic and static yield stress of AAS mixtures declined as Ms value of the activator increased. In terms of mechanical properties, the compressive strength increased with an increase of Ms value, while the flexural strength decreased slightly as Ms value increased. A higher Ms value can result in a lower porosity, but more micro-cracks. The mixture with Ms value of 0.8 and 1% nano clay addition was found to be the most suitable for 3D printing as it had greater buildability during printing with less bottom deformation, and had higher strength and lower porosity in the later stages. The main reaction product for the AAS mixture is found to be the C-A-S-H gel with a chain-like structure.

21 References

  1. Chen Yuning, Liu Chao, Cao Ruilin, Chen Chun et al. (2022-02)
    Systematical Investigation of Rheological Performance Regarding 3D Printing Process for Alkali-Activated Materials:
    Effect of Precursor Nature
  2. Le Thanh, Austin Simon, Lim Sungwoo, Buswell Richard et al. (2012-01)
    Hardened Properties of High-Performance Printing Concrete
  3. Ma Guowei, Li Zhijian, Wang Li, Wang Fang et al. (2019-01)
    Mechanical Anisotropy of Aligned Fiber-Reinforced Composite for Extrusion-Based 3D Printing
  4. 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
  5. Mohan Manu, Rahul Attupurathu, Tittelboom Kim, Schutter Geert (2020-10)
    Rheological and Pumping Behavior of 3D Printable Cementitious Materials with Varying Aggregate Content
  6. Panda Biranchi, Paul Suvash, Lim Jian, Tay Yi et al. (2017-08)
    Additive Manufacturing of Geopolymer for Sustainable Built Environment
  7. Panda Biranchi, Paul Suvash, Tan Ming (2017-07)
    Anisotropic Mechanical Performance of 3D Printed Fiber-Reinforced Sustainable Construction-Material
  8. Panda Biranchi, Ruan Shaoqin, Unluer Cise, Tan Ming (2018-11)
    Improving the 3D Printability of High-Volume Fly-Ash Mixtures via the Use of Nano-Attapulgite-Clay
  9. Panda Biranchi, Ruan Shaoqin, Unluer Cise, Tan Ming (2020-01)
    Investigation of the Properties of Alkali-Activated Slag Mixes Involving the Use of Nano-Clay and Nucleation-Seeds for 3D Printing
  10. Panda Biranchi, Tan Ming (2018-11)
    Rheological Behavior of High-Volume Fly-Ash Mixtures Containing Micro-Silica for Digital Construction Application
  11. Panda Biranchi, Unluer Cise, Tan Ming (2018-10)
    Investigation of the Rheology and Strength of Geopolymer Mixtures for Extrusion-Based 3D Printing
  12. Panda Biranchi, Unluer Cise, Tan Ming (2019-08)
    Extrusion and Rheology Characterization of Geopolymer Nanocomposites Used in 3D Printing
  13. Qian Ye, Schutter Geert (2018-06)
    Enhancing Thixotropy of Fresh Cement-Pastes with Nano-Clay in Presence of Polycarboxylate-Ether Superplasticizer (PCE)
  14. Rahul Attupurathu, Santhanam Manu, Meena Hitesh, Ghani Zimam (2018-12)
    3D Printable Concrete:
    Mixture-Design and Test-Methods
  15. Rahul Attupurathu, Santhanam Manu, Meena Hitesh, Ghani Zimam (2019-08)
    Mechanical Characterization of 3D Printable Concrete
  16. Roussel Nicolas (2018-05)
    Rheological Requirements for Printable Concretes
  17. Roussel Nicolas, Bessaies-Bey Hela, Kawashima Shiho, Marchon Delphine et al. (2019-08)
    Recent Advances on Yield-Stress and Elasticity of Fresh Cement-Based Materials
  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, Tittelboom Kim et al. (2021-11)
    Mechanical and Microstructural Properties of 3D Printable Concrete in the Context of the Twin-Pipe Pumping-Strategy
  20. Weng Yiwei, Li Mingyang, Zhang Dong, Tan Ming et al. (2021-02)
    Investigation of Inter-Layer Adhesion of 3D Printable Cementitious Material from the Aspect of Printing-Process
  21. Wolfs Robert, Bos Freek, Salet Theo (2019-03)
    Hardened Properties of 3D Printed Concrete:
    The Influence of Process Parameters on Inter-Layer Adhesion

22 Citations

  1. Liu Ruiying, Xiong Zhongming, Chen Xuan, Jia Qiong et al. (2025-09)
    Industrial Waste in 3D Printed Concrete:
    A Mechanistic Review on Rheological Control and Printability
  2. Si Wen, Carr Liam, Zia Asad, Khan Mehran et al. (2025-08)
    Advancing 3D Printable Concrete with Nanoclays:
    Rheological and Mechanical Insights for Construction Applications
  3. Si Wen, Khan Mehran, McNally Ciaran (2025-08)
    Effect of Nano Silica with High Replacement of GGBS on Enhancing Mechanical Properties and Rheology of 3D Printed Concrete
  4. Chen Yanjuan, Cheikh Khadija, Rahier Hubert (2025-07)
    Methodology for the Design and Optimization of Potassium Silicate-Activated Slag Used as the Binder of 3D Printable Materials
  5. Li Qiyan, Su Anshuang, Gao Xiaojian (2025-06)
    Improvement of Interlayer Performance of 3D Printable Magnesium Oxysulfate Cement-Based Materials by Carbonation Curing
  6. Kumar Sandeep, Kumar Abhishek, Pundir Aakanksha, Dwivedi Ashutosh et al. (2025-06)
    Low-Clay Soil as Fine Aggregate in 3D Printed Concrete:
    Insights into Fresh and Hardened Properties
  7. Tao Yaxin, Wang Li, Wangler Timothy, Lesage Karel et al. (2025-05)
    A (P)Review:
    Adhesion of Printcrete for Tunnel Structures
  8. Tao Yaxin, Zhang Yi, Mohan Manu, Dai Xiaodi et al. (2025-05)
    Waste-Derived Aggregates in 3D Printable Concrete:
    Current Insights and Future Perspectives
  9. Kandy Sharu, Remke Sebastian, Ranganathan Thiyagarajan, Wani Shubham et al. (2025-01)
    Design and Function of Thermoresponsive-Ultrafast Stiffening Suspension Formulations for 3D Printing
  10. Abedi Mohammadmadhi, Waris Muhammad, Alawi Mubarak, Jabri Khalifa et al. (2024-12)
    From Local Earth to Modern Structures:
    A Critical Review of 3D Printed Cement Composites for Sustainable and Efficient Construction
  11. Sakhare Vishakha, Najar Mohamed, Deshpande Sachin (2024-12)
    Printing Performance of 3D Printed Geopolymer Through Pumpability, Extrudability, Buildability Properties:
    A Review
  12. Dai Xiaodi, Kandy Sharu, Neithalath Narayanan, Kumar Aditya et al. (2024-11)
    Thermally Stimulated Stiffening and Fly-Ash’s Alkaline-Activation by Ca(OH)2 Addition Facilitates 3D Printing
  13. Habibi Alireza, Buswell Richard, Osmani Mohamed, Aziminezhad Mohamadmahdi (2024-11)
    Sustainability Principles in 3D Concrete Printing:
    Analysing Trends, Classifying Strategies, and Future Directions
  14. Jin Peng, Hasany Masoud, Kohestanian Mohammad, Mehrali Mehdi (2024-10)
    Micro/Nano Additives in 3D Printing Concrete:
    Opportunities, Challenges, and Potential Outlook in Construction Applications
  15. Dai Xiaodi, Tao Yaxin, Zhang Yi, Ding Luchuan et al. (2024-08)
    Development of 3D Printable Alkali-Activated Slag-Metakaolin Concrete
  16. Zhou Zhijie, Geng Jian, Jin Chen, Liu Genjin et al. (2024-06)
    Influence of Residue Soil on the Properties of Fly-Ash-Slag-Based Geopolymer Materials for 3D Printing
  17. Tao Yaxin, Dai Xiaodi, Schutter Geert, Tittelboom Kim (2024-05)
    Adhesion Performance of Alkali-Activated Material for 3D Printing of Tunnel Linings at Different Temperatures
  18. Soda Prabhath, Dwivedi Ashutosh, Sahana C., Gupta Souradeep (2024-03)
    Development of 3D Printable Stabilized Earth-Based Construction Materials Using Excavated Soil:
    Evaluation of Fresh and Hardened Properties
  19. 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
  20. Khan Shayan, Ghazi Syed, Amjad Hassan, Imram Muhammad et al. (2023-12)
    Emerging Horizons in 3D Printed Cement-Based Materials with Nano-Material-Integration:
    A Review
  21. Fahim Abdullah, Admassu Natnael, Dailey Garret, Moradllo Mehdi (2023-12)
    Application of Cellulose-Nano-Crystals in 3D Printed Alkali-Activated Cementitious Composites
  22. Noaimat Yazeed, Chougan Mehdi, Albar Abdulrahman, Skibicki Szymon et al. (2023-10)
    Recycled Brick-Aggregates in One-Part Alkali-Activated Materials:
    Impact on 3D Printing Performance and Material-Properties

BibTeX 
@article{dai_tao_titt_schu.2023.RaMPo3PAASMwAoNC,
  author            = "Xiaodi Dai and Yaxin Tao and Kim van Tittelboom and Geert de Schutter",
  title             = "Rheological and Mechanical Properties of 3D Printable Alkali-Activated Slag Mixtures with Addition of Nano Clay",
  doi               = "10.1016/j.cemconcomp.2023.104995",
  year              = "2023",
  journal           = "Cement and Concrete Composites",
  volume            = "139",
}
Formatted Citation

X. Dai, Y. Tao, K. van Tittelboom and G. de Schutter, “Rheological and Mechanical Properties of 3D Printable Alkali-Activated Slag Mixtures with Addition of Nano Clay”, Cement and Concrete Composites, vol. 139, 2023, doi: 10.1016/j.cemconcomp.2023.104995.

Dai, Xiaodi, Yaxin Tao, Kim van Tittelboom, and Geert de Schutter. “Rheological and Mechanical Properties of 3D Printable Alkali-Activated Slag Mixtures with Addition of Nano Clay”. Cement and Concrete Composites 139 (2023). https://doi.org/10.1016/j.cemconcomp.2023.104995.