Skip to content

PVA-Fiber-Reinforced Red Mud-Based Geopolymer for 3D Printing (2024-09)

Printability, Mechanical Properties and Microanalysis

10.1016/j.jobe.2024.110733

 Han Kang,  Gu Fei,  Yang Huashan,  Tian Xinchen,  Du Xiangqin
Journal Article - Journal of Building Engineering, Vol. 97, No. 110733

Abstract

Red mud-based geopolymers are an efficient alternative to resolve the high cement consumption in 3D printed concrete (3DPC). From a materials perspective, good printability and mechanical properties are critical to adopting red mud-based geopolymers in 3DPC. In this study, we selected bauxite tailings-red mud and blast furnace slag to prepare geopolymers. Polyvinyl alcohol (PVA) fibers with 0, 0.3 %, 0.6 %, 0.9 %, and 1.2 % volume fractions were used to reinforce 3D printed red mud-based geopolymers. To evaluate the influence of PVA fiber on the printability and mechanical properties of 3D printed red mud-based geopolymer. We tested the workability, extrudability, structural build-up ability, shape stability, and mechanical properties of the red mud-based geopolymer containing different volume fraction PVA fibers, and a microstructural analysis was performed to reveal the interface bond between the fibers and the geopolymer matrix. The results showed that adding PVA fibers impaired the workability of the red mud-based geopolymer mortar. The red mud-based geopolymer mortar showed a more than threefold increase in extrusion pressure compared to the control mixture (P0) when adding 1.2 % vol fiber. For all other mixtures, the increase was less than twice that of the control mixture. The PVA fiber had a significant positive impact on the structural build-up ability and shape stability of the 3D printable red mud-based geopolymer. In addition, PVA fibers promoted the bending strength of the hardened geopolymer specimens better than the compression strength, and the geopolymer gel on the fibers indicated the good interfacial bonding ability of the PVA fiber. This study demonstrates the feasibility of 3D printed red mud-based geopolymer and the reinforcement of 3D printed red mud-based geopolymer by PVA fibers, providing a material perspective to increase the range of red mud applications in 3D printed concrete.

28 References

  1. Arunothayan Arun, Nematollahi Behzad, Ranade Ravi, Bong Shin et al. (2021-02)
    Fiber-Orientation Effects on Ultra-High-Performance Concrete Formed by 3D Printing
  2. Bayat Hamid, Kashani Alireza (2023-09)
    Analysis of Rheological Properties and Printability of a 3D Printing Mortar Containing Silica-Fume, Hydrated Lime, and Blast-Furnace-Slag
  3. Bos Freek, Wolfs Robert, Ahmed Zeeshan, Salet Theo (2016-08)
    Additive Manufacturing of Concrete in Construction:
    Potentials and Challenges of 3D Concrete Printing
  4. Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
    3D Printing Using Concrete-Extrusion:
    A Roadmap for Research
  5. Chen Yu, Figueiredo Stefan, Li Zhenming, Chang Ze et al. (2020-03)
    Improving Printability of Limestone-Calcined-Clay-Based Cementitious Materials by Using Viscosity-Modifying Admixture
  6. Chen Mingxu, Yang Lei, Zheng Yan, Li Laibo et al. (2021-01)
    Rheological Behaviors and Structure Build-Up of 3D Printed Polypropylene- and Polyvinyl-Alcohol-Fiber-Reinforced Calcium-Sulphoaluminate-Cement Composites
  7. Chu Shaohua, Li Leo, Kwan Albert (2020-09)
    Development of Extrudable High-Strength Fiber-Reinforced Concrete Incorporating Nano-Calcium-Carbonate
  8. Han Yilong, Yang Zhihan, Ding Tao, Xiao Jianzhuang (2020-08)
    Environmental and Economic Assessment on 3D Printed Buildings with Recycled Concrete
  9. Li Zhijian, Wang Li, Ma Guowei (2020-01)
    Mechanical Improvement of Continuous Steel-Micro-Cable-Reinforced Geopolymer Composites for 3D Printing Subjected to Different Loading Conditions
  10. Liu Chao, Wang Xianggang, Chen Yuning, Zhang Chao et al. (2021-06)
    Influence of Hydroxypropyl-Methylcellulose and Silica-Fume on Stability, Rheological Properties, and Printability of 3D Printing Foam-Concrete
  11. Luo Surong, Li Wenqiang, Wang Dehui (2024-05)
    Study on Bending Performance of 3D Printed PVA-Fiber-Reinforced Cement-Based Material
  12. Mechtcherine Viktor, Nerella Venkatesh, Will Frank, Näther Mathias et al. (2019-08)
    Large-Scale Digital Concrete Construction:
    CONPrint3D Concept for On-Site, Monolithic 3D Printing
  13. Nematollahi Behzad, Vijay Praful, Sanjayan Jay, Nazari Ali et al. (2018-11)
    Effect of Polypropylene Fiber Addition on Properties of Geopolymers Made by 3D Printing for Digital Construction
  14. Nodehi Mehrab, Ozbakkaloglu Togay, Gholampour Aliakbar (2022-04)
    Effect of Supplementary Cementitious Materials on Properties of 3D Printed Conventional and Alkali-Activated Concrete:
    A Review
  15. Panda Biranchi, Bhagath Singh Gangapatnam, Unluer Cise, Tan Ming (2019-02)
    Synthesis and Characterization of One-Part Geopolymers for Extrusion-Based 3D Concrete Printing
  16. Panda Biranchi, Unluer Cise, Tan Ming (2018-10)
    Investigation of the Rheology and Strength of Geopolymer Mixtures for Extrusion-Based 3D Printing
  17. Reiter Lex, Wangler Timothy, Roussel Nicolas, Flatt Robert (2022-04)
    Slow Penetration for Characterizing Concrete for Digital Fabrication
  18. Roussel Nicolas (2018-05)
    Rheological Requirements for Printable Concretes
  19. Shahmirzadi Mohsen, Gholampour Aliakbar, Kashani Alireza, Ngo Tuan (2023-10)
    Geopolymer Mortars for Use in Construction 3D Printing:
    Effect of LSS, Graphene-Oxide and Nano-Clay at Different Environmental Conditions
  20. Sun Xiaoyan, Zhou Jiawei, Wang Qun, Shi Jiangpeng et al. (2021-11)
    PVA-Fiber-Reinforced High-Strength Cementitious Composite for 3D Printing:
    Mechanical Properties and Durability
  21. Wangler Timothy, Roussel Nicolas, Bos Freek, Salet Theo et al. (2019-06)
    Digital Concrete:
    A Review
  22. Wi Kwangwoo, Wang Kejin, Taylor Peter, Laflamme Simon et al. (2021-09)
    Properties and Microstructure of Extrusion-Based 3D Printing Mortar Containing a Highly Flowable, Rapid Set Grout
  23. Wolfs Robert, Bos Freek, Salet Theo (2019-06)
    Triaxial Compression Testing on Early-Age Concrete for Numerical Analysis of 3D Concrete Printing
  24. Yang Huashan, Che Yujun (2022-01)
    Recycling of Aggregate Micro-Fines as a Partial Replacement for Fly-Ash in 3D Printing Cementitious Materials
  25. Zhang Chao, Nerella Venkatesh, Krishna Anurag, Wang Shen et al. (2021-06)
    Mix-Design Concepts for 3D Printable Concrete:
    A Review
  26. Zhang Yi, Zhu Yanmei, Ren Qiang, He Bei et al. (2023-08)
    Comparison of Printability and Mechanical Properties of Rigid and Flexible Fiber-Reinforced 3D Printed Cement-Based Materials
  27. Zhong Hui, Zhang Mingzhong (2022-02)
    3D Printing Geopolymers:
    A Review
  28. Ziada Mahmoud, Tanyildizi Harun, Seloglu Maksut, Coskun Ahmet (2024-02)
    Bacteria-Based Crack-Healing of 3D Printed PVA-Fiber-Reinforced Geopolymer Mortars

7 Citations

  1. Shilar Fatheali, Shilar Mubarakali (2025-12)
    Performance-Based Analysis of 3D Printed Geopolymers Relating Durability, Microstructure, and Life Cycle Assessment
  2. Hasan Md, Xu Jie, Uddin Md (2025-11)
    A Critical Review of 3D Printed Fiber-Based Geopolymer Concrete:
    Fresh Properties, Mechanical Performance, and Current Limitations
  3. Khalid Lawand, Mermerdaş Kasım, Ekmen Şevin, Khidhir Bzeni Dillshad (2025-11)
    Optimization of Fresh and Hardened Properties of Fiber-Reinforced 3D Printed Geopolymer Composites Using Response Surface Methodology:
    A Data-Driven Approach Based on Prior Experimental Studies
  4. Li Leo, Fei Zuojie, Jiao Chujie, Luo Tao et al. (2025-09)
    Bauxite Residue-Based 3D Printing Mortar:
    Enhancing Performance and Sustainability Through the Paste Replacement Approach
  5. Luo Surong, Jin Wenhao, Zhang Zhaorui, Zhang Kaijian (2025-09)
    Constitutive Relationship of 3D Printed Fiber Reinforced Recycled Sand Concrete Under Uniaxial Compression
  6. Srinivas Dodda, Panda Biranchi, Suraneni Prannoy, Sitharam Thallak (2025-06)
    Mix Design Optimization of 3D-Printed Cementitious Composites for Marine Applications:
    Impact of Binder Composition, Accelerated Carbonation, and PVA Fibers on Strength and Durability
  7. Luo Surong, Jin Wenhao, Wu Weihong, Zhang Kaijian (2024-11)
    Rheological and Mechanical Properties of Polyformaldehyde-Fiber-Reinforced 3D Printed High-Strength Concrete with the Addition of Fly-Ash

BibTeX 
@article{han_gu_yang_tian.2024.PFRRMBGf3P,
  author            = "Kang Han and Fei Gu and Huashan Yang and Xinchen Tian and Xiangqin Du",
  title             = "PVA-Fiber-Reinforced Red Mud-Based Geopolymer for 3D Printing: Printability, Mechanical Properties and Microanalysis",
  doi               = "10.1016/j.jobe.2024.110733",
  year              = "2024",
  journal           = "Journal of Building Engineering",
  volume            = "97",
  pages             = "110733",
}
Formatted Citation

K. Han, F. Gu, H. Yang, X. Tian and X. Du, “PVA-Fiber-Reinforced Red Mud-Based Geopolymer for 3D Printing: Printability, Mechanical Properties and Microanalysis”, Journal of Building Engineering, vol. 97, p. 110733, 2024, doi: 10.1016/j.jobe.2024.110733.

Han, Kang, Fei Gu, Huashan Yang, Xinchen Tian, and Xiangqin Du. “PVA-Fiber-Reinforced Red Mud-Based Geopolymer for 3D Printing: Printability, Mechanical Properties and Microanalysis”. Journal of Building Engineering 97 (2024): 110733. https://doi.org/10.1016/j.jobe.2024.110733.