Skip to content

Mechanical and Shrinkage Performance of 3D Printed Rubberised Engineered Cementitious Composites (2022-05)

10.1016/j.conbuildmat.2022.127665

 Aslani Farhad, Dale Ryan,  Hamidi Fatemeh, Valizadeh Afsaneh
Journal Article - Construction and Building Materials, Vol. 339

Abstract

Taking the advantages of 3D concrete printing (3DCP) and tackling the environmental issues related to the waste tires, current paper evaluates the material behaviour of rubberised engineered cementitious composites (ECC) using waste crumb rubber (CR) aggregates and polyvinyl alcohol (PVA) fibres, manufactured through 3DCP. To elaborate on the role of PVA fibres on the material properties, two different control mix designs were prepared through conventional mould-casting method, including control mix design without PVA fibres and ECC with PVA fibres equal to 1.75 vol% of binder. Thereafter, using the control ECC mix design, four mix designs containing 5, 10, 15, and 20% CR aggregates as replacement of fly ash, were prepared to assess the effect of CR on the mechanical performance of ECC. The prepared mix designs were subjected to compressive and flexural strengths, and shrinkage tests, and the rubberised ECC containing 5% CR was selected for 3DCP as it revealed superior compressive, flexural and shrinkage behaviour. Results obtained for 3D-printed specimens confirmed the dominant role of anisotropy on the material performance, which was very pronounced for flexural behaviour of printed elements. Comparing to the samples loaded in perpendicular direction, loading in the parallel direction to the fibre orientation (X direction) led to 3 and 4% higher 7- and 28-day compressive strengths, and loading parallel to the fibre alignment along the longitudinal axis of the specimen (Z direction) resulted in 104% and 47% increase in the 7- and 28-day flexural strengths, respectively. Moreover, printed specimens in the fibre-parallel direction showed 37% less drying shrinkage comparing to those printed in the perpendicular direction. Additionally, 3D-printed elements represent superior performance in terms of compressive strength, ductile characteristics, flexural behaviour, and shrinkage performance over the mould-casted ones.

11 References

  1. Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
    3D Printing Using Concrete-Extrusion:
    A Roadmap for Research
  2. Hambach Manuel, Rutzen Matthias, Volkmer Dirk (2019-02)
    Properties of 3D-Printed Fiber-Reinforced Portland Cement-Paste
  3. Hamidi Fatemeh, Aslani Farhad (2019-05)
    Additive Manufacturing of Cementitious Composites:
    Materials, Methods, Potentials, and Challenge
  4. Le Thanh, Austin Simon, Lim Sungwoo, Buswell Richard et al. (2012-01)
    Hardened Properties of High-Performance Printing Concrete
  5. Li Victor, Bos Freek, Yu Kequan, McGee Wesley et al. (2020-04)
    On the Emergence of 3D Printable Engineered, Strain-Hardening Cementitious Composites
  6. Ma Guowei, Li Zhijian, Wang Li, Wang Fang et al. (2019-01)
    Mechanical Anisotropy of Aligned Fiber-Reinforced Composite for Extrusion-Based 3D Printing
  7. Panda Biranchi, Paul Suvash, Lim Jian, Tay Yi et al. (2017-08)
    Additive Manufacturing of Geopolymer for Sustainable Built Environment
  8. Panda Biranchi, Paul Suvash, Mohamed Nisar, Tay Yi et al. (2017-09)
    Measurement of Tensile Bond Strength of 3D Printed Geopolymer Mortar
  9. Paul Suvash, Tay Yi, Panda Biranchi, Tan Ming (2017-08)
    Fresh and Hardened Properties of 3D Printable Cementitious Materials for Building and Construction
  10. Sun Junbo, Aslani Farhad, Lu Jenny, Wang Lining et al. (2021-06)
    Fiber-Reinforced Lightweight Engineered Cementitious Composites for 3D Concrete Printing
  11. Zhang Yifan, Aslani Farhad (2021-08)
    Development of Fiber-Reinforced Engineered Cementitious Composite Using Polyvinyl-Alcohol-Fiber and Activated Carbon-Powder for 3D Concrete Printing

39 Citations

  1. Tulliani Jean-Marc (2025-11)
    Latest Developments in 3D-Printed Engineered Cementitious Composites:
    Technologies, Prospects, and Challenges
  2. Song Qiang, Zhou Guangyu, Bao Hailing, Liu Qiong (2025-11)
    Study on the Effects of Nozzle Proximal Carbonation Mixing and Vacuum Dewatering on the Printability and Mechanical Properties of the 3D Printed Construction Mortar
  3. Chen Wenguang, Yu Jie, Ye Junhong, Yu Jiangtao et al. (2025-11)
    3D Printed High-Performance Fiber-Reinforced Cementitious Composites:
    Fresh, Mechanical, and Microstructural Properties
  4. Varghese Renny, Rangel Bárbara, Maia Lino (2025-10)
    Strength, Structure, and Sustainability in 3D-Printed Concrete Using Different Types of Fiber Reinforcements
  5. Delavar Mohammad, Aslani Farhad, Sercombe Tim (2025-10)
    Cracking Behaviour in 3D Concrete Printed Fiber-Reinforced Cementitious Composites:
    A Review
  6. Chen Wenguang, Liang Long, Ye Junhong, Liu Lingfei et al. (2025-09)
    Machine Learning-Enabled Performance-Based Design of Three-Dimensional Printed Engineered Cementitious Composites
  7. Zhang Yifan, Aslani Farhad (2025-08)
    Mechanical and Ultrasonic Pulse Velocity Performance of 3D Printed Rubberised Cementitious Composites Reinforced with PVA Fibers
  8. Lin Manfang, Ding Yao, Yu Fan, Li Lingzhi et al. (2025-08)
    Synergistic Strengthening of 3D‑printed ECC Beams Through Steel-Wire Mesh and Interfaces Treatments
  9. Ravichandran Darssni, Prem Prabhat, Bhaskara Gollapalli, Maheswaran Srinivasan et al. (2025-07)
    Time-Dependent Properties of 3D Printable Plain and Fibered High Strength Concrete Incorporating Copper Slag as an Alternate Fine Aggregate
  10. Sahebi Soleyman, Aslani Farhad (2025-07)
    Mechanical Strength and Heat Tolerance of 3D Printed Rubberised Concrete at Elevated Temperatures
  11. Su Yanli, Wu Chang, Shang Jiaqi, Zhang Pu (2025-06)
    Mechanical Properties of 3D-Printed High-Ductility Cementitious Composite with Sulphoaluminate Cement and Modified Crumb Rubber
  12. Bhattacharjee Biswajoy, Sahu Prakash (2025-05)
    Recent Innovations and Implementations of 3D Printing in the Building and Construction Sector
  13. Liu Qiong, Singh Amardeep, Wang Qiming, Qifeng Lyu (2025-05)
    3D-Printed Application in Concretes
  14. Xia Kailun, Chen Yuning, Chen Yu, Jia Lutao et al. (2025-04)
    Programmable Toughening for 3D Printed Concrete and Architected Cementitious Materials
  15. Qiao Zhigang, Li Hui, Wang Fei, Qi Yongle et al. (2025-04)
    Optimizing Thermal Energy Storage in 3D Printed Concrete with Hollow Ceramsite Composite Phase Change Materials
  16. Liu Chuanbei, Zou Mengtong, Chen Xuemei, Deng Yongjun et al. (2025-04)
    Feasibility Study of 3D-Printed Rubberized Concrete as a Permanent Formwork:
    Mechanical Properties, Interlayer Interface and Durability
  17. Zhou Wen, Xu Yading, Meng Zhaozheng, Xie Jinbao et al. (2025-03)
    Filament Stitching:
    An Architected Printing Strategy to Mitigate Anisotropy in 3D-Printed Engineered Cementitious Composites
  18. Zhu Binrong, Zhang Yuhang, Ye Huzi, Wei Yang et al. (2025-03)
    Low-Velocity Impact Performance of Biomimetic 3D Printed Engineered Cementitious Composites Beams
  19. Yaqub Walid, Aslani Farhad (2024-12)
    Mechanical Properties and Fire-Resistance of 3D Printed Cementitious Composites with Plastic Waste
  20. Habibi Alireza, Buswell Richard, Osmani Mohamed, Aziminezhad Mohamadmahdi (2024-11)
    Sustainability Principles in 3D Concrete Printing:
    Analysing Trends, Classifying Strategies, and Future Directions
  21. Kaszyńska Maria, Skibicki Szymon (2024-11)
    Sustainable Development Approach for 3D Concrete Printing
  22. Lin Manfang, Li Lingzhi, Jiang Fangming, Ding Yao et al. (2024-11)
    Automated Reinforcement of 3D Printed Engineered Cementitious Composite Beams
  23. Sun Junbo, Zhang Yanling, Wu Qi, Wang Yufei et al. (2024-10)
    3D Printed Concrete Incorporating Waste-Rubber:
    Anisotropic Properties and Environmental Impact-Analysis
  24. Wang Xiangyu, Du Liangfen, Liu Zhenbang, Li Mingyang et al. (2024-09)
    3D Cementitious Composites Printing with Pretreated Recycled Crumb-Rubber:
    Mechanical and Acoustic Insulation Properties
  25. Asghari Y., Mohammadyan-Yasouj S., Petrů M., Ghandvar H. et al. (2024-07)
    3D Printing and Implementation of Engineered Cementitious Composites:
    A Review
  26. Wang Yuting, Chen Meng, Zhang Tong, Zhang Mingzhong (2024-07)
    Hardening Properties and Microstructure of 3D Printed Engineered Cementitious Composites Based on Limestone-Calcined-Clay-Cement
  27. Aslani Farhad, Zhang Yifan (2024-06)
    Sustainable 3D Printed Concrete Structures Using High-Quality Secondary Raw Materials
  28. Rahman Mahfuzur, Rawat Sanket, Yang Chunhui, Mahil Ahmed et al. (2024-05)
    A Comprehensive Review on Fresh and Rheological Properties of 3D Printable Cementitious Composites
  29. Sarker Mohiuddin, Rahmadan Md, Abedin Mohammad (2024-05)
    Engineered Cementitious Composites:
    Design, Structural and 3D Printing Applications
  30. 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
  31. 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
  32. 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
  33. Zhou Wen, McGee Wesley, Gökçe H., Li Victor (2023-08)
    A Bio-Inspired Solution to Alleviate Anisotropy of 3D Printed Engineered Cementitious Composites (3DP-ECC):
    Knitting/Tilting Filaments
  34. Riaz Raja, Usman Muhammad, Ali Ammar, Majid Usama et al. (2023-06)
    Inclusive Characterization of 3D Printed Concrete in Additive Manufacturing:
    A Detailed Review
  35. Wang Yuxin, Aslani Farhad, Dyskin Arcady, Pasternak Elena (2023-01)
    Digital Twin Applications in 3D Concrete Printing
  36. Sambucci Matteo, Biblioteca Ilario, Valente Marco (2023-01)
    Life Cycle Assessment (LCA) of 3D Concrete Printing and Casting Processes for Cementitious Materials Incorporating Ground Waste Tire Rubber
  37. Zhu Lingli, Yao Jie, Zhao Yu, Ruan Wenqiang et al. (2022-12)
    Effects of Composite Cementation System on Rheological and Working Performances of Fresh 3D Printable Engineered Cementitious Composites
  38. Lv Chun, Shen Hongtao, Liu Jie, Wu Dan et al. (2022-11)
    Properties of 3D Printing Fiber-Reinforced Geopolymers Based on Inter-Layer Bonding and Anisotropy
  39. Liu Junli, Setunge Sujeeva, Tran Jonathan (2022-07)
    3D Concrete Printing with Cement-Coated Recycled Crumb Rubber:
    Compressive and Microstructural Properties

BibTeX 
@article{asla_dale_hami_vali.2022.MaSPo3PRECC,
  author            = "Farhad Aslani and Ryan Dale and Fatemeh Hamidi and Afsaneh Valizadeh",
  title             = "Mechanical and Shrinkage Performance of 3D Printed Rubberised Engineered Cementitious Composites",
  doi               = "10.1016/j.conbuildmat.2022.127665",
  year              = "2022",
  journal           = "Construction and Building Materials",
  volume            = "339",
}
Formatted Citation

F. Aslani, R. Dale, F. Hamidi and A. Valizadeh, “Mechanical and Shrinkage Performance of 3D Printed Rubberised Engineered Cementitious Composites”, Construction and Building Materials, vol. 339, 2022, doi: 10.1016/j.conbuildmat.2022.127665.

Aslani, Farhad, Ryan Dale, Fatemeh Hamidi, and Afsaneh Valizadeh. “Mechanical and Shrinkage Performance of 3D Printed Rubberised Engineered Cementitious Composites”. Construction and Building Materials 339 (2022). https://doi.org/10.1016/j.conbuildmat.2022.127665.