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Steel-Cable Bonding in Fresh Mortar and 3D Printed Beam Flexural Behavior (2023-11)

10.1016/j.autcon.2023.105165

 Liu Qiong,  Cheng Shengbo,  Sun Chang,  Chen Kailun,  Li Wengui,  Tam Vivian
Journal Article - Automation in Construction, Vol. 158, No. 105165

Abstract

This paper presents an approach for enhancing the path-following capability of concrete printing by integrating steel cables into the center of printed mortar strips during the print process, thus satisfying the synchronous and continuous requirements of 3D printing construction. To investigate the impact of steel cables on buildability of printed composites, the bonding strength between mortars and three types of steel cables with different diameters (0.5 mm, 1 mm, and 1.5 mm) was examined through pull-out tests. Moreover, four-point bending tests were conducted to examine the flexural performance of printed mortar beams reinforced with varying numbers and diameters of steel cables. Experimental results demonstrate that mortar filaments reinforced with 0.5 mm and 1 mm diameter steel cables can meet the buildability requirements within the designated open-time, while 1.5 mm diameter steel cables tend to rebound out of the fresh printed mortar due to their rebound force exceeding the grip strength of the mortar, rendering reinforced 3D printing unfeasible. Pull-out tests reveal that bonding strength between steel cables and 3D printed mortars is between 1.4 and 2.4 MPa. Due to steel cable's bundle structure and printing methods, this bonding strength is lower than that of traditional reinforced concrete. In addition, the flexural strength of printed beams reinforced with steel cables is increased by up to around 90%, and the ductile fracture mode trend was observed. This paper confirms the feasibility and effectiveness of this enhancement approach, providing a reference for other reinforcement methods in 3D printed building structures.

35 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. Bos Freek, Ahmed Zeeshan, Jutinov Evgeniy, Salet Theo (2017-11)
    Experimental Exploration of Metal-Cable as Reinforcement in 3D Printed Concrete
  3. Buchli Jonas, Giftthaler Markus, Kumar Nitish, Lussi Manuel et al. (2018-07)
    Digital In-Situ Fabrication:
    Challenges and Opportunities for Robotic In-Situ Fabrication in Architecture, Construction, and Beyond
  4. Caron Jean-François, Demont Léo, Ducoulombier Nicolas, Mesnil Romain (2021-06)
    3D Printing of Mortar with Continuous Fibers:
    Principle, Properties and Potential for Application
  5. Hou Shaodan, Xiao Jianzhuang, Duan Zhenhua, Ma Guowei (2021-10)
    Fresh Properties of 3D Printed Mortar with Recycled Powder
  6. Ivanova Irina, Ivaniuk Egor, Bisetti Sameercharan, Nerella Venkatesh et al. (2022-03)
    Comparison Between Methods for Indirect Assessment of Buildability in Fresh 3D Printed Mortar and Concrete
  7. 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
  8. Li Zhijian, Wang Li, Ma Guowei, Sanjayan Jay et al. (2020-07)
    Strength and Ductility Enhancement of 3D Printing Structure Reinforced by Embedding Continuous Micro-Cables
  9. Lim Sungwoo, Buswell Richard, Le Thanh, Austin Simon et al. (2011-07)
    Developments in Construction-Scale Additive Manufacturing Processes
  10. Lim Jian, Panda Biranchi, Pham Quang-Cuong (2018-05)
    Improving Flexural Characteristics of 3D Printed Geopolymer Composites with In-Process Steel-Cable-Reinforcement
  11. Liu Chao, Chen Yuning, Xiong Yuanliang, Jia Lutao et al. (2022-06)
    Influence of Hydroxypropyl-Methylcellulose and Silica-Fume on Buildability of 3D Printing Foam-Concrete:
    From Water State and Flocculation Point of View
  12. Long Wujian, Tao Jie-Lin, Lin Can, Gu Yucun et al. (2019-08)
    Rheology and Buildability of Sustainable Cement-Based Composites Containing Micro-Crystalline Cellulose for 3D Printing
  13. Ma Guowei, Li Zhijian, Wang Li (2017-12)
    Printable Properties of Cementitious Material Containing Copper-Tailings for Extrusion-Based 3D Printing
  14. Ma Guowei, Li Zhijian, Wang Li, Wang Fang et al. (2019-01)
    Mechanical Anisotropy of Aligned Fiber-Reinforced Composite for Extrusion-Based 3D Printing
  15. Marchment Taylor, Sanjayan Jay (2019-10)
    Mesh Reinforcing Method for 3D Concrete Printing
  16. Mechtcherine Viktor, Buswell Richard, Kloft Harald, Bos Freek et al. (2021-02)
    Integrating Reinforcement in Digital Fabrication with Concrete:
    A Review and Classification Framework
  17. Moelich Gerrit, Kruger Jacques, Combrinck Riaan (2021-09)
    Modelling the Inter-Layer Bond Strength of 3D Printed Concrete with Surface Moisture
  18. Moelich Gerrit, Kruger Jacques, Combrinck Riaan (2022-06)
    Mitigating Early-Age Cracking in 3D Printed Concrete Using Fibers, Superabsorbent Polymers, Shrinkage Reducing Admixtures, B-CSA Cement and Curing Measures
  19. Nair Sooraj, Tripathi Avinaya, Neithalath Narayanan (2021-09)
    Examining Layer-Height Effects on the Flexural and Fracture Response of Plain and Fiber-Reinforced 3D Printed Beams
  20. Ngo Tuan, Kashani Alireza, Imbalzano Gabriele, Nguyen Quynh et al. (2018-02)
    Additive Manufacturing (3D Printing):
    A Review of Materials, Methods, Applications and Challenges
  21. Panda Biranchi, Lim Jian, Tan Ming (2019-02)
    Mechanical Properties and Deformation Behavior of Early-Age Concrete in the Context of Digital Construction
  22. Panda Biranchi, Unluer Cise, Tan Ming (2018-10)
    Investigation of the Rheology and Strength of Geopolymer Mixtures for Extrusion-Based 3D Printing
  23. Perrot Arnaud, Rangeard Damien, Nerella Venkatesh, Mechtcherine Viktor (2019-02)
    Extrusion of Cement-Based Materials:
    An Overview
  24. Roussel Nicolas (2018-05)
    Rheological Requirements for Printable Concretes
  25. Sanjayan Jay, Nematollahi Behzad (2019-02)
    3D Concrete Printing for Construction Applications
  26. Tripathi Avinaya, Nair Sooraj, Neithalath Narayanan (2022-01)
    A Comprehensive Analysis of Buildability of 3D Printed Concrete and the Use of Bi-Linear Stress-Strain Criterion-Based Failure Curves Towards Their Prediction
  27. Wang Zhibin, Jia Lutao, Deng Zhicong, Zhang Chao et al. (2022-08)
    Bond Behavior Between Steel-Bars and 3D Printed Concrete:
    Effect of Concrete Rheological Property, Steel-Bar Diameter and Paste-Coating
  28. Wang Li, Ma Guowei, Liu Tianhao, Buswell Richard et al. (2021-07)
    Inter-Layer Reinforcement of 3D Printed Concrete by the In-Process Deposition of U-Nails
  29. Wolfs Robert, Bos Freek, Salet Theo (2018-02)
    Early-Age Mechanical Behaviour of 3D Printed Concrete:
    Numerical Modelling and Experimental Testing
  30. Xiao Jianzhuang, Chen Zixuan, Ding Tao, Zou Shuai (2021-10)
    Bending Behavior of Steel-Cable-Reinforced 3D Printed Concrete in the Direction Perpendicular to the Interfaces
  31. Xiao Jianzhuang, Zou Shuai, Ding Tao, Duan Zhenhua et al. (2021-08)
    Fiber-Reinforced Mortar with 100% Recycled Fine Aggregates:
    A Cleaner Perspective on 3D Printing
  32. Yu Kequan, McGee Wesley, Ng Tsz, Zhu He et al. (2021-02)
    3D Printable Engineered Cementitious Composites:
    Fresh and Hardened Properties
  33. Zhang Hanghua, Xiao Jianzhuang (2021-08)
    Plastic Shrinkage and Cracking of 3D Printed Mortar with Recycled Sand
  34. Zhu Binrong, Pan Jinlong, Li Junrui, Wang Penghui et al. (2022-07)
    Relationship Between Microstructure and Strain-Hardening Behavior of 3D Printed Engineered Cementitious Composites
  35. 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

17 Citations

  1. Wang Xiangyu, Wang Sizhe, Deng North, Liu Zhenbang et al. (2026-01)
    Robotic Rebar Insertion and Grouting for Reinforcement of 3D Printed Concrete:
    Technique Development and Bond Behavior Characterization
  2. Slavcheva Galina, Levchenko Artem, Artamonova Olga, Karakchi-Ogli Davut et al. (2025-12)
    Mechanical Behavior and Reinforcement Efficiency of 3D Printed Concrete Under Compression, Tension, and Bending
  3. Öztürk Ece, Ince Ceren, Borgianni Yuri, Nicolaides Demetris et al. (2025-12)
    Printability, Engineering Properties and Environmental Implications of 3D-Printed Cementitious Mortars Incorporating Hydrated Lime, Tile Powder and Accelerator
  4. Telichko Victor, Slavcheva Galina, Levchenko Artem (2025-12)
    Experimentally Verified FE Model of Bending Reinforced 3D-Printed Concrete Elements
  5. Wang Li, Fan Haichen, Wang Qiang, Bai Gang et al. (2025-09)
    Design Method and Force Transmission Mechanism of 3D Printed Concrete Truss Beams Reinforced with 3D Conical Reinforcement
  6. Maurya Shubham, Kumar Vijay, Panda Biranchi, Borsaikia Arun et al. (2025-09)
    Inline Polymer Cable Reinforcement in 3D Concrete Printing with a Special Nozzle
  7. Motiani Ronak, Sylvain Saha, Dalal Sejal, Vora Jay et al. (2025-08)
    Innovative Reinforcement Techniques for 3D-Printed Concrete:
    The Impact of Shape Memory Alloys on Flexural Strength and Crack Mitigation
  8. Girskas Giedrius, Kligys Modestas (2025-06)
    3D Concrete Printing Review:
    Equipment, Materials, Mix Design, and Properties
  9. Liu Qiong, Singh Amardeep, Wang Qiming, Qifeng Lyu (2025-05)
    3D-Printed Application in Concretes
  10. Liu Qiong, Wang Qiming, Sun Chang, Singh Amardeep et al. (2025-04)
    Compressive Performance and Damage Evolution of Concrete Short Columns with Shell-Filling Structure Confined by Continuous Fiber Reinforced 3D Printed Mortar
  11. Zeng Jun-Jie, Sun Hou-Qi, Deng Run-Bin, Yan Zitong et al. (2025-02)
    Bond Performance Between FRP-Bars and 3D-Printed High-Performance Concrete
  12. Du Guoqiang, Qian Ye (2025-01)
    Enhancing the Fracture and Flexural Behavior of 3D Printed Strain-Hardening Cementitious Composites with Nature-Inspired Single and Double Bouligand Structures
  13. Chen Meng, Yu Kanghao, Zhang Tong, Wang Yuting (2025-01)
    Characterizing and Modelling the Bond-Slip-Behavior of Steel-Bars in 3D Printed Engineered Cementitious Composites
  14. Sun Hou-Qi, Zeng Jun-Jie, Hong Guang-Yao, Zhuge Yan et al. (2025-01)
    3D Printed Functionally Graded Concrete Plates:
    Concept and Bending Behavior
  15. Du Guoqiang, Sun Yan, Qian Ye (2024-08)
    3D Printed Strain-Hardening Cementitious Composites (3DP-SHCC) Reticulated Shell Roof Inspired by the Water Spider
  16. Lu Yue, Xiao Jianzhuang, Li Yan (2024-03)
    3D Printing Recycled Concrete Incorporating Plant-Fibers:
    A Comprehensive Review
  17. Wang Xiaonan, Li Wengui, Guo Yipu, Kashani Alireza et al. (2024-02)
    Concrete 3D Printing Technology in Sustainable Construction:
    A Review on Raw Materials, Concrete Types and Performances

BibTeX 
@article{liu_chen_sun_chen.2024.SCBiFMa3PBFB,
  author            = "Qiong Liu and Shengbo Cheng and Chang Sun and Kailun Chen and Wengui Li and Vivian W. Y. Tam",
  title             = "Steel-Cable Bonding in Fresh Mortar and 3D Printed Beam Flexural Behavior",
  doi               = "10.1016/j.autcon.2023.105165",
  year              = "2024",
  journal           = "Automation in Construction",
  volume            = "158",
  pages             = "105165",
}
Formatted Citation

Q. Liu, S. Cheng, C. Sun, K. Chen, W. Li and V. W. Y. Tam, “Steel-Cable Bonding in Fresh Mortar and 3D Printed Beam Flexural Behavior”, Automation in Construction, vol. 158, p. 105165, 2024, doi: 10.1016/j.autcon.2023.105165.

Liu, Qiong, Shengbo Cheng, Chang Sun, Kailun Chen, Wengui Li, and Vivian W. Y. Tam. “Steel-Cable Bonding in Fresh Mortar and 3D Printed Beam Flexural Behavior”. Automation in Construction 158 (2024): 105165. https://doi.org/10.1016/j.autcon.2023.105165.