Eco-Friendly 3D Printed Concrete with Fine Aggregate Replacements (2024-01)¶
10.1016/j.conbuildmat.2024.134905
Zhu Ronghua, , Salehi Hadi, Shi Zhongtian,
Journal Article - Construction and Building Materials, Vol. 413, No. 134905
Abstract
During the last decade, 3D printing technology has experienced significant development, especially for concrete printing in construction. However, eco-friendly 3D printed concrete with fine aggregate replacements has not yet been sufficiently studied. Herein, twenty-five (25) mix categories are designed for use in 3D printed concrete. The mix materials include fine aggregates, silica fume (SF), ground waste rubber tire (Ru), and glass fiber (GF) composites. The mechanical characterization (i.e., stress-strain relations) are investigated, and the mechanical performance (i.e., compressive and flexural strengths) are reported. Numerical simulations are carried out to validate the experimental results, and satisfactory agreements are obtained. Machine learning prediction model is developed using the experimental and numerical results to predict the compressive and flexural strengths of the aggregate-mixed 3D printed concrete. An inverse relationship was observed between the rubber content and compressive strength of 3D printed concrete (RuC) printing imperfections is highly correlated with high rubber content. Similarly, increasing fiber volume in fiber concrete (FC) resulted in a decreased compressive strength due to reduced interlayer bond. Notably, hybridized concrete (HC) exhibited comparable strengths to fiber concretes at 1% fiber content, but a significant strength increase was observed at 5%, 10%, and 15% rubber contents with 2.5% fiber volume. Better stress-strain response (i.e., higher strength) is observed with larger SF content. It is evident that the addition of SF, GF, and Ru to concrete, improves cost efficiency and the stress-strain behavior of 3D printed concrete. The reported eco-friendly 3D printed concrete has a relatively low peak strength compared to normal concrete but shows traces of fatigue resistance. The eco-friendly 3D printed concrete provides the alternative for normal concrete for in-situ construction applications.
¶
23 References
- Arunothayan Arun, Nematollahi Behzad, Ranade Ravi, Bong Shin et al. (2021-02)
Fiber-Orientation Effects on Ultra-High-Performance Concrete Formed by 3D Printing - Bai Gang, Wang Li, Ma Guowei, Sanjayan Jay et al. (2021-03)
3D Printing Eco-Friendly Concrete Containing Under-Utilised and Waste Solids as Aggregates - Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
3D Printing Using Concrete-Extrusion:
A Roadmap for Research - Ding Tao, Xiao Jianzhuang, Zou Shuai, Yu Jiangtao (2021-03)
Flexural Properties of 3D Printed Fiber-Reinforced Concrete with Recycled Sand - Ghasemi Alireza, Naser Mohannad (2023-07)
Tailoring 3D Printed Concrete Through Explainable Artificial Intelligence - Hambach Manuel, Rutzen Matthias, Volkmer Dirk (2019-02)
Properties of 3D-Printed Fiber-Reinforced Portland Cement-Paste - Hambach Manuel, Volkmer Dirk (2017-02)
Properties of 3D Printed Fiber-Reinforced Portland-Cement-Paste - Hosseini Ehsan, Zakertabrizi Mohammad, Korayem Asghar, Xu Guanzhong (2019-03)
A Novel Method to Enhance the Inter-Layer Bonding of 3D Printing Concrete:
An Experimental and Computational Investigation - Khan Mohammad, Sanchez Florence, Zhou Hongyu (2020-04)
3D Printing of Concrete:
Beyond Horizons - Kristombu Baduge Shanaka, Navaratnam Satheeskumar, Zidan Yousef, McCormack Tom et al. (2021-01)
Improving Performance of Additive Manufactured Concrete:
A Review on Material Mix-Design, Processing, Inter-Layer Bonding, and Reinforcing-Methods - Li Victor, Bos Freek, Yu Kequan, McGee Wesley et al. (2020-04)
On the Emergence of 3D Printable Engineered, Strain-Hardening Cementitious Composites - Liu Hanqiu, Egbe King-James, Wang Haipeng, Nazar Ali et al. (2021-11)
A Numerical Study on 3D Printed Cementitious Composites Mixes Subjected to Axial Compression - Rahul Attupurathu, Santhanam Manu, Meena Hitesh, Ghani Zimam (2019-08)
Mechanical Characterization of 3D Printable Concrete - Shakor Pshtiwan, Gowripalan Nadarajah, Rasouli Habib (2021-03)
Experimental and Numerical Analysis of 3D Printed Cement Mortar Specimens Using Inkjet 3DP - Singh Amardeep, Liu Qiong, Xiao Jianzhuang, Lyu Qifeng (2022-02)
Mechanical and Macrostructural Properties of 3D Printed Concrete Dosed with Steel-Fibers under Different Loading-Direction - Suiker Akke, Wolfs Robert, Lucas Sandra, Salet Theo (2020-06)
Elastic Buckling and Plastic Collapse During 3D Concrete Printing - 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 - Weng Yiwei, Lu Bing, Li Mingyang, Liu Zhixin et al. (2018-09)
Empirical Models to Predict Rheological Properties of Fiber-Reinforced Cementitious Composites for 3D Printing - Wolfs Robert, Bos Freek, Salet Theo (2018-02)
Early-Age Mechanical Behaviour of 3D Printed Concrete:
Numerical Modelling and Experimental Testing - Wolfs Robert, Bos Freek, Salet Theo (2019-03)
Hardened Properties of 3D Printed Concrete:
The Influence of Process Parameters on Inter-Layer Adhesion - Yao Xiaofei, Lyu Xin, Sun Junbo, Wang Bolin et al. (2023-03)
AI-Based Performance Prediction for 3D Printed Concrete Considering Anisotropy and Steam-Curing Condition - Yu Kequan, McGee Wesley, Ng Tsz, Zhu He et al. (2021-02)
3D Printable Engineered Cementitious Composites:
Fresh and Hardened Properties - Zhang Chao, Hou Zeyu, Chen Chun, Zhang Yamei et al. (2019-09)
Design of 3D Printable Concrete Based on the Relationship Between Flowability of Cement-Paste and Optimum Aggregate-Content
17 Citations
- Taborda-Llano Isabella, Hoyos-Montilla Ary, Asensio Eloy, Guerrero Ana et al. (2025-12)
Influence of the Construction Process Parameters on the Mechanical Performance and Durability of 3D Printed Concrete:
A Systematic Review - Abbas Yassir, Alsaif Abdulaziz (2025-11)
Explainable Data-Driven Modeling for Optimized Mix Design of 3D-Printed Concrete:
Interpreting Nonlinear Synergies Among Binder Components and Proportions - 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 - Mousavi Moein, Rangaraju Prasad (2025-09)
Freeze-Thaw Durability of 3D Printed Concrete:
A Comprehensive Review of Mechanisms, Materials, and Testing Strategies - 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 - Hermida José, Saavedra Ruth, Hidalgo-Astudillo Samantha, Tošić Nikola et al. (2025-06)
Influence of Fine Recycled Aggregates on the Properties of 3D Printing Concrete - Bhattacharjee Biswajoy, Sahu Prakash (2025-05)
Recent Innovations and Implementations of 3D Printing in the Building and Construction Sector - Asif Usama (2025-05)
Comparative Analysis of Evolutionary Computational Methods for Predicting Mechanical Properties of Fiber-Reinforced 3D Printed Concrete - Mim Nusrat, Shaikh Faiz, Sarker Prabir (2025-03)
Sustainable 3D Printed Concrete Incorporating Alternative Fine Aggregates:
A Review - Banijamali Kasra, Dempsey Mary, Chen Jianhua, Kazemian Ali (2025-02)
Machine Learning Approach to Predict the Early-Age Flexural Strength of Sensor-Embedded 3D-Printed Structures - Lori Ali, Mehrali Mehdi (2025-01)
Filament-Geometry-Control of Printable Geopolymer Using Experimental and Data-Driven Approaches - Huang Junxiang, Peng Zeqin, Tan Xianzhong, Gong Guofang et al. (2024-12)
Mechanism Analysis of the Magnetic Field-Assisted 3D Printed Steel-Fiber-Reinforced Concrete - Murali Gunasekaran, Leong Sing (2024-11)
Waste-Driven Construction:
A State of the Art Review on the Integration of Waste in 3D Printed Concrete in Recent Researches for Sustainable Development - Ma Xin-Rui, Wang Xian-Lin, Chen Shi-Zi (2024-09)
Trustworthy Machine Learning-Enhanced 3D Concrete Printing:
Predicting Bond Strength and Designing Reinforcement Embedment Length - Xu Wen, Jiang Dengjie, Zhao Qian, Wang Linbing (2024-08)
Study on Printability of 3D Printing Carbon-Fiber-Reinforced Eco-Friendly Concrete:
Characterized by Fluidity and Consistency - Malik Umair, Riaz Raja, Rehman Saif, Usman Muhammad et al. (2024-07)
Advancing Mix-Design Prediction in 3D Printed Concrete:
Predicting Anisotropic Compressive Strength and Slump-Flow - Mohamed Ibrahim, Senthil Kumar (2024-05)
3D Printed Concrete Using Portland-Pozzolana-Cement:
Fly-Ash-Based
BibTeX
@article{zhu_egbe_sale_shi.2024.EF3PCwFAR,
author = "Ronghua Zhu and King-James Idala Egbe and Hadi Salehi and Zhongtian Shi and Pengcheng Jiao",
title = "Eco-Friendly 3D Printed Concrete with Fine Aggregate Replacements: Fabrication, Characterization and Machine Learning Prediction",
doi = "10.1016/j.conbuildmat.2024.134905",
year = "2024",
journal = "Construction and Building Materials",
volume = "413",
pages = "134905",
}
Formatted Citation
R. Zhu, K.-J. I. Egbe, H. Salehi, Z. Shi and P. Jiao, “Eco-Friendly 3D Printed Concrete with Fine Aggregate Replacements: Fabrication, Characterization and Machine Learning Prediction”, Construction and Building Materials, vol. 413, p. 134905, 2024, doi: 10.1016/j.conbuildmat.2024.134905.
Zhu, Ronghua, King-James Idala Egbe, Hadi Salehi, Zhongtian Shi, and Pengcheng Jiao. “Eco-Friendly 3D Printed Concrete with Fine Aggregate Replacements: Fabrication, Characterization and Machine Learning Prediction”. Construction and Building Materials 413 (2024): 134905. https://doi.org/10.1016/j.conbuildmat.2024.134905.