A New Strategy to Enhance 3D Printability of Cement-Based Materials (2024-07)¶
, Liu Zhaolong, Liu Qi, , Wang Chong, Wang Wei, Hong Jinxiang, Miao Changwen,
Journal Article - Additive Manufacturing, Vol. 89, No. 104299
Abstract
Printability is a crucial attribute for 3D-printed cement-based materials, as it not only governs the material's printability but also directly impacts the quality of the final structure. A good printability indicates that the printed materials are flowable for transport and extrusion, followed by a rapid increase in strength to establish a stable structure. In this paper, a novel strategy is proposed to enhance the 3D printability of cementitious materials by leveraging the rapid strength enhancement of fresh mortar during in-situ polymerization of acrylamide (AM) in the matrix within 30–60 min of contact with water. Prior to extrusion, AM monomers are absorbed onto cement particles to enhance the flowability of mortar to approximately 185 mm, thereby improving pumpability and extrudability of printed materials. Shortly after extrusion, in-situ polymerization of AM monomers within the mortar takes place, resulting in a sudden albeit modest strength increases in the fresh mortar, enhancing the buildability of the printed mortar. Moreover, the flexural strength of 3D printed filaments with 5 % AM are increased by 52.4 % at 28d, respectively. Meanwhile, the interactions between the AM in-situ polymerization and cement hydration are comprehensively discussed. This innovative approach to enhance 3D printability is expected to drive the advancement of 3D-printed materials with enhanced adaptability and superior properties.
¶
27 References
- Arunothayan Arun, Nematollahi Behzad, Ranade Ravi, Bong Shin et al. (2020-10)
Development of 3D Printable Ultra-High-Performance Fiber-Reinforced Concrete for Digital Construction - 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 - Chen Yu, He Shan, Gan Yidong, Çopuroğlu Oğuzhan et al. (2021-11)
A Review of Printing-Strategies, Sustainable Cementitious Materials and Characterization Methods in the Context of Extrusion-Based 3D Concrete Printing - Chen Mingxu, Li Laibo, Zheng Yan, Zhao Piqi et al. (2018-09)
Rheological and Mechanical Properties of Admixtures-Modified 3D Printing Sulphoaluminate Cementitious Materials - Chu Shaohua, Li Leo, Kwan Albert (2020-09)
Development of Extrudable High-Strength Fiber-Reinforced Concrete Incorporating Nano-Calcium-Carbonate - Gosselin Clément, Duballet Romain, Roux Philippe, Gaudillière-Jami Nadja et al. (2016-03)
Large-Scale 3D Printing of Ultra-High-Performance Concrete:
A New Processing Route for Architects and Builders - Hambach Manuel, Volkmer Dirk (2017-02)
Properties of 3D Printed Fiber-Reinforced Portland-Cement-Paste - Khalil Noura, Aouad Georges, Cheikh Khadija, Rémond Sébastien (2017-09)
Use of Calcium-Sulfoaluminate-Cements for Setting-Control of 3D Printing Mortars - Liu Miao, Huang Yimiao, Wang Fang, Sun Junbo et al. (2021-05)
Tensile and Flexural Properties of 3D Printed Jackets-Reinforced Mortar - Muthukrishnan Shravan, Ramakrishnan Sayanthan, Sanjayan Jay (2020-09)
Effect of Microwave-Heating on Inter-Layer Bonding and Buildability of Geopolymer 3D Concrete Printing - Muthukrishnan Shravan, Ramakrishnan Sayanthan, Sanjayan Jay (2021-06)
Technologies for Improving Buildability in 3D Concrete Printing - 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 - Paritala Spandana, Singaram Kailash, Bathina Indira, Khan Mohd et al. (2023-08)
Rheology and Pumpability of Mix Suitable for Extrusion-Based Concrete 3D Printing:
A Review - Rahul Attupurathu, Santhanam Manu (2020-02)
Evaluating the Printability of Concretes Containing Lightweight Coarse Aggregates - Rehman Atta, Melesse Birru, Kim Jung-Hoon (2023-02)
Set-on-Demand 3D Concrete Printing Construction and Potential Outcome of Shotcrete-Accelerators on Its Hardened Properties - Reiter Lex, Wangler Timothy, Roussel Nicolas, Flatt Robert (2018-06)
The Role of Early-Age Structural Build-Up in Digital Fabrication with Concrete - Shao Lijing, Feng Pan, Zuo Wenqiang, Wang Haochuan et al. (2022-02)
A Novel Method for Improving the Printability of Cement-Based Materials:
Controlling the Releasing of Capsules Containing Chemical Admixtures - Souza Marcelo, Ferreira Igor, Moraes Elisângela, Senff Luciano et al. (2020-09)
3D Printed Concrete for Large-Scale Buildings:
An Overview of Rheology, Printing Parameters, Chemical Admixtures, Reinforcements, and Economic and Environmental Prospects - Souza Marcelo, Ferreira Igor, Moraes Elisângela, Senff Luciano et al. (2021-11)
Role of Chemical Admixtures on 3D Printed Portland Cement:
Assessing Rheology and Buildability - Tao Yaxin, Rahul Attupurathu, Lesage Karel, Yuan Yong et al. (2021-02)
Stiffening Control of Cement-Based Materials Using Accelerators in In-Line Mixing Processes:
Possibilities and Challenges - Vaitkevičius Vitoldas, Šerelis Evaldas, Kerševičius Vidas (2018-03)
Effect of Ultra-Sonic Activation on Early Hydration Process in 3D Concrete Printing Technology - Weng Yiwei, Ruan Shaoqin, Li Mingyang, Mo Liwu et al. (2019-06)
Feasibility Study on Sustainable-Magnesium-Potassium-Phosphate Cement-Paste for 3D Printing - Wolfs Robert, Bos Freek, Salet Theo (2018-06)
Correlation Between Destructive Compression Tests and Non-Destructive Ultrasonic Measurements on Early-Age 3D Printed Concrete - 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 (2019-06)
Triaxial Compression Testing on Early-Age Concrete for Numerical Analysis of 3D Concrete Printing - Yuan Qiang, Xie Zonglin, Yao Hao, Huang Tingjie et al. (2022-06)
Effect of Polyacrylamide on the Workability and Inter-Layer Interface Properties of 3D Printed Cementitious Materials - Zhang Chao, Nerella Venkatesh, Krishna Anurag, Wang Shen et al. (2021-06)
Mix-Design Concepts for 3D Printable Concrete:
A Review
4 Citations
- Xia Kailun, Chen Yuning, Chen Yu, Jia Lutao et al. (2025-04)
Programmable Toughening for 3D Printed Concrete and Architected Cementitious Materials - 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 - Sun Zhaoyang, Zhao Yuyang, Hou Dongshuai, Li Zongjin et al. (2024-11)
Rheology-Control of Cement-Paste by In-Situ Polymerization for 3D Printing Applications - Chajec Adrian, Šavija Branko (2024-09)
The Effect of Using Surface Functionalized Granite-Powder-Waste on Fresh Properties of 3D Printed Cementitious Composites
BibTeX
@article{shao_liu_liu_wang.2024.ANStE3PoCBM,
author = "Lijing Shao and Zhaolong Liu and Qi Liu and Haochuan Wang and Chong Wang and Wei Wang and Jinxiang Hong and Changwen Miao and Pan Feng",
title = "A New Strategy to Enhance 3D Printability of Cement-Based Materials: In-Situ Polymerization",
doi = "10.1016/j.addma.2024.104299",
year = "2024",
journal = "Additive Manufacturing",
volume = "89",
pages = "104299",
}
Formatted Citation
L. Shao, “A New Strategy to Enhance 3D Printability of Cement-Based Materials: In-Situ Polymerization”, Additive Manufacturing, vol. 89, p. 104299, 2024, doi: 10.1016/j.addma.2024.104299.
Shao, Lijing, Zhaolong Liu, Qi Liu, Haochuan Wang, Chong Wang, Wei Wang, Jinxiang Hong, Changwen Miao, and Pan Feng. “A New Strategy to Enhance 3D Printability of Cement-Based Materials: In-Situ Polymerization”. Additive Manufacturing 89 (2024): 104299. https://doi.org/10.1016/j.addma.2024.104299.