Skip to content

Modifying Effect of Anionic Polyacrylamide Dose for Cement-Based 3DP Materials (2022-03)

Printability and Mechanical Performance Tests

10.1016/j.conbuildmat.2022.127156

Liu Qiang,  Jiang Quan, Huang Mojia, Xin Jie, Chen Pengfei, Wu Si
Journal Article - Construction and Building Materials, Vol. 330

Abstract

Cement-based materials have been broadly applied as constructional materials in 3D printing (3DP) civil engineering due to their high mechanical strength, yet their non-ideal performance in ductile and compaction during the printing process always limits their further application. To improve the buildability and antisettling capability of 3D printing materials, a new cement-based 3DP material is proposed by partly replacing traditional hydroxypropyl methyl cellulose (HPMC) with anionic polyacrylamide (APAM). To compare the modifying effect of APAM to that of the cement-based 3DP (APAM-3DP) material, the printability, physical–mechanical performance of APAM-3DP material are tested, and the corresponding microstructural characteristics of mortars with different replacement ratios are analysed. The experimental results show that under the same dosage, APAM can reduce the fluidity of cement-based materials, shorten the setting time and slow down the hydration process compared with HPMC. Addition of the appropriate amount of APAM can improve the buildability of cementbased materials by 57 % and the compressive strength of the samples is increased by 7.7%, but the deformation rate is also doubled. When the APAM dosage is appropriate the samples were more prone to brittle failure and overall failure, if the APAM dosage is too large, the sample is prone to ductile failure and local failure. The modification mechanism of APAM was also analyzed from the microscopic pore characteristics and the morphology of hydration products of the samples.

20 References

  1. Al-Qutaifi Sarah, Nazari Ali, Bagheri Ali (2018-07)
    Mechanical Properties of Layered Geopolymer Structures Applicable in Concrete 3D Printing
  2. Bessaies-Bey Hela, Baumann Robert, Schmitz Marc, Radler Michael et al. (2015-05)
    Effect of Polyacrylamide on Rheology of Fresh Cement-Pastes
  3. 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
  4. Chen Mingxu, Li Laibo, Wang Jiaao, Huang Yongbo et al. (2019-10)
    Rheological Parameters and Building Time of 3D Printing Sulphoaluminate-Cement-Paste Modified by Retarder and Diatomite
  5. Ding Zhu, Wang Xiaodong, Sanjayan Jay, Zou Patrick et al. (2018-11)
    A Feasibility Study on HPMC-Improved Sulphoaluminate Cement for 3D Printing
  6. Guo Xiaolu, Yang Junyi, Xiong Guiyan (2020-09)
    Influence of Supplementary Cementitious Materials on Rheological Properties of 3D Printed Fly-Ash-Based Geopolymer
  7. Hou Shaodan, Duan Zhenhua, Xiao Jianzhuang, Ye Jun (2020-12)
    A Review of 3D Printed Concrete:
    Performance-Requirements, Testing Measurements and Mix-Design
  8. Hou Shaodan, Xiao Jianzhuang, Duan Zhenhua, Ma Guowei (2021-10)
    Fresh Properties of 3D Printed Mortar with Recycled Powder
  9. Khan Mohammad, Sanchez Florence, Zhou Hongyu (2020-04)
    3D Printing of Concrete:
    Beyond Horizons
  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. Muthukrishnan Shravan, Ramakrishnan Sayanthan, Sanjayan Jay (2021-06)
    Technologies for Improving Buildability in 3D Concrete Printing
  12. Panda Biranchi, Unluer Cise, Tan Ming (2018-10)
    Investigation of the Rheology and Strength of Geopolymer Mixtures for Extrusion-Based 3D Printing
  13. Perrot Arnaud, Rangeard Damien, Courteille Eric (2018-04)
    3D Printing of Earth-Based Materials:
    Processing Aspects
  14. Perrot Arnaud, Rangeard Damien, Pierre Alexandre (2015-02)
    Structural Build-Up of Cement-Based Materials Used for 3D Printing-Extrusion-Techniques
  15. Xiao Jianzhuang, Liu Haoran, Ding Tao (2020-11)
    Finite-Element-Analysis on the Anisotropic Behavior of 3D Printed Concrete under Compression and Flexure
  16. Yu Shiwei, Du Hongjian, Sanjayan Jay (2020-07)
    Aggregate-Bed 3D Concrete Printing with Cement-Paste Binder
  17. Yuan Qiang, Zhou Dajun, Huang Hai, Peng Jianwei et al. (2020-06)
    Structural Build-Up, Hydration and Strength Development of Cement-Based Materials with Accelerators
  18. Zhang Yi, Jiang Zhengwu, Zhu Yanmei, Zhang Jie et al. (2020-10)
    Effects of Redispersible Polymer-Powders on the Structural Build-Up of 3D Printing Cement Paste with and without Hydroxypropyl-Methylcellulose
  19. Zhao Zhihui, Chen Mingxu, Xu Jiabin, Li Laibo et al. (2021-03)
    Mix-Design and Rheological Properties of Magnesium-Potassium-Phosphate Cement Composites Based on the 3D Printing-Extrusion-System
  20. Zhu Binrong, Nematollahi Behzad, Pan Jinlong, Zhang Yang et al. (2021-04)
    3D Concrete Printing of Permanent Formwork for Concrete Column Construction

18 Citations

  1. Tulliani Jean-Marc (2025-11)
    Latest Developments in 3D-Printed Engineered Cementitious Composites:
    Technologies, Prospects, and Challenges
  2. Lu Chenyu, Sun Dongpu, Shen Qiang, Zhang Zhigang et al. (2025-07)
    Buildability of 3D Printing Engineered Cementitious Composites (ECC):
    A Comprehensive Assessment Framework Under Laboratory Conditions
  3. Liu Qiang, Zhang Xinwei, Jiang Quan, Xia Yong et al. (2025-07)
    Effects of Nano-Al2O3, Nano-MgO and Nano-Fe2O3 on the Properties of Cement-Based 3D Printing:
    A Comparative Study
  4. Liu Shun, Yang Xiaobin, Wu Jianing (2025-06)
    Damage Evolution Analysis of Cement-Based 3D Printing Similar Materials Under Different Cyclic Loading-Unloading Conditions
  5. Li Hualong, Shi Ye, Rong Hui, Dai Kaichao (2025-03)
    Effect of Additives on the Performance of 3D-Printing Ultra-High Performance Concrete
  6. Liu Qiang, Jiang Quan, Zhao Herui, Yu Yang et al. (2025-02)
    Porous Diatomite Promotes Lightweight and Low-Carbon Concrete 3D Printing:
    An Exploratory Study
  7. Lori Ali, Mehrali Mehdi (2024-11)
    Mechanical Properties and Crack-Deflection Mechanisms in 3D Printed Porous Geopolymers with Cellular Structures
  8. Liu Bing, Guo Yazhao, Wang Yang, Liu Qizhou et al. (2024-11)
    Study on the Compression Performance of 3D Printing Concrete Permanent Formwork Composite Columns
  9. 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
  10. Zhang Hongping, Duan Shuni, Hu Zhichao, Liu Litao et al. (2024-09)
    Evaluation of Plasticity and Determination of Deformation Index of 3D Printed Composite Cement-Based Materials
  11. Shao Yulong, Yang Jingwei, Kim Jineon, Song Jaejoon et al. (2024-05)
    Microscopic Analysis of Mechanical Anisotropy and Damage-Evolution of 3D Printed Rock-Like Samples Under Uniaxial Compressive Tests
  12. Liu Qiang, Jiang Quan, Yu Rang, Rong Yao et al. (2023-12)
    Extrusion 3D Printing Circular and Horseshoe Tunnel Physical Models:
    A Comparative Study of Deformation and Brittle Failure
  13. Razzaghian Ghadikolaee Mehrdad, Cerro-Prada Elena, Pan Zhu, Korayem Asghar (2023-04)
    Nanomaterials as Promising Additives for High-Performance 3D Printed Concrete:
    A Critical Review
  14. Liu Qiang, Jiang Quan, Zhou Zhenhua, Xin Jie et al. (2023-02)
    The Printable and Hardened Properties of Nano-Calcium Carbonate with Modified Polypropylene-Fibers for Cement-Based 3D Printing
  15. Liu Qiang, Jiang Quan, Huang Mojia, Xin Jie et al. (2022-10)
    The Fresh and Hardened Properties of 3D Printing Cement-Base Materials with Self-Cleaning Nano-TiO2:
    An Exploratory Study
  16. Zhou Wen, McGee Wesley, Zhu He, Gökçe H. et al. (2022-08)
    Time-Dependent Fresh Properties Characterization of 3D Printing Engineered Cementitious Composites:
    On the Evaluation of Buildability
  17. 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
  18. Jiang Quan, Liu Qiang, Wu Si, Zheng Hong et al. (2022-06)
    Modification Effect of Nano-Silica and Polypropylene-Fiber for Extrusion-Based 3D Printing Concrete:
    Printability and Mechanical Anisotropy

BibTeX 
@article{liu_jian_huan_xin.2022.MEoAPDfCB3M,
  author            = "Qiang Liu and Quan Jiang and Mojia Huang and Jie Xin and Pengfei Chen and Si Wu",
  title             = "Modifying Effect of Anionic Polyacrylamide Dose for Cement-Based 3DP Materials: Printability and Mechanical Performance Tests",
  doi               = "10.1016/j.conbuildmat.2022.127156",
  year              = "2022",
  journal           = "Construction and Building Materials",
  volume            = "330",
}
Formatted Citation

Q. Liu, Q. Jiang, M. Huang, J. Xin, P. Chen and S. Wu, “Modifying Effect of Anionic Polyacrylamide Dose for Cement-Based 3DP Materials: Printability and Mechanical Performance Tests”, Construction and Building Materials, vol. 330, 2022, doi: 10.1016/j.conbuildmat.2022.127156.

Liu, Qiang, Quan Jiang, Mojia Huang, Jie Xin, Pengfei Chen, and Si Wu. “Modifying Effect of Anionic Polyacrylamide Dose for Cement-Based 3DP Materials: Printability and Mechanical Performance Tests”. Construction and Building Materials 330 (2022). https://doi.org/10.1016/j.conbuildmat.2022.127156.