Modelling of 3D Concrete Printing Based on SPH Method with the Herschel-Bulkley-Papanastasiou Rheology Model (2025-05)¶
, Qiu Liu-Chao, Chen Song-Gui, Liu Yi, Li Shuo
Journal Article - Engineering Applications of Computational Fluid Mechanics, Vol. 19, Iss. 1
Abstract
A smooth particle hydrodynamic (SPH) method combined with the Herschel–Bulkley-Papanastasiou (HBP) model is proposed to simulate 3D concrete printing (3DCP). HBP model can better resolve the divergence of equivalent viscosity coefficient under small deformation and extend the compatibility of simulation to dilatant and pseudoplastic fluids, so it possesses natural superiority in modelling the 3D printing of cement-based material with visco-plastic rheology behaviour. The HBP-based SPH method considers the influence of the printing parameters including nozzle characteristics and printing-to-extrusion velocity ratio on the cross-sectional geometry of the deposited filament, and its outcomes agree qualitatively well with the experiment results. Furthermore, by utilising process parameters furnished by simulation cases, it is possible to determine the critical conditions under which filaments printed by different nozzle shapes are vulnerable to tearing, and the corresponding critical intervals when tearing occurs are also defined. 3DPC experiments verify these findings and confirm that SPH simulation provides additional information on the geometric characteristics of single-layer structures, as well as physical quantities that cannot be straightforwardly measured.
¶
34 References
- Abbaoui Khalid, Korachi Issam, Jai Mostapha, Šeta Berin et al. (2024-04)
3D Concrete Printing Using Computational Fluid Dynamics:
Modeling of Material-Extrusion with Slip-Boundaries - Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
3D Printing Using Concrete-Extrusion:
A Roadmap for Research - Cheng Hanbin, Radlińska Aleksandra, Hilman Michael, Liu Feihong et al. (2024-05)
Modeling Concrete-Deposition via 3D Printing Using Reproducing Kernel-Particle-Method - Comminal Raphaël, Silva Wilson, Andersen Thomas, Stang Henrik et al. (2020-10)
Modelling of 3D Concrete Printing Based on Computational Fluid Dynamics - Hassan Amer, Alomayri Thamer, Noaman Mohammed, Zhang Chunwei (2025-01)
3D Printed Concrete for Sustainable Construction:
A Review of Mechanical Properties and Environmental Impact - He Lewei, Tan Jolyn, Chow Wai, Li Hua et al. (2021-11)
Design of Novel Nozzles for Higher Inter-Layer Strength of 3D Printed Cement-Paste - Heever Marchant, Bester Frederick, Kruger Jacques, Zijl Gideon (2021-07)
Mechanical Characterisation for Numerical Simulation of Extrusion-Based 3D Concrete Printing - Jayathilakage Roshan, Rajeev Pathmanathan, Sanjayan Jay (2021-05)
Extrusion Rheometer for 3D Concrete Printing - Lao Wenxin, Li Mingyang, Tjahjowidodo Tegoeh (2020-09)
Variable-Geometry Nozzle for Surface Quality Enhancement in 3D Concrete Printing - Li Zhanzhao, Hojati Maryam, Wu Zhengyu, Piasente Jonathon et al. (2020-07)
Fresh and Hardened Properties of Extrusion-Based 3D Printed Cementitious Materials:
A Review - Liu Zhixin, Li Mingyang, Tay Yi, Weng Yiwei et al. (2020-04)
Rotation-Nozzle and Numerical Simulation of Mass-Distribution at Corners in 3D Cementitious Material-Printing - Ma Guowei, Wang Li (2017-08)
A Critical Review of Preparation Design and Workability Measurement of Concrete Material for Large-Scale 3D Printing - Marchment Taylor, Sanjayan Jay (2019-10)
Mesh Reinforcing Method for 3D Concrete Printing - Mechtcherine Viktor, Nerella Venkatesh, Will Frank, Näther Mathias et al. (2019-08)
Large-Scale Digital Concrete Construction:
CONPrint3D Concept for On-Site, Monolithic 3D Printing - Nguyen Vuong, Li Shuai, Liu Junli, Nguyen Kien et al. (2022-11)
Modelling of 3D Concrete Printing Process:
A Perspective on Material and Structural Simulations - Nguyen Vuong, Panda Biranchi, Zhang Guomin, Nguyen-Xuan Hung et al. (2021-01)
Digital Design Computing and Modelling for 3D Concrete Printing - Paolini Alexander, Kollmannsberger Stefan, Rank Ernst (2019-10)
Additive Manufacturing in Construction:
A Review on Processes, Applications, and Digital Planning Methods - Perrot Arnaud, Pierre Alexandre, Nerella Venkatesh, Wolfs Robert et al. (2021-07)
From Analytical Methods to Numerical Simulations:
A Process Engineering Toolbox for 3D Concrete Printing - Pierre Maxime, Ghabezloo Siavash, Dangla Patrick, Mesnil Romain et al. (2024-09)
Multi-Physics Modelling for Extrusion-Based 3D Printing:
Material, Process and Applications - Plessis Anton, Babafemi Adewumi, Paul Suvash, Panda Biranchi et al. (2020-12)
Biomimicry for 3D Concrete Printing:
A Review and Perspective - Reinold Janis, Gudžulić Vladislav, Meschke Günther (2023-03)
Computational Modeling of Fiber Orientation During 3D Concrete Printing - Roussel Nicolas (2018-05)
Rheological Requirements for Printable Concretes - Shakor Pshtiwan, Nejadi Shami, Paul Gavin (2019-05)
A Study into the Effect of Different Nozzles Shapes and Fiber-Reinforcement in 3D Printed Mortar - 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 - Suiker Akke (2018-01)
Mechanical Performance of Wall Structures in 3D Printing Processes:
Theory, Design Tools and Experiments - Suiker Akke, Wolfs Robert, Lucas Sandra, Salet Theo (2020-06)
Elastic Buckling and Plastic Collapse During 3D Concrete Printing - Tran Mien, Cu Yen, Le Chau (2021-10)
Rheology and Shrinkage of Concrete Using Polypropylene-Fiber for 3D Concrete Printing - Wei Ying, Han Song, Chen Ziwei, Lu Jianxian et al. (2024-04)
Numerical Simulation of 3D Concrete Printing Derived from Printer Head and Printing Process - 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 - Wolfs Robert, Salet Theo, Roussel Nicolas (2021-10)
Filament-Geometry-Control in Extrusion-Based Additive Manufacturing of Concrete:
The Good, the Bad and the Ugly - Xiao Jianzhuang, Liu Haoran, Ding Tao (2020-11)
Finite-Element-Analysis on the Anisotropic Behavior of 3D Printed Concrete under Compression and Flexure - Zareiyan Babak, Khoshnevis Behrokh (2017-06)
Inter-Layer Adhesion and Strength of Structures in Contour Crafting:
Effects of Aggregate-Size, Extrusion-Rate, and Layer-Thickness - Zhi Peng, Wu Yuching, Yang Qianfan, Kong Xiangrui et al. (2022-03)
Effect of Spiral Blade Geometry on 3D Printed Concrete Rheological Properties and Extrudability Using Discrete Event Modeling
0 Citations
BibTeX
@article{wang_qiu_chen_liu.2025.Mo3CPBoSMwtHBPRM,
author = "Yang Wang and Liu-Chao Qiu and Song-Gui Chen and Yi Liu and Shuo Li",
title = "Modelling of 3D Concrete Printing Based on SPH Method with the Herschel-Bulkley-Papanastasiou Rheology Model",
doi = "10.1080/19942060.2025.2498359",
year = "2025",
journal = "Engineering Applications of Computational Fluid Mechanics",
volume = "19",
number = "1",
}
Formatted Citation
Y. Wang, L.-C. Qiu, S.-G. Chen, Y. Liu and S. Li, “Modelling of 3D Concrete Printing Based on SPH Method with the Herschel-Bulkley-Papanastasiou Rheology Model”, Engineering Applications of Computational Fluid Mechanics, vol. 19, no. 1, 2025, doi: 10.1080/19942060.2025.2498359.
Wang, Yang, Liu-Chao Qiu, Song-Gui Chen, Yi Liu, and Shuo Li. “Modelling of 3D Concrete Printing Based on SPH Method with the Herschel-Bulkley-Papanastasiou Rheology Model”. Engineering Applications of Computational Fluid Mechanics 19, no. 1 (2025). https://doi.org/10.1080/19942060.2025.2498359.