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Effects of Nozzle Height on the Layer Deposition Process and Forming Performance of 3D Printing Concrete (2026-03)

Evidence from Experiments and CFD Simulations

10.1016/j.conbuildmat.2026.146115

 Wang Qingwei,  Pan Jinlong,  Han Song,  Zhu Binrong, Ye Huzi
Journal Article - Construction and Building Materials, Vol. 521, No. 146115

Abstract

In extrusion-based 3D printing concrete, nozzle height directly governs filament shape, internal stress distribution, and stacking stability. This study examines how varying nozzle height affects filament cross-section, deposition dynamics, and interlayer bonding. Combining experiments with computational fluid dynamics, a set of descriptors including cross-sectional area, aspect ratio, settlement ratio, coefficient of variation, and the height-to-nozzle-diameter ratio are introduced to systematically characterize filament cross-sections formed during extrusion layer deposition from single to multilayer stacking. The results show that increasing nozzle height alters filament shape, modifies the magnitude and duration of transient impact forces during deposition, reshapes the stress distribution at the interlayer interface, and reduces splitting tensile strength, following a Logistic relationship with a dimensionless impact indicator. Mechanistically, a higher nozzle reduces peak transient forces but prolongs their duration, causing irreversible settlement of underlying layers. These findings reveal the critical mechanistic role of nozzle height in controlling deposition behavior and interlayer bonding, and suggest a height-to-diameter ratio of 0.5–0.7 for circular nozzles to optimize filament shape consistency, stress symmetry, and bonding quality. These findings provide a basis for developing a parameter ranges and quality control methods that are independent of nozzle size.

38 References

  1. Chen Wei, Guan Yongying, Zhu Binrong, Han Jinsheng et al. (2025-01)
    Influence of Extruded Strip-Shape and Dimension on the Mechanical Properties and Pore-Characteristics of 3D Printed Geopolymer Concrete
  2. Duan Jiaqi, Sun Shouzheng, Chi Shengfeng, Hu Chunyou et al. (2024-06)
    Effect of Process Parameters on Forming Quality and Flexural Strength of Continuous-Fiber-Reinforced Cement-Based 3D Printed Composites
  3. Huang Xin, Yang Weihao, Song Fangnian, Zou Jiuqun (2022-04)
    Study on the Mechanical Properties of 3D Printing Concrete Layers and the Mechanism of Influence of Printing Parameters
  4. İlcan Hüseyin, Özkılıç Hamza, Tuğluca Merve, Şahmaran Mustafa (2024-02)
    Inter-Layer Mechanical Performance of 3D Printed Cementitious Systems:
    A Comprehensive Study on Operational and Material Parameters
  5. Kruger Jacques, Cho Seung, Zeranka Stephan, Vintila Cristian et al. (2019-12)
    3D Concrete Printer Parameter Optimization for High-Rate Digital Construction Avoiding Plastic Collapse
  6. Kruger Jacques, Zeranka Stephan, Zijl Gideon (2019-07)
    3D Concrete Printing:
    A Lower-Bound Analytical Model for Buildability-Performance-Quantification
  7. Lachmayer Lukas, Böhler David, Freund Niklas, Mai (née Dressler) Inka et al. (2022-11)
    Modelling the Influence of Material and Process Parameters on Shotcrete 3D Printed Strands:
    Cross-Section Adjustment for Automatic Robotic Manufacturing
  8. Le Thanh, Austin Simon, Lim Sungwoo, Buswell Richard et al. (2012-01)
    Mix-Design and Fresh Properties for High-Performance Printing Concrete
  9. Li Shuai, Nguyen-Xuan Hung, Tran Jonathan (2022-11)
    Digital Design and Parametric Study of 3D Concrete Printing on Non-Planar Surfaces
  10. Liu Xiongfei, Cai Huachong, Ma Guowei, Hou Guanyu (2024-01)
    Spray-Based 3D Concrete Printing-Parameter Design-Model:
    Actionable Insight for High Printing Quality
  11. 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
  12. Liu Chao, Xiong Yuanliang, Chen Yuning, Jia Lutao et al. (2022-01)
    Effect of Sulphoaluminate Cement on Fresh and Hardened Properties of 3D Printing Foamed Concrete
  13. Liu Dawei, Zhang Zhigang, Zhang Xiaoyue, Chen Zhaohui (2023-09)
    3D Printing Concrete Structures:
    State of the Art, Challenges, and Opportunities
  14. Miranda Luiza, Jovanović Balša, Lesage Karel, Schutter Geert (2023-10)
    Geometric Conformability of 3D Concrete Printing Mixtures from a Rheological Perspective
  15. Nair Sooraj, Panda Subhashree, Santhanam Manu, Sant Gaurav et al. (2020-05)
    A Critical Examination of the Influence of Material-Characteristics and Extruder-Geometry on 3D Printing of Cementitious Binders
  16. 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
  17. Nair Sooraj, Tripathi Avinaya, Neithalath Narayanan (2023-11)
    Constitutive Response and Failure Progression in Digitally Fabricated 3D Printed Concrete Under Compression and Their Dependence on Print Layer-Height
  18. Nerella Venkatesh, Krause Martin, Mechtcherine Viktor (2019-11)
    Direct Printing-Test for Buildability of 3D Printable Concrete Considering Economic Viability
  19. Pan Tinghong, Guo Rongxin, Jiang Yaqing, Ji Xuping (2022-07)
    How Do the Contact Surface Forces Affect the Inter-Layer Bond Strength of 3D Printed Mortar?
  20. Pan Tinghong, Jiang Yaqing, Ji Xuping (2022-03)
    Inter-Layer Bonding Investigation of 3D Printing Cementitious Materials with Fluidity-Retaining Polycarboxylate-Superplasticizer and High-Dispersion Polycarboxylate Superplasticizer
  21. Perrot Arnaud, Rangeard Damien, Pierre Alexandre (2015-02)
    Structural Build-Up of Cement-Based Materials Used for 3D Printing-Extrusion-Techniques
  22. Rizzieri Giacomo, Meni Simone, Cremonesi Massimiliano, Ferrara Liberato (2025-07)
    A Particle Finite Element Method for Investigating the Influence of Material and Process Parameters in 3D Concrete Printing
  23. Suiker Akke (2021-11)
    Effect of Accelerated Curing and Layer Deformations on Structural Failure During Extrusion-Based 3D Printing
  24. Suiker Akke, Wolfs Robert, Lucas Sandra, Salet Theo (2020-06)
    Elastic Buckling and Plastic Collapse During 3D Concrete Printing
  25. Tran Mien, Ly Duy-Khuong, Nguyen Tan, Tran Nhi (2024-05)
    Robust Prediction of Workability Properties for 3D Printing with Steel-Slag-Aggregate Using Bayesian Regularization and Evolution Algorithm
  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 Qingwei, Han Song, Yang Junhao, Li Ziang et al. (2024-11)
    Optimizing Printing and Rheological Parameters for 3D Printing with Cementitious Materials
  28. Wang Qing, Ren Xiaodan, Li Jie (2023-08)
    Damage-Rheology Model for Predicting 3D Printed Concrete Buildability
  29. Wei Ying, Han Song, Yu Shiwei, Chen Ziwei et al. (2024-05)
    Parameter Impact on 3D Concrete Printing from Single to Multi-Layer Stacking
  30. Weng Yiwei, Li Mingyang, Wong Teck, Tan Ming (2021-01)
    Synchronized Concrete and Bonding-Agent-Deposition-System for Inter-Layer Bond Strength Enhancement in 3D Concrete Printing
  31. Xu Bin, Sun Zhaoyang, Sun Ming, Chen Binmeng (2025-09)
    Realizing Rheological Manipulation by Adjusting Initiator Concentrations for In-Situ Polymerization:
    Towards 3D Concrete Printing Applications
  32. Yan Yufei, Zhang Mo, Ma Guowei, Sanjayan Jay (2024-05)
    Enhancing Inter-Layer Bonding Strength of 3D Printed Ternary Geopolymer Using Calcium-Carbonate-Whiskers Spray
  33. Yao Weijing, Gao Yangyunzhi, Huang Xin, Du Hongjian (2025-08)
    Influence of Printing Speed and Extrusion Speed on the Performance and Pore Structures of 3D Printed Mortar
  34. Yin Yunchao, Huang Jian, Wang Tiezhu, Yang Rong et al. (2023-09)
    Effect of Hydroxypropyl-Methylcellulose on Rheology and Printability of the First Printed Layer of Cement Activated Slag-Based 3D Printing Concrete
  35. Zeng Jun-Jie, Hu Xianwen, Sun Hou-Qi, Liu Yue et al. (2024-10)
    Triaxial Compressive Behavior of 3D Printed PE-Fiber-Reinforced Ultra-High-Performance Concrete
  36. Zhang Nan, Sanjayan Jay (2023-01)
    Extrusion Nozzle Design and Print Parameter Selections for 3D Concrete Printing
  37. Zhou Wen, Zhang Yamei, Ma Lei, Li Victor (2022-04)
    Influence of Printing Parameters on 3D Printing Engineered Cementitious Composites
  38. Zuo Zibo, Huang Yulin, Corte Wouter (2025-06)
    Real-Time Monitoring of Printed Concrete Weight During 3D Concrete Printing to Inversely Assess Process Stability:
    Indicators and Experiments

0 Citations

BibTeX 
@article{wang_pan_han_zhu.2026.EoNHotLDPaFPo3PC,
  author            = "Qingwei Wang and Jinlong Pan and Song Han and Binrong Zhu and Huzi Ye",
  title             = "Effects of Nozzle Height on the Layer Deposition Process and Forming Performance of 3D Printing Concrete: Evidence from Experiments and CFD Simulations",
  doi               = "10.1016/j.conbuildmat.2026.146115",
  year              = "2026",
  journal           = "Construction and Building Materials",
  volume            = "521",
  pages             = "146115",
}
Formatted Citation

Q. Wang, J. Pan, S. Han, B. Zhu and H. Ye, “Effects of Nozzle Height on the Layer Deposition Process and Forming Performance of 3D Printing Concrete: Evidence from Experiments and CFD Simulations”, Construction and Building Materials, vol. 521, p. 146115, 2026, doi: 10.1016/j.conbuildmat.2026.146115.

Wang, Qingwei, Jinlong Pan, Song Han, Binrong Zhu, and Huzi Ye. “Effects of Nozzle Height on the Layer Deposition Process and Forming Performance of 3D Printing Concrete: Evidence from Experiments and CFD Simulations”. Construction and Building Materials 521 (2026): 146115. https://doi.org/10.1016/j.conbuildmat.2026.146115.