Skip to content

Virtual Sliding-Pipe Rheometer for Estimating Pumpability of Concrete (2018-03)

10.1016/j.conbuildmat.2018.03.003

 Nerella Venkatesh,  Mechtcherine Viktor
Journal Article - Construction and Building Materials, Vol. 170, pp. 366-377

Abstract

Predicting the pumping pressure needed to ensure a consistent flow rate of concrete is crucial to the success of current construction processes and newly introduced, but fast-growing 3D-concrete printing techniques. The Sliding Pipe Rheometer (Sliper) has recently proved to be a reliable experimental tool in predicting pumping pressure. Building on the experimental results of an earlier investigation by means of Sliper, a single-fluid numerical model for simulating Sliper tests (virtual Sliper) was developed using Computational Fluid Dynamics (CFD). Various observations as well as numerical limitations of the model and their physical origins were analysed. It was demonstrated that lubricating layer has vital influence on concrete pumping and that single phase numerical models, not considering the lubricating layer are only applicable to some specific concrete compositions. Hence, the initial single-phase model was improved by implementing a separate lubricating layer; its properties were calculated using Chateau-Ovarlez-Trung and Krieger-Dougherty models. Experimental and numerical comparative analyses confirm the validity of the above-mentioned approach in calculating lubricating layer properties. Parameter sensitivity analysis showed that the plastic viscosity and thickness of the lubricating exert the dominant influences on pumping pressure. The virtual pumpability testing tool as developed should enable a more purposeful material design of pumpable concrete and pre-estimation of pumping processes.

3 References

  1. Choi Myoungsung, Roussel Nicolas, Kim Youngjin, Kim Jinkeun (2013-01)
    Lubrication-Layer Properties During Concrete Pumping
  2. Mechtcherine Viktor, Nerella Venkatesh, Kasten Knut (2013-12)
    Testing Pumpability of Concrete Using Sliding-Pipe Rheometer
  3. Secrieru Egor, Fataei Shirin, Schröfl Christof, Mechtcherine Viktor (2017-04)
    Study on Concrete Pumpability Combining Different Laboratory Tools and Linkage to Rheology

39 Citations

  1. Xie Xiangyu, Liu Xuemei, Zhang Nan, Zhang Lihai et al. (2025-09)
    Capillary Extrusion Rheometry for Characterising Wall Slip Behaviour in 3D Printed Concrete
  2. Mishra Sanjeet, Snehal K., Das B., Chandrasekaran Rajasekaran et al. (2025-05)
    From Printing to Performance:
    A Review on 3D Concrete Printing Processes, Materials, and Life Cycle Assessment
  3. Ducoulombier Nicolas, Bono Victor, Kachkouch Fatima, Jacquet Yohan et al. (2025-01)
    From Laboratory to Practice
  4. 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
  5. Liu Chao, Zhang Yukun, Liu Huawei, Wu Yiwen et al. (2024-10)
    Inter-Layer Reinforced 3D Printed Concrete with Recycled Coarse Aggregate:
    Shear Properties and Enhancement Methods
  6. Ibrahim Kamoru, Zijl Gideon, Babafemi Adewumi (2024-08)
    Time-Dependent Behavior of 3D Printed Fiber-Reinforced Limestone-Calcined-Clay-Cement Concrete Under Sustained Loadings
  7. Asghari Y., Mohammadyan-Yasouj S., Petrů M., Ghandvar H. et al. (2024-07)
    3D Printing and Implementation of Engineered Cementitious Composites:
    A Review
  8. Oulkhir Fatima, Akhrif Iatimad, Jai Mostapha (2024-05)
    3D Concrete Printing Success:
    An Exhaustive Diagnosis and Failure-Modes-Analysis
  9. Yang Liuhua, Gao Yang, Chen Hui, Jiao Huazhe et al. (2024-04)
    3D Printing Concrete Technology from a Rheology Perspective:
    A Review
  10. 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
  11. Ahmed Ghafur (2023-01)
    A Review of 3D Concrete Printing:
    Materials and Process Characterization, Economic Considerations and Environmental Sustainability
  12. 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
  13. Boddepalli Uday, Panda Biranchi, Gandhi Indu (2022-09)
    Rheology and Printability of Portland-Cement-Based Materials:
    A Review
  14. Liu Huawei, Liu Chao, Wu Yiwen, Bai Guoliang et al. (2022-09)
    3D Printing Concrete with Recycled Coarse Aggregates:
    The Influence of Pore-Structure on Inter-Layer Adhesion
  15. Ahmed Ghafur, Askandar Nasih, Jumaa Ghazi (2022-07)
    A Review of Large-Scale 3DCP:
    Material-Characteristics, Mix-Design, Printing-Process, and Reinforcement-Strategies
  16. Liu Huawei, Liu Chao, Wu Yiwen, Bai Guoliang et al. (2022-06)
    Hardened Properties of 3D Printed Concrete with Recycled Coarse Aggregate
  17. Liu Huawei, Liu Chao, Bai Guoliang, Wu Yiwen et al. (2022-04)
    Influence of Pore-Defects on the Hardened Properties of 3D Printed Concrete with Coarse Aggregate
  18. Bakar Muhammad, Saude Nasuha, Ibrahim Mustaffa, Ismail Nur (2022-01)
    Additive Manufacturing:
    A Review of Current 3D Concrete Printing on Materials, Methods, Applications, Properties and Challenges
  19. Xie Xiangyu, Zhang Lihai, Shi Caijun, Liu Xuemei (2022-01)
    Prediction of Lubrication-Layer Properties of Pumped Concrete Based on Flow-Induced Particle-Migration
  20. Mechtcherine Viktor, Fataei Shirin, Bos Freek, Buswell Richard et al. (2022-01)
    Digital Fabrication with Cement-Based Materials:
    Underlying Physics
  21. Tavangar Tooran, Hosseinpoor Masoud, Yahia Ammar, Khayat Kamal (2021-12)
    Novel Tri-Viscous-Model to Simulate Pumping of Flowable Concrete Through Characterization of Lubrication-Layer and Plug-Zones
  22. Xu Zhisong, Li Zhuguo, Jiang Fei (2021-11)
    Numerical Approach to Pipe Flow of Fresh Concrete Based on MPS Method
  23. 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
  24. 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
  25. Liu Yu, Jing Rui, Cao Fengze, Yan Peiyu (2021-11)
    Effects of Aggregate Content on Rheological Properties of Lubrication-Layer and Pumping Concrete
  26. Tavangar Tooran, Hosseinpoor Masoud, Yahia Ammar, Khayat Kamal (2021-11)
    Computational Investigation of Concrete-Pipe-Flow:
    Critical Review
  27. 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
  28. Shen Wenkai, Shi Caijun, Khayat Kamal, Yuan Qiang et al. (2021-06)
    Change in Fresh Properties of High-Strength Concrete Due to Pumping
  29. Xiao Jianzhuang, Ji Guangchao, Zhang Yamei, Ma Guowei et al. (2021-06)
    Large-Scale 3D Printing Concrete Technology:
    Current Status and Future Opportunities
  30. Mohan Manu, Rahul Attupurathu, Tittelboom Kim, Schutter Geert (2020-10)
    Rheological and Pumping Behavior of 3D Printable Cementitious Materials with Varying Aggregate Content
  31. He Lewei, Chow Wai, Li Hua (2020-06)
    Effects of Inter-Layer Notch and Shear Stress on Inter-Layer Strength of 3D Printed Cement-Paste
  32. Roussel Nicolas, Spangenberg Jon, Wallevik Jon, Wolfs Robert (2020-06)
    Numerical Simulations of Concrete Processing:
    From Standard Formative Casting to Additive Manufacturing
  33. Li Victor, Bos Freek, Yu Kequan, McGee Wesley et al. (2020-04)
    On the Emergence of 3D Printable Engineered, Strain-Hardening Cementitious Composites
  34. Mechtcherine Viktor, Bos Freek, Perrot Arnaud, Silva Wilson et al. (2020-03)
    Extrusion-Based Additive Manufacturing with Cement-Based Materials:
    Production Steps, Processes, and Their Underlying Physics
  35. Paolini Alexander, Kollmannsberger Stefan, Rank Ernst (2019-10)
    Additive Manufacturing in Construction:
    A Review on Processes, Applications, and Digital Planning Methods
  36. 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
  37. Nerella Venkatesh, Mechtcherine Viktor (2019-02)
    Studying the Printability of Fresh Concrete for Formwork-Free Concrete Onsite 3D Printing Technology (CONPrint3D)
  38. Nerella Venkatesh, Näther Mathias, Iqbal Arsalan, Butler Marko et al. (2018-09)
    In-Line Quantification of Extrudability of Cementitious Materials for Digital Construction
  39. Wolfs Robert, Bos Freek, Salet Theo (2018-06)
    Correlation Between Destructive Compression Tests and Non-Destructive Ultrasonic Measurements on Early-Age 3D Printed Concrete

BibTeX 
@article{nere_mech.2018.VSPRfEPoC,
  author            = "Venkatesh Naidu Nerella and Viktor Mechtcherine",
  title             = "Virtual Sliding-Pipe Rheometer for Estimating Pumpability of Concrete",
  doi               = "10.1016/j.conbuildmat.2018.03.003",
  year              = "2018",
  journal           = "Construction and Building Materials",
  volume            = "170",
  pages             = "366--377",
}
Formatted Citation

V. N. Nerella and V. Mechtcherine, “Virtual Sliding-Pipe Rheometer for Estimating Pumpability of Concrete”, Construction and Building Materials, vol. 170, pp. 366–377, 2018, doi: 10.1016/j.conbuildmat.2018.03.003.

Nerella, Venkatesh Naidu, and Viktor Mechtcherine. “Virtual Sliding-Pipe Rheometer for Estimating Pumpability of Concrete”. Construction and Building Materials 170 (2018): 366–77. https://doi.org/10.1016/j.conbuildmat.2018.03.003.