Skip to content

A Desorptivity-Based Approach for the Assessment of Phase Separation During Extrusion of Cementitious Materials (2020-01)

10.1016/j.cemconcomp.2020.103546

 Rahul Attupurathu, Sharma Abhishek,  Santhanam Manu
Journal Article - Cement and Concrete Composites, Vol. 108

Abstract

A critical criterion for the extrusion of cementitious materials is that the mix used must remain stable and homogeneous without undergoing phase separation. Therefore, it is important to have an assessment of water retention capacity of mortars to be used for such purposes. Although there are empirical methods like bleed test (ASTM C1741 – 18 [1]), these methods are single-point measurements, i.e., conducted at a single pressure value for a fixed amount of time. In the current approach, desorptivity is used as a fundamental material parameter to evaluate the water retaining capability of different cement mortars. Desorptivity values were obtained at different constant pressures to obtain a desorptivity-pressure relationship. The influence of various factors on desorptivity such as the addition of superplasticizer, the addition of water retaining admixtures like hydroxypropyl methylcellulose (HPMC), particle packing density, and water content were examined. Finally, the different mixes were examined for phase separation by using a piston-pump-based system. Based on the maximum pressure applied in the piston pump, an index was proposed that distinguishes the mortars with the required water retention capability for the extrusion process.

4 References

  1. Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
    3D Printing Using Concrete-Extrusion:
    A Roadmap for Research
  2. Le Thanh, Austin Simon, Lim Sungwoo, Buswell Richard et al. (2012-01)
    Mix-Design and Fresh Properties for High-Performance Printing Concrete
  3. Perrot Arnaud, Rangeard Damien, Nerella Venkatesh, Mechtcherine Viktor (2019-02)
    Extrusion of Cement-Based Materials:
    An Overview
  4. Rahul Attupurathu, Santhanam Manu, Meena Hitesh, Ghani Zimam (2018-12)
    3D Printable Concrete:
    Mixture-Design and Test-Methods

54 Citations

  1. Li Haodao, Khayat Kamal (2026-04)
    Extrusion-Based 3D Printing of Fiber-Reinforced Concrete
  2. Das Souvik, Lee Jonathan, Wei Jianqiang (2026-02)
    Tailoring Ultra-High Performance Concrete for Additive Manufacturing:
    Synergistic Roles of Superplasticizer and Viscosity-Modifying Admixture in Printability and Performance
  3. Ahmed Nishad, Sarkar Sudipto, Ashraf Warda (2026-02)
    Rheological and Mechanical Properties of Carbon-Negative 3D Printed Mortar Using Functionalized Biochar
  4. Garshasbi Sajad, Mousavi Seyed, Nazarpour Hadi, Dehestani Mehdi (2026-02)
    Low Carbon Dioxide 3D Printable Concrete:
    Balancing Rheology, Strength and Environmental Impact Using Bentonite and Ground Granulated Blast-Furnace Slag
  5. Dey Dhrutiman, Panda Biranchi, Kole Jagabandhu (2026-02)
    Investigation into the Effect of Full Replacement with Portland Slag Cement and Screened Slag Sand for Development of Sustainable 3D Printed Concrete
  6. Patel Aniket, Santhanam Manu (2026-01)
    Rheological and Fresh-State Characterization for 3D-Printable Concrete:
    Evaluating Printability Across Different Binder Systems
  7. Murali Gunasekaran, Kravchenko Ekaterina, Yuvaraj Divya, Avudaiappan Siva (2025-12)
    Next-Generation Green Construction:
    3D-Printed Geopolymer Concrete with Optimized Rheology, Mechanical Performance, and Environmental Efficiency
  8. Yang Xia, Wang Jiuyuan, Huang Han, Wu Gengchen et al. (2025-08)
    Anti-Washout Cement-Based Material for Under-Seawater 3D Concrete Printing:
    Design, Mechanical Properties and Microstructural Analysis
  9. Patel Abhishek, Raphael Benny (2025-07)
    Reducing Carbon Emissions in 3D Printed RCC Slabs
  10. Girskas Giedrius, Kligys Modestas (2025-06)
    3D Concrete Printing Review:
    Equipment, Materials, Mix Design, and Properties
  11. Tran Mien, Le Thanh, Cao Nguyen, Nguyen Thi (2025-03)
    Sustainable Prospect for Entire Replacement of River Sand with Recycled Glass Aggregate in 3D Printing Concrete:
    Rheological Properties, Printability, and Alkali-Silica Reaction
  12. Aktürk Büşra, Ertuğrul Onur, Özen Ömer, Oktay Didem et al. (2025-03)
    Influence of Nano-Silica and R-MgO on Rheological Properties, 3D Printability, and Mechanical Properties of One-Part Sodium Carbonate-Activated Slag-Based Mixes
  13. Araújo Rísia, Martinelli Antônio, Cabral Kleber, Nunes Ueslei et al. (2025-03)
    Effect of Lightweight Expanded Clay Aggregate (LECA) On the Printability of Cementitious Compositions for 3D Printing
  14. Sakhare Vishakha, Najar Mohamed, Deshpande Sachin (2024-12)
    Printing Performance of 3D Printed Geopolymer Through Pumpability, Extrudability, Buildability Properties:
    A Review
  15. Tarhan Yeşim, Tarhan İsmail, Şahin Remzi (2024-12)
    Comprehensive Review of Binder Matrices in 3D Printing Construction:
    Rheological Perspectives
  16. Gurunandan M., Mala Hiranya, Nanthagopalan Prakash (2024-12)
    Effect of Water-to-Binder, Aggregate-to-Binder-Ratio and Admixtures on Printability and Mechanical Properties of 3D Printable Mortar Mixtures
  17. Dams Barrie, Chen Binling, Kaya Yusuf, Shepherd Paul et al. (2024-11)
    The Rise of Aerial Additive Manufacturing in Construction:
    A Review of Material Advancements
  18. Over Derya, Ozbakan Nesil, Bustani Mehmet, Karali Bulut (2024-10)
    An Investigation of Rheological Properties and Sustainability of Various 3D Printing Concrete Mixtures with Alternative Binders and Rheological Modifiers
  19. Bhattacherjee Shantanu, Jain Smrati, Santhanam Manu (2024-07)
    Investigating the Interaction of Limestone-Calcined-Clay and OPC-Based Systems with a Methylhydroxyethyl-Cellulose-Based Viscosity-Modifier Used for 3D Printable Concrete
  20. Aslani Farhad, Zhang Yifan (2024-06)
    Sustainable 3D Printed Concrete Structures Using High-Quality Secondary Raw Materials
  21. Ghaffar Seyed, Noaimat Yazeed, Chougan Mehdi, Kheetan Mazen (2024-06)
    Emerging Resources for the Development of Low-Carbon Cementitious Composites for 3D Printing Applications
  22. Li Haodao, Wei Jingjie, Khayat Kamal (2024-06)
    3D Printing of Fiber-Reinforced Calcined Clay-Limestone-Based Cementitious Materials:
    From Mixture Design to Printability Evaluation
  23. Khan Mehran, McNally Ciaran (2024-05)
    Recent Developments on Low-Carbon 3D Printing Concrete:
    Revolutionizing Construction Through Innovative Technology
  24. Patel Abhishek, Raphael Benny (2024-04)
    Robotic 3D Printing of Structural Slabs Using Polyethylene Waste as Filler to Reduce Carbon Footprint
  25. Vallurupalli Kavya, Libre Nicolas, Khayat Kamal (2024-04)
    Characterization of Extrudability Using Rheology and Desorptivity
  26. Zhu Binrong, Wang Yufei, Sun Junbo, Wei Yang et al. (2023-10)
    An Experimental Study on the Influence of Waste-Rubber-Particles on the Compressive, Flexural and Impact Properties of 3D Printable Sustainable Cementitious Composites
  27. Mani Aravindhraj, Muthukumar S., Sathyanarayanan K. (2023-08)
    Use of Alccofine 1203 as a Sustainable Supplementary Cementitious Material for Printable Concrete
  28. Zhu Lingli, Zhang Meng, Zhang Yaqi, Yao Jie et al. (2023-07)
    Research Progress on Shrinkage Properties of Extruded 3D Printed Cement-Based Materials
  29. Tu Haidong, Wei Zhenyun, Bahrami Alireza, Kahla Nabil et al. (2023-06)
    Recent Advancements and Future Trends in 3D Printing Concrete Using Waste-Materials
  30. Singh Narinder, Colangelo Francesco, Farina Ilenia (2023-06)
    Sustainable Non-Conventional Concrete 3D Printing:
    A Review
  31. Chen Yu, Zhang Yu, He Shan, Liang Xuhui et al. (2023-06)
    Improving Structural Build-Up of Limestone-Calcined-Clay-Cement-Pastes by Using Inorganic Additives
  32. Tamimi Adil, Alqamish Habib, Khaldoune Ahlam, Alhaidary Haidar et al. (2023-03)
    Framework of 3D Concrete Printing Potential and Challenges
  33. Fonseca Mariana, Matos Ana (2023-03)
    3D Construction Printing Standing for Sustainability and Circularity:
    Material-Level Opportunities
  34. Pasupathy Kirubajiny, Ramakrishnan Sayanthan, Sanjayan Jay (2023-01)
    3D Concrete Printing of Eco-Friendly Geopolymer Containing Brick Waste
  35. Uddin Md (2022-12)
    Influence of 3D Printable Sustainable Concrete and Industrial Waste on Industry 5.0
  36. Bhattacherjee Shantanu, Jain Smrati, Santhanam Manu (2022-11)
    Criticality of Binder-Aggregate Interaction for Buildability of 3D Printed Concrete Containing Limestone-Calcined-Clay
  37. Boddepalli Uday, Panda Biranchi, Gandhi Indu (2022-09)
    Rheology and Printability of Portland-Cement-Based Materials:
    A Review
  38. Ma Lei, Zhang Qing, Lombois-Burger Hélène, Jia Zijian et al. (2022-09)
    Pore-Structure, Internal Relative Humidity, and Fiber-Orientation of 3D Printed Concrete with Polypropylene-Fiber and Their Relation with Shrinkage
  39. Jayathilakage Roshan, Rajeev Pathmanathan, Sanjayan Jay (2022-08)
    Rheometry for Concrete 3D Printing:
    A Review and an Experimental Comparison
  40. Bhattacherjee Shantanu, Jain Smrati, Santhanam Manu (2022-06)
    Criticality of Microstructural Evolution at an Early-Age on the Buildability of an Accelerated 3D Printable Concrete
  41. Bhattacherjee Shantanu, Santhanam Manu (2022-04)
    Investigation on the Effect of Alkali-Free Aluminium Sulfate-Based Accelerator on the Fresh Properties of 3D Printable Concrete
  42. Mohan Manu, Rahul Attupurathu, Dam Benjamin, Zeidan Talina et al. (2022-02)
    Performance Criteria, Environmental Impact and Cost-Assessment for 3D Printable Concrete Mixtures
  43. Zhong Hui, Zhang Mingzhong (2022-02)
    3D Printing Geopolymers:
    A Review
  44. Dey Dhrutiman, Srinivas Dodda, Panda Biranchi, Suraneni Prannoy et al. (2022-02)
    Use of Industrial Waste-Materials for 3D Printing of Sustainable Concrete:
    A Review
  45. Amran Mugahed, Abdelgader Hakim, Onaizi Ali, Fediuk Roman et al. (2021-12)
    3D Printable Alkali-Activated Concretes for Building Applications:
    A Critical Review
  46. 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
  47. Rahul Attupurathu, Mohan Manu, Schutter Geert, Tittelboom Kim (2021-10)
    3D Printable Concrete with Natural and Recycled Coarse Aggregates:
    Rheological, Mechanical and Shrinkage Behavior
  48. Chen Yu, He Shan, Zhang Yu, Wan Zhi et al. (2021-08)
    3D Printing of Calcined-Clay-Limestone-Based Cementitious Materials
  49. Bhattacherjee Shantanu, Basavaraj Anusha, Rahul Attupurathu, Santhanam Manu et al. (2021-06)
    Sustainable Materials for 3D Concrete Printing
  50. Tarhan Yeşim, Şahin Remzi (2021-05)
    Fresh and Rheological Performances of Air-Entrained 3D Printable Mortars
  51. Mohan Manu, Rahul Attupurathu, Schutter Geert, Tittelboom Kim (2021-01)
    Early-Age Hydration, Rheology and Pumping Characteristics of CSA Cement-Based 3D Printable Concrete
  52. Mohan Manu, Rahul Attupurathu, Schutter Geert, Tittelboom Kim (2020-10)
    Extrusion-Based Concrete 3D Printing from a Material Perspective:
    A State of the Art Review
  53. Mohan Manu, Rahul Attupurathu, Tittelboom Kim, Schutter Geert (2020-10)
    Rheological and Pumping Behavior of 3D Printable Cementitious Materials with Varying Aggregate Content
  54. Rahul Attupurathu, Santhanam Manu (2020-02)
    Evaluating the Printability of Concretes Containing Lightweight Coarse Aggregates

BibTeX 
@article{rahu_shar_sant.2020.ADBAftAoPSDEoCM,
  author            = "Attupurathu Vijayan Rahul and Abhishek Sharma and Manu Santhanam",
  title             = "A Desorptivity-Based Approach for the Assessment of Phase Separation During Extrusion of Cementitious Materials",
  doi               = "10.1016/j.cemconcomp.2020.103546",
  year              = "2020",
  journal           = "Cement and Concrete Composites",
  volume            = "108",
}
Formatted Citation

A. V. Rahul, A. Sharma and M. Santhanam, “A Desorptivity-Based Approach for the Assessment of Phase Separation During Extrusion of Cementitious Materials”, Cement and Concrete Composites, vol. 108, 2020, doi: 10.1016/j.cemconcomp.2020.103546.

Rahul, Attupurathu Vijayan, Abhishek Sharma, and Manu Santhanam. “A Desorptivity-Based Approach for the Assessment of Phase Separation During Extrusion of Cementitious Materials”. Cement and Concrete Composites 108 (2020). https://doi.org/10.1016/j.cemconcomp.2020.103546.