Skip to content

Lightweight Concrete 3D Printing by Selective Cement-Activation (2020-07)

Investigation of Thermal Conductivity, Strength and Water-Distribution

10.1007/978-3-030-49916-7_17

 Weger Daniel,  Kim Heejeong,  Talke Daniel,  Henke Klaudius,  Kränkel Thomas,  Gehlen Christoph
Contribution - Proceedings of the 2nd RILEM International Conference on Concrete and Digital Fabrication, pp. 162-171

Abstract

The 3D printing technology Selective Cement Activation (SCA) is a particle-bed-based additive manufacturing method in which a dry mixture of sand and cement is spread in thin layers and solidified with water. SCA allows the production of complex and high-resolution components without the necessity for additional support structures. One drawback of concrete 3D-printing for free formed facade elements has been the need for additional thermal insulation to fulfil relevant building requirements. This causes an additional economic and ecological effort to create custom-built insulation to fit the 3D facade. Therefore, this paper discusses the fabrication of lightweight concrete through SCA by replacing the sand (S) with lightweight aggregates (LA, expanded glass beads) in order to decrease the thermal conductivity. However, the open pore structure of the lightweight aggregate could also change the water distribution behavior between the layers which would positively affect the hydration process. Test series with different w/c-ratios (0.3, 0.4 and 0.5) and type of aggregate (S and LA) were produced. Additionally, the test series with LA were fabricated without and with methylcellulose to further increase water absorption. The strength (compressive and flexural) and thermal conductivity were measured direction dependent to take anisotropic effects into account. Additionally, the water distribution perpendicular to the layers was determined using1H-NMR. Specimens produced with LA showed a 3.5 to 4.4 times lower thermal conductivity compared to the specimens produced with S. However, using LA affected the density and thus the strength values of the material. Additionally, the open pore structure of the LA affected the water distribution between the layers which lead to an increase in strength with decreasing w/c-ratio. This is contrary to previous experiments using SCA and sand where strength has improved with increasing w/c-ratio [1–3].

7 References

  1. Agustí-Juan Isolda, Müller Florian, Hack Norman, Wangler Timothy et al. (2017-04)
    Potential Benefits of Digital Fabrication for Complex Structures:
    Environmental Assessment of a Robotically Fabricated Concrete Wall
  2. Asprone Domenico, Auricchio Ferdinando, Menna Costantino, Mercuri Valentina (2018-03)
    3D Printing of Reinforced Concrete Elements:
    Technology and Design Approach
  3. Asprone Domenico, Menna Costantino, Bos Freek, Salet Theo et al. (2018-06)
    Rethinking Reinforcement for Digital Fabrication with Concrete
  4. Lowke Dirk, Dini Enrico, Perrot Arnaud, Weger Daniel et al. (2018-07)
    Particle-Bed 3D Printing in Concrete Construction:
    Possibilities and Challenges
  5. Lowke Dirk, Talke Daniel, Mai (née Dressler) Inka, Weger Daniel et al. (2020-05)
    Particle-Bed 3D Printing by Selective Cement-Activation:
    Applications, Material and Process Technology
  6. Matthäus Carla, Weger Daniel, Kränkel Thomas, Carvalho Luis et al. (2019-09)
    Extrusion of Lightweight Concrete:
    Rheological Investigations
  7. Schutter Geert, Lesage Karel, Mechtcherine Viktor, Nerella Venkatesh et al. (2018-08)
    Vision of 3D Printing with Concrete:
    Technical, Economic and Environmental Potentials

32 Citations

  1. Xing Wenjing, Li Zhengrong (2025-09)
    Quantifying the Heterogeneous Anisotropic Thermal Performance of Extrusion-Based 3D Printed Structures:
    A Multiscale Computational Approach
  2. Bajwa Asad, Samarasinghe Don, Flemmer Claire, Bao Ding (2025-06)
    A Systematic Literature Review on the Thermal Behaviour of Building Elements Constructed Through 3D Concrete Printing (3DCP)
  3. Tanyildizi Harun, Seloglu Maksut, Bakri Abdullah Mohd, Razak Rafiza et al. (2025-04)
    The Rheological and Mechanical Properties of 3D-Printed Geopolymers:
    A Review
  4. Brunner Kim, Stengel Thorsten, Kustermann Andrea (2025-01)
    3D Particle-Bed Printing Using Different Cementitious Binders and Recycled Sand
  5. Khan Mirza, Ahmed Aayzaz, Ali Tariq, Qureshi Muhammad et al. (2024-12)
    Comprehensive Review of 3D Printed Concrete, Life Cycle Assessment, AI and ML Models:
    Materials, Engineered Properties and Techniques for Additive Manufacturing
  6. Zaid Osama, Ouni Mohamed (2024-04)
    Advancements in 3D Printing of Cementitious Materials:
    A Review of Mineral Additives, Properties, and Systematic Developments
  7. Zandifaez Peyman, Shen Zhenglai, Sorgenfrei Reese, Li Yucen et al. (2024-03)
    Pathways to Formulate Lightweight and Ultra-Lightweight 3D Printable Cementitious Composites
  8. Li Zhengrong, Xing Wenjing, Sun Jingting, Feng Xiwen et al. (2024-03)
    Thermal Network Model for Anisotropic Heat Transfer in 3D Printed Complex Geometry Structures
  9. Azimi Zahir, Mousavi Moein, Bengar Habib, Javadi Akbar (2023-12)
    Study on the Post-Fire Mechanical Properties of Lightweight 3D Printed Concrete Containing Expanded Perlite as Partial Replacement of Natural Sand
  10. Briels David, Renz Mauritz, Nouman Ahmad, Straßer Alexander et al. (2023-10)
    Monolithic AM Façade:
    Multi-Objective Parametric Design-Optimization of Additively Manufactured Insulating Wall Elements
  11. Du Longyu, Zhou Jiehang, Lai Jianzhong, Wu Kai et al. (2023-07)
    Effect of Pore-Structure on Durability and Mechanical Performance of 3D Printed Concrete
  12. Arrêteau Manon, Fabien Aurélie, Haddaji Badreddine, Chateigner Daniel et al. (2023-07)
    Review of Advances in 3D Printing Technology of Cementitious Materials:
    Key Printing Parameters and Properties Characterization
  13. Cuevas Villalobos Karla, Strzałkowski Jarosław, Kim Ji-Su, Ehm Clemens et al. (2023-02)
    Towards Development of Sustainable Lightweight 3D Printed Wall Building Envelopes:
    Experimental and Numerical Studies
  14. Şahin Hatice, Mardani Ali (2023-02)
    Mechanical Properties, Durability Performance and Inter-Layer Adhesion of 3DPC Mixtures:
    A State‐of‐the‐art Review
  15. Li Zhengrong, Xing Wenjing, Sun Jingting, Feng Xiwen (2022-12)
    Multi-Scale Structural Characteristics and Heat-Moisture Properties of 3D Printed Building Walls:
    A Review
  16. Kamel Ehsan, Kazemian Ali (2022-11)
    BIM-Integrated Thermal Analysis and Building Energy Modeling in 3D Printed Residential Buildings
  17. Nodehi Mehrab, Aguayo Federico, Nodehi Shahab, Gholampour Aliakbar et al. (2022-07)
    Durability Properties of 3D Printed Concrete
  18. Pasupathy Kirubajiny, Ramakrishnan Sayanthan, Sanjayan Jay (2022-07)
    Enhancing the Properties of Foam-Concrete 3D Printing Using Porous Aggregates
  19. Pasupathy Kirubajiny, Ramakrishnan Sayanthan, Sanjayan Jay (2022-06)
    Fresh and Hardened Properties of 3D Printable Foam-Concrete Containing Porous Aggregates
  20. Straßer Alexander, Matthäus Carla, Weger Daniel, Kränkel Thomas et al. (2022-06)
    Selective Paste-Intrusion:
    Stability of Cement-Paste Mixtures Towards Changing Ambient Temperature
  21. Weger Daniel, Talke Daniel, Lowke Dirk, Henke Klaudius et al. (2022-06)
    Additive Manufacturing of Free-Formed Concrete Elements by Selective Binding with Calcium Silicate-Based Cements
  22. Lowke Dirk, Mai (née Dressler) Inka, Keita Emmanuel, Perrot Arnaud et al. (2022-02)
    Material-Process Interactions in Particle-Bed 3D Printing and the Underlying Physics
  23. Weger Daniel, Gehlen Christoph, Korte Waldemar, Meyer-Brötz Fabian et al. (2022-02)
    Building Rethought:
    3D Concrete Printing in Building Practice
  24. Weger Daniel, Stengel Thorsten, Gehlen Christoph, Maciejewski Yannick et al. (2021-12)
    Approval for the Construction of the First 3D Printed Detached House in Germany:
    Significance of Large-Scale Element Testing
  25. Lyu Fuyan, Zhao Dongliang, Hou Xiaohui, Sun Li et al. (2021-10)
    Overview of the Development of 3D Printing Concrete:
    A Review
  26. Xu Yanqun, Yuan Qiang, Li Zemin, Shi Caijun et al. (2021-09)
    Correlation of Inter-Layer Properties and Rheological Behaviors of 3DPC with Various Printing Time Intervals
  27. Ramakrishnan Sayanthan, Muthukrishnan Shravan, Sanjayan Jay, Pasupathy Kirubajiny (2021-08)
    Concrete 3D Printing of Lightweight Elements Using Hollow-Core Extrusion of Filaments
  28. Rehman Atta, Kim Jung-Hoon (2021-07)
    3D Concrete Printing:
    A Systematic Review of Rheology, Mix Designs, Mechanical, Microstructural, and Durability Characteristics
  29. Bhattacherjee Shantanu, Basavaraj Anusha, Rahul Attupurathu, Santhanam Manu et al. (2021-06)
    Sustainable Materials for 3D Concrete Printing
  30. Dielemans Gido, Briels David, Jaugstetter Fabian, Henke Klaudius et al. (2021-04)
    Additive Manufacturing of Thermally Enhanced Lightweight Concrete Wall Elements with Closed Cellular Structures
  31. Weger Daniel, Gehlen Christoph (2021-01)
    Particle-Bed Binding by Selective Paste-Intrusion:
    Strength and Durability of Printed Fine-Grain Concrete Members
  32. Weger Daniel, Pierre Alexandre, Perrot Arnaud, Kränkel Thomas et al. (2021-01)
    Penetration of Cement-Pastes into Particle-Beds:
    A Comparison of Penetration Models

BibTeX 
@inproceedings{wege_kim_talk_henk.2020.LC3PbSCA,
  author            = "Daniel Weger and Heejeong Kim and Daniel Talke and Klaudius Henke and Thomas Kränkel and Christoph Gehlen",
  title             = "Lightweight Concrete 3D Printing by Selective Cement-Activation: Investigation of Thermal Conductivity, Strength and Water-Distribution",
  doi               = "10.1007/978-3-030-49916-7_17",
  year              = "2020",
  volume            = "28",
  pages             = "162--171",
  booktitle         = "Proceedings of the 2nd RILEM International Conference on Concrete and Digital Fabrication: Digital Concrete 2020",
  editor            = "Freek Paul Bos and Sandra Simaria de Oliveira Lucas and Robert Johannes Maria Wolfs and Theo A. M. Salet",
}
Formatted Citation

D. Weger, H. Kim, D. Talke, K. Henke, T. Kränkel and C. Gehlen, “Lightweight Concrete 3D Printing by Selective Cement-Activation: Investigation of Thermal Conductivity, Strength and Water-Distribution”, in Proceedings of the 2nd RILEM International Conference on Concrete and Digital Fabrication: Digital Concrete 2020, 2020, vol. 28, pp. 162–171. doi: 10.1007/978-3-030-49916-7_17.

Weger, Daniel, Heejeong Kim, Daniel Talke, Klaudius Henke, Thomas Kränkel, and Christoph Gehlen. “Lightweight Concrete 3D Printing by Selective Cement-Activation: Investigation of Thermal Conductivity, Strength and Water-Distribution”. In Proceedings of the 2nd RILEM International Conference on Concrete and Digital Fabrication: Digital Concrete 2020, edited by Freek Paul Bos, Sandra Simaria de Oliveira Lucas, Robert Johannes Maria Wolfs, and Theo A. M. Salet, 28:162–71, 2020. https://doi.org/10.1007/978-3-030-49916-7_17.