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Printable Cement-Based Materials (2022-01)

Fresh Properties Measurements and Control

10.1007/978-3-030-90535-4_4

 Wangler Timothy,  Flatt Robert,  Roussel Nicolas,  Perrot Arnaud,  Sonebi Mohammed,  Wolfs Robert,  Bos Freek,  Lowke Dirk,  Freund Niklas,  Stephan Dietmar,  Pott Ursula,  Reiter Lex, Grünewald Steffen,  da Silva Wilson,  de Schutter Geert
Contribution - Digital Fabrication with Cement-Based Materials, pp. 99-136

Abstract

Digital fabrication with cementitious materials is a rapidly growing field of research in which the evolution of strength during the various processes, such as 3D printing, is the key controlling parameter. The strength evolves over multiple orders of magnitude during the process, and thus, it is essential to properly characterize the strength evolution in order to guarantee process success. This chapter summarizes the state of the art in these characterization methods for digital fabrication with fresh cementitious materials, reviewing well-known and more recently developed methods.

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6 Citations

  1. Raza Saim, Triantafyllidis Zafiris, Anton Ana-Maria, Dillenburger Benjamin et al. (2024-01)
    Seismic Performance of Fe-SMA Pre-Stressed Segmental Bridge Columns with 3D Printed Permanent Concrete Formwork
  2. Bos Derk, Wolfs Robert (2023-12)
    A Quality-Control Framework for Digital Fabrication with Concrete
  3. Demont Léo, Mesnil Romain, Ducoulombier Nicolas, Caron Jean-François (2023-10)
    Affordable In-Line Structuration Measurements of Printable Mortar with a Pocket-Shear-Vane
  4. Şahin Hatice, Mardani Ali (2023-10)
    How Does Rheological Behavior Affect the Inter-Layer Bonding Strength of 3DPC Mixtures?
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    CCR Digital Concrete 2022 SI:
    Editorial
  6. Matos Paulo, Zat Tuani, Corazza Kiara, Fensterseifer Emilia et al. (2022-05)
    Effect of TiO2 Nano-Particles on the Fresh Performance of 3D Printed Cementitious Materials

BibTeX 
@inproceedings{wang_flat_rous_perr.2022.PCBM,
  author            = "Timothy Paul Wangler and Robert Johann Flatt and Nicolas Roussel and Arnaud Perrot and Mohammed Sonebi and Robert Johannes Maria Wolfs and Freek Paul Bos and Dirk Lowke and Niklas Freund and Dietmar Stephan and Ursula Pott and Lex Reiter and Steffen Grünewald and Wilson Ricardo Leal da Silva and Geert de Schutter",
  title             = "Printable Cement-Based Materials: Fresh Properties Measurements and Control",
  doi               = "10.1007/978-3-030-90535-4_4",
  year              = "2022",
  volume            = "36",
  pages             = "99--136",
  booktitle         = "Digital Fabrication with Cement-Based Materials",
  editor            = "Nicolas Roussel and Dirk Lowke",
}
Formatted Citation

T. P. Wangler, “Printable Cement-Based Materials: Fresh Properties Measurements and Control”, in Digital Fabrication with Cement-Based Materials, 2022, vol. 36, pp. 99–136. doi: 10.1007/978-3-030-90535-4_4.

Wangler, Timothy Paul, Robert Johann Flatt, Nicolas Roussel, Arnaud Perrot, Mohammed Sonebi, Robert Johannes Maria Wolfs, Freek Paul Bos, et al.. “Printable Cement-Based Materials: Fresh Properties Measurements and Control”. In Digital Fabrication with Cement-Based Materials, edited by Nicolas Roussel and Dirk Lowke, 36:99–136, 2022. https://doi.org/10.1007/978-3-030-90535-4_4.