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2022 | OriginalPaper | Buchkapitel

2. Digital Fabrication with Cement-Based Materials: Process Classification and Case Studies

verfasst von : R. A. Buswell, F. P. Bos, Wilson Ricardo Leal da Silva, N. Hack, Harald Kloft, Dirk Lowke, Niklas Freund, Asko Fromm, E. Dini, Timothy Wangler, E. Lloret-Fritschi, Roel Schipper, Viktor Mechtcherine, Arnaud Perrot, K. Vasilic, Nicolas Roussel

Erschienen in: Digital Fabrication with Cement-Based Materials

Verlag: Springer International Publishing

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Abstract

The need for methods for forming concrete has existed for as long as concrete has been used in constructing the built environment. Creating flat, rectilinear formers have traditionally been the cost and time efficient default for the majority of applications. The desire for greater design freedom and the drive to automate construction manufacturing is providing a platform for the continued development of a family of processes called Digital Fabrication with Concrete (DFC) technologies. DFC technologies are many and varied. Much of the material science theory is common, but the process steps vary significantly between methods, creating challenges as we look towards performance comparison and standardisation. Presented here is a framework to help identify and describe process differences and a showcase of DFC application case studies that explain the processes behind a sub-set of the technologies available.

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Vorheriges Kapitel Digital Fabrication with Cement-Based Materials—The Rilem D.F.C. Technical Committee History, Strategy and Achievements

Nächstes Kapitel Digital Fabrication with Cement-Based Materials: Underlying Physics

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Titel: Digital Fabrication with Cement-Based Materials: Process Classification and Case Studies
verfasst von: R. A. Buswell
F. P. Bos
Wilson Ricardo Leal da Silva
N. Hack
Harald Kloft
Dirk Lowke
Niklas Freund
Asko Fromm
E. Dini
Timothy Wangler
E. Lloret-Fritschi
Roel Schipper
Viktor Mechtcherine
Arnaud Perrot
K. Vasilic
Nicolas Roussel
Verlag: Springer International Publishing
Buch: Digital Fabrication with Cement-Based Materials
Print ISBN: 978-3-030-90534-7

Electronic ISBN: 978-3-030-90535-4

Copyright-Jahr: 2022
DOI: https://doi.org/10.1007/978-3-030-90535-4_2

Springer Professional

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Abstract

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