Large-Scale Additive Manufacturing of Ultra-High-Performance Concrete of Integrated Formwork for Truss-Shaped Pillars
Chapitre d'ouvrage scientifique
Auteur
Date
2018Résumé
In the present paper a new additive manufacturing processing route is introduced to produce ultra-high-performance concrete complex architectonic elements, by printing integrated formwork. Interdisciplinary work involving material science, computation, robotics, architecture and design resulted in the development of an innovative way of 3D printing cementitious materials. The 3D printing process involved is based on a FDM-like technique, in the sense that a material is deposited layer by layer through an extrusion printhead mounted on a 6-axis robotic arm. An architectural application is used as a case-study to demonstrate the potentialities of the technology. Along with the detailed description of the design and construction process, a description of the responsibilities and their distribution amongst the stakeholders involved in the project is given. The steps taken to include the 3D printed element in an authorized regulatory context are presented as well. The structural elements produced constitute some of the largest 3D printed concrete parts available until now. Multi-functionality was enabled for structural elements by taking advantage of the complex geometry which can be achieved using our technology for large-scale additive manufacturing. The proposed process succeeds in solving several of the current issues problems that can be found in the production of 3D printed architectural features for an AEC industrial context and therefore suggests an immediately viable route for industry assimilation.
Fichier(s) constituant cette publication
- Nom:
- PIMM-ROBARCH_2018_GAUDILLIERE.pdf
- Taille:
- 3.002Mo
- Format:
- Fin d'embargo:
- 2019-02-28
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Documents liés
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Chapitre d'ouvrage scientifiqueGAUDILLIÈRE, Nadja; DUBALLET, Romain; BOUYSSOU, Charles; MALLET, Alban; ROUX, Philippe; ZAKERI, Mahriz; DIRRENBERGER, Justin (Butterworth-Heinemann, 2019)In this chapter a new additive manufacturing (AM) processing route is introduced for ultra-high-performance concrete. Interdisciplinary work involving materials science, computation, robotics, architecture, and design ...
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Article dans une revue avec comité de lectureGOSSELIN, Clément; DUBALLET, Romain; ROUX, Philippe; GAUDILLIÈRE, Nadja; DIRRENBERGER, Justin; MOREL, Philippe (Elsevier, 2016)In the present paper a new additive manufacturing processing route is introduced for ultra-high performance concrete. Interdisciplinary work involving materials science, computation, robotics, architecture and design ...
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Chapitre d'ouvrage scientifiqueGAUDILLIÈRE, Nadja; DIRRENBERGER, Justin; BAVEREL, Olivier; SOLLOGOUB, Cyrille (RVTR Design Research Group, 2015)This project results from the collaboration of architects, structural and material scientists. It consists in a multidisciplinary, collective design method, based on the deep relations between material selection, process ...
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Article dans une revue avec comité de lectureDUBALLET, Romain; BAVEREL, Olivier; DIRRENBERGER, Justin (Elsevier, 2017)In the present paper, a study is conducted on building systems associated with concrete extrusion-based additive manufacturing techniques. Specific parameters are highlighted - concerning scale, environment, support, and ...
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Article dans une revue avec comité de lectureDUBALLET, Romain; BAVEREL, Olivier; DIRRENBERGER, Justin (Institution of Structural Engineers - Elsevier, 2019)This work presents a generalized method for robotic mortar extrusion, allowing the fabrication of structural-insulating walls of novel performances. It involves two distinct steps that are to be simultaneously automated: ...