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Extruded Tessellations: A novel structural ceramic system at the intersection of industrial ceramic extrusion and CNC fabrication

Extruded Tessellations: A novel structural ceramic system at the intersection of industrial ceramic extrusion and CNC fabrication

Ugarte-Urzúa, Juan Pablo; Mhatre, Saurabh; Bechthold, Martin; Norman, Sarah;

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This research explores the customization potential of ceramic extrusion by means of integrating CNC fabrication tools into current industrial ceramic extrusion lines. In order to support this approach, we designed and built two wall prototypes made of 700 extruded ceramic pieces. The pieces were produced using a single extrusion die and were cut to custom lengths and angles using CNC disk cutters to produce a total of 38 unique pieces. We introduce the motivation behind our work, present a three-stage design workflow for the design of this type of ceramic system, and show our built prototype.

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Palavras-chave: Ceramic extrusio, CNC customization, Design workflow, Prototype, Tessellation,

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DOI: 10.5151/sigradi2020-45

Referências bibliográficas
  • [1] Alothman, S., Im, H. C., Jung, F., & Bechthold, M. (2019). Spatial Print Trajectory. In J. Willmann, P. Block, M. Hutter, K. Byrne, & T. Schork (Eds.), Robotic Fabrication in Architecture, Art and Design 2018 (pp. 167–180). Springer International Publishing. https://doi.org/10.1007/978-3-319-92294-2_13
  • [2] Andreani, S., & Bechthold, M. (2014). [Re]volving Brick: Geometry and Performance Innovation in Ceramic Building Systems Through Design Robotics. In Gramazio F., Kohler M., & Langenberg S. (Authors), Fabricate 2014: Negotiating Design & Making (pp. 182-191). London: UCL Press. https://doi.org/10.2307/j.ctt1tp3c5w.26
  • [3] Bechthold, M. (2016). Prototipos cerámicos – diseño, computación y fabricación digital. Informes de La Construcción, 68(544), 167. https://doi.org/10.3989/ic.15.170.m15
  • [4] Bechthold, Martin, Kane, A., & King, N. (2015). Ceramic Material Systems: In Architecture and Interior Design. In Ceramic Material Systems. Birkhäuser. https://www.degruyter.com/view/title/301948
  • [5] Bechthold, Martin, King, J., Kane, A., Niemasz, J., & Reinhart, C. (2011). Integrated Environmental Design and Robotic Fabrication Workflow for Ceramic Shading Systems. ISARC Proceedings, 70–7
  • [6] Boothroyd, G., & Alting, L. (1992). Design for Assembly and Disassembly. CIRP Annals, 41(2), 625–63 https://doi.org/10.1016/S0007-8506(07)63249-1
  • [7] Ceramic Hypar Tower (2020). Retrieved from https://research.gsd.harvard.edu/maps/
  • [8] Dyskin, A. V., Estrin, Y., Pasternak, E., Khor, H. C., & Kanel-Belov,
  • [9] A. J. (2003). Fracture Resistant Structures Based on Topological Interlocking with Non-planar Contacts. Advanced Engineering Materials, 5(3), 116–11 https://doi.org/10.1002/adem.200390016
  • [10] Friedman, J., Kim, H., & Mesa, O. (2014). Experiments in additive clay depositions. In Robotic Fabrication in Architecture, Art and Design 2014 (pp. 261-272). Springer, Cham.
  • [11] García del Castillo y López, J. L. B. (2019). Janus Printing. ACADIA 19: UBIQUITY AND AUTONOMY [Proceedings of
  • [12] the 39th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA)]. Pp. 576-585. http://papers.cumincad.org/cgi- bin/works/paper/acadia19_576
  • [13] Händle, F. (Ed.). (2007). Extrusion in Ceramics. Springer-Verlag. https://doi.org/10.1007/978-3-540-27102-4
  • [14] Khoshnevis, B. (2004). Automated construction by contour crafting—Related robotics and information technologies. Automation in Construction, 13(1), 5–19. https://doi.org/10.1016/j.autcon.2003.08.012
  • [15] Protoceramics (2015). Retrieved from https://research.gsd.harvard.edu/maps/
  • [16] Ramamurthy, K., & Nambiar, E. K. K. (2004). Accelerated masonry construction review and future prospects. Progress in Structural Engineering and Materials, 6(1), 1–9. https://doi.org/10.1002/pse.162
  • [17] Schmidt, P. (2014). Architect manufacturer collaboration through the design of a ruled surface cutter for extruded terracotta (Order No. 1566983). Available from ProQuest Dissertations & Theses Global. (1627753367). Retrieved from http://search.proquest.com/docview/1627753367
  • [18] Seibold, Z. H. (2018). Ceramic Morphologies. Precision and control in paste-based additive manufacturing. ACADIA // 2018: Recalibration. On Imprecision and Infidelity. [Proceedings of the 38th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA)]. Pp. 350-357. http://papers.cumincad.org/cgi- bin/works/paper/acadia18_350
  • [19] Seibold, Z., Mesa, O., Stavric, M., & Bechthold, M. (2018, July). Ceramic Tectonics: Tile Grid Shell. In Proceedings of IASS Annual Symposia (Vol. 2018, No. 8, pp. 1-8). International Association for Shell and Spatial Structures (IASS)
  • [20] Suspended Ceramic Shell (2014). Retrieved from https://research.gsd.harvard.edu/maps
Como citar:

Ugarte-Urzúa, Juan Pablo; Mhatre, Saurabh; Bechthold, Martin; Norman, Sarah; "Extruded Tessellations: A novel structural ceramic system at the intersection of industrial ceramic extrusion and CNC fabrication", p. 326-333 . In: Congreso SIGraDi 2020. São Paulo: Blucher, 2020.
ISSN 2318-6968, DOI 10.5151/sigradi2020-45

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