| id |
sigradi2021_28 |
| authors |
Atsumi, Kei, Hanazato, Toshihiro and Kato, Osamu |
| year |
2021 |
| title |
The Assembly and Fabrication of Double Curved Panel Structure Using Japanese wood Joints created by Desktop 3D Printers |
| source |
Gomez, P and Braida, F (eds.), Designing Possibilities - Proceedings of the XXV International Conference of the Ibero-American Society of Digital Graphics (SIGraDi 2021), Online, 8 - 12 November 2021, pp. 1245–1255 |
| summary |
This research presents a new direction for freeform structure assembly and fabrication through the collaboration of 3D printing technology and Japanese wood joining technology. Full-scale, self-build prototyping is demonstrated without glue or metal fittings. Rather than relying on digital fabrication machines to match the architectural scale, this study utilizes the Fused Filament Fabrication (FFF) with desktop 3D printers, which is the most widespread and inexpensive printing technology. By incorporating the perspectives of wood joinery and compact 3D printers, this study promotes a drastic change in 3D printed architectural production from a massive structure-oriented system to a module-oriented system. The project demonstrates how artisanal knowledge integrates with 3D printing architectural production by reconfiguring joint geometry, parametric modeling, fabrication, and assembly processes. We discuss our research process and final achievements, and we provide new ideas for architectural production using digital fabrication. |
| keywords |
Digital fabrication, Assembly, Japanese wood joints, 3D printing, Double- curved panel structure |
| series |
SIGraDi |
| email |
|
| full text |
 file.pdf (1,038,019 bytes) |
| references |
Content-type: text/plain
|
Beyhan, F., & Arslan Selcuk, S. (2018)
 3D Printing in Architecture: One Step Closer to a Sustainable Built Environment
, Lecture Notes in Civil Engineering, 253–268. https://doi.org/10.1007/978-3-319-63709-9_20Ching-Shun, T. (2006). Smart Structures: Designs with Rapid Prototyping. Progress in Design & Decision Support Systems in Architecture and Urban Planning, 415–429. Retrieved from http://papers.cumincad.org/data/works/att/ddss2006-pb-415.content.pdfDefacto (2016) The Rise Pavilion [Project] Guinness World Record: Largest 3D Printed Structure 2016 Retrieved from https://3dprint.com/147981/defacto-rise-pavilion-guinness/
|
|
|
|
|
Krieg O.D. et al. (2015)
Modeling curved-layered printing paths for fabricating large-scale construction components
, Additive Manufacturing, 12, 216–230. https://doi.org/10.1016/j.addma.2016.06.004Rael, R., & Fratello, V. S. (2015). Bloom [Project]. Retrieved from http://emergingobjects.com/project/bloom-2/Raspall, F., Banon, C., & Maheshwary, S. (2020). Timescapes: Design and Additive Manufacturing Workflows for freeform, ornamental architectural surfaces. Congreso SIGraDi 2020. Sao Paulo: Blucher, 2020, 306–311. https://doi.org/10.5151/sigradi2020-42Sass, L. (2004). Design for Self Assembly of Building Components using Rapid Prototyping. Retrieved from http://diyhpl.us/~bryan/papers2/Design%20for%20Self%20Assembly%20of%20Building%20Components%20using%20Rapid%20Prototyping.pdf Proceedings/ISBN 0–9541183-2-4, Architecture in the Network Society. 22nd eCAADe Conference, 95–104
|
|
|
|
|
Uchida, Y. (1993)
A Study of Conventional Construction Method about Tsugite Shiguchi
, Housing Research Foundation
|
|
|
|
|
Yuan, P. F., & Chai, H. (2019)
Reinterpretation of Traditional Wood Structures with Digital Design and Fabrication Technologies
, Lecture Notes in Civil Engineering, 24, 265–282. https://doi.org/10.1007/978-3-030-03676-8_9
|
|
|
|
| last changed |
2022/05/23 12:11 |
|
