| id |
caadria2020_361 |
| authors |
Geht, Alexander, Weizmann, Michael, Grobman, Yasha Jacob and Tarazi, Ezri |
| year |
2020 |
| title |
Horizontal Forming in Additive Manufacturing: Design and Architecture Perspective |
| doi |
https://doi.org/10.52842/conf.caadria.2020.1.203
|
| source |
D. Holzer, W. Nakapan, A. Globa, I. Koh (eds.), RE: Anthropocene, Design in the Age of Humans - Proceedings of the 25th CAADRIA Conference - Volume 1, Chulalongkorn University, Bangkok, Thailand, 5-6 August 2020, pp. 203-212 |
| summary |
Extrusion based three-dimensional additive manufacturing technology forms objects by driving the material through a nozzle depositing a linear structure through vector-building blocks called roads. In a common 3-axis system, the roads are stacked layer upon layer for forming the final object. However, forming overhanging geometry in this way requires additional support structures increasing material usage and effective printing time. The paper presents a novel Horizontal forming (HF) approach and method for forming overhanging geometry, HF is a new extrusion-based AM approach that allows rapid and stable forming of horizontal structures without additional support in 3-axis systems. This approach can provide new design and manufacturing possibilities for extrusion AM, with emphasis on medium and large-scale AM. HF can affect the outcome's aesthetic and mechanical properties. Moreover, it can significantly accelerate the production process and reduce material waste. The present paper maps the influence of various parameters employed in the HF method, providing a deeper understanding of the printing process. Additionally, it explores and demonstrates the potential functional and aesthetic characteristics that can be achieved with HF for industrial design and architectural products. |
| keywords |
Additive manufacturing; Support; Horizontal forming (HF); Extrusion-based system; Fused granulate forming (FGF) |
| series |
CAADRIA |
| email |
|
| full text |
 file.pdf (5,846,784 bytes) |
| references |
Content-type: text/plain
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Austern, G, Capeluto, IG and Grobman, YJ (2018)
 Rationalization methods in computer aided fabrication: A critical review
, Automation in Construction, 90(December 2017), pp. 281-293
|
|
|
|
|
Bellehumeur, C and Li, L (2004)
Modeling of Bond Formation Between Polymer Filaments in the Fused Deposition Modeling Process
, Journal of Manufacturing Processes, 6(2), pp. 170-178
|
|
|
|
|
Bellini, A, Gu?c?eri, S and Bertoldi, M (2004)
Liquefier Dynamics in Fused Deposition
, Journal of Manufacturing Science and Engineering, 126(2), p. 237
|
|
|
|
|
Comminal, R, Serdeczny, MP, Pedersen, DB and Spangenberg, J (2018)
Numerical modeling of the strand deposition flow in extrusion-based additive manufacturing
, Additive Manufacturing, 20, pp. 68-76
|
|
|
|
|
Huang, Y, Zhang, J, Hu, X, Song, G, Liu, Z, Yu, L and Liu, L (2016)
FrameFab: robotic fabrication of frame shapes
, ACM Transactions on Graphics, 35(6), pp. 1-11
|
|
|
|
|
Keating, SJ (2016)
From Bacteria to Buildings: Additive Manufacturing Outside the Box
, no thesis type given, no school given
|
|
|
|
|
Molloy, I and Miller, T (2018)
Digital Dexterity
, ACADIA, pp. 266-275
|
|
|
|
|
O'Dowd, P, Hoskins, S, Walters, P and Gelsow, A (2015)
Modulated extrusion for textured 3D printing
, International Conference on Digital Printing Technologies, pp. 173-178
|
|
|
|
|
Oxman, N, Laucks, J, Kayser, M, Tsai, E and Firstenberg, M (2013)
Freeform 3D printing
, Green Design, Materials and Manufacturing Processes, pp. 479-483
|
|
|
|
|
Sabin, JBBNDRJLLJ (2018)
Robosense 2.0
, ACADIA, pp. 276-285
|
|
|
|
|
Turner, BN, Strong, R and Gold, SA (2014)
A review of melt extrusion additive manufacturing processes: I. Process design and modeling
, Rapid Prototyping Journal, 20(3), pp. 192-204
|
|
|
|
|
Wang, TM, Xi, JT and Jin, Y (2007)
A model research for prototype warp deformation in the FDM process
, International Journal of Advanced Manufacturing Technology, 33(11-12), pp. 1087-1096
|
|
|
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| last changed |
2022/06/07 07:51 |
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