Integrated design strategies for multiscalarbiopolymer robotic 3d printing

Gabriella Rossi; Ruxandra-Stefania  Chiujdea; Laura Hochegger; Ayoub Lharchi; Paul Nicholas; Martin Tamke; Mette Ramsgaard Thomsen

Integrated design strategies for multiscalarbiopolymer robotic 3d printing

Gabriella Rossi, Ruxandra-Stefania Chiujdea, Laura Hochegger, Ayoub Lharchi, Paul Nicholas, Martin Tamke, Mette Ramsgaard Thomsen

Publikation: Bidrag til bog/antologi/rapport › Konferencebidrag i proceedings › Forskning › peer review

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Abstract

Additive manufacturing technologies have the potential to initiate changes in architecture’smaterial culture and move us towards a bio-based paradigm. Robotic 3d-printing can proposenew design languages, logics and tectonics specific to wet biopolymers. In this paper we presentstrategies and workflows for cellulose-based biopolymer 3d-printing. We propose a digital designframework informed by the fabrication system and guided through human design input. The workflowstabilizes the material at the scale of the toolpath, the component, and the wall assembly, byintegrating joinery and cross-bracing together with the component geometry. We showcase thefeasibility of a large-scale dry-assembly of 3d-printed biopolymer components. The demonstratorwall allows us to evaluate our workflows and discuss the challenges and implication of bringingbiomaterials in our built environment.

Originalsprog	Engelsk
Titel	Hybrids & Haecceities : Proceedings of the 2022 Acadia conference
Publikationsdato	okt. 2023
Sider	346-355
Status	Udgivet - okt. 2023
Begivenhed	ACADIA 2022: Hybrid & Haeccetties - University of Pennsylvania, Philadelphia, USA Varighed: 27 okt. 2022 → 29 jan. 2023 https://2022.acadia.org https://2022.acadia.org/

Konference

Konference	ACADIA 2022
Lokation	University of Pennsylvania
Land/Område	USA
By	Philadelphia
Periode	27/10/2022 → 29/01/2023
Internetadresse	https://2022.acadia.org https://2022.acadia.org/

Kunstnerisk udviklingsvirksomhed (KUV)

Nej

Adgang til dokumentet

Final_IntegratedDesignStrategiesforMulti-scalarBiopolymerRobotic3dpForlagets udgivne version, 4,6 MBLicens: CC BY-NC

https://drive.google.com/drive/folders/1dI9Bp1kjxZpQIAEU9tehEcRI9ysBd500?fbclid=IwAR0EJaxiLd5m4M3T-C2qu6gx1jK3Po-kiEUUirkj-rVpXXwAjVGYffyVNI0Licens: CC BY-NC

Citationsformater

Rossi, G., Chiujdea, R.-S., Hochegger, L., Lharchi, A., Nicholas, P., Tamke, M., & Ramsgaard Thomsen, M. (2023). Integrated design strategies for multiscalarbiopolymer robotic 3d printing. I Hybrids & Haecceities: Proceedings of the 2022 Acadia conference (s. 346-355) https://drive.google.com/drive/folders/1dI9Bp1kjxZpQIAEU9tehEcRI9ysBd500?fbclid=IwAR0EJaxiLd5m4M3T-C2qu6gx1jK3Po-kiEUUirkj-rVpXXwAjVGYffyVNI0

@inproceedings{63c2dc9a796f4b2aa2e10d45829214bd,

title = "Integrated design strategies for multiscalarbiopolymer robotic 3d printing",

abstract = "Additive manufacturing technologies have the potential to initiate changes in architecture{\textquoteright}smaterial culture and move us towards a bio-based paradigm. Robotic 3d-printing can proposenew design languages, logics and tectonics specific to wet biopolymers. In this paper we presentstrategies and workflows for cellulose-based biopolymer 3d-printing. We propose a digital designframework informed by the fabrication system and guided through human design input. The workflowstabilizes the material at the scale of the toolpath, the component, and the wall assembly, byintegrating joinery and cross-bracing together with the component geometry. We showcase thefeasibility of a large-scale dry-assembly of 3d-printed biopolymer components. The demonstratorwall allows us to evaluate our workflows and discuss the challenges and implication of bringingbiomaterials in our built environment.",

author = "Gabriella Rossi and Ruxandra-Stefania Chiujdea and Laura Hochegger and Ayoub Lharchi and Paul Nicholas and Martin Tamke and {Ramsgaard Thomsen}, Mette",

year = "2023",

month = oct,

language = "English",

pages = "346--355",

booktitle = "Hybrids & Haecceities",

note = "ACADIA 2022 : Hybrid & Haeccetties ; Conference date: 27-10-2022 Through 29-01-2023",

url = "https://2022.acadia.org, https://2022.acadia.org/",

}

Rossi, G , Chiujdea, R-S, Hochegger, L, Lharchi, A , Nicholas, P , Tamke, M & Ramsgaard Thomsen, M 2023, Integrated design strategies for multiscalarbiopolymer robotic 3d printing. i Hybrids & Haecceities: Proceedings of the 2022 Acadia conference. s. 346-355, ACADIA 2022, Philadelphia, Pennsylvania, USA, 27/10/2022. <https://drive.google.com/drive/folders/1dI9Bp1kjxZpQIAEU9tehEcRI9ysBd500?fbclid=IwAR0EJaxiLd5m4M3T-C2qu6gx1jK3Po-kiEUUirkj-rVpXXwAjVGYffyVNI0>

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T1 - Integrated design strategies for multiscalarbiopolymer robotic 3d printing

AU - Rossi, Gabriella

AU - Chiujdea, Ruxandra-Stefania

AU - Hochegger, Laura

AU - Lharchi, Ayoub

AU - Nicholas, Paul

AU - Tamke, Martin

AU - Ramsgaard Thomsen, Mette

PY - 2023/10

Y1 - 2023/10

N2 - Additive manufacturing technologies have the potential to initiate changes in architecture’smaterial culture and move us towards a bio-based paradigm. Robotic 3d-printing can proposenew design languages, logics and tectonics specific to wet biopolymers. In this paper we presentstrategies and workflows for cellulose-based biopolymer 3d-printing. We propose a digital designframework informed by the fabrication system and guided through human design input. The workflowstabilizes the material at the scale of the toolpath, the component, and the wall assembly, byintegrating joinery and cross-bracing together with the component geometry. We showcase thefeasibility of a large-scale dry-assembly of 3d-printed biopolymer components. The demonstratorwall allows us to evaluate our workflows and discuss the challenges and implication of bringingbiomaterials in our built environment.

AB - Additive manufacturing technologies have the potential to initiate changes in architecture’smaterial culture and move us towards a bio-based paradigm. Robotic 3d-printing can proposenew design languages, logics and tectonics specific to wet biopolymers. In this paper we presentstrategies and workflows for cellulose-based biopolymer 3d-printing. We propose a digital designframework informed by the fabrication system and guided through human design input. The workflowstabilizes the material at the scale of the toolpath, the component, and the wall assembly, byintegrating joinery and cross-bracing together with the component geometry. We showcase thefeasibility of a large-scale dry-assembly of 3d-printed biopolymer components. The demonstratorwall allows us to evaluate our workflows and discuss the challenges and implication of bringingbiomaterials in our built environment.

M3 - Article in proceedings

SP - 346

EP - 355

BT - Hybrids & Haecceities

T2 - ACADIA 2022

Y2 - 27 October 2022 through 29 January 2023

ER -