Matrix architecture: 3d-printed and simulated kirigami matrices & auxetic materials

Madeleine Eggers; Jingyang Liu; Jasmine Chia Chia Liu; Ben Norman; Jenny E. Sabin

Matrix architecture: 3d-printed and simulated kirigami matrices & auxetic materials

Madeleine Eggers, Jingyang Liu, Jasmine Chia Chia Liu, Ben Norman, Jenny E. Sabin

Cornell University

Research output: Chapter in Book or Report/Conference proceeding › Conference Proceeding › peer-review

1 Citation (Scopus)

Abstract

This paper explores the possibilities of kirigami geometry — folding with the addition of strategically placed cuts and holes — through simulation and kinetic and adaptive architectural assemblies. Typical kinetic assemblies consist of rigid components connected by mechanical joints that offer limited range of motion and tend to require mechatronic actuation. While mechanical motion is adequate for specific applications, mechanically motile systems lack the adaptive potential, elasticity, and embedded intelligence of adaptive structures. We propose to focus on the design of flexible matrices as a way of moving away from stiff, mechanical unitized systems and toward pliable, continuous 2D and 3D structures that can elastically change geometry in response to external stimuli without the need for external mechatronic energy input. As a proof-of-concept, we have produced an integrated panel-and-hinge assembly in which the panels and hinges are not discrete, mechanically connected components, but are instead functional zones of a continuous matrix. In addition, by controlling aspects of the individual units (panel size, hinge geometry, spacing, unit shape), we can induce larger-scale behavioral changes in the whole matrix.

Original language	English
Title of host publication	Simulation Series
Editors	Michela Turrin, Brady Peters, Timur Dogan, William O'Brien, Rudi Stouffs
Publisher	The Society for Modeling and Simulation International
Pages	96-102
Number of pages	7
Edition	11
ISBN (Electronic)	9781510870185
Publication status	Published - 2017
Externally published	Yes
Event	8th Annual Symposium on Simulation for Architecture and Urban Design, SimAUD 2017 - Toronto, Canada Duration: 22 May 2017 → 24 May 2017

Publication series

Name	Simulation Series
Number	11
Volume	49
ISSN (Print)	0735-9276

Conference

Conference	8th Annual Symposium on Simulation for Architecture and Urban Design, SimAUD 2017
Country/Territory	Canada
City	Toronto
Period	22/05/17 → 24/05/17

Keywords

3D printing
Adaptive architecture
Auxetic materials
Computational design
Kirigami
Material design
Programmable matter
Simulation and modeling

Cite this

@inproceedings{b3877c83566c447c8c05f83ce2f9553c,

title = "Matrix architecture: 3d-printed and simulated kirigami matrices & auxetic materials",

abstract = "This paper explores the possibilities of kirigami geometry — folding with the addition of strategically placed cuts and holes — through simulation and kinetic and adaptive architectural assemblies. Typical kinetic assemblies consist of rigid components connected by mechanical joints that offer limited range of motion and tend to require mechatronic actuation. While mechanical motion is adequate for specific applications, mechanically motile systems lack the adaptive potential, elasticity, and embedded intelligence of adaptive structures. We propose to focus on the design of flexible matrices as a way of moving away from stiff, mechanical unitized systems and toward pliable, continuous 2D and 3D structures that can elastically change geometry in response to external stimuli without the need for external mechatronic energy input. As a proof-of-concept, we have produced an integrated panel-and-hinge assembly in which the panels and hinges are not discrete, mechanically connected components, but are instead functional zones of a continuous matrix. In addition, by controlling aspects of the individual units (panel size, hinge geometry, spacing, unit shape), we can induce larger-scale behavioral changes in the whole matrix.",

keywords = "3D printing, Adaptive architecture, Auxetic materials, Computational design, Kirigami, Material design, Programmable matter, Simulation and modeling",

author = "Madeleine Eggers and Jingyang Liu and Liu, {Jasmine Chia Chia} and Ben Norman and Sabin, {Jenny E.}",

note = "Publisher Copyright: {\textcopyright} 2017 Society for Modeling & Simulation International (SCS).; 8th Annual Symposium on Simulation for Architecture and Urban Design, SimAUD 2017 ; Conference date: 22-05-2017 Through 24-05-2017",

year = "2017",

language = "English",

series = "Simulation Series",

publisher = "The Society for Modeling and Simulation International",

number = "11",

pages = "96--102",

editor = "Michela Turrin and Brady Peters and Timur Dogan and William O'Brien and Rudi Stouffs",

booktitle = "Simulation Series",

edition = "11",

}

Eggers, M, Liu, J, Liu, JCC, Norman, B & Sabin, JE 2017, Matrix architecture: 3d-printed and simulated kirigami matrices & auxetic materials. in M Turrin, B Peters, T Dogan, W O'Brien & R Stouffs (eds), Simulation Series. 11 edn, Simulation Series, no. 11, vol. 49, The Society for Modeling and Simulation International, pp. 96-102, 8th Annual Symposium on Simulation for Architecture and Urban Design, SimAUD 2017, Toronto, Canada, 22/05/17.

Matrix architecture: 3d-printed and simulated kirigami matrices & auxetic materials. / Eggers, Madeleine; Liu, Jingyang; Liu, Jasmine Chia Chia et al.
Simulation Series. ed. / Michela Turrin; Brady Peters; Timur Dogan; William O'Brien; Rudi Stouffs. 11. ed. The Society for Modeling and Simulation International, 2017. p. 96-102 (Simulation Series; Vol. 49, No. 11).

Research output: Chapter in Book or Report/Conference proceeding › Conference Proceeding › peer-review

TY - GEN

T1 - Matrix architecture

T2 - 8th Annual Symposium on Simulation for Architecture and Urban Design, SimAUD 2017

AU - Eggers, Madeleine

AU - Liu, Jingyang

AU - Liu, Jasmine Chia Chia

AU - Norman, Ben

AU - Sabin, Jenny E.

PY - 2017

Y1 - 2017

N2 - This paper explores the possibilities of kirigami geometry — folding with the addition of strategically placed cuts and holes — through simulation and kinetic and adaptive architectural assemblies. Typical kinetic assemblies consist of rigid components connected by mechanical joints that offer limited range of motion and tend to require mechatronic actuation. While mechanical motion is adequate for specific applications, mechanically motile systems lack the adaptive potential, elasticity, and embedded intelligence of adaptive structures. We propose to focus on the design of flexible matrices as a way of moving away from stiff, mechanical unitized systems and toward pliable, continuous 2D and 3D structures that can elastically change geometry in response to external stimuli without the need for external mechatronic energy input. As a proof-of-concept, we have produced an integrated panel-and-hinge assembly in which the panels and hinges are not discrete, mechanically connected components, but are instead functional zones of a continuous matrix. In addition, by controlling aspects of the individual units (panel size, hinge geometry, spacing, unit shape), we can induce larger-scale behavioral changes in the whole matrix.

AB - This paper explores the possibilities of kirigami geometry — folding with the addition of strategically placed cuts and holes — through simulation and kinetic and adaptive architectural assemblies. Typical kinetic assemblies consist of rigid components connected by mechanical joints that offer limited range of motion and tend to require mechatronic actuation. While mechanical motion is adequate for specific applications, mechanically motile systems lack the adaptive potential, elasticity, and embedded intelligence of adaptive structures. We propose to focus on the design of flexible matrices as a way of moving away from stiff, mechanical unitized systems and toward pliable, continuous 2D and 3D structures that can elastically change geometry in response to external stimuli without the need for external mechatronic energy input. As a proof-of-concept, we have produced an integrated panel-and-hinge assembly in which the panels and hinges are not discrete, mechanically connected components, but are instead functional zones of a continuous matrix. In addition, by controlling aspects of the individual units (panel size, hinge geometry, spacing, unit shape), we can induce larger-scale behavioral changes in the whole matrix.

KW - 3D printing

KW - Adaptive architecture

KW - Auxetic materials

KW - Computational design

KW - Kirigami

KW - Material design

KW - Programmable matter

KW - Simulation and modeling

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BT - Simulation Series

A2 - Turrin, Michela

A2 - Peters, Brady

A2 - Dogan, Timur

A2 - O'Brien, William

A2 - Stouffs, Rudi

PB - The Society for Modeling and Simulation International

Y2 - 22 May 2017 through 24 May 2017

ER -

Matrix architecture: 3d-printed and simulated kirigami matrices & auxetic materials

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Keywords

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