Shape-morphing architected sheets with non-periodic cut patterns

Paolo Celli; Connor McMahan; Brian Ramirez; Anton Bauhofer; Christina Naify; Douglas Hofmann; Basile Audoly; Chiara Daraio

doi:10.1039/c8sm02082e

Shape-morphing architected sheets with non-periodic cut patterns

Paolo Celli
, Connor McMahan
, Brian Ramirez
, Anton Bauhofer
, Christina Naify
, Douglas Hofmann
, Basile Audoly
, Chiara Daraio

Civil Engineering

California Institute of Technology
Swiss Federal Institute of Technology Zurich
Institut polytechnique de Paris

Research output: Contribution to journal › Article › peer-review

106 Scopus citations

Abstract

We investigate the out-of-plane shape morphing capability of single-material elastic sheets with architected cut patterns that result in arrays of tiles connected by flexible hinges. We demonstrate that a non-periodic cut pattern can cause a sheet to buckle into three-dimensional shapes, such as domes or patterns of wrinkles, when pulled at specific boundary points. These global buckling modes are observed in experiments and rationalized by an in-plane kinematic analysis that highlights the role of the geometric frustration arising from non-periodicity. The study focuses on elastic sheets, and is later extended to elastic-plastic materials to achieve shape retention. Our work illustrates a scalable route towards the fabrication of three-dimensional objects with nonzero Gaussian curvature from initially-flat sheets.

Original language	English
Pages (from-to)	9744-9749
Number of pages	6
Journal	Soft Matter
Volume	14
Issue number	48
DOIs	https://doi.org/10.1039/c8sm02082e
State	Published - 2018

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10.1039/c8sm02082e

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title = "Shape-morphing architected sheets with non-periodic cut patterns",

abstract = "We investigate the out-of-plane shape morphing capability of single-material elastic sheets with architected cut patterns that result in arrays of tiles connected by flexible hinges. We demonstrate that a non-periodic cut pattern can cause a sheet to buckle into three-dimensional shapes, such as domes or patterns of wrinkles, when pulled at specific boundary points. These global buckling modes are observed in experiments and rationalized by an in-plane kinematic analysis that highlights the role of the geometric frustration arising from non-periodicity. The study focuses on elastic sheets, and is later extended to elastic-plastic materials to achieve shape retention. Our work illustrates a scalable route towards the fabrication of three-dimensional objects with nonzero Gaussian curvature from initially-flat sheets.",

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AU - Celli, Paolo

AU - McMahan, Connor

AU - Ramirez, Brian

AU - Bauhofer, Anton

AU - Naify, Christina

AU - Hofmann, Douglas

AU - Audoly, Basile

AU - Daraio, Chiara

PY - 2018

Y1 - 2018

N2 - We investigate the out-of-plane shape morphing capability of single-material elastic sheets with architected cut patterns that result in arrays of tiles connected by flexible hinges. We demonstrate that a non-periodic cut pattern can cause a sheet to buckle into three-dimensional shapes, such as domes or patterns of wrinkles, when pulled at specific boundary points. These global buckling modes are observed in experiments and rationalized by an in-plane kinematic analysis that highlights the role of the geometric frustration arising from non-periodicity. The study focuses on elastic sheets, and is later extended to elastic-plastic materials to achieve shape retention. Our work illustrates a scalable route towards the fabrication of three-dimensional objects with nonzero Gaussian curvature from initially-flat sheets.

AB - We investigate the out-of-plane shape morphing capability of single-material elastic sheets with architected cut patterns that result in arrays of tiles connected by flexible hinges. We demonstrate that a non-periodic cut pattern can cause a sheet to buckle into three-dimensional shapes, such as domes or patterns of wrinkles, when pulled at specific boundary points. These global buckling modes are observed in experiments and rationalized by an in-plane kinematic analysis that highlights the role of the geometric frustration arising from non-periodicity. The study focuses on elastic sheets, and is later extended to elastic-plastic materials to achieve shape retention. Our work illustrates a scalable route towards the fabrication of three-dimensional objects with nonzero Gaussian curvature from initially-flat sheets.

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VL - 14

SP - 9744

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JO - Soft Matter

JF - Soft Matter

IS - 48

ER -

Shape-morphing architected sheets with non-periodic cut patterns

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