Rapid deployment of curved surfaces via programmable auxetics

Konaković-Luković, Mina; Panetta, Julian; Crane, Keenan; Pauly, Mark

doi:10.1145/3197517.3201373

Cited by 109 publications

(109 citation statements)

References 39 publications

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“…Konaković et al [2016] and Malomo et al [2018] exploit parametric auxetic metamaterials to optimize two-dimensional plates that can assume three-dimensional custom shapes when deformed. In a similar vein, Konaković-Luković [2018] investigate the design of spatially-graded auxetic metamaterials that can be deployed into desired shapes. However, restricting materials for the inverse problems to originate from a single family of microstructures, selected a priori, limits the space of achievable behaviors and therefore the scope of the proposed methods.…”

Section: Related Workmentioning

confidence: 99%

Star-shaped metrics for mechanical metamaterial design

et al. 2019

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We present a method for designing mechanical metamaterials based on the novel concept of Voronoi diagrams induced by star-shaped metrics. As one of its central advantages, our approach supports interpolation between arbitrary metrics. This capability opens up a rich space of structures with interesting aesthetics and a wide range of mechanical properties, including isotropic, tetragonal, orthotropic, as well as smoothly graded materials. We evaluate our method by creating large sets of example structures, provided as accompanying material. We validate the mechanical properties predicted by simulation through tensile tests on a set of physical prototypes.

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Section: Related Workmentioning

confidence: 99%

Star-shaped metrics for mechanical metamaterial design

et al. 2019

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“…Follow-up work, likewise based on conformal geometry, treats the process of deployment of a more general class of cut/fold patterns. [Konaković-Luković et al 2018] construct structures that are fully deployed exactly when the limit of expansion is reached. The class of possible shapes achievable in this way includes nonconvex ones and is only restricted by the Fig.…”

Section: Previous Workmentioning

confidence: 99%

Freeform quad-based kirigami

et al. 2020

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Kirigami, the traditional Japanese art of paper cutting and folding generalizes origami and has initiated new research in material science as well as graphics. In this paper we use its capabilities to perform geometric modeling with corrugated surface representations possessing an isometric unfolding into a planar domain after appropriate cuts are made. We initialize our box-based kirigami structures from orthogonal networks of curves, compute a first approximation of their unfolding via mappings between meshes, and complete the process by global optimization. Besides the modeling capabilities we also study the interesting geometry of special kirigami structures from the theoretical side. This experimental paper strives to relate unfoldable checkerboard arrangements of boxes to principal meshes, to the transformation theory of discrete differential geometry, and to a version of the Gauss theorema egregium.

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“…Researchers successfully fabricated 3D surfaces with inflatable structures [Skouras et al 2014], cut-and-sew method [Mori and Igarashi 2007], and non-stretchable airbags [Ou et al 2016]. Auxetic structures can transform under air pressure, gravity, or manual activation [Konaković-Luković et al 2018;Wang et al 2018a]. The in-plane strain of pneumatic channels can be turned into out-ofplane shape change [Siéfert et al 2019].…”

Section: Related Work 21 2d-to-3d Shape Changing Mechanismmentioning

confidence: 99%

Inverse Design Tool for Asymmetrical Self-Rising Surfaces with Color Texture

Narayanan

Wang

et al. 2020

Symposium on Computational Fabrication

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4D printing encodes self-actuating deformation during the printing process, such that objects can be fabricated flat and then transformed into target 3D shapes. While many flattening algorithms have been introduced for 4D printing, a general method customized for FDM (Fused-Deposition Modeling) printing method is lacking. In this work, we vary both the printing direction and local layer thickness; and extend the shape space to continuous-height-field surfaces without the requirement of symmetry. We introduce an end-to-end tool that enables an initially flat sheet to self-transform into the input height field. The tool first flattens the height field into a 2D layout with stress information using a geometry-based optimization algorithm, then computes printing tool paths with a path planning algorithm. Although FDM printing is the fabrication method in this work, our approach can be applied to most extrusion-based printing methods in theory. The results exemplify how the tool broadens the capabilities of 4D printing with an expanded shape space, a low-cost but precise coloring technique, and an intuitive design process. CCS CONCEPTS • Computing methodologies → Interactive simulation; Mesh geometry models; Physical simulation; • Human-centered computing → Graphical user interfaces; • Applied computing → Computer-aided manufacturing.

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Rapid deployment of curved surfaces via programmable auxetics

Cited by 109 publications

References 39 publications

Star-shaped metrics for mechanical metamaterial design

Star-shaped metrics for mechanical metamaterial design

Freeform quad-based kirigami

Inverse Design Tool for Asymmetrical Self-Rising Surfaces with Color Texture

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