A Computational Design Methodology for Assembly and Actuation of Thin-Film Structures via Patterning of Eigenstrains

Howard, Micah; Pajot, Joseph M.; Maute, Kurt; Dunn, Martin L.

doi:10.1109/jmems.2009.2025562

Cited by 11 publications

(5 citation statements)

References 47 publications

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“…We developed a theoretical model to describe the behavior of the printed active composite hinges and used it to design several active origami structures, including a self-assembling box and pyramid and two origami airplanes. While our design parameters here were limited to composite hinges placed at locations where we desired folding, a more flexible approach based on topology optimization with active materials could be used in more general situations (Howard et al 2009, Pajot et al 2006. Finally, we also demonstrated the direct printing of a complex 3D structure that can then be programmed to assume a simpler temporary shape (a flat sheet in our case) and then recover its original 3D shape.…”

Section: Discussionmentioning

confidence: 99%

Active origami by 4D printing

Ge¹,

Dunn²,

Hu³

et al. 2014

Smart Mater. Struct.

592

398

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Recent advances in three dimensional (3D) printing technology that allow multiple materials to be printed within each layer enable the creation of materials and components with precisely controlled heterogeneous microstructures. In addition, active materials, such as shape memory polymers, can be printed to create an active microstructure within a solid. These active materials can subsequently be activated in a controlled manner to change the shape or configuration of the solid in response to an environmental stimulus. This has been termed 4D printing, with the 4th dimension being the time-dependent shape change after the printing. In this paper, we advance the 4D printing concept to the design and fabrication of active origami, where a flat sheet automatically folds into a complicated 3D component. Here we print active composites with shape memory polymer fibers precisely printed in an elastomeric matrix and use them as intelligent active hinges to enable origami folding patterns. We develop a theoretical model to provide guidance in selecting design parameters such as fiber dimensions, hinge length, and programming strains and temperature. Using the model, we design and fabricate several active origami components that assemble from flat polymer sheets, including a box, a pyramid, and two origami airplanes. In addition, we directly print a 3D box with active composite hinges and program it to assume a temporary flat shape that subsequently recovers to the 3D box shape on demand.

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Section: Discussionmentioning

confidence: 99%

Active origami by 4D printing

Ge¹,

Dunn²,

Hu³

et al. 2014

Smart Mater. Struct.

592

398

View full text Add to dashboard Cite

show abstract

“…Numerical algorithms that can track the nonlinear structural response following a path that exhibits snap-through behavior have been developed [194][195][196][197][198]. Recent efforts have also showcased the use of topology optimization to find material layouts that lead to larger displacement and energy release from snap-through behavior for different purposes, such as actuators [61,73,83,145,199], energy harvesters [53,56,200], dampers [67], multistable compliant mechanisms [201,202], thermoelectric generators [203], and flutter control [36]. Thus, topology optimization is a promising technique for finding new structural and material layouts to meet a targeted elastic unstable response.…”

Section: In Prototypesmentioning

confidence: 99%

Buckling-induced smart applications: recent advances and trends

Burgueño

2015

Smart Mater. Struct.

296

139

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A paradigm shift has emerged over the last decade pointing to an exciting research area dealing with the harnessing of elastic structural instabilities for 'smart' purposes in a variety of venues. Among the different types of unstable responses, buckling is a phenomenon that has been known for centuries, and yet it is generally avoided through special design modifications. Increasing interest in the design of smart devices and mechanical systems has identified buckling and postbuckling response as a favorable behavior. The objective of this topical review is to showcase the recent advances in buckling-induced smart applications and to explain why buckling responses have certain advantages and are especially suitable for these particular applications. Interesting prototypes in terms of structural forms and material uses associated with these applications are summarized. Finally, this review identifies potential research avenues and emerging trends for using buckling and other elastic instabilities for future innovations.

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“…In this respect, several numerical methods have been presented to address these problems by providing a predictive window for these interesting behaviors. Diverse aspects of LCNs ranging from the effect of different molecular compositions to structural behavior [18] to the programming of bending curvatures induced by changing macroscopic shapes of structures [19,20] have been investigated. Furthermore, multiscale methods where one or two numerical methods are intertwined have also been proposed [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Recent Trends in Continuum Modeling of Liquid Crystal Networks: A Mini-Review

Park

Moon

et al. 2023

Polymers

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This work aims to provide a comprehensive review of the continuum models of the phase behaviors of liquid crystal networks (LCNs), novel materials with various engineering applications thanks to their unique composition of polymer and liquid crystal. Two distinct behaviors are primarily considered: soft elasticity and spontaneous deformation found in the material. First, we revisit these characteristic phase behaviors, followed by an introduction of various constitutive models with diverse techniques and fidelities in describing the phase behaviors. We also present finite element models that predict these behaviors, emphasizing the importance of such models in predicting the material’s behavior. By disseminating various models essential to understanding the underlying physics of the behavior, we hope to help researchers and engineers harness the material’s full potential. Finally, we discuss future research directions necessary to advance our understanding of LCNs further and enable more sophisticated and precise control of their properties. Overall, this review provides a comprehensive understanding of the state-of-the-art techniques and models used to analyze the behavior of LCNs and their potential for various engineering applications.

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A Computational Design Methodology for Assembly and Actuation of Thin-Film Structures via Patterning of Eigenstrains

Cited by 11 publications

References 47 publications

Active origami by 4D printing

Active origami by 4D printing

Buckling-induced smart applications: recent advances and trends

Recent Trends in Continuum Modeling of Liquid Crystal Networks: A Mini-Review

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