A Model for Multi-Input Mechanical Advantage in Origami-Based Mechanisms

Butler, Jared; Bowen, Landen; Wilcox, Eric W.; Shrager, Adam C.; Frecker, Mary; Lockette, Paris von; Simpson, Timothy W.; Lang, Robert J.; Howell, Larry L.; Magleby, Spencer P.

doi:10.1115/1.4041199

Cited by 22 publications

(14 citation statements)

References 44 publications

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“…[160] Messenger et al [161] integrated piezoresistive sensing into a microdisplacement transducer for closed-loop feedback control of thermal MEMS actuators. Magnetoelastic coupling was exploited by Butler et al [162] for an origami-based mechanism with multi-input mechanical advantage. Alternatively, bifurcations in compliant mechanism behavior, such as due to elastic instabilities, have been harnessed as means to detect both continuous gradients of response as well as thresholds of extreme events, including by electrostatic and piezoelectric coupling.…”

Section: Field-responsive Materials and Devicesmentioning

confidence: 99%

Foundations for Soft, Smart Matter by Active Mechanical Metamaterials

Pishvar

Harne

2020

Advanced Science

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Emerging interest to synthesize active, engineered matter suggests a future where smart material systems and structures operate autonomously around people, serving diverse roles in engineering, medical, and scientific applications. Similar to biological organisms, a realization of active, engineered matter necessitates functionality culminating from a combination of sensory and control mechanisms in a versatile material frame. Recently, metamaterial platforms with integrated sensing and control have been exploited, so that outstanding non‐natural material behaviors are empowered by synergistic microstructures and controlled by smart materials and systems. This emerging body of science around active mechanical metamaterials offers a first glimpse at future foundations for autonomous engineered systems referred to here as soft, smart matter. Using natural inspirations, synergy across disciplines, and exploiting multiple length scales as well as multiple physics, researchers are devising compelling exemplars of actively controlled metamaterials, inspiring concepts for autonomous engineered matter. While scientific breakthroughs multiply in these fields, future technical challenges remain to be overcome to fulfill the vision of soft, smart matter. This Review surveys the intrinsically multidisciplinary body of science targeted to realize soft, smart matter via innovations in active mechanical metamaterials and proposes ongoing research targets that may deliver the promise of autonomous, engineered matter to full fruition.

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Section: Field-responsive Materials and Devicesmentioning

confidence: 99%

Foundations for Soft, Smart Matter by Active Mechanical Metamaterials

Pishvar

Harne

2020

Advanced Science

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“…Different creases make a diversified possibility of origami structures, realizing various movements, e.g., stretching, [26] compressing, [36] bending, [39] stepping, [40] clamping, [25] jumping, [34,[41][42][43][44] flying, [45] etc. Consequently, the driving method of origami/ kirigami-inspired robots has developed well in past years, e.g., pneumatic drive, [26,28,[46][47][48] cable dragging, [33,34,49] magnetic traction, [25,35,36,[50][51][52] small-steering engine driving, [39] heat driving, [16] etc. In addition, integrated with various advanced functional materials, e.g., shape memory alloys DOI: 10.1002/adem.202100473 Origami/kirigami, the ancient art of paper folding and cutting techniques, has provided considerable inspiration for structural design routes in the engineering and medical fields over the last few decades.…”

Section: Introductionmentioning

confidence: 99%

“…As a result, many self-folding composites that could subsequently fold themselves into 3D shapes are generated. [4,7,[14][15][16][17][18] Previous studies in this area of research have been reported, e.g., the studies toward expandable stents, [19] high energy-weight ratio soft grippers, [20][21][22][23][24][25][26] worm-like soft robotics, [20,24,[27][28][29][30][31][32][33][34][35][36] vibration dampers, diameter-variable wheels, [37,38] etc. Different creases make a diversified possibility of origami structures, realizing various movements, e.g., stretching, [26] compressing, [36] bending, [39] stepping, [40] clamping, [25] jumping, [34,[41][42][43][44] flying, [45] etc.…”

Section: Introductionmentioning

confidence: 99%

Current Development on Origami/Kirigami‐Inspired Structure of Creased Patterns toward Robotics

Chen

et al. 2021

Adv Eng Mater

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Origami/kirigami, the ancient art of paper folding and cutting techniques, has provided considerable inspiration for structural design routes in the engineering and medical fields over the last few decades. The practicability of the methods and concepts of origami/kirigami has been demonstrated in several emerging classes of technologies, e.g., stretchable electronics, deformable devices, self‐assembly fabrication, etc. More and more related products are produced pursuing a folding form for better storage, deformation capacity, and multifunction realization. Herein, the innovative creased patterns of origami/kirigami designs are distinguished and discussed, and the four most widely used creased pattern types are introduced, which may potentially provide origami/kirigami related inspiration and additional solutions toward many research fields.

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“…Its unique motion has provided footing for the emergence of new mechanisms [33]. Analysis of origami and its motion has already found application in robotics [34][35][36][37][38][39][40] and has been used in the development of medical devices [41][42][43].…”

Section: Introductionmentioning

confidence: 99%

An Origami-Based Medical Support System to Mitigate Flexible Shaft Buckling

Sargent

Butler

Seymour

et al. 2020

Journal of Mechanisms and Robotics

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This paper presents the development of an origami-inspired support system (the OriGuide) that enables the insertion of flexible instruments using medical robots. Varying parameters of a triangulated cylindrical origami pattern were combined to create an effective highly compressible anti-buckling system that maintains a constant inner diameter for supporting an instrument and a constant outer diameter throughout actuation. The proposed origami pattern is composed of two repeated patterns: a bistable pattern to create support points to mitigate flexible shaft buckling and a monostable pattern to enable axial extension and compression of the support system. The origami-based portion of the device is combined with two rigid mounts for interfacing with the medical robot. The origami-based portion of the device is fabricated from a single sheet of polyethylene terephthalate. The length, outer diameter, and inner diameter that emerge from the fold pattern can be customized to accommodate various robot designs and flexible instrument geometries without increasing the part count. The support system also adds protection to the instrument from external contamination.

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A Model for Multi-Input Mechanical Advantage in Origami-Based Mechanisms

Cited by 22 publications

References 44 publications

Foundations for Soft, Smart Matter by Active Mechanical Metamaterials

Foundations for Soft, Smart Matter by Active Mechanical Metamaterials

Current Development on Origami/Kirigami‐Inspired Structure of Creased Patterns toward Robotics

An Origami-Based Medical Support System to Mitigate Flexible Shaft Buckling

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