A Review of Thickness-Accommodation Techniques in Origami-Inspired Engineering

Lang, Robert J.; Tolman, Kyler A.; Crampton, Erica B.; Magleby, Spencer P.; Howell, Larry L.

doi:10.1115/1.4039314

Cited by 153 publications

(48 citation statements)

References 113 publications

(133 reference statements)

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“…In other words, the origami has a dual-stiffness behavior that conveniently merges the features of rigid and soft systems: load bearing in the stiff state and resilience and safe interaction in the soft state. Moreover, the membrane stretches during folding and stores elastic energy that can be used to rapidly deploy the compliant origami, and it can intrinsically accommodate the thickness of the tiles in folded state without resorting to dedicated methods that increase design and manufacturing complexity (16,32). For a given geometry of the fold and material of the membrane, the behavior of the dual-stiffness origami depends on two parameters.…”

Section: Resultsmentioning

confidence: 99%

Bioinspired dual-stiffness origami

2018

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Origami manufacturing has led to considerable advances in the field of foldable structures with innovative applications in robotics, aerospace, and metamaterials. However, existing origami are either load-bearing structures that are prone to tear and fail if overloaded or resilient soft structures with limited load capability. In this manuscript, we describe an origami structure that displays both high load bearing and high resilience characteristics. The structure, which is inspired by insect wings, consists of a prestretched elastomeric membrane, akin to the soft resilin joints of insect wings, sandwiched between rigid tiles, akin to the rigid cuticles of insect wings. The dualstiffness properties of the proposed structure are validated by using the origami as an element of a quadcopter frame that can withstand aerodynamic forces within its flight envelope but softens during collisions to avoid permanent damage. In addition, we demonstrate an origami gripper that can be used for rigid grasping but softens to avoid overloading of the manipulated objects.

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Section: Resultsmentioning

confidence: 99%

Bioinspired dual-stiffness origami

2018

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“…1c), respectively, where symbols with subscripts max and min are the corresponding maximum and minimum dimensions. Some engineering considerations like residual deformation 32,33 , sheet thickness [34][35][36] , and external forces 36 reduce the range of the folding degree φ in a Miura-ori design (Fig. 2c).…”

Section: Geometry Analysis Of Mo-scbsmentioning

confidence: 99%

“…• Ideal folding range (RANGE I): For an ideal Miura-ori structure with negligible sheet thickness and bending radius, the maximum and minimum in-plane dimensions are taken to be those in the flat-folded state 36 and fully unfolded state, respectively.…”

Section: Geometry Analysis Of Mo-scbsmentioning

confidence: 99%

Miura-ori enabled stretchable circuit boards

Liu

Deng

et al. 2021

npj Flex Electron

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Origami, an ancient form of papercraft, provides a way to develop functional structures for engineering applications. In this paper, we report an approach to design and manufacture a stretchable circuit board (SCB) with origami structures. The benefits of developable, flat-foldable, and rigid-foldable origami-based structures as SCBs are discussed, and a representative structure, Miura fold (or Miura-ori), is chosen to be investigated. Under the constraints induced by the mounted components’ dimensions, the Miura-ori structures for specific applications can be defined. We propose three methods for better fabrication, including direct folding, stiffness modification, and kirigami enhancement, to improve a planar sheet’s foldability. A wearable ECG (electrocardiogram) system based on MO-SCB (Miura-ori enabled SCB) technology is built, and the stretchable portion is made of commercial FPCBs (flexible printed circuit board), providing desired stretchability and reliability. The proposed technology routine is compatible with industrial production and may pave the application of stretchable electronics.

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“…These algorithms are not limited to paper, although the algorithms typically neglect the effect of substrate thickness and, thus, work best on materials that are thin and inextensible, like paper. Oftentimes, the desired structures need to be made of materials that have a non-negligible thickness [7,8]. Folding rigid materials is typically done by attaching rigid facets with compliant hinges [9], but this places restrictions on what can be produced, a term called rigid foldability [10].…”

Section: Introductionmentioning

confidence: 99%

Making Light Work of Metal Bending: Laser Forming in Rapid Prototyping

Bachmann

Dickey

Lazarus

2020

QuBS

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Lasers can be used to bend 2D metal sheets into complex 3D objects in a process called ‘laser forming.’ Laser forming bends metal sheets by locally heating the sheets to generate plastic strains and is an established metal bending technology in the shipbuilding industry. Recent studies have investigated the laser forming of thin metal parts as a complementary rapid prototyping technology to metal 3D printing. This review discusses the laser forming process, beginning with the mechanisms before covering various design considerations. Laser forming for the rapid manufacturing of metal parts is then reviewed, including the recent advances in process planning, before highlighting promising future research directions.

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A Review of Thickness-Accommodation Techniques in Origami-Inspired Engineering

Cited by 153 publications

References 113 publications

Bioinspired dual-stiffness origami

Bioinspired dual-stiffness origami

Miura-ori enabled stretchable circuit boards

Making Light Work of Metal Bending: Laser Forming in Rapid Prototyping

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