“…(g) Supratransmission in a Kresling meta structure. Reprinted from [172], Copyright (2023), with permission from Elsevier. (h) Impact mitigation via rarefaction solitary wave creation.…”
Section: Metamaterials Bandgapsmentioning
confidence: 99%
“…Ywang et al [172] studied the nonlinear supratransmission 6 of waves in the bi-stable Kresling origami metamaterial shown in figure 23(g). They showed that, by exciting the structure near the resonant frequency of the KOS with a forcing amplitude greater than the threshold to escape the potential well of the state, the cells undergo large interwell oscillations.…”
Structures inspired by the Kresling origami pattern have recently emerged as a foundation for building functional engineering
systems with versatile characteristics that target niche applications spanning different technological fields. Their light weight,
deployability, modularity, and customizability are a few of the key characteristics that continue to drive their implementation
in robotics, aerospace structures, metamaterial and sensor design, switching, actuation, energy harvesting and absorption,
and wireless communications, among many other examples. This work aims to perform a systematic review of the literature
to assess the potential of the Kresling origami springs as a structural component for engineering design keeping three
objectives in mind: i) facilitating future research by summarizing and categorizing the current literature, ii) identifying the current
shortcomings and voids, and iii) proposing directions for future research to fill those voids.
“…(g) Supratransmission in a Kresling meta structure. Reprinted from [172], Copyright (2023), with permission from Elsevier. (h) Impact mitigation via rarefaction solitary wave creation.…”
Section: Metamaterials Bandgapsmentioning
confidence: 99%
“…Ywang et al [172] studied the nonlinear supratransmission 6 of waves in the bi-stable Kresling origami metamaterial shown in figure 23(g). They showed that, by exciting the structure near the resonant frequency of the KOS with a forcing amplitude greater than the threshold to escape the potential well of the state, the cells undergo large interwell oscillations.…”
Structures inspired by the Kresling origami pattern have recently emerged as a foundation for building functional engineering
systems with versatile characteristics that target niche applications spanning different technological fields. Their light weight,
deployability, modularity, and customizability are a few of the key characteristics that continue to drive their implementation
in robotics, aerospace structures, metamaterial and sensor design, switching, actuation, energy harvesting and absorption,
and wireless communications, among many other examples. This work aims to perform a systematic review of the literature
to assess the potential of the Kresling origami springs as a structural component for engineering design keeping three
objectives in mind: i) facilitating future research by summarizing and categorizing the current literature, ii) identifying the current
shortcomings and voids, and iii) proposing directions for future research to fill those voids.
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