A Novel Lateral Deployment Mechanism for Segmented Mirror/Solar Panel of Space Telescope

Thesiya, Dignesh; Srinivas, A. R.; Shukla, Piyush Kumar

doi:10.1142/s2251171715500063

Cited by 10 publications

(4 citation statements)

References 6 publications

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“…Therefore, origami structure has aroused many researchers' interest and provided a continuous source of inspiration for the development of metamaterials. At present, origami structure has been utilized in medical devices, soft robots, protective armor, and aerospace [2][3][4][5][6][7][8].…”

Section: Introductionmentioning

confidence: 99%

Research About the Poisson’s Ratio of a Deployable Structure Based on the Kresling Origami

Wang,

Han

2023

Advances in Transdisciplinary Engineering

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Due to its unique mechanical properties, broad application prospect and design freedom, Kresling structure has been proven as a valuable tool to build deployable structures in numerous fields such as medical devices, high-tech weaponry and aerospace. However, the stress concentration caused by deformation incompatibility will occur when the structure is applied in combination with other structures Therefore, the deformation characteristic of the structure is studied in this paper. Different from the classical configuration, the Kresling structure whose relative angle (φ) between the top and bottom panels is 0 is selected in this paper. After simplification, the Poisson’s ratio of the structure during deploying and collapsing is studied, and the corresponding numerical model is constructed. Finally, finite element simulation is carried out to verify the numerical model, and the error between the simulation result and the numerical model is 2.81%, which demonstrates that the numerical model possesses the capacity to describe Poisson’s ratio of Kresling structure. In addition, the model proposed in this paper can also be utilized to predict the Poisson’s ratio of the model whose φ is not 0, which will have a significant effect in broadening the application range of the Kresling structure.

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Section: Introductionmentioning

confidence: 99%

Research About the Poisson’s Ratio of a Deployable Structure Based on the Kresling Origami

Wang,

Han

2023

Advances in Transdisciplinary Engineering

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“…Reconfigurable three-dimensional (3D) structures that can actively change their geometries and thereby their functionalities upon external stimuli (like mechanical forces, magnetic fields, hydration, and temperature) [1][2][3][4] are promising for a diverse range of applications including deployable solar panels 5 , electromagnetic metamaterials 6,7 , phononics [8][9][10] , biomedical devices 11,12 , soft robotics [13][14][15][16][17] , metasurfaces [18][19][20][21] , and many others. The design of reconfigurable structures usually relies on structural instabilities, stimuli-responsive constituent materials (like swellable gels and shape memory polymers) [22][23][24] , or their heterogeneous combinations 25 .…”

Section: Introductionmentioning

confidence: 99%

Reconfiguration of multistable 3D ferromagnetic mesostructures guided by energy landscape surveys

Avis

Chen

et al. 2021

Extreme Mechanics Letters

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Reconfigurable three-dimensional (3D) structures that can reversibly change their geometries and thereby their functionalities are promising for a wide range of applications. Despite intensive studies, the lack of fundamental understanding of the highly nonlinear multistable states existing in these structures has significantly hindered the development of reconfigurable systems that can realize rapid, well-controlled shape change. Herein we present a systematic, integrated experimental and computational study to control and tailor the multistable states of 3D structures and their reconfiguration paths. Our energy landscape analysis using a discrete shell model and minimum energy pathway methods leads to design maps for a controlled number of stable states by varying geometry and material parameters, and energy-efficient reconfiguration paths among the multistable states. Concurrently, our experiments show that 3D structures assembled from ferromagnetic composite thin films of diverse geometries can be rapidly reconfigured among their multistable states, with the number of stable states and reconfigurable paths in excellent agreement with computational predictions. In addition, we demonstrate a wide breadth of applications including reconfigurable 3D light emitting systems, remotely-controlled release of particles/drugs from a reconfigurable structure, and 3D structure arrays that can form desired patterns following the written path of a magnetic "pen". Our results represent a critical step towards the rational design and development of well-controlled, rapidly and remotely reconfigurable structures for many applications.

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“…Origami, the ancient art of folding two-dimensional (2D) thin sheets along predefined creases to create three-dimensional (3D) objects, 1-3 has inspired the design of many engineering structures for a wide range of applications, including deployable systems, [4][5][6] self-folding machines, 7 reconfigurable metamaterials, [8][9][10] and DNA origami. 11 For those applications, a key design feature of the structures is their ability to have multiple stable states as well as the tailoring of those states for tunability and adaptability.…”

Section: Introductionmentioning

confidence: 99%

Tailoring the multistability of origami-inspired, buckled magnetic structures via compression and creasing

Avis

Zhang

et al. 2021

Mater. Horiz.

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A Novel Lateral Deployment Mechanism for Segmented Mirror/Solar Panel of Space Telescope

Cited by 10 publications

References 6 publications

Research About the Poisson’s Ratio of a Deployable Structure Based on the Kresling Origami

Research About the Poisson’s Ratio of a Deployable Structure Based on the Kresling Origami

Reconfiguration of multistable 3D ferromagnetic mesostructures guided by energy landscape surveys

Tailoring the multistability of origami-inspired, buckled magnetic structures via compression and creasing

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