Impact Dispersion Using 2D and 3D Composite Granular Packing

Sen, Surajit; Mohan, T. R. Krishna; Tiwari, M. D.

doi:10.14356/kona.2017014

Cited by 10 publications

(3 citation statements)

References 47 publications

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“…Moreover, we find that for most other propagation angles the wave separates into two distinct solitary modes, each following a principal direction of symmetry. While 2D nonlinear elastic waves have been previously studied in granular media [22][23][24][25], the monolithicity and printability of our system allow facile control of the architecture, and hence control of the system's nonlinear dynamic response, providing a powerful platform to explore, visualize, and engineer new wave phenomena.…”

mentioning

confidence: 99%

Focusing and Mode Separation of Elastic Vector Solitons in a 2D Soft Mechanical Metamaterial

Deng

Tournat

et al. 2019

Phys. Rev. Lett.

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Soft mechanical metamaterials can support a rich set of dynamic responses, which, to date, have received relatively little attention. Here, we report experimental, numerical, and analytical results describing the behavior of an anisotropic two-dimensional flexible mechanical metamaterial when subjected to impact loading. We not only observe the propagation of elastic vector solitons with three components-two translational and one rotational-that are coupled together, but also very rich direction-dependent behaviors such as the formation of sound bullets and the separation of pulses into different solitary modes.

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confidence: 99%

Focusing and Mode Separation of Elastic Vector Solitons in a 2D Soft Mechanical Metamaterial

Deng

Tournat

et al. 2019

Phys. Rev. Lett.

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“…2 We can therefore have blocks with cubic packing of spheres, and a similar decorated arrangement at the interface, such that the radius of the sphere at the interface is twice that of the spheres below it. 67 The di↵erence is that the larger sphere is in contact with four smaller spheres at the interface, which leads to enhanced dispersion ability for the 3D arrangement. For the sphere arrangement at the interface as shown in Fig.…”

Section: Impact Decimation With Decorated Layers In 3dmentioning

confidence: 99%

Impact decimation using alignment of granular spheres

Tiwari

Mohan

Sen

2017

Int. J. Mod. Phys. B

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Solitary waves in alignment of elastic beads have been an important area of study. An important and rich area has been the behavior of solitary waves at a boundary, where features such as localization, anomalous behavior in scattering and transmission, quasiequilibrium phase, etc. are being studied. An application area of significance is the design of artificial granular alignments for shock decimation and dispersion. In this review article, we first present a summary and background of these unique features, and some designs in 1D which exploit these features. We further discuss some extensions to higher dimensional systems and their impact decimation ability.

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“…Impulse wave propagation is more attenuated in this quasi-one-dimensional (1D) tapered chain than the regular tapered chain. Ideas of stacking tapered granular chains into two-dimensional (2D) (Tiwari et al, 2016) and three-dimensional (3D) (Sen et al, 2017) space have been proposed recently. However, these studies on tapered granular structures in higher dimensions are limited to numerical investigation, and their experimental demonstration is yet elusive, mainly due to the challenges in their assembly.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear wave propagation in 3D-printed graded lattices of hollow elliptical cylinders

Kim

Yang

2019

Journal of the Mechanics and Physics of Solids

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We propose a 3D-printed graded lattice made of hollow elliptical cylinders (HECs) as a new way to design impact mitigation systems. We observe asymmetric dynamics in the graded HEC chains with increasing and decreasing stiffness. Specifically, the increasing stiffness chain shows an acceleration of the propagating waves, while the decreasing stiffness chain shows the opposite. From the standpoint of impact mitigation, the decreasing stiffness chain combined with the strain-softening behavior of HECs results in an order-of-magnitude improvement in force attenuation compared to the increasing stiffness chain. We extend this finding to the graded 2D arrays and demonstrate a similar trend of wave transmission efficiency contrast between the increasing and decreasing stiffness lattices. The 3D-printed HEC lattices shown in this study can lead to the development of a new type of impact mitigating and shock absorbing structures.

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Impact Dispersion Using 2D and 3D Composite Granular Packing

Cited by 10 publications

References 47 publications

Focusing and Mode Separation of Elastic Vector Solitons in a 2D Soft Mechanical Metamaterial

Focusing and Mode Separation of Elastic Vector Solitons in a 2D Soft Mechanical Metamaterial

Impact decimation using alignment of granular spheres

Nonlinear wave propagation in 3D-printed graded lattices of hollow elliptical cylinders

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