Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis
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![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/profile/Mehrdad-Farajzadeh-Ahari/publication/375416877/figure/fig5/AS:11431281203464883@1699325799727/Ratio-of-nonlinear-to-linear-natural-frequency-versus-porosity-coefficient-for-different_Q320.jpg)
Ratio of nonlinear to linear natural frequency versus porosity
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/351971213/figure/fig7/AS:1029032099450892@1622351779793/The-influence-of-the-constant-gain-for-time-domain-response.png)
The influence of the constant gain for time-domain response
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://media.springernature.com/lw685/springer-static/image/art%3A10.1007%2Fs00419-017-1240-2/MediaObjects/419_2017_1240_Fig14_HTML.gif)
General three-dimensional scattering and dynamic stress concentration of Lamb-like waves in a spherical shell with a spherical inclusion
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://media.springernature.com/w215h120/springer-static/image/art%3A10.1365%2Fs13291-021-00241-5/MediaObjects/13291_2021_241_Fig1_HTML.png)
On the eversion of incompressible elastic spherical shells
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/358750397/figure/fig2/AS:11431281111836837@1673232763163/Nonlocal-nonlinear-frequency-versus-aspect-ratio-for-different-values-of-the_Q320.jpg)
The dynamic model of the functionally graded graphene platelet
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/373339209/figure/fig1/AS:11431281183423258@1692878933473/Translational-and-rotational-equilibrium-of-the-elementary-ashlar-Separate-contributions_Q320.jpg)
The variation of equivalent mechanical properties along the thickness
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/367389470/figure/fig4/AS:11431281149724162@1681824446360/Nine-nodded-isoparametric-element_Q320.jpg)
In-plane displacement throughout the laminate's plate thickness
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/354411986/figure/fig5/AS:1065630409175056@1631077496283/Effect-of-GPL-geometry-size-on-fundamental-natural-frequency-of-flap-wise-bending_Q320.jpg)
Free vibration frequency ω (rad/s) of GPL reinforced porous composite
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/371035906/figure/fig1/AS:11431281176023783@1689991124028/Schematic-view-of-general-doubly-curved-shell_Q320.jpg)
The scheme of HM-carbon fiber nanocomposite joined
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/342227389/figure/fig5/AS:11431281212989747@1702948463636/Three-dimensional-non-destructive-X-ray-micro-computed-tomography-3D-micro-CT-images-of_Q320.jpg)
The mode shapes of the rotating pretwisted composite tapered cantilever
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/355971434/figure/fig1/AS:11431281118867094@1675911821865/Description-for-large-deflection-non-uniform-beam-with-arbitrary-boundary-conditions_Q320.jpg)
The variation of (a) Young's modulus and (b) density of porous HM
![Nonlinear vibrations of graphene-reinforced porous rotating conical shell with arbitrary boundary conditions using traveling wave vibration analysis](https://www.researchgate.net/publication/352557120/figure/fig3/AS:11431281098002431@1668740329259/The-variation-of-a-Youngs-modulus-and-b-density-of-porous-HM-according-to_Q320.jpg)
The variation of (a) Young's modulus and (b) density of porous HM
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