Abstract
Non-linear damped vibrations of a cylindrical shell embedded into a fractional derivative medium are investigated for the case of the combinational internal resonance, resulting in modal interaction, using two different numerical methods with further comparison of the results obtained. The damping properties of the surrounding medium are described by the fractional derivative Kelvin-Voigt model utilizing the Riemann-Liouville fractional derivatives. Within the first method, the generalized displacements of a coupled set of nonlinear ordinary differential equations of the second order are estimated using numerical solution of nonlinear multi-term fractional differential equations by the procedure based on the reduction of the problem to a system of fractional differential equations. According to the second method, the amplitudes and phases of nonlinear vibrations are estimated from the governing nonlinear differential equations describing amplitude-and-phase modulations for the case of the combinational internal resonance. A good agreement in results is declared.
Highlights
Shells are in the art of many structural and building elements due to their several applications
According to the second method, the amplitudes and phases of nonlinear vibrations are estimated from the governing nonlinear differential equations describing amplitude-and-phase modulations for the case of the combinational internal resonance [7] using the Runga-Kutta fourth order method
Free damped vibrations of a shallow nonlinear thin cylindrical shell in a fractional derivative viscoelastic medium are investigated numerically by two different methods based on the new approach proposed in [6]
Summary
Shells are in the art of many structural and building elements due to their several applications. The procedure resulting in decoupling linear parts of equations is proposed with the further use of the method of multiple scales for solving nonlinear governing equations of motion. This procedure has been utilized for the analytical analysis of free vibrations of cylindrical shell subjected to the conditions of the different internal resonances, resulting in the interaction of two (in the case of two-toone, one-to-one or three-to-one internal resonance [6, 9]) or three modes corresponding to the mutually orthogonal displacements (in the case of combinational internal resonances of additive or difference type [7]). According to the second method, the amplitudes and phases of nonlinear vibrations are estimated from the governing nonlinear differential equations describing amplitude-and-phase modulations for the case of the combinational internal resonance [7] using the Runga-Kutta fourth order method
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