Multi-degree of freedom nonlinear energy sinks for passive control of vortex-induced vibrations in a sprung cylinder

Multi-degree of freedom nonlinear energy sinks for passive control of vortex-induced vibrations in a sprung cylinder

The application of multi-degree of freedom nonlinear energy sinks (MDOF-NES) to control the vortex-induced vibrations of a sprung cylinder passively is investigated in this paper. The flow-induced loads on the cylinder are modeled by the wake Van der Pol oscillator. The MDOF-NES consists of three os...

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Bibliographic Details
Published in:Acta mechanica Vol. 232; no. 10; pp. 3917 - 3937
Main Authors: da Silva, José Augusto I., Marques, Flávio D.
Format: Journal Article
Language:English
Published: Vienna Springer Vienna 01-10-2021
Springer
Springer Nature B.V
Subjects:
Amplitudes
Classical and Continuum Physics
Control
Couplings
Cylinder liners
Dampers
Degrees of freedom
Design parameters
Dynamical Systems
Engineering
Engineering Fluid Dynamics
Engineering Thermodynamics
Frequency ranges
Heat and Mass Transfer
Limit cycle oscillations
Original Paper
Oscillators
Passive control
Solid Mechanics
Springs (elastic)
Stiffness
Synchronism
Theoretical and Applied Mechanics
Vibration
Vortex-induced vibrations
Vortices
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Summary:The application of multi-degree of freedom nonlinear energy sinks (MDOF-NES) to control the vortex-induced vibrations of a sprung cylinder passively is investigated in this paper. The flow-induced loads on the cylinder are modeled by the wake Van der Pol oscillator. The MDOF-NES consists of three oscillators connected in series, where the first mass is linked to the cylinder structure by a linear spring. The second mass is connected with the first and third masses by pure cubic springs and linear viscous dampers. The cylinder-MDOF-NES assemble model is analyzed in two scenarios involving lower and strong linear stiffness couplings. Numerical investigations of the bifurcation and limit cycle oscillation (LCO) behavior associated with parametric changes are performed. An appropriate design of the MDOF-NES parameters allows mitigating the sub-critical behavior and control LCO amplitudes. The MDOF-NES approach based on the lower linear stiffness coupling has shown to be more effective in controlling the LCO amplitudes. Moreover, it is verified that the MDOF-NES masses have a significant effect on the LCO stability, amplitudes, and synchronization frequency range. Comparison between the MDOF-NES and a classical Type I NES was also performed to ensure the superiority of the MDOF-NES in suppressing the vortex-induced oscillations.
ISSN:0001-5970
1619-6937
DOI:10.1007/s00707-021-03037-x