On the dynamics around targeted energy transfer for vibro-impact nonlinear energy sink

Li, Tao; Seguy, Sébastien; Berlioz, Alain

doi:10.1007/s11071-016-3127-0

Cited by 72 publications

(57 citation statements)

References 38 publications

(49 reference statements)

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“…A design procedure [24] is proposed and the suggested optimum regime is actually corresponding to the minimal point in the slow invariant manifold (SIM) [19]. There are some discrepancy between analytical calculations and numerical results because that the proposed analytical solution may not be stable [25]. The edge of chaos, i.e.…”

Section: Introductionmentioning

confidence: 99%

“…Based on the already developed asymptotic method [18][19][20], a general equation governing the variation of motion, e.g., the resonance part of SMR, is developed for both cubic and VI NES [28], in which the interaction force between NES and main structure plays the central role in explaining the variation of different response regimes. As a further study of VI NES, the study of the influence of parameters on dynamics is improved [25] from the previous study of different parameters in a separate way to the study of different parameters as a whole. By this way, their mutual influence and the same underlying mechanism is clearer.…”

Section: Introductionmentioning

confidence: 99%

“…zero amplitude of outside force), only the latter is analyzed. The objective here is to apply the asymptotic method used in a series of papers [18][19][20]25,28] to obtain the possible optimization design criterion of the system with damping rather than its underlying Hamiltonian system.…”

Section: Introductionmentioning

confidence: 99%

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Optimization mechanism of targeted energy transfer with vibro-impact energy sink under periodic and transient excitation

Seguy

Berlioz

2016

Nonlinear Dyn

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This paper is dedicated to exploit the same optimization mechanism of targeted energy transfer under different types of excitation. Specifically, a linear oscillator (LO) coupled with a vibro-impact (VI) nonlinear energy sink (NES) is analytically studied with an asymptotical method. The optimization mechanism under periodic excitation with a single frequency and under transient excitation is numerically obtained and experimentally validated for the first time. For periodic excitation, the boundary between the regime with two impacts per cycle and that of strongly modulated response (SMR) is proved to be optimal rather than SMR. The chaotic SMR is experimentally observed from the viewpoint of displacement of LO. The above observed mechanism is further applied to explain the optimization mechanism under transient excitation and that under periodic excitation with a range of frequency. It is experimentally verified that the optimization of the latter can be simplified to the optimization under an excitation with a single resonance frequency. For transient excitation, the efficiency of different transient response regimes is experimentally compared, which agrees with the periodic results. Moreover, the efficiency comparison of different lengths of cavity is also experimentally validated. In short, the close relation of optimization under different excitations is clearly demonstrated.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Optimization mechanism of targeted energy transfer with vibro-impact energy sink under periodic and transient excitation

Seguy

Berlioz

2016

Nonlinear Dyn

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“…We utilized such sliding friction as damping of the present NES, as it is simpler to implement than viscous damping. Moreover, we neglected frictions of the two guiders coupled to the springs, as they are nonbearing components with much smaller friction forces. Hence, the reaction force of the present NES is

F = 2 k ((), u - u_{c}) ((), 1 - l {(l_{0}^{2} + {((), u - u_{c})}^{2})}^{- 1 / 2}) + f,

where k and l are the constant stiffness and relaxation length of the hinged spring, respectively, and

u_{c} = \sqrt{l^{2} - l_{0}^{2}} .

…”

Section: Problem Formulationmentioning

confidence: 99%

“…McFarland et al realized the cubic NES (Type I NES) by using transverse elastic wire that yields geometrically nonlinear restoring force. Nucera et al, Ahmadi et al, Gendelman et al, and Li et al presented vibro‐impact NESs, which can absorb the vibration energy of the primary structure by transient internal resonance captured at high frequencies. Luo et al completed the shake table test on the large‐scale structure model, for which cubic NES and vibro‐impact NES were adopted for seismic control.…”

Section: Introductionmentioning

confidence: 99%

Seismic performance of a nonlinear energy sink with negative stiffness and sliding friction

Chen

Qian

Chen

et al. 2019

Struct Control Health Monit

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In this paper, to enhance passive targeted energy transfer, a novel nonlinear energy sink (NES) system is developed. The NES system integrates negative stiffness obtained through geometrical nonlinearities, friction, and sliding mass. Considering a one-story shear frame, governing equations of the NES system are developed and substantiated through experimental work. The governing equations of the system were subsequently used to select the optimal design parameters. The experimental results validate the numerical predictions that a significant fraction of energy introduced directly to the primary structure by seismic excitation is transferred to the present NES and dissipated. The seismic performance of the present NES is compared with those of the linear tuned mass damper and the cubic NES. The comparison shows that the attenuation observed under the present NES control is competitive and is robust with respect to variation of the primary structural stiffness. Numerically, further sensitivity analysis was carried out to investigate the effect of peak ground acceleration values and stiffness ratio.

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A Study on the Coefficient of Restitution Effect on Single-Sided Vibro-Impact Nonlinear Energy Sink

Saeed

AL-Shudeifat

2021

Perspectives in Dynamical Systems II: Mathematical and Numerical Approaches

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On the dynamics around targeted energy transfer for vibro-impact nonlinear energy sink

Cited by 72 publications

References 38 publications

Optimization mechanism of targeted energy transfer with vibro-impact energy sink under periodic and transient excitation

Optimization mechanism of targeted energy transfer with vibro-impact energy sink under periodic and transient excitation

Seismic performance of a nonlinear energy sink with negative stiffness and sliding friction

A Study on the Coefficient of Restitution Effect on Single-Sided Vibro-Impact Nonlinear Energy Sink

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