On the Frequency Up-Conversion Mechanism in Metamaterials-Inspired Vibro-Impact Structures

Rekhy, Anuj; Snyder, Robert J.; Manimala, James M.

doi:10.3390/acoustics1010011

Cited by 4 publications

(2 citation statements)

References 39 publications

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“…The combination of added linear and nonlinear dampers to an ABH beam is studied in [30], showing also important improvements toward broadband vibration mitigation. In related fields, other studies considered similar ideas and reported results, see for example the quadratic hysteretic nonlinearity characteristic of micro-inhomogeneous materials investigated in [31] for diminishing the wave speed, or the tuned mass-loaded membranes as vibro-impact attachments on a baseline structure in [32]. Nevertheless, all of these studies focus simply on the 1D beam case with a single type of nonlinearity.…”

Section: Introductionmentioning

confidence: 92%

Linear and nonlinear dynamics of a plate with acoustic black hole, geometric and contact nonlinearity for vibration mitigation

Touzé

Gautier

et al. 2021

Journal of Sound and Vibration

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A rectangular plate with a wedge profile creating an Acoustic Black Hole (ABH) termination is studied numerically. A particular emphasis is put on combining two different types of nonlinearity in order to improve the passive damping capacity of the ABH by transferring energy to the high-frequency range where it is more efficient. First, the addition of contact points to create a vibro-impact black hole (VI-ABH) is taken into account, following a previous study on beams. The contact nonlinearity allows for a rapid and efficient transfer of energy. Second, the large-amplitude vibrations of the plate in the ABH region where small thickness is reached, is also considered. The geometric nonlinearity is incorporated using a von Kármán plate model, and the regime of wave turbulence is shown to be triggered thus creating an energy flux from the low to the high frequencies. The linear characteristics of the ABH plate are first analyzed. Numerical results show the appearance of overdamped modes gathered in solution branches with constant number of half-waves in the transverse direction of the ABH, seen as a waveguide. The structure of the branches is shown to be more and more prominent when increasing the width of the plate, showing a transition from beam-like to full plate structure, with a fixed value for the fundamental cut-on frequency. The combination of both contact and geometric nonlinearities to improve the ABH effect is then reported. It is shown that the coexistence of both nonlinearities provides better passive damping efficacy.

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Section: Introductionmentioning

confidence: 92%

Linear and nonlinear dynamics of a plate with acoustic black hole, geometric and contact nonlinearity for vibration mitigation

Touzé

Gautier

et al. 2021

Journal of Sound and Vibration

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show abstract

“…However, the prospect of using material systems with non-linear response characteristics for sound barrier applications was investigated only recently by Rekhy et al [17]. The authors studied both numerically and experimentally the characteristics of plate structures with a mass-loaded membrane and an impactor; thus creating a non-linear system, and the feasibility of shifting energy from lower frequencies to higher frequencies was demonstrated.…”

Section: Introductionmentioning

confidence: 99%

Acoustical characteristics of segmented plates with contact interfaces

Varanasi

Siegmund

Bolton³

2020

Journal of Sound and Vibration

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The possibility of shifting sound energy from lower to higher frequency bands is investigated. The system configuration considered is a segmented structure having non-linear stiffness characteristics. It is proposed here that such a frequency-shifting mechanism could complement metamaterial concepts for mass-efficient sound barriers. The acoustical behavior of the material system was studied through a representative two-dimensional model consisting of a segmented plate with a contact interface. Multiple harmonic peaks were observed in response to a purely single frequency excitation, and the strength of the response was found to depend on the degree of non-linearity introduced. The lower and closer an excitation frequency was to the characteristic resonance frequencies of the base system, the stronger was the predicted higher harmonic response. The broadband sound transmission loss of these systems has also been calculated and the low frequency sound transmission loss was found to increase as the level of the broadband incident sound field increased. The present findings support the feasibility of designing material systems that transfer energy from lower frequency 1

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Review of exploiting nonlinearity in phononic materials to enable nonlinear wave responses

Patil

Matlack

2021

Acta Mech

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On the Frequency Up-Conversion Mechanism in Metamaterials-Inspired Vibro-Impact Structures

Cited by 4 publications

References 39 publications

Linear and nonlinear dynamics of a plate with acoustic black hole, geometric and contact nonlinearity for vibration mitigation

Linear and nonlinear dynamics of a plate with acoustic black hole, geometric and contact nonlinearity for vibration mitigation

Acoustical characteristics of segmented plates with contact interfaces

Review of exploiting nonlinearity in phononic materials to enable nonlinear wave responses

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