Experimental study of the acoustic frequency-up conversion effect by nonlinear thin plates
Abstract
Classical methods of sound absorption present fundamental limits that can be overcome by using nonlinear effects. Thin clamped plates have been identified as strongly nonlinear elements, capable of transferring the acoustic power of an incident air-borne wave towards higher frequencies. Here, we experimentally show that these plates exhibit different vibrational nonlinear behaviors depending on the amplitude and frequency of the excitation signal. The lowest excitation levels achieved lead to harmonic generation in a weakly nonlinear regime, while higher levels produce quasi-periodic and chaotic regimes. Since these nonlinear vibration regimes govern the acoustic frequency-up conversion process, we investigate the influence of relevant physical and geometrical parameters on the emergence of these nonlinear regimes. A parametric study on plates of different thicknesses reveals that the frequency-up conversion effect is mostly guided by the resonance of the plate at its first eigenfrequency, which depends not only on its thickness but also on a static tension introduced by the clamping. Finally, a design proposition involving multiple plates with different properties is presented in order to reach a broadband frequency-up conversion.