Optimization of a silencer design using an helmholtz resonators array in grazing incident waves for broadband noise reduction

In this work, we propose a general design strategy of passive acoustic treatments dealing with low fre-quency, broadband noise. The acoustic treatment is realized by arrays of Helmholtz resonators along the walls of the considered rectangular waveguide. The transfer matrix method is used to explicitly relate the geometric parameters of the resonators and acoustical response of the system. Based on this analyt-ical model, an optimization is carried out to find the optimized structural design that minimizes the transmission coefficient in the considered frequency range. By using this design method, two specific designs are provided; their acoustic performances are validated by both simulations and measurements. The proposed design method can be easily generalized for waveguide with other cross-section shape, and thus can find broad applications in engineering projects which consider noise reductions in heat ventila-tion and air conditioning systems. Note that this work does not consider the effect of an air flow in the waveguide, however the design strategy still applies when the mean flow Mach number is sufficiently small.(c) 2022 Elsevier Ltd. All rights reserved.

Automated summary

In this work, a general design strategy for passive acoustic treatments dealing with low frequency, broadband noise is proposed. The design involves the use of arrays of Helmholtz resonators along the walls of a rectangular waveguide. An analytical model based on the transfer matrix method is used to relate the resonator parameters and acoustic response of the system. Optimization is carried out to find the optimal structural design that minimizes the transmission coefficient in the desired frequency range. Two specific designs are provided and their acoustic performances are validated through simulations and measurements. The proposed design method can be easily applied to waveguides with different cross-sectional shapes and has broad applications in engineering projects involving noise reduction in HVAC systems.