Sound Transmission Through a Finite-Sized Double Panel Cavity with a Micro-Perforated Panel Insertion
Zhenwei. Zhou, Jiaming. Wu, and Zhiyu Yang

TL;DR
This study introduces a theoretical model for a double-panel cavity with a micro-perforated plate that enhances sound insulation across various frequencies, validated by numerical and experimental results.
Contribution
It presents a comprehensive theoretical model considering all structural couplings and demonstrates improved sound transmission loss with micro-perforated plates.
Findings
Significant STL improvement at certain frequencies with micro-perforated insertion
Resonance weakening below 200 Hz due to energy dissipation
Broadband STL enhancement at medium to high frequencies
Abstract
This paper proposes a noise insulation cavity composed of two parallel plates and a micro-perforated plate insertion parallel to the plates, which divides the cavity between the plates into two parts. A theoretical model was established that takes into account of all the couplings among the major parts of the structure, namely the two solid plates, the perforated plate, and the air cavity, together with the simply support boundary conditions. Numerical calculations were performed with different parameters of the micro-perforated plate including its position, perforation ratio, plate thickness, and hole diameters. The calculations indicated that the proposed double-panel structure with a micro-perforated plate insertion exhibited significant improvements in the sound transmission loss (STL) in certain frequency range as compared to a double- or triple-panel structure without a…
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Taxonomy
TopicsAcoustic Wave Phenomena Research · Aerodynamics and Acoustics in Jet Flows · Vehicle Noise and Vibration Control
