Experimental characterization of acoustic damping materials

Journal
Proceedings in applied mathematics and mechanics  
Volume
24
Issue
3
Article Number
e202400143
Citation
Proceedings in Applied Mathematics and Mechanics 24 (3): e202400143 (2024)
Contribution to Conference
94th Annual Meeting of the International Association of Applied Mathematics and Mechanics, GAMM 2024  
Publisher DOI
10.1002/pamm.202400143
Publisher
Wiley
Due to their ease of use and low cost, passive damping methods are a preferred mean for the reduction of noise in many engineering applications. This applies in particular to foam materials, which exhibit good acoustic and mechanical damping properties. The selection of suitable materials is usually carried out experimentally and can be very labor‐intensive and time‐consuming. For this reason, it is helpful to develop qualified numerical methodsthat can be used for material design and selection. Hence, foam materials must be characterized experimentally in order to enable a later comparison with vibroacoustic simulations. This contribution, therefore, aims at providing suitable parameters for the use in numerical analyses and their validation. Firstly, the microstructure of a foam specimen is captured by means of a CT scan. In addition to providing the geometry for the multi‐physics simulations, this measurement is also used to determine characteristic foam features, for example, strut thickness and pore size distribution. In the second step, the frequency‐dependent stiffness and damping properties of the material are determined by a special experimental setup utilizing an electrodynamic shaker. Here, the dynamic system is approximated as a single‐mass oscillator, which is sufficiently accurate for low frequencies. These properties will later be used in the numerical model to evaluate different parameter identification approaches. In the third and last step of the experimental campaign, measurements with an impedance tube are conducted to obtain the coefficient of absorption. This material parameter is particularly suitable for comparing experiments and simulations. Finally, the correlation between the experimental results is examined to provide a deeper understanding of the foam materials.
DDC Class
620.1: Engineering Mechanics and Materials Science
530: Physics
Publication version
publishedVersion
Lizenz
https://creativecommons.org/licenses/by/4.0/
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