Experimental verification of additively manufactured stacked multi-wedge acoustic black holes in beams for low frequency

Noise from machine vibrations and oscillations is a growing problem in today’s society. The use of acoustic black holes (ABH) in the area of passive vibration damping as an absorbing metamaterial is an active research field. Previous work has been successful mainly in the higher frequency range abov...

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Bibliographic Details
Published in:Mechanical systems and signal processing 2024-02, Vol.208, p.111065, Article 111065
Main Authors: Käfer, Max, Dohnal, Fadi, Goettgens, Valerie, Stajkovic, Janko, Brunner, Martin, Leichtfried, Gerhard
Format: Article
Language:English
Subjects:
Additive manufacturing
Metamaterial
Multi-wedge acoustic black hole
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Summary:Noise from machine vibrations and oscillations is a growing problem in today’s society. The use of acoustic black holes (ABH) in the area of passive vibration damping as an absorbing metamaterial is an active research field. Previous work has been successful mainly in the higher frequency range above 1500 Hz. This work aims at vibration damping in the lower frequency range below 1500 Hz. Here, additively manufactured multi-wedge ABH with two, three, four and ten wedges were welded to a beam structure and measured to estimate which number of wedges produces the best damping for a specific frequency range. The manufactured wedges largely absorbed a vast amount of the vibration energy induced into the structure and showed promising results. It was found that the more wedges were welded to the beam, the more natural frequencies occurred in the low frequency range. In the case of the ABH with ten wedges, ten eigenmodes were detected in this range, all of which absorbed the induced vibration energy effectively in the low frequency range. •Low frequency metamaterial exploiting acoustic black holes.•Tuning multi-wedge acoustic black holes for specific frequency ranges and their experimental verification.•Additive manufacturing for stacked multi-wedge acoustic black holes.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2023.111065