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A novel transient vibration and noise reducer (TVR) for vibratory machines

•In this study, a novel transient vibration and noise reducer is proposed.•It is a passive solution, but it works only in case of high displacements like an active damper.•Steady-state motion of compressor is considered, FEM-coupled design of experiments are conducted.•51% reduction in peak transien...

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Bibliographic Details
Published in:Applied acoustics 2022-12, Vol.201, p.109139, Article 109139
Main Authors: Oral, Atacan, Subasi, Omer, Korkmaz, Cansın, Lazoglu, Ismail
Format: Article
Language:English
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Summary:•In this study, a novel transient vibration and noise reducer is proposed.•It is a passive solution, but it works only in case of high displacements like an active damper.•Steady-state motion of compressor is considered, FEM-coupled design of experiments are conducted.•51% reduction in peak transient displacement and average 41 to 25 dBA in peak transient noise level decrease are recorded. Maximum vibration and maximum noise are generated during the transient startup and shut down operational phases of machines that demonstrate harmonic motion. Such vibrations and noise are especially undesired in household products. To abate such undesired effects associated with excessive body displacements and noise, a transient vibration and noise reducer (TVR) design is proposed, and a reciprocating compressor of a refrigerator is utilized in this study as an example. Polymer mount-spring sleeves with a stepwise geometry that allows free vibration during steady-state and vibration suppression only at transient phases are 3D printed to be installed at each leg of compressor body-outer housing linkage. Finite element analysis coupled design of experiments are conducted to characterize the vibration suppression response and to optimize the critical dimensional parameters of the TVR. The best candidate design is then implemented to a compressor to be compared against the performance of a compressor without the attachment of TVRs. The experimental results reveal a 51% decrease in peak transient displacement and a decrease from average 41 dBA to 25 dBA in peak transient noise level which are testaments to the success of the prospective design addition to the vibratory machines.
ISSN:0003-682X
1872-910X
DOI:10.1016/j.apacoust.2022.109139