The dynamic behaviour of a finite periodic structure comprising either symmetric or asymmetric exponential- and conical-shaped rods

•A passive vibration control strategy is developed using rods with exponential and conical varying cross sections.•Symmetrical and asymmetrical periodic cells configurations are explored.•Results are validated by experimental tests for different cells configurations. Periodic structure research is d...

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Bibliographic Details
Published in:Journal of sound and vibration 2025-01, Vol.595, p.118741, Article 118741
Main Authors: da Silva, Camila Albertin Xavier, Sorokin, Vladislav, Brennan, Michael John, Gonçalves, Paulo José Paupitz
Format: Article
Language:English
Subjects:
Asymmetric structure
Bandgap
Non-uniform cross-section
Periodic structures
Symmetric structure
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Summary:•A passive vibration control strategy is developed using rods with exponential and conical varying cross sections.•Symmetrical and asymmetrical periodic cells configurations are explored.•Results are validated by experimental tests for different cells configurations. Periodic structure research is driven by the aim of incorporating them into modern engineering systems to address specific challenges, such as vibration reduction within defined frequency ranges. This paper explores the dynamic behaviour of a periodic structure comprising rods with varying cross-sectional areas. Two specific cases are considered, one in which the unit cell consists of two rods where the cross-sectional area varies exponentially and one where the cross-sectional areas vary conically. The structures are modelled using receptance matrices of a single cell, which are then transformed into transfer matrices. This facilitates a comparison of the two structures and helps to relate the results between finite and infinite structures. An experimental study to validate the approach and some of the results is also presented. It is shown that the structures composed of rods with exponentially or conically varying cross-section areas have similar behaviour. Reasonably good correspondence between the predictions and the experimental results were found. However, some additional features were found in the measured receptances due to bending vibration that was not considered in the theoretical model. Asymmetric cells are found to perform better and have a wider attenuation band when compared to symmetrical cells. [Display omitted]
ISSN:0022-460X
DOI:10.1016/j.jsv.2024.118741