A semi-analytical method for characterizing vibrations in circular beams with embedded acoustic black holes

Jie Deng, Oriol Guasch, Ling Zheng

Research output: Contribution to journalArticlepeer-review

64 Scopus citations

Abstract

Acoustic black hole (ABH) indentations have proven to be an efficient way for reducing vibrations on straight beams and plates. However, many built-up structures in the naval and aerospace sectors involve curved beams and shells, so there is a need to check whether the ABH effect could be also beneficial for them. To date, such issue has not been yet addressed and in this work some initial steps are proposed towards it. In particular, an analysis is made of the vibrational behavior of a circular beam with embedded ABHs. A semi-analytical model is suggested in the framework of the Rayleigh-Ritz method, making use of Gaussian trial functions. The key to the approach is building a basis of Gaussian functions that fulfill the periodic boundary conditions on the beam, to approximate its radial and tangential motions. It is shown how this can be done quite directly and efficiently. The validity of the proposed approach is then tested by comparison with finite element simulations, showing very good matching. The Gaussian expansion is then applied to study the dependence of the bending vibration of an ABH circular beam with frequency. After that, the influence of curvature and boundary conditions are established by comparing the performance of close and open circular ABH beams and straight periodic beams. Circular beams containing different number of ABHs are also studied and the appearance of frequency stopbands is reported.

Original languageEnglish
Article number115307
JournalJournal of Sound and Vibration
Volume476
DOIs
StatePublished - 23 Jun 2020
Externally publishedYes

Keywords

  • Acoustic black holes (ABHs)
  • Curved structures
  • Gaussian expansion method
  • Semi-analytical method
  • Shape functions

Fingerprint

Dive into the research topics of 'A semi-analytical method for characterizing vibrations in circular beams with embedded acoustic black holes'. Together they form a unique fingerprint.

Cite this