Wake interactions between two side-by-side circular cylinders with different sizes

TL;DR

This study investigates the complex flow interactions between two side-by-side circular cylinders of different sizes, revealing various flow regimes and the mechanisms behind wake synchronization and frequency interactions.

Contribution

It introduces a quantitative analysis of wake interactions with size mismatch, uncovering the transition mechanisms between different flow states using spectral and modal analysis.

Findings

Identification of quasi-periodic, synchronized, and chaotic flow regimes.

Discovery of vortex shedding frequency interactions and beat phenomena.

Insights into wake synchronization mechanisms based on size and gap ratios.

Abstract

Flows over two side-by-side circular cylinders exhibit fascinating flow physics due to complex interactions between the coupled wakes. However, their mutual interference effects have not been elucidated in a quantitative manner thus far. In this paper, we create a mismatch between the two wakes by introducing a size difference in the cylinder pair, such that the effects of one wake on the other can be distinguished. Depending on the size and gap ratios between the two cylinders, the coupled wake exhibits distinct dynamical features including the quasi-periodic flow, synchronized flow, and chaotic flow. Through advanced spectral analysis of lift coefficients and dynamic mode decomposition of the flow fields, we reveal that the quasi-periodic flows are mainly composed of two primary frequencies associated with vortex shedding in the near wakes of the two cylinders. Both wakes impose their own frequencies on the other, resulting in the beating phenomenon in the lift coefficients. The triad interactions between the two wakes generate the sideband frequencies, which are associated with modal structures that are mostly active in the far wake. The transition from quasi-periodicity to synchronization is dominated by the vortex shedding behind the larger cylinder, to which the wake of the smaller cylinder locks in. These results reveal new insights on the coupled wakes of two circular cylinders, and are pivotal for understanding more general wake interaction problems.