Onset of Vortex Shedding and Hysteresis in Flow over Tandem Sharp-Edged Cylinders of Diverse Cross Sections

TL;DR

This study uses numerical simulations to analyze how flow patterns, vortex shedding, and hysteresis depend on cylinder cross sections, spacing, and Reynolds number in tandem sharp-edged cylinders, revealing flow pattern transitions and suppression effects.

Contribution

It provides new insights into flow structure transitions, vortex shedding suppression, and hysteresis behavior for tandem cylinders with diverse cross sections at various Reynolds numbers.

Findings

Vortex shedding is suppressed as downstream cylinder aspect ratio increases.

Critical Reynolds number for vortex shedding decreases with increased scaled gap.

Hysteresis occurs within specific gap ranges at high Reynolds numbers.

Abstract

Numerical simulations are conducted to analyze flow characteristics around two tandem sharp-edged cylinders with cross sections of square (b*1 = 1) for the upstream cylinder and rectangle (b*2) for the downstream cylinder (b* = b/a, where a and b are the sides of cylinders). The study investigates the effects of Reynolds numbers (Re = 30 - 150), cross-sectional aspect ratios of the downstream cylinder (b*2 = 1 - 4), and scaled gap-spacing between cylinders (S* = 1 - 6) on the flow structure, onset of vortex shedding, hysteresis and aerodynamic parameters. The results reveal that increasing b2* suppresses the vortex shedding of the upstream cylinder, depending on S*. The suppression is attributed to the interference effect and the adhesion of the shear layers on the downstream cylinder. Three distinct time-mean flow patterns are identified based on the separation and reattachment of shear layers. The first flow pattern (I) exhibits parallel flow along the side faces of the upstream cylinder, while the separation bubbles associated with reattachment points are formed in flow pattern II on these faces. For pattern III, no reattachment point is observed and the separation bubbles cover the upstream cylinder' side faces. Additionally, two instantaneous flow patterns of extended-body and co-shedding are apperceived within the ranges of examined Re and S*. The behaviors of time-mean and varying forces as well as the vortex shedding frequency are correlated with the flow structures. The onset of vortex shedding and hysteresis dependence are discussed comprehensively. The results show that the critical Reynolds numbers for the onset of vortex shedding decrease from 128 to 50 with S* increasing from 1 to 6 (b*1 = 1 and b*2 = 4). The hysteresis limit is found within the range of 3.5 < S* < 4.5 for flow over two tandem cylinders (b*1 = 1 and b*2 = 4) at Re = 150.