The wakes of cylindrical bluff bodies at low Reynolds number

Gerrard, J. H.

doi:10.1098/rsta.1978.0020

Cited by 286 publications

(72 citation statements)

References 29 publications

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“…It is noted that all vortices except the ones that follow UT 2 further upstream and 0.25D higher as compared to those of UT 2 . They go upwards until x/D ≈ 4 and then downwards until they reach the trajectory UT 2 .…”

Section: A Spanwise Vorticesmentioning

confidence: 98%

“…A lot of effort was made to explain the physics of circular cylinder wake dynamics. [1][2][3] They showed that vortex shedding for low Reynolds numbers can be characterized by vortex splitting and high shear stress occurring in the near-wake. Unal and Rockwell 4 investigated the near wake vortex formation from the context of absolute instability and showed that the shear layer separating from the cylinder shows an exponential variation of fluctuating kinetic energy with distance downstream of the cylinder.…”

Section: Introductionmentioning

confidence: 99%

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Energy contents and vortex dynamics in Mode-C transition of wired-cylinder wake

2013

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The 3D transition of the flow behind a circular cylinder with a near-wake wire disturbance has been investigated experimentally. The flow is oriented horizontally and the wire is positioned in the upper half of the wake. We performed flow visualization and particle image velocimetry experiments to investigate the influence of the wire on various properties of the flow, such as the dynamics of the spanwise structures. Experiments were performed in the Reynolds number range of Re = 165–300. It is shown that in Mode-C transition of the wired cylinder wake, some part of the streamwise vorticity content of the upper von Kármán vortices located at the perturbed side, is transferred to the secondary vortices. This vorticity transfer results in upper von Kármán vortices which are weaker than the lower ones. The analysis of the discrete energy content of the wake supports this analysis by showing that the energy intensity at von Kármán vortex shedding frequency f0 at the perturbed side of the wake is less than the energy intensity in the lower half. This leads to conclusion that the excess energy is transferred to the subharmonic frequency f1 ≈ f0/2.

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Section: A Spanwise Vorticesmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Energy contents and vortex dynamics in Mode-C transition of wired-cylinder wake

2013

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“…The exact Reynolds number at which vortex shedding begins depends on the flow conditions. For a laterally uniform upstream velocity, the transition occurs at Re, = 60 (Gerrard 1978). However, in the presence of shear the transition may be delayed to Re, = 200 (Tamura et al 1980).…”

Section: Acknowledgmentsmentioning

confidence: 99%

A model for diffusion within emergent vegetation

Nepf

Sullivan

Zavistoski

1997

Limnology & Oceanography

184

148

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Detailed velocity measurements made with laser Doppler velocimetry have shown that, except very close to the bed, the production of turbulence within a stand of emergent vegetation is dominated by the stem wakes rather than by the bottom-boundary shear, as in open-channel flows. This observation formed the basis for a modified randomwalk model that describes the contribution of stem wakes to the turbulent diffusivity within marsh grasses. The model was validated by comparison to observed diffusivity over a range of population and flow conditions within a simple plantlike array of circular cylinders. The diffusion model was also evaluated for a more complex morphology that included a flexible canopy. Laser-induced fluorescence and image-processing techniques were used to measure the diffusivity as well as to examine turbulence structure within the experimental system. The latter analysis documented changes in turbulcncc scale that arise as larger eddies are broken apart by the stems and smaller eddies (comparable to the stem diameter) are produced within the wakes.Field observations demonstrate that submerged and emergent aquatic vegetation can baflle local currents and dampen wave energy by providing a new source of drag associated with the plant stems and branches (Jackson and Winant 1983;Ward et al. 1984;Gambi et al. 1990;Leonard and Luther 1995). When the flow is reduced, the production of turbulence is also reduced, leading to diminished turbulent diffusivity within the canopy (Raupach and Thorn 1981;Worcester 1995). These changes in advection and diffusion influence the dispersal and settlement of seeds and larvae and thus can affect recruitment, reproductive success, and genetic diversity (Okubo

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“…A visualization of Hama 4 showed that the instability in the wake transition takes the form of a three-dimensional waviness of the von Kármán vortices. This is essentially what Gerrard 5 later called ''fingers of dye.'' Williamson's flow visualization 6 showed that Gerrard's dye fingers are associated with vortex loops and streamwise vortices.…”

Section: Introductionmentioning

confidence: 99%

Experimental and numerical investigation of the vortex formation process behind a heated cylinder

2004

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This paper describes the three-dimensional (3D) vortex formation process behind a heated cylinder at low Reynolds numbers. Both experimental and numerical techniques are used, including an electrochemical tin-precipitation visualization method, a two-dimensional (2D) high resolution particle velocimetry technique, and a 3D spectral element method. The wake flow is simultaneously investigated in two perpendicular planes using a “dual-plane” configuration. It appears that for Reynolds number around 100 and Richardson number larger than 1.0 thermal plumes occur in the far wake. Correspondingly distinct counterrotating vortices, with a spanwise wavelength of two cylinder diameters, are shown in the near wake. Furthermore, a difference in the flow motion for “in-plume” and “out-of-plume” positions is observed. The vortex shedding process for the “out-of-plume” positions is quite similar to the one for an unheated cylinder, which is a 2D flow. At in-plume positions, it is observed that the flow moves upward from the lower to the upper half of the wake. From the calculated temperature field, a region of unstable thermal stratification in gravity direction is observed at the in-plume positions. This indicates that the upward motion at the in-plume positions is induced by buoyancy when the temperature gradient is large enough.

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The wakes of cylindrical bluff bodies at low Reynolds number

Cited by 286 publications

References 29 publications

Energy contents and vortex dynamics in Mode-C transition of wired-cylinder wake

Energy contents and vortex dynamics in Mode-C transition of wired-cylinder wake

A model for diffusion within emergent vegetation

Experimental and numerical investigation of the vortex formation process behind a heated cylinder

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