Curvature instability of a curved Batchelor vortex

Blanco–Rodríguez, Francisco J.; Dizès, Stéphane Le

doi:10.1017/jfm.2017.34

Cited by 25 publications

(39 citation statements)

References 38 publications

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“…, where the numerical factor 0.638 is peculiar to the Gaussian distribution of vorticity. Here, a 0 is the initial core radius and u ,max and ⌦ (0) max = /(2⇡a 2 0 ) are the maximum circumferential velocity and the maximum angular velocity around the vortex core, respectively; it is pointed out that ⌦ 0max is defined for the initial Gaussian vorticity distribution as in Blanco-Rodríguez & Le Dizès (2017).…”

Section: Simulation Parametersmentioning

confidence: 99%

“…= (1.14, 0.11) in the present work corresponds to (m A , m B ) = (0, 1) and (l A , l B ) = (3, 1) with (k, !) = ( 1.14, 0.11) in Blanco-Rodríguez & Le Dizès (2017). Theoretical values for some typical modes taken from Blanco-Rodríguez & Le Dizès (2016) and Blanco-Rodríguez & Le Dizès (2017) are also included by lines in the figures 8-11.…”

Section: Growth Ratementioning

confidence: 99%

“…However, the vortex rings observed in the experiments usually have smooth vorticity distributions which are often approximated by Gaussian distributions. Recently, Blanco-Rodríguez & Le Dizès (2016) and Blanco-Rodríguez & Le Dizès (2017) have shown theoretically that vortex rings which have Gaussian distributions of azimuthal vorticity and velocity at the leading order are also subjected to elliptic and curvature instabilities. They found that some important features of the instabilities are quite di↵erent from those of Kelvin's vortex ring.…”

Section: Introductionmentioning

confidence: 99%

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Numerical stability analysis of a vortex ring with swirl

2019

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The linear instability of a vortex ring with swirl with Gaussian distributions of azimuthal vorticity and velocity in its core is studied by direct numerical simulation. The numerical study is carried out in two steps: first, an axisymmetric simulation of the Navier–Stokes equations is performed to obtain the quasi-steady state that forms a base flow; then, the equations are linearized around this base flow and integrated for a sufficiently long time to obtain the characteristics of the most unstable mode. It is shown that the vortex rings are subjected to curvature instability as predicted analytically by Blanco-Rodríguez & Le Dizès (J. Fluid Mech., vol. 814, 2017, pp. 397–415). Both the structure and the growth rate of the unstable modes obtained numerically are in good agreement with the analytical results. However, a small overestimation (e.g. 22 % for a curvature instability mode) by the theory of the numerical growth rate is found for some instability modes. This is most likely due to evaluation of the critical layer damping which is performed for the waves on axisymmetric line vortices in the analysis. The actual position of the critical layer is affected by deformation of the core due to the curvature effect; as a result, the damping rate changes since it is sensitive to the position of the critical layer. Competition between the curvature and elliptic instabilities is also investigated. Without swirl, only the elliptic instability is observed in agreement with previous numerical and experimental results. In the presence of swirl, sharp bands of both curvature and elliptic instabilities are obtained for $\unicode[STIX]{x1D700}=a/R=0.1$, where $a$ is the vortex core radius and $R$ the ring radius, while the elliptic instability dominates for $\unicode[STIX]{x1D700}=0.18$. New types of instability mode are also obtained: a special curvature mode composed of three waves is observed and spiral modes that do not seem to be related to any wave resonance. The curvature instability is also confirmed by direct numerical simulation of the full Navier–Stokes equations. Weakly nonlinear saturation and subsequent decay of the curvature instability are also observed.

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Section: Simulation Parametersmentioning

confidence: 99%

Section: Growth Ratementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Numerical stability analysis of a vortex ring with swirl

2019

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“…The short-wavelength instabilities observed in the stability analysis correspond to the elliptic instability, which has been a topic of intense research over the past decades (see [34] for a recent review, and [47] for details regarding the curvature instability, which is another short-wavelength instability in curved Batchelor vortices).…”

Section: Elliptic Instabilitiesmentioning

confidence: 99%

“…One also has that ε = Ra/(R 2 + L 2 ), and as before, = L/R is the dimensionless reduced pitch. Approximate relations for the other coefficients appearing in (31) are given in Appendix C of [51] (note also the corrigendum to some of these relations appended to [47]). The Reynolds number used in (31) is defined as Re = Re/(2π).…”

Section: Elliptic Instabilitiesmentioning

confidence: 99%

Numerical realization of helical vortices: application to vortex instability

Brynjell-Rahkola

Henningson

2019

Theor. Comput. Fluid Dyn.

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The need to numerically represent a free vortex system arises frequently in fundamental and applied research. Many possible techniques for realizing this vortex system exist but most tend to prioritize accuracy either inside or outside of the vortex core, which therefore makes them unsuitable for a stability analysis considering the entire flow field. In this article, a simple method is presented that is shown to yield an accurate representation of the flow inside and outside of the vortex core. The method is readily implemented in any incompressible Navier-Stokes solver using primitive variables and Cartesian coordinates. It can potentially be used to model a wide range of vortices but is here applied to the case of two helices, which is of renewed interest due to its relevance for wind turbines and helicopters. Three-dimensional stability analysis is performed in both a rotating and a translating frame of reference, which yield eigenvalue spectra that feature both mutual inductance and elliptic instabilities. Comparison of these spectra with available theoretical predictions is used to validate the proposed baseflow model, and new insights into the elliptic instability of curved Batchelor vortices are presented. Furthermore, it is shown that the instabilities in the rotating and the translating reference frames have the same structure and growth rate, but different frequency. A relation between these frequencies is provided.

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Experimental investigation of a rotor blade tip vortex pair

et al. 2021

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This paper presents the results of an experimental study of two closely spaced vortices generated by a rotating blade with a modified tip geometry. The experiments are carried out in two water channel facilities and involve a generic one-bladed rotor operating in a regime near hover. It is equipped with a parametric fin placed perpendicular to the pressure surface near the tip, which generates a co-rotating vortex pair having a helical geometry. Based on previous results obtained with a fixed wing, a series of small-scale experiments is first carried out, to validate the method of vortex pair generation also for a rotating blade, and to obtain a qualitative overview of its evolution going downstream. A more detailed quantitative study is then performed in a larger facility at three times the initial scale. By varying the fin parameters, it was possible to obtain a configuration in which the two vortices have almost the same circulation. In both experiments, the vortex pair is found to merge into a single helical wake vortex within one blade rotation. Particle image velocimetry measurements show that the resulting vortex has a significantly larger core radius than the single tip vortex from a blade without fin. This finding may have relevance in the context of blade–vortex interactions, where noise generation and fatigue from fluid–structure interactions depend strongly on the vortex core size.

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Curvature instability of a curved Batchelor vortex

Cited by 25 publications

References 38 publications

Numerical stability analysis of a vortex ring with swirl

Numerical stability analysis of a vortex ring with swirl

Numerical realization of helical vortices: application to vortex instability

Experimental investigation of a rotor blade tip vortex pair

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