The motion of a vortex near two circular cylinders

Johnson, E. R.; McDonald, N. Robb

doi:10.1098/rspa.2003.1193

Cited by 57 publications

(65 citation statements)

References 13 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…This calculation implies the use of the Green function G(x, y; x 0 , y 0 ), which can be interpreted as the stream function of a flow induced by a unit point vortex located at a point (x 0 , y 0 ) on the (x, y)-plane, and computation of contour integrals over the patch boundaries. The construction of the Green function in complex domains is often facilitated by the use of image vortices (Coppa, Peano & Peinetti 2002;Johnson & McDonald 2004;Elcrat, Fornberg & Miller 2005;Crowdy & Surana 2007). For a plane with a circular cutout of unit radius centred at the origin of the frame of reference, a Green function can be written as Makarov, L. Kamp and G. van Heijst (e.g.…”

Section: Numerical Simulationsmentioning

confidence: 99%

Instabilities of the flow around a cylinder and emission of vortex dipoles

Kizner

Makarov²,

Kamp

et al. 2013

J. Fluid Mech.

View full text Add to dashboard Cite

Instabilities and long-term evolution of two-dimensional circular flows around a rigid circular cylinder (island) are studied analytically and numerically. For that we consider a base flow consisting of two concentric neighbouring rings of uniform but different vorticity, with the inner ring touching the cylinder. We first study the inviscid linear stability of such flows to perturbations of the free edges of the rings. For a given ratio of the vorticity in the rings, the governing parameters of the problem are the radii of the inner and outer rings scaled on the cylinder radius. In this two-dimensional parameter space, we determine analytically the regions of linear stability/instability of each azimuthal mode m = 1, 2, . . . . In the physically most meaningful case of zero net circulation, for each mode m > 1, two regions are identified: a regular instability region where mode m is unstable along with some other modes, and a unique instability region where only mode m is unstable. After the conditions of linear instability are established, inviscid contour-dynamics and high-Reynolds-number finite-element simulations are conducted. In the regular instability regions, simulations of both kinds typically result in the formation of vortical dipoles or multipoles. In the unique instability regions, where the inner vorticity ring is much thinner than the outer ring, the inviscid contour-dynamics simulations do not reveal dipole emission. In the viscous simulation, because viscosity has time to widen the inner ring, the instability develops in the same manner as in the regular instability regions.

show abstract

Section: Numerical Simulationsmentioning

confidence: 99%

Instabilities of the flow around a cylinder and emission of vortex dipoles

Kizner

Makarov²,

Kamp

et al. 2013

J. Fluid Mech.

View full text Add to dashboard Cite

show abstract

“…According to lemma 3.1, either B 0 or B 2 can follow the initial word O. Hence, the structurally stable streamline patterns in D ζ (2) are OB 0 and OB 2 , whose saddle connection diagrams are shown in figure 6a,c, respectively. Now, we consider the structurally stable streamline patterns with the 1-source-sink point constructed from the initial patterns I and II.…”

Section: Word Representation Of Streamline Topologiesmentioning

confidence: 99%

“…Hence, we have the maximal expression (3.2). (2). Owing to k = 1 for M = 1, we have three combinations of the indices (p, s 1 , t 1 ) = (1, 0, 0), (0, 1, 0) and (0, 0, 1), whose corresponding maximal II-words are IIA 0 , IIB 0 and IIB 2 , whose corresponding ss-saddle connection diagrams are shown in figure 10a-d, respectively.…”

Section: Proof Note That the Relation ≤ Implies The Reflexive And Trmentioning

confidence: 99%

Word representation of streamline topologies for structurally stable vortex flows in multiply connected domains

Yokoyama

Sakajo

2013

Proc. R. Soc. A.

View full text Add to dashboard Cite

Let us consider incompressible and inviscid flows in two-dimensional domains with multiple obstacles. The instantaneous velocity field becomes a Hamiltonian vector field defined from the stream function, and it is topologically characterized by the streamline pattern that corresponds to the contour plot of the stream function. The present paper provides us with a procedure to construct structurally stable streamline patterns generated by finitely many point vortices in the presence of the uniform flow. Starting from some basic structurally stable streamline patterns in a disc of low genus, i.e. a disc with a small number of holes, we repeat some fundamental operations that append a streamline pattern by increasing one genus to them. Owing to the inductive procedure, one can assign a sequence of operations as a representing word to each structurally stable streamline pattern. We also give the canonical expression for the word representation, which allows us to make a catalogue of all possible structurally stable streamline patterns in a combinatorial manner. As an example, we show all streamline patterns in the discs of genus 1 and 2.

show abstract

“…The problem is tackled by finding the appropriate Green's function (Section III) from the conservation of vorticity with pressure and normal mass flux continuous across the topographic boundary. Unlike previous studies 7 in which the streamfunction was found by first ignoring the boundaries and then evaluating a complementary irrotational flow so the normal velocity of the combined flow is zero at the boundaries, a different method, avoiding these supplementary computations, is introduced. Section IV describes the form of the steadily propagating solutions and their robustness is tested using time-dependent contour dynamics.…”

Section: Introductionmentioning

confidence: 99%

“…5 Laboratory experiments 6 found that the cylinder diameter affects the vortex trajectories significantly. These observations motivated a study 7 of point vortex and vortex-patch motion around two impermeable circular cylinders where the point-vortex motion is shown to be governed by a Hamiltonian, derivable from complex variable techniques which extend directly 8 to point-vortex motion around multiple cylinders. Dipolar 9,10 and monopolar 11 surf-zone vortices (i.e., zero background rotation) have been studied analytically near a step of finite depth-ratio.…”

Section: Introductionmentioning

confidence: 99%

Beach vortices near circular topography

2016

Self Cite

View full text Add to dashboard Cite

Finite-area monopolar vortices which propagate around topography without change in shape are computed for circular seamounts and wells including the limiting cases of each: islands and infinitely deep wells. The time-dependent behaviour of vortex pairs propagating toward circular topography is also examined. Trajectories of point-vortex pairs exterior to the topography are found and compared to trajectories of vortex patches computed using contour dynamics.

show abstract

The motion of a vortex near two circular cylinders

Cited by 57 publications

References 13 publications

Instabilities of the flow around a cylinder and emission of vortex dipoles

Instabilities of the flow around a cylinder and emission of vortex dipoles

Word representation of streamline topologies for structurally stable vortex flows in multiply connected domains

Beach vortices near circular topography

Contact Info

Product

Resources

About