Helical vortices in swirl flow

S. V. ALEKSEENKO; P. A. KUIBIN; V. L. OKULOV; S. I. SHTORK

doi:10.1017/S0022112098003772

Abstract

Helical vortices in swirl flow are studied theoretically and experimentally.

A theory of helical vortices has been developed. It includes the following results: an analytical solution describing an elementary helical vortex structure – an infinitely thin filament; a solution for axisymmetrical vortices accounting for the helical shape of vortex lines and different laws of vorticity distribution; a formula for calculation of the self-induced velocity of helical vortex rotation (precession) in a cylindrical tube; an explanation of the zone with reverse flow (recirculation zone) arising in swirl flows; and the classification of vortex structures.

The experimental study of helical vortices was carried out in a vertical hydrodynamical vortex chamber with a tangential supply of liquid through turning nozzles. Various vortex structures were formed owing to changing boundary conditions on the bottom and at the exit section of the chamber. The hypothesis of helical symmetry is confirmed for various types of swirl flow. The stationary helical vortex structures are described (most of them for the first time) the features of which agree with the results and predictions of the theoretical model developed. They are the following: a rectilinear vortex; a composite columnar vortex; helical vortices screwed on the right or on the left; a vortex with changing helical symmetry; a double helix – two entangled vortex filaments of the same sign.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Rossi, Maurice 2000. Vortex Structure and Dynamics. Vol. 555, Issue. , p. 40.

Murakhtina, T. O. and Okulov, V. L. 2000. Changes in the topology and symmetry of a vorticity field upon turbulent vortex breakdown. Technical Physics Letters, Vol. 26, Issue. 5, p. 432.

Alekseenko, S. and Markovich, D. 2000. Science and Art Symposium 2000. p. 127.

Okulov, V. L. and Martemianov, S. A. 2001. The effect of decreased mass transfer in twisted flows. Technical Physics Letters, Vol. 27, Issue. 9, p. 765.

Brücker, Ch. 2002. Some Observations of Vortex Breakdown in a Confined Flow with Solid Body Rotation. Flow, Turbulence and Combustion, Vol. 69, Issue. 1, p. 63.

Okulov, V. L. Sørensen, J. N. and Voigt, L. K. 2002. Alternation of the right-and left-handed helical vortices caused by increased flow swirling in a cylindrical cavity with rotating lids. Technical Physics Letters, Vol. 28, Issue. 1, p. 55.

Afanasyev, Ya. D. 2002. Experiments on instability of columnar vortex pairs in rotating fluid. Geophysical & Astrophysical Fluid Dynamics, Vol. 96, Issue. 1, p. 31.

Martemianov, S. and Okulov, V.L. 2002. Mass transfer ambiguities in swirling pipe flows. Journal of Applied Electrochemistry, Vol. 32, Issue. 1, p. 25.

Okulov, V. L. 2002. Instability of an equilibrium circular configuration of helical vortices. Technical Physics Letters, Vol. 28, Issue. 12, p. 1060.

Okulov, V. L. Martemianov, S. and Murakhtina, T. O. 2002. Generalization of the Leveque problem for mass transfer in swirling flows in the entrance region of a cylindrical section. Doklady Physics, Vol. 47, Issue. 9, p. 685.

Okulov, V. L. Meledin, V. G. and Naumov, I. V. 2003. Experimental investigation of a swirling flow in a cubic container. Technical Physics, Vol. 48, Issue. 10, p. 1249.

Rocklage-Marliani, Gerta Schmidts, Maren and Vasanta Ram, Venkatesa I. 2003. Three-Dimensional Laser-Doppler Velocimeter Measurements in Swirling Turbulent Pipe Flow. Flow, Turbulence and Combustion, Vol. 70, Issue. 1-4, p. 43.

Ohtsuka, Kazumichi Takaki, Ryuji and Watanabe, Shinsuke 2003. Dynamics of the local entanglement on two vortex filaments described by the Korteweg–de Vries equation. Physics of Fluids, Vol. 15, Issue. 4, p. 1065.

Cullivan, J.C. Williams, R.A. Dyakowski, T. and Cross, C.R. 2004. New understanding of a hydrocyclone flow field and separation mechanism from computational fluid dynamics. Minerals Engineering, Vol. 17, Issue. 5, p. 651.

Kuibin, Pavel A. 2004. Tubes, Sheets and Singularities in Fluid Dynamics. Vol. 71, Issue. , p. 81.

Okulov, Valery SØrensen, Jens N. and Voigt, Lars K. 2004. Tubes, Sheets and Singularities in Fluid Dynamics. Vol. 71, Issue. , p. 55.

Martemianov, S. and Okulov, V.L. 2004. On heat transfer enhancement in swirl pipe flows. International Journal of Heat and Mass Transfer, Vol. 47, Issue. 10-11, p. 2379.

Jawarneh, Ali and Vatistas, Georgios 2004. Vortex Chamber Flows.

Galletti, C. Paglianti, A. Lee, K. C. and Yianneskis, M. 2004. Reynolds number and impeller diameter effects on instabilities in stirred vessels. AIChE Journal, Vol. 50, Issue. 9, p. 2050.

Fukumoto, Y. and Okulov, V. L. 2005. The velocity field induced by a helical vortex tube. Physics of Fluids, Vol. 17, Issue. 10,

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