The linearized stability analysis is applied to investigate the wave behavior in a water vortex produced in a cylindrical tank with a flat disk rotating at the bottom. Two flow cases are considered herein. The first case deals with waves developed on the free surface of a hollow vortex, while the second with waves generated in the core of a Rankine vortex. It is evident from the analysis that the experimental dispersion velocity approaches the calculated one when the wave amplitude becomes smaller. The latter is consistent with the small perturbation assumption that is inherent in the theory. For the case where the core is flooded, the presen…(more)
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%0 Journal Article
%1 vatistas1994recent
%A Vatistas, G. H.
%A Wang, J.
%A Lin, S.
%D 1994
%J Acta Mechanica
%K 76b47-vortex-flows 76e07-hydrodynamic-stability-rotation 76e17-interfacial-stability 76t10-liquid-gas-two-phase-flows-bubbly-flows
%N 1
%P 89--102
%R 10.1007/BF01180220
%T Recent findings on Kelvin's equilibria
%U https://link.springer.com/article/10.1007/BF01180220
%V 103
%X The linearized stability analysis is applied to investigate the wave behavior in a water vortex produced in a cylindrical tank with a flat disk rotating at the bottom. Two flow cases are considered herein. The first case deals with waves developed on the free surface of a hollow vortex, while the second with waves generated in the core of a Rankine vortex. It is evident from the analysis that the experimental dispersion velocity approaches the calculated one when the wave amplitude becomes smaller. The latter is consistent with the small perturbation assumption that is inherent in the theory. For the case where the core is flooded, the presence of a cylindrical wall is shown to enhance the wave speed. A hypothesis as to how the core develops in the mixed state regions is proposed. The graphical simulations appear to predict reasonably well the main features of the observations.
@article{vatistas1994recent,
abstract = {The linearized stability analysis is applied to investigate the wave behavior in a water vortex produced in a cylindrical tank with a flat disk rotating at the bottom. Two flow cases are considered herein. The first case deals with waves developed on the free surface of a hollow vortex, while the second with waves generated in the core of a Rankine vortex. It is evident from the analysis that the experimental dispersion velocity approaches the calculated one when the wave amplitude becomes smaller. The latter is consistent with the small perturbation assumption that is inherent in the theory. For the case where the core is flooded, the presence of a cylindrical wall is shown to enhance the wave speed. A hypothesis as to how the core develops in the mixed state regions is proposed. The graphical simulations appear to predict reasonably well the main features of the observations.},
added-at = {2023-08-11T03:13:46.000+0200},
author = {Vatistas, G. H. and Wang, J. and Lin, S.},
biburl = {https://www.bibsonomy.org/bibtex/2c4693904e037f4fd073eb9f3df399cc2/gdmcbain},
day = 01,
doi = {10.1007/BF01180220},
interhash = {2b6a142e1e6222aa310b43837df6f5e5},
intrahash = {c4693904e037f4fd073eb9f3df399cc2},
issn = {1619-6937},
journal = {Acta Mechanica},
keywords = {76b47-vortex-flows 76e07-hydrodynamic-stability-rotation 76e17-interfacial-stability 76t10-liquid-gas-two-phase-flows-bubbly-flows},
month = mar,
number = 1,
pages = {89--102},
timestamp = {2023-08-11T03:13:46.000+0200},
title = {Recent findings on Kelvin's equilibria},
url = {https://link.springer.com/article/10.1007/BF01180220},
volume = 103,
year = 1994
}