When buoyant vortex rings form, azimuthal disturbances occur on their surface. When the magnitude of the disturbance is sufficiently high, the ring will become turbulent. This paper establishes conditions for categorization of a buoyant vortex ring as laminar, transitional, or turbulent. The transition regime of enclosed-air buoyant vortex rings rising in still water was examined experimentally via two high-speed cameras. Sequences of the recorded pictures were analyzed using matlab. Key observations were summarized as follows: for Reynolds number lower than 14,000, Bond number below 30, and Weber number below 50, the vortex ring could not be produced. A transition regime was observed for Reynolds numbers between 40,000 and 70,000, Bond numbers between 120 and 280, and Weber number between 400 and 800. Below this range, only laminar vortex rings were observed, and above, only turbulent vortex rings.
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May 2018
Technical Briefs
Laminar to Turbulent Buoyant Vortex Ring Regime in Terms of Reynolds Number, Bond Number, and Weber Number
Xueying Yan,
Xueying Yan
Turbulence and Energy Laboratory,
Department of Mechanical, Automotive
and Materials Engineering,
University of Windsor,
Windsor, ON N9B3P4, Canada
e-mail: yan12d@uwindsor.ca
Department of Mechanical, Automotive
and Materials Engineering,
University of Windsor,
Windsor, ON N9B3P4, Canada
e-mail: yan12d@uwindsor.ca
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Rupp Carriveau,
Rupp Carriveau
Turbulence and Energy Laboratory,
Department of Civil and Environmental Engineering,
Windsor, ON N9B3P4, Canada
e-mail: rupp@uwindsor.ca
Department of Civil and Environmental Engineering,
Windsor, ON N9B3P4, Canada
e-mail: rupp@uwindsor.ca
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David S. K. Ting
David S. K. Ting
Turbulence and Energy Laboratory,
Department of Mechanical, Automotive
and Materials Engineering,
Windsor, ON N9B3P4, Canada
e-mail: dting@uwindsor.ca
Department of Mechanical, Automotive
and Materials Engineering,
Windsor, ON N9B3P4, Canada
e-mail: dting@uwindsor.ca
Search for other works by this author on:
Xueying Yan
Turbulence and Energy Laboratory,
Department of Mechanical, Automotive
and Materials Engineering,
University of Windsor,
Windsor, ON N9B3P4, Canada
e-mail: yan12d@uwindsor.ca
Department of Mechanical, Automotive
and Materials Engineering,
University of Windsor,
Windsor, ON N9B3P4, Canada
e-mail: yan12d@uwindsor.ca
Rupp Carriveau
Turbulence and Energy Laboratory,
Department of Civil and Environmental Engineering,
Windsor, ON N9B3P4, Canada
e-mail: rupp@uwindsor.ca
Department of Civil and Environmental Engineering,
Windsor, ON N9B3P4, Canada
e-mail: rupp@uwindsor.ca
David S. K. Ting
Turbulence and Energy Laboratory,
Department of Mechanical, Automotive
and Materials Engineering,
Windsor, ON N9B3P4, Canada
e-mail: dting@uwindsor.ca
Department of Mechanical, Automotive
and Materials Engineering,
Windsor, ON N9B3P4, Canada
e-mail: dting@uwindsor.ca
1Corresponding author.
Contributed by the Fluids Engineering Division of ASME for publication in the JOURNAL OF FLUIDS ENGINEERING. Manuscript received July 20, 2017; final manuscript received October 7, 2017; published online January 9, 2018. Assoc. Editor: Arindam Banerjee.
J. Fluids Eng. May 2018, 140(5): 054502 (5 pages)
Published Online: January 9, 2018
Article history
Received:
July 20, 2017
Revised:
October 7, 2017
Citation
Yan, X., Carriveau, R., and Ting, D. S. K. (January 9, 2018). "Laminar to Turbulent Buoyant Vortex Ring Regime in Terms of Reynolds Number, Bond Number, and Weber Number." ASME. J. Fluids Eng. May 2018; 140(5): 054502. https://doi.org/10.1115/1.4038661
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