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Experimental investigation of flow development and gap vortex street in an eccentric annular channel. Part 2. Effects of inlet conditions, diameter ratio, eccentricity and Reynolds number

Published online by Cambridge University Press:  06 March 2015

George H. Choueiri  and
Stavros Tavoularis
George H. Choueiri
Affiliation:
Department of Mechanical Engineering, University of Ottawa, Ottawa, ON, K1N 6N5, Canada
Stavros Tavoularis*
Affiliation:
Department of Mechanical Engineering, University of Ottawa, Ottawa, ON, K1N 6N5, Canada
*
Email address for correspondence: [email protected]
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Abstract

The development and structure of flows in eccentric annular channels and their dependence on inlet conditions, inner-to-outer diameter ratio $d/D$, eccentricity $e=2{\rm\Delta}y/(D-d)$, where ${\rm\Delta}y$ is the distance between the axes of the inner and outer cylinders, and Reynolds number $\mathit{Re}$, based on the hydraulic diameter and the bulk velocity, were studied experimentally, with focus on the phenomena of gap instability and the resulting vortex street. Experimental conditions covered a Reynolds number range between 0 and 19 000, an eccentricity range from 0 to 0.9 and inner-to-outer diameter ratios equal to 0.25, 0.50 and 0.75. Much of the discussion is based on measurements in the middle of the narrow annular gap, where the phenomena of interest could be observed most vividly. In the range $\mathit{Re}<10\,000$, the Strouhal number, the normalized mid-gap axial flow velocity and the normalized axial and cross-flow fluctuations at mid-gap were found to increase with increasing $\mathit{Re}$ and to depend strongly on inlet conditions. At higher Reynolds numbers, however, these parameters reached asymptotic values that were less sensitive to inlet conditions. We constructed a map for the various stages of periodic motions versus eccentricity and Reynolds number and found that for $e<0.5$ or $\mathit{Re}<1100$ the flow was unconditionally stable, as far as gap instability is concerned. For $e\leqslant 0.5$, transition to turbulence occurred at $\mathit{Re}\approx 6000$, whereas, for $0.6\leqslant e\leqslant 0.9$, the critical Reynolds number for the formation of periodic motions was found to increase with eccentricity from 1100 for $e=0.6$ to 3800 for $e=0.9$.

JFM classification

Instability: Nonlinear instability Mixing: Turbulent mixing Vortex Flows: Vortex dynamics
Type
Papers
Information
Journal of Fluid Mechanics , Volume 768 , 10 April 2015 , pp. 294 - 315
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Copyright
© 2015 Cambridge University Press 

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References

Baratto, F., Bailey, S. C. & Tavoularis, S. 2006 Measurements of frequencies and spatial correlations of coherent structures in rod bundle flows. Nucl. Engng Des. 236, 18301837.CrossRefGoogle Scholar
Chang, D. & Tavoularis, S. 2008 Simulations of turbulence, heat transfer and mixing across narrow gaps between rod-bundle subchannels. Nucl. Engng Des. 238 (1), 109123.CrossRefGoogle Scholar
Choueiri, G. H.2014 Experimental investigations of flow development, gap instability and gap vortex street generation in eccentric annular channels. PhD thesis, University of Ottawa.Google Scholar
Choueiri, G. H. & Tavoularis, S. 2014 Experimental investigation of flow development and gap vortex street in an eccentric annular channel. Part 1. Overview of the flow structure. J. Fluid Mech. 752, 521542.Google Scholar
Gosset, A. & Tavoularis, S. 2006 Laminar flow instability in a rectangular channel with a cylindrical core. Phys. Fluids 18, 044108.Google Scholar
Guellouz, M. S. & Tavoularis, S. 2000 The structure of turbulent flow in a rectangular channel containing a cylindrical rod – part 1: Reynolds-averaged measurements. Exp. Therm. Fluid Sci. 23, 5973.Google Scholar
Hooper, J. D.1983 Large scale structural effects in a symmetrical four-rod subchannel. In Eighth Australasian Fluid Mechanics Conference, Newcastle, New South Wales.Google Scholar
Hooper, J. D.1984 The development of a large structure in the rod gap region for turbulent flow through closely spaced rod arrays. In Fourth Symposium on Turbulent Shear Flows, Karlsruhe, Germany, pp. 1.23–1.27.Google Scholar
Hooper, J. D. & Rehme, K. 1984 Large-scale structural effects in developed turbulent flow through closely spaced rod array. J. Fluid Mech. 145, 305337.Google Scholar
Hooper, J. D. & Wood, D. H. 1984 Fully developed rod bundle flow over a large range of Reynolds number. Nucl. Engng Des. 83, 3146.Google Scholar
Lexmond, A. S., Mudde, R. F. & van der Hagen, T. H. J. J.2005 Visualisation of the vortex street and characterisation of the cross flow in the gap between two sub-channels. In NURETH-11. Avignon, France.Google Scholar
Mahmood, A.2011 Single-phase crossflow mixing in a vertical tube bundle geometry: an experimental study. PhD thesis, Technical University Delft.Google Scholar
Meyer, L. 2010 From discovery to recognition of periodic large scale vortices in rod bundles as source of natural mixing between subchannels – a review. Nucl. Engng Des. 240, 15751588.Google Scholar
Möller, S. V. 1991 On phenomena of turbulent flow through rod bundles. Exp. Therm. Fluid Sci. 4, 2535.Google Scholar
Piot, E. & Tavoularis, S. 2011 Gap instability in laminar flows in eccentric annular channels. Nucl. Engng Des. 241 (11), 46154620.Google Scholar
Rehme, K. 1987 The structure of turbulent flow through rod bundles. Nucl. Engng Des. 99, 141154.Google Scholar
Rehme, K. 1989 Experimental observations of turbulent flow through subchannels of rod bundles. Exp. Therm. Fluid Sci. 2, 341349.Google Scholar
Rowe, D. S., Johnson, B. M. & Knudsen, J. G. 1974 Implications concerning rod bundle crossflow mixing based on measurment of turbulent flow sturcture. Intl J. Heat Mass Transfer 17, 407419.CrossRefGoogle Scholar
Tapucu, A. & Merilo, M. 1977 Studies on diversion cross-flow between two parallel channels communicating by a lateral slot. II: axial pressure variations. Nucl. Engng Des. 42, 307318.Google Scholar
Tavoularis, S. 2011 Rod bundle vortex networks, gap vortex streets, and gap instability: a nomenclature and some comments on available methodologies. Nucl. Engng Des. 241 (11), 46124614.Google Scholar
Wu, X. & Trupp, A. C. 1993 Experimental study on the unusual turbulence intensity distribution in rod-to-wall gap regions. Exp. Therm. Fluid Sci. 6, 360370.Google Scholar
Wu, X. & Trupp, A. C. 1994 Spectral measurements and mixing correlation in simulated rod bundle subchannels. Intl J. Heat Mass Transfer 37 (8), 12771281.CrossRefGoogle Scholar