Browse > Article
http://dx.doi.org/10.2478/IJNAOE-2013-0197

Reynolds and froude number effect on the flow past an interface-piercing circular cylinder  

Koo, Bonguk (IIHR-Hydroscience & Engineering, University of Iowa, Iowa City)
Yang, Jianming (IIHR-Hydroscience & Engineering, University of Iowa, Iowa City)
Yeon, Seong Mo (IIHR-Hydroscience & Engineering, University of Iowa, Iowa City)
Stern, Frederick (IIHR-Hydroscience & Engineering, University of Iowa, Iowa City)
Publication Information
International Journal of Naval Architecture and Ocean Engineering / v.6, no.3, 2014 , pp. 529-561 More about this Journal
Abstract
The two-phase turbulent flow past an interface-piercing circular cylinder is studied using a high-fidelity orthogonal curvilinear grid solver with a Lagrangian dynamic subgrid-scale model for large-eddy simulation and a coupled level set and volume of fluid method for air-water interface tracking. The simulations cover the sub-critical and critical and post critical regimes of the Reynolds and sub and super-critical Froude numbers in order to investigate the effect of both dimensionless parameters on the flow. Significant changes in flow features near the air-water interface were observed as the Reynolds number was increased from the sub-critical to the critical regime. The interface makes the separation point near the interface much delayed for all Reynolds numbers. The separation region at intermediate depths is remarkably reduced for the critical Reynolds number regime. The deep flow resembles the single-phase turbulent flow past a circular cylinder, but includes the effect of the free-surface and the limited span length for sub-critical Reynolds numbers. At different Froude numbers, the air-water interface exhibits significantly changed structures, including breaking bow waves with splashes and bubbles at high Froude numbers. Instantaneous and mean flow features such as interface structures, vortex shedding, Reynolds stresses, and vorticity transport are also analyzed. The results are compared with reference experimental data available in the literature. The deep flow is also compared with the single-phase turbulent flow past a circular cylinder in the similar ranges of Reynolds numbers. Discussion is provided concerning the limitations of the current simulations and available experimental data along with future research.
Keywords
Large-eddy simulation; Interface-piercing circular cylinder; Run-up; Wave breaking; Vortical structures;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Achenbach, E., 1968. Distribution of local pressure and skin friction around a circular cylinder in cross-flow up to Re = 5$\times$106. Journal of Fluid Mechanics, 34(4), pp.625-639.   DOI
2 Bonmarin, P., 1989. Geometric properties of deep-water breaking waves. Journal of Fluid Mechanics, 209, pp.405-433.   DOI   ScienceOn
3 Bhushan, S., Stern, F. and Doctors, L.J., 2010. Verification and validation of URANS wave resistance for air cushion vehicles, and comparison with linear theory. Journal of Ship Research, 55, pp.249-267.
4 Cantwell, B.J., and Coles, D., 1983. An experimental study of entrainment and transport in turbulent near wake of a circular cylinder. Journal of Fluid Mechanics, 136, pp.321-374.   DOI   ScienceOn
5 Chaplin, J.R., and Teigen, P., 2003. Steady flow past a vertical surface-piercing circular cylinder. Journal of Fluids and Structures, 18(3-4), pp.271-285.   DOI   ScienceOn
6 Falgout, R.D., Jones, J.E., Yang, U.M., 2006. Numerical solution of partial differential equations on parallel computers. Berlin: Springer.
7 Galvin, C.J., 1968. Breaker type classification on three laboratory beaches. Journal of Geophysical Research, 73(12), pp. 3651-3659.   DOI
8 Grue, J. and Jensen, A., 2006. Experimental velocities and accelerations in very steep wave events in deep water. European Journal of Mechanics B/Fluids, 25(5), pp.554-564.   DOI   ScienceOn
9 Hay, A.D., 1947. Flow about semi-submerged cylinders of finite length, Princeton University Report. Princeton, NJ: Princeton University.
10 Hunt, J., Wray, A. and Moin, P., 1988. Eddies, stream, and convergence zones in turbulent flows. In: Proceedings CTR Summer Program. Center for Turbulence Research, Stanford, CA, pp.193-208.
11 Inoue, M., Bara, N. and Himeno, Y., 1993. Experimental and numerical study of viscous flow field around an advancing vertical circular cylinder piercing a free-surface. Journal of Kansai Society Naval Architecture, 220, pp.57-64.
12 Jiang, G.S. and Shu, C.W., 1996. Efficient implementation of weighted ENO schemes. Journal of Computational Physics, 126, pp.202-228.   DOI   ScienceOn
13 Kandasamy, M., Xing, T. and Stern, F., 2009. Unsteady free surface wave-induced separation: Vortical structures and instabilities. Journal of Fluids and Structures, 25(2), pp.343-363.   DOI   ScienceOn
14 Kawamura, T., Mayer, S., Garapon, A. and Sørensen, L., 2002. Large eddy simulation of a flow past free surface piercing circular cylinder. Journal of Fluids Engineering, 124, pp.91-101.   DOI   ScienceOn
15 Norberg, C., 1992. Pressure forces on a circular cylinder in cross flow. In: IUTAM Symposium Bluff-Body Wakes, Dynamics and Instabilities, Gottingen, Germany, 7-11 September 1992, pp.275-278.
16 Kimmoun, O. and Branger, H., 2007. A particle image velocimetry investigation on laboratory surf-zone breaking waves over a sloping beach. Journal of Fluid Mechanics, 588, pp.353-397.
17 Koo, B., Wang, Z., Yang, J. and Stern, F., 2012. Impulsive plunging wave breaking downstream of a bump in a shallow water flume-Part II: Numerical simulations. Journal of Fluids and Structures, 32, pp.121-134.   DOI   ScienceOn
18 Kravchenko, A.G. and Moin, P., 2000. Numerical studies of flow over a circular cylinder at ReD=3900. Physics of Fluids, 12, pp.403-417.   DOI   ScienceOn
19 Peregrine, D.H., 1983. Breaking waves on beaches. Annual Review of Fluid Mechanics, 15, pp.147-178.
20 Sarghini, F., Piomelli, U., Balaras, E., 1999. Scale-similar models for large-eddy simulations. Physics of Fluids, 11(6), pp. 1596-1607.   DOI   ScienceOn
21 Shakeri, M., Tavakolinejad, M. and Duncan, J.H., 2009. An experimental investigation of divergent bow waves simulated by a two-dimensional plus temporal wave marker technique. Journal of Fluid Mechanics, 634, pp.217-243.   DOI   ScienceOn
22 Shu, C.W. and Osher, S., 1988. Efficient implementation of essentially non oscillatory shock-capturing schemes. Journal of Computational Physics, 77(2), pp.439-471.   DOI   ScienceOn
23 Singh, S.P. and Mittal, S., 2005. Flow past a cylinder: shear layer instability and drag crisis. International Journal for Numerical Methods in Fluids, 47(1), pp.75-98.   DOI   ScienceOn
24 Stern, F., Wilson, R. and Shao, J., 2006. Quantitative V&V of CFD simulations and certification of CFD codes. International Journal for Numerical Methods in Fluids, 50(11), pp.1335-1355.   DOI   ScienceOn
25 Wang, Z., Yang, J., Koo, B.G. and Stern, F., 2009. A coupled level set and volume-of-fluid method for sharp interface simulation of plunging breaking waves. International Journal of Multiphase Flow, 35(3), pp.227-246.   DOI   ScienceOn
26 Suh, J., Yang, J. and Stern, F., 2011. The effect of air-water interface on the vortex shedding from a vertical circular cylinder. Journal of Fluids and Structure, 27(1), pp.1-22.   DOI   ScienceOn
27 Sujudi, D. and Haimess, R., 1995. Identification of swirling flow in 3D vector fields, Technical report. Department of Aeronautics and Astronautics.
28 Tallent, J.R., Yamashita, T. and Tsuchiya, Y., 1990. Transformation characteristics of breaking water waves. Water Wave Kinematics, 178, pp.509-523.
29 Wang, Z., Yang, J. and Stern, F., 2010. Numerical simulations of wave breakings around a wedge-shaped bow. Proceedings of 28th Symposium on Naval Hydrodynamics, Pasadena, California, 12-17 September 2010.
30 Wang, Z., Yang, J. and Stern, F., 2012. A new volume-of-fluid method with a constructed distance function on general structured grids. Journal of Computational Physics, 231(9), pp.3703-3722.   DOI   ScienceOn
31 Wissink, J.G. and Rodi, W., 2008. Numerical study of the near wake of a circular cylinder. International Journal of Heat and Fluid Flow, 29(4), pp.1060-1070.   DOI   ScienceOn
32 Xing, T. and Stern, F., 2010. Factors of safety for Richardson extrapolation. ASME Journal of Fluids Engineering, 132, pp.1-13.
33 Yang, J. and Stern, F., 2009. Sharp interface immersed-boundary/level-set method for wave-body interactions. Journal of Computational Physics, 228(17), pp.6590-6616.   DOI   ScienceOn
34 Yeon, S., Yang, J. and Stern, F., 2013. Large eddy simulation of drag crisis in turbulent flow past a circular cylinder. ITTC workshop on wave run-up and vortex shedding, Nantes, France, 17-18 October 2013.
35 Yu, G., Avital, E.J. and Williams, J.J.R., 2008. Large eddy simulation of flow past free surface piercing circular cylinders. Journal of Fluids Engineering, 130, pp.10134.1-9.
36 Yoon, S.H., Kim, D.H., Sadat-Hosseini, H., Yang, J. and Stern, F., 2013. High-fidelity CFD simulation of wave run-up around vertical cylinders in monochromatic waves. ITTC workshop on wave run-up and vortex shedding, Nantes, France, 17-18 October 2013.