Hostname: page-component-848d4c4894-xm8r8 Total loading time: 0 Render date: 2024-06-24T04:22:33.609Z Has data issue: false hasContentIssue false
  • English
  • Français

A numerical nonlinear analysis of the flow around two- and three-dimensional partially cavitating hydrofoils

Published online by Cambridge University Press:  26 April 2006

Spyros A. Kinnas  and
Neal E. Fine
Spyros A. Kinnas
Affiliation:
Department of Ocean Engineering, Massachusetts Institute of Technology, Cambridge, MA 02139, USA
Neal E. Fine
Affiliation:
Department of Ocean Engineering, Massachusetts Institute of Technology, Cambridge, MA 02139, USA
Get access Rights & Permissions [Opens in a new window]

Abstract

The partially cavitating two-dimensional hydrofoil problem is treated using nonlinear theory by employing a low-order potential-based boundary-element method. The cavity shape is determined in the framework of two independent boundary-value problems; in the first, the cavity length is specified and the cavitation number is unknown, and in the second the cavitation number is known and the cavity length is to be determined. In each case, the position of the cavity surface is determined in an iterative manner until both a prescribed pressure condition and a zero normal velocity condition are satisfied on the cavity. An initial approximation to the nonlinear cavity shape, which is determined by satisfying the boundary conditions on the hydrofoil surface rather than on the exact cavity surface, is found to differ only slightly from the converged nonlinear result.

The boundary element method is then extended to treat the partially cavitating three-dimensional hydrofoil problem. The three-dimensional kinematic and dynamic boundary conditions are applied on the hydrofoil surface underneath the cavity. The cavity planform at a given cavitation number is determined via an iterative process until the thickness at the end of the cavity at all spanwise locations becomes equal to a prescribed value (in our case, zero). Cavity shapes predicted by the present method for some three-dimensional hydrofoil geometries are shown to satisfy the dynamic boundary condition to within acceptable accuracy. The method is also shown to predict the expected effect of foil thickness on the cavity size. Finally, cavity planforms predicted from the present method are shown to be in good agreement to those measured in a cavitating three-dimensional hydrofoil experiment, performed in MIT's cavitation tunnel.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 254 , September 1993 , pp. 151 - 181
Copyright
© 1993 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Abbott, I. H. & Von Doenhoff, A. E. 1959 Theory of Wing Sections. Dover.
Acosta, A. J. 1955 A note on partial cavitation of flat plate hydrofoils. Tech. Rep. E-19.9, California Institute of Technology, Hydrodynamics Lab.
Arakeri, H. 1975 Viscous effects on the position of cavitation separation from smooth bodies. J. Fluid Mech. 68, 779799.Google Scholar
Birkhoff, G. & Zarantonello, E. H. 1957 Jets, Wakes and Cavities. Academic.
Brennen, C. 1969 A numerical solution of axisymmetric cavity flows. J. Fluid Mech. 37, 671688.Google Scholar
Breslin, J. P., Van Houten, R. J., Kerwin, J. E. & Johnsson, C.-A. 1982 Theoretical and experimental propeller-induced hull pressures arising from intermittent blade cavitation, loading, and thickness. Trans. Soc. Naval Archit. Mar. Engrs 90, 111151.Google Scholar
Fabula, A. G. 1962 Thin-airfoil theory applied to hydrofoils with a single finite cavity and arbitrary free streamline detachment. J. Fluid Mech. 12, 227240.Google Scholar
Fine, N. E. 1988 Computational and experimental investigations of the flow around cavitating hydrofoils. Tech. Rep. 88-6, MIT, Department of Ocean Engineering.
Fine, N. E. 1992 Nonlinear analysis of cavitating propellers in nonuniform flow. PhD thesis, Department of Ocean Engineering, MIT.
Fine, N. E. & Kinnas, S. A. 1992 A boundary element method for the analysis of the flow around 3-d cavitating hydrofoils. J. Ship Res. (to appear.)Google Scholar
Franc, J. P. & Michel, J. M. 1985 Attached cavitation and the boundary layer: experimental investigation and numerical treatment. J. Fluid Mech. 154, 6390.Google Scholar
Furuya, O. 1975a Nonlinear calculation of arbitrarily shaped supercavitating hydrofoils near a free surface. J. Fluid Mech. 68, 2140.Google Scholar
Furuya, O. 1975b Three-dimensional theory on supercavitating hydrofoils near a free surface. J. Fluid Mech. 71, 339359.Google Scholar
Geurst, J. A. & Timman, R. 1956 Linearized theory of two-dimensional cavitational flow around a wing section. IX Intl Cong. Applied Mech.
Lemonnier, H. & Rowe, A. 1988 Another approach in modelling cavitating flows. J. Fluid Mech. 195, 557580.Google Scholar
Jiang, C. W. & Leehey, P. 1977 A numerical method for determining forces and moments on supercavitating hydrofoils of finite span. In Second Intl Conf. Numer. Ship Hydrodynamics, Berkeley, September. National Academy Press.
Kerwin, J. E., Kinnas, S. A., Lee, J.-T. & Shih, W.-Z. 1987 A surface panel method for the hydrodynamic analysis of ducted propellers. Trans. Soc. Naval Archit. Mar. Engrs 95, 93122.Google Scholar
Kerwin, J. E., Kinnas, S. A., Wilson, M. B. & McHugh, J. 1986 Experimental and analytical techniques for the study of unsteady propeller sheet cavitation. In Proc. Sixteenth Symp. on Naval Hydrodynamics, Berkeley, California, July, pp. 387414. National Academy Press.
Kinnas, S. A. 1991 Leading-edge corrections to the linear theory of partially cavitating hydrofoils. J. Ship Res. 35, 1527.Google Scholar
Kinnas, S. A. & Fine, N. E. 1991 Non-linear analysis of the flow around partially or supercavitating hydrofoils by a potential based panel method. In Boundary Integral Methods-Theory and Applications, Proc. IABEM-90 Symp. Rome, Italy, October 15–19, pp. 289300. Springer.
Kinnas, S. A. & Fine, N. E. 1992 A nonlinear boundary element method for the analysis of unsteady propeller sheet cavitation. In Proc. Nineteenth Symp. on Naval Hydrodynamics, Seoul, Korea, August 1992. National Academy Press (in press).
Kinnas, S. A. & Mazel, C. H. 1992 Numerical vs. experimental cavitation tunnel (a supercavitating hydrofoil experiment). In Proc. 23rd American Towing Tank Conference, University of New Orleans, June 11–12, 1992. National Academy Press (in press).
Lee, C.-S. 1979 Prediction of steady and unsteady performance of marine propellers with or without cavitation by numerical lifting surface theory. PhD thesis, MIT, Department of Ocean Engineering.
Lee, J.-T. 1987 A potential based panel method for the analysis of marine propellers in steady flow. PhD thesis, MIT, Department of Ocean Engineering.
Leehey, P. 1971 Supercavitating hydrofoil of finite span. In IUTAM Symp. on Non-Steady Flow of Water at High Speeds, Leningrad, June 1971, pp. 277298.
Morino, L. & Kuo, C.-C. 1974 Subsonic potential aerodynamic for complex configurations: a general theory. AIAA J. 12, 191197.Google Scholar
Nishiyama, T. 1970 Lifting line theory of supercavitating hydrofoil of finite span. Z. Angew. Math. Mech. 50, 645653.Google Scholar
Pellone, C. & Rowe, A. 1981 Supercavitating hydrofoils in non-linear theory. In Third Intl Conf. on Numerical Ship Hydrodynamics, Basin d'essais des Carènes, Paris, France. National Academy Press.
Tulin, M. P. 1953 Steady two-dimensional cavity flows about slender bodies. Tech. Rep. 834, David Taylor Model Basin.
Tulin, M. P. 1955 Supercavitating flow past foils and struts. In Symp. on Cavitation in Hydrodynamics, NPL, Teddington, UK, September 1955.
Tulin, M. P. 1964 Supercavitating flows – small perturbation theory. J. Ship Res. 7, 1637.Google Scholar
Tulin, M. P. & Hsu, C. C. 1980 New applications of cavity flow theory. In 13th Symp. on Naval Hydrodynamics, Tokyo, Japan, 1980. National Academy Press.
Uhlman, J. S. 1978 A partially cavitated hydrofoil of finite span. Trans. ASME I: J. Fluids Engng 100, 353354.Google Scholar
Uhlman, J. S. 1987 The surface singularity method applied to partially cavitating hydrofoils. J. Ship Res. 31, 107124.Google Scholar
Uhlman, J. S. 1989 The surface singularity or boundary integral method applied to supercavitating hydrofoils. J. Ship Res. 33, 1620.Google Scholar
Van Houten, R. J. 1982 The numerical prediction of unsteady sheet cavitation on high aspect ratio hydrofoils. In 14th Symp. on Naval Hydrodynamics. National Academy Press.
Widnall, S. E. 1966 Unsteady loads on supercavitating hydrofoils. J. Ship Res. 9, 107118.Google Scholar
Wu, T. Y. & Wang, D. P. 1964 A wake model for free-streamline flow theory. Part 2. Cavity flow past obstacles of arbitrary profile. J. Fluid Mech. 18, 6593.Google Scholar