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Effects of compressibility, pitch rate, and Reynolds number on unsteady incipient leading-edge boundary layer separation over a pitching airfoil

Published online by Cambridge University Press:  26 April 2006

P. Ghosh Choudhuri  and
D. D. Knight
P. Ghosh Choudhuri
Affiliation:
Department of Mechanical and Aerospace Engineering, PO Box 909, Rutgers University, Piscataway, NJ 08855, USA
D. D. Knight
Affiliation:
Department of Mechanical and Aerospace Engineering, PO Box 909, Rutgers University, Piscataway, NJ 08855, USA
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Abstract

The effects of compressibility, pitch rate and Reynolds number on the initial stages of two-dimensional unsteady separation of laminar subsonic flow over a pitching NACA-0012 airfoil have been studied numerically. The approach involves the simulation of the flow by solving the two-dimensional unsteady compressible laminar Navier-Stokes equations employing the implicit approximate-factorization algorithm of Beam & Warming and a boundary-fitted C-grid. The algorithm has been extensively validated through comparison with analytical and previous numerical results. The computations display several important trends for the ‘birth’ of the primary recirculating region which is a principal precursor to leading-edge separation. Increasing the non-dimensional pitch rate from 0.05 to 0.2 at a fixed Reynolds number and Mach number delays the formation of the primary recirculating region. The primary recirculating region also forms closer to the leading edge. Increasing the Mach number from 0.2 to 0.5 at a fixed Reynolds number and pitch rate causes a delay in the formation of the primary recirculating region and also leads to its formation farther from the airfoil top surface. The length scale associated with the recirculating regions increases as well. Increasing the Reynolds number from 104 to 105 at a fixed Mach number and pitch rate hastens the appearance of the primary recirculating region. A shock appears on the top surface at a Reynolds number of 105 along with the simultaneous formation of multiple recirculating regions near the leading edge.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 308 , 10 February 1996 , pp. 195 - 217
Copyright
© 1996 Cambridge University Press

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References

Acharya, M. & Metwally, M. 1990 Evolution of the unsteady pressure field and vorticity production at the surface of a pitching airfoil. AIAA Paper 90-1472.
Beam, R. M. & Warming, R. F. 1978 An implicit factored scheme for the compressible Navier-Stokes equations. AIAA J. 16, 393402.Google Scholar
Carr, L. 1988 Progress in analysis and prediction of dynamic stall. J. Aircraft 25, 617.Google Scholar
Carr, L. & Chandrasekhara, M. S. 1995 An assessment of the impact of compressibility on dynamic stall. AIAA Paper 95-0779.
Carr, L. & McCroskey, W. 1992 A review of recent advances in computational and experimental analysis of dynamic stall. IUTAM Symp. on Fluid Dynamics of High Angle of Attack.
Chandrasekhara, M. S. & Ahmed, S. 1991 Laser velocimetry measurements of oscillating airfoil dynamic stall flow field. AIAA Paper 91-1799.
Chandrasekhara, M. S., Carr, L. W. & Wilder, M. C. 1994 Interferometric investigations of compressible dynamic stall over a transiently pitching airfoil. AIAA J. 32, 586593.Google Scholar
Crisler, W., Krothapalli, A. & Lourenco, L. 1994 PIV investigation of high speed flow over a pitching airfoil. AIAA Paper 94-0533.
Currier, J. M. & Fung, K. Y. 1992 Analysis of the onset of dynamic stall. AIAA J. 30, 24692477.Google Scholar
Doligalski, T. L., Smith, C. R. & Walker, J. D. A. 1994 Vortex interactions with walls. Ann. Rev. Fluid Mech. 26, 573616.Google Scholar
Ghia, K. N., Yang, J., Osswald, G. A. & Ghia, U. 1992 Study of the role of unsteady separation in the formation of dynamic stall vortex. AIAA Paper 92-0196.
Ghosh Choudhuri, P., Knight, D. & Visbal, M. 1994 Two-dimensional unsteady leading-edge separation on a pitching airfoil. AIAA J. 32, 673681.Google Scholar
Karim, Md. A. 1992 Experimental investigation of the formation and control of the dynamic-stall vortex over a pitching airfoil. MS thesis, Illinois Institute of Technology.
Kinsey, D. & Barth, T. 1984 Description of a hyperbolic grid generating procedure for arbitrary two dimensional bodies. AFWAL-TM-84–191.
McCroskey, W., Carr, L. & McAlister, K. 1976 Dynamic stall experiments on oscillating airfoils. AIAA J. 14, 5763.Google Scholar
Mehta, U. 1977 Dynamic stall of an oscillating airfoil. AGARD CP–227.
Peridier, V, Smith, F. & Walker, J. 1991a Vortex-induced boundary layer separation. Part 1. The limit problem Re. J. Fluid Mech. 232, 99131.Google Scholar
Peridier, V., Smith, F. & Walker, J. 1991b Vortex-induced boundary layer separation. Part 2. Unsteady interacting boundary layer theory. J. Fluid Mech. 232, 133165.Google Scholar
Pulliam T. H. 1986 Artificial dissipation models for the euler equations. AIAA J. 24, 19311940.Google Scholar
Sankar, N. L. & Tassa, Y. 1981 Compressibility effects on dynamic stall of an NACA-0012 airfoil. AIAA J. 19, 557558.Google Scholar
Shih, C., Lourenco, L., Dommelen, L. Van & Krothapalli, A. 1992 Unsteady flow past an airfoil pitching at a constant rate. AIAA J. 30, 11531161.Google Scholar
Smith, F. T. 1982 Concerning dynamic stall. Aero. Q. 33, 331352.Google Scholar
Smith, F. T. 1988 Finite-time break-up can occur in any unsteady interacting boundary layer. Mathematika 35, 256273.Google Scholar
Smith, F. T. & Elliott, J. W. 1985 On the abrupt turbulent reattachment downstream of leading-edge laminar separation. Proc. R. Soc. Lond. A 401, 127.Google Scholar
Steger, J. 1978 Implicit finite-difference simulation of flow about arbitrary two-dimensional geometries. AIAA J. 16, 679686.Google Scholar
Steger, J. & Chaussee, D. 1980 Generation of body-fitted coordinates using hyperbolic partial differential equations. SIAM J. Sci. Statist. Comput. 1, 431437.Google Scholar
Thomas, J. & Salas, M. 1986 Far field boundary conditions for transonic lifting solutions to the Euler equations. AIAA J. 24, 10741080.Google Scholar
Thomas, P. & Lombard, C. 1979 Geometric conservation law and its applications to flow computations on moving grids. AIAA J. 17, 10301037.Google Scholar
Dommelen, L. L. Van & Shen, S. F. 1980 The spontaneous generation of the singularity in a separating laminar boundary layer. J. Comput. Phys. 38, 125140.Google Scholar
Visbal, M. R. 1986a Calculation of viscous transonic flows about a supercritical airfoil. AFWAL TR-86–3013.
Visbal, M. R. 1986b Evaluation of an implicit Navier-Stokes solver for some unsteady separated flows. AIAA Paper 86-1053.
Visbal, M. R. 1990 Dynamic stall of a constant rate pitching airfoil. J. Aircraft 27, 400407.
Visbal, M. R. 1991 On the formation and control of the dynamic stall vortex on a pitching airfoil. AIAA Paper 91–0006.Google Scholar
Visbal, M. R. & Shang, J. 1989 Investigation of the flow structure around a rapidly pitching airfoil. AIAA J. 24, 10441051.Google Scholar
White, F. 1974 Viscous Fluid Flow. McGraw-Hill.
Yang, J., Ghia, K. N., Ghia, U. & Osswald, G. A. 1993 Management of dynamic stall phenomenon through active control of unsteady separation. AIAA Paper 93-3284.