A theoretical study is carried out to determine the conditions under which steady-state pitching oscillations of an airfoil in one degree of freedom are possible in two-dimensional subsonic incompressible stalled flow using Parkin’s [1] coefficients. The results show that such oscillations can occur if the axis of rotation is located at a point that is approximately rearward of airfoil midchord but not too far rearward of the airfoil trailing edge. The practical significance of these results with respect to flutter is briefly examined. Torsional flutter [2] in the case of potential flow can occur only at very low reduced frequencies and under special circumstances, namely, when the rotation point is ahead of quarter chord, K′ > 550 and k < 0.0435. The significant difference between classical and stall flutter (torsional) is that the real part of the pitching moment coefficient [2] is negative in the former case and is positive in the latter case in the region of instability. Therefore, stall flutter can occur at very low values of K′, unlike classical flutter where K′ has to be greater than 550. The ratio of torsional natural frequency to flutter frequency is greater than 1 in the case of stall flutter, whereas in classical flutter the ratio is less than 1 because of the sign of the real part of the moment coefficient. A single-degree-of-freedom torsional flutter equation was derived, and by equating the real and the imaginary parts of the equation, relationships between the various flutter parameters were obtained. Stability boundaries were obtained for the structural damping coefficient gα = 0, 0.001, 0.005, 0.01, 0.02, 0.04, and 0.1 for various values of K′, namely, 5, 20, 40, 60, 80, 100, and 1000. The above values practically cover all airplane wings and compressor blades. The significant results are tabulated and some of the important parameters are plotted in the attached figures. By utilizing these figures, a typical airfoil in question could be checked, whether it is flutter-free or not, and if it is in flutter, all the flutter parameters could be determined. The analysis was conducted using Parkin’s coefficients [1], which require that the airfoil be completely stalled during the cycle.
Skip Nav Destination
Article navigation
November 1967
This article was originally published in
Journal of Engineering for Industry
Research Papers
Torsional Instability of Fully Stalled Airfoil (or Supercavitating Hydrofoil)
M. S. Natesh
M. S. Natesh
Aero Elasticity and Methods Group, Vibration Department, Wright Aeronautical Division, Curtiss-Wright Corporation, Wood-Ridge, N. J.
Search for other works by this author on:
M. S. Natesh
Aero Elasticity and Methods Group, Vibration Department, Wright Aeronautical Division, Curtiss-Wright Corporation, Wood-Ridge, N. J.
J. Eng. Ind. Nov 1967, 89(4): 671-680
Published Online: November 1, 1967
Article history
Received:
December 1, 1966
Online:
August 25, 2011
Connected Content
Citation
Natesh, M. S. (November 1, 1967). "Torsional Instability of Fully Stalled Airfoil (or Supercavitating Hydrofoil)." ASME. J. Eng. Ind. November 1967; 89(4): 671–680. https://doi.org/10.1115/1.3610131
Download citation file:
10
Views
Get Email Alerts
Cited By
On-Orbit Processing and Hardware Performance of Microgravity Hydrothermal Synthesis for Graphene Aerogel
J. Manuf. Sci. Eng (December 2024)
A Review on Metallic Drilling Burrs: Geometry, Formation, and Effect on the Mechanical Strength of Metallic Assemblies
J. Manuf. Sci. Eng (April 2025)
Related Articles
A Navier–Stokes Analysis of the Stall Flutter Characteristics of the Buffum Cascade
J. Turbomach (October,2000)
Supersonic Stall Flutter of High-Speed Fans
J. Eng. Power (July,1982)
Effect of Interblade Phase Angle and Incidence Angle on Cascade Pitching Stability
J. Eng. Power (April,1980)
Related Proceedings Papers
Related Chapters
Experimental Investigation of Ventilated Supercavitation Under Unsteady Conditions
Proceedings of the 10th International Symposium on Cavitation (CAV2018)
Control and Operational Performance
Closed-Cycle Gas Turbines: Operating Experience and Future Potential
Introduction and Definitions
Handbook on Stiffness & Damping in Mechanical Design