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RESEARCH PAPERS

On the Application of a Linearized Unsteady Potential-Flow Analysis to Fan-Tip Cascades

[+] Author and Article Information
W. J. Usab, J. M. Verdon

United Technologies Research Center, East Hartford, CT 06108

J. Turbomach 108(1), 59-67 (Jul 01, 1986) (9 pages) doi:10.1115/1.3262025 History: Received January 17, 1986; Online November 09, 2009

Abstract

A linearized potential flow analysis, which accounts for the effects of nonuniform steady flow phenomena on the unsteady response to prescribed blade motions, has been applied to five two-dimensional cascade configurations. These include a flat-plate cascade and three cascades which are representative of the tip sections of current fan designs. Here the blades are closely spaced, highly staggered, and operate at low mean incidence. The fifth configuration is a NASA Lewis cascade of symmetric biconvex airfoils for which experimental measurements are available. Numerical solutions are presented that clearly illustrate the effects and importance of blade geometry and mean blade loading on the linearized unsteady response at high subsonic inlet Mach number and high blade-vibrational frequency. In addition, a good qualitative agreement is shown between the analytical predictions and experimental measurements for the cascade of symmetric biconvex airfoils. Finally, recommendations on the research needed to extend the range of application of linearized unsteady aerodynamic analyses are provided.

Copyright © 1986 by ASME
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