Forcing Function Effects on Unsteady Aerodynamic Gust Response: Part 1—Forcing Functions

[+] Author and Article Information
G. H. Henderson, S. Fleeter

School of Mechanical Engineering, Purdue University, West Lafayette, IN 47907

J. Turbomach 115(4), 741-750 (Oct 01, 1993) (10 pages) doi:10.1115/1.2929309 History: Received February 17, 1992; Online June 09, 2008


The fundamental gust modeling assumption is investigated by means of a series of experiments performed in the Purdue Annular Cascade Research Facility. The unsteady periodic flow field is generated by rotating rows of perforated plates and airfoil cascades. In this paper, the measured unsteady flow fields are compared to linear-theory vortical gust requirements, with the resulting unsteady gust response of a downstream stator cascade correlated with linear theory predictions in an accompanying paper. The perforated-plate forcing functions closely resemble linear-theory forcing functions, with the static pressure fluctuations small and the periodic velocity vectors parallel to the downstream mean-relative flow angle over the entire periodic cycle. In contrast, the airfoil forcing functions exhibit characteristics far from linear-theory vortical gusts, with the alignment of the velocity vectors and the static pressure fluctuation amplitudes dependent on the rotor-loading condition, rotor solidity, and the inlet mean-relative flow angle. Thus, these unique data clearly show that airfoil wakes, both compressor and turbine, are not able to be modeled with the boundary conditions of current state-of-the-art linear unsteady aerodynamic theory.

Copyright © 1993 by The American Society of Mechanical Engineers
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