Accession Number : ADA180534

Title :   Aeroelasticity in Turbomachines Comparison of Theoretical and Experimental Cascade Results. Appendix A5. All Experimental and Theoretical Results for the 9 Standard Configurations.

Descriptive Note : Final rept. 2 May 84-1 Nov 85,

Corporate Author : ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE (SWITZERLAND) LAB DE THERMIQUE APPLIQUEE

Personal Author(s) : Boelcs,A. ; Fransson,T. H.

Report Date : 1986

Pagination or Media Count : 422

Abstract : The aeroelastician needs reliable, efficient methods for calculating unsteady blade forces in turbomachines. The validity of such theoretical or empirical prediction models can be established only if researchers apply their flutter and forced vibration predictions to a number of well documented experimental test cases. In this report, the geometrical and time average flow conditions of nine two dimensional and quasi-three dimensional experimental (mainly) standard configurations for aeroelasticity in turbomachine cascades are given. Some aeroelastic test cases are defined for each configuration, comprising different incidence angles, Mach numbers, interblade phase angle, reduced frequencies, ets. Furthermore, proposal for uniform nomenclature and reporting formats is included, in order to facilitate the comparison of different experimental data and theoretical results. Results from 15 theoretical prediction methods have been compared with each other, and with experimental data. The comparative investigation has shown that present theoretical models can predict accurately the aeroelastic behavior of certain cascade configurations in two dimensional flow. Other configurations, on the other hand, cannot be predicted as well. It is concluded that, although present methods can predict stability limits in some cases, the physical reasons for flutter in cascades are not yet fully understood. Further investigations, both experimental and theoretical, are thus urgently required.

Descriptors :   *AEROELASTICITY, *FLUTTER, *CASCADES(FLUID DYNAMICS), MODELS, PREDICTIONS, VIBRATION, ANGLE OF INCIDENCE, MACH NUMBER, CASCADE STRUCTURES, GEOMETRY, MEAN, TIME, EFFICIENCY, METHODOLOGY, RELIABILITY, LIMITATIONS, MATHEMATICAL PREDICTION, TURBOMACHINERY, THEORY, COMPARISON, TURBINE BLADES, TWO DIMENSIONAL FLOW, SWITZERLAND

Subject Categories : Fluid Mechanics

Distribution Statement : APPROVED FOR PUBLIC RELEASE