Experimental Evaluation of High Lift, High Work LPT Blades in a Transonic Cascade

Authors

Ryan R. Sauder, Wright State University
Mitch Wolff, Wright State University - Main CampusFollow
Gloria E. Savela, Florida Turbine Technologies
Geoffery B. Norris, Florida Turbine Technologies
Andrew T. Lethander, Wright-Patterson Air Force
Natalia A. Posada, Wright-Patterson Air Force
John P. Clark, Wright-Patterson Air Force

Document Type

Article

Publication Date

1-1-2024

Identifier/URL

41553106 (Pure)

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Abstract

A family of low-pressure turbine stages was recently developed to investigate the limits of achievable work and lift for future engines applicable to unmanned air systems. Subsequently, mid-span sections of a pair of turbine blades from those stages were manufactured for testing in a transonic cascade facility to verify predicted performance at both on- and off-design conditions. Both turbine blades were designed at the meanline level to a work coefficient of 2.80, and the velocity triangles and pitch-to-chord ratios were consistent with incompressible Zweifel coefficients of 1.60 and 1.78. At design conditions, the airfoils provided 123° of flow turning at an exit isentropic Mach number of 0.78. Both inlet- and exit-total pressure traverses were conducted, and the inlet turbulence intensity and length scale were measured at a pair of locations upstream of the instrumented airfoils in the mid-passage. The experimental datasets presented herein include loading variations as well as loss variations versus Reynolds number. It was found that neither airfoil experienced separation at the lowest Reynolds number achievable at design exit Mach number. Accordingly, it was necessary to operate the cascade at reduced total-to-static pressure ratios to observe significant effects of separation on the loading and loss results. The experimental results presented here are compared against design-level predictions using Reynolds Averaged Navier-Stokes (RANS) codes with transition modeling as well as Large Eddy Simulation (LES). The results are encouraging and bode well for the development of future engines that have reduced part-count, weight, and cost while providing acceptable performance lapse at altitude.

Comments

Publisher Copyright: Copyright © 2024 by The United States Government.

Repository Citation

Sauder, R. R., Wolff, M., Savela, G. E., Norris, G. B., Lethander, A. T., Posada, N. A., & Clark, J. P. (2024). Experimental Evaluation of High Lift, High Work LPT Blades in a Transonic Cascade. Turbomachinery - Axial Flow Turbine Aerodynamics; Deposition, Erosion, Fouling, and Icing.
https://corescholar.libraries.wright.edu/mme/536

DOI

10.1115/GT2024-125023