This paper presents measurements and the companion computational fluid dynamics (CFD) predictions for a fully cooled, high-work single-stage HP turbine operating in a short-duration blowdown rig. Part I of this paper (Haldeman, C. W., Mathison, R. M., Dunn, M. G., Southworth, S. A., Harral, J. W., and Heltland, G., 2008, ASME J. Turbomach., 130(2), p. 021015) presented the experimental approach, and Part II focuses on the results of the measurements and demonstrates how these results compare to predictions made using the Numeca FINE/Turbo CFD package. The measurements are presented in both time-averaged and time-accurate formats. The results include the heat transfer at multiple spans on the vane, blade, and rotor shroud as well as flow path measurements of total temperature and total pressure. Surface pressure measurements are available on the vane at midspan, and on the blade at 50% and 90% spans as well as the rotor shroud. In addition, temperature and pressure measurements obtained inside the coolant cavities of both the vanes and blades are presented. Time-averaged values for the surface pressure on the vane and blade are compared to steady CFD predictions. Additional comparisons will be made between the heat transfer on cooled blades and uncooled blades with identical surface geometry. This, along with measurements of adiabatic wall temperature, will provide a basis for analyzing the effectiveness of the film cooling scheme at a number of locations.
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April 2008
Research Papers
Aerodynamic and Heat Flux Measurements in a Single-Stage Fully Cooled Turbine—Part II: Experimental Results
C. W. Haldeman,
C. W. Haldeman
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
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R. M. Mathison,
R. M. Mathison
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
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M. G. Dunn,
M. G. Dunn
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
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S. A. Southworth,
S. A. Southworth
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
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J. W. Harral,
J. W. Harral
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
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G. Heltland
G. Heltland
Honeywell Aerospace
, Phoenix, AZ 85034
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C. W. Haldeman
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
R. M. Mathison
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
M. G. Dunn
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
S. A. Southworth
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
J. W. Harral
Gas Turbine Laboratory,
The Ohio State University
, Columbus, OH 43235
G. Heltland
Honeywell Aerospace
, Phoenix, AZ 85034J. Turbomach. Apr 2008, 130(2): 021016 (11 pages)
Published Online: March 24, 2008
Article history
Received:
July 13, 2006
Revised:
July 17, 2006
Published:
March 24, 2008
Citation
Haldeman, C. W., Mathison, R. M., Dunn, M. G., Southworth, S. A., Harral, J. W., and Heltland, G. (March 24, 2008). "Aerodynamic and Heat Flux Measurements in a Single-Stage Fully Cooled Turbine—Part II: Experimental Results." ASME. J. Turbomach. April 2008; 130(2): 021016. https://doi.org/10.1115/1.2750678
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