Heat transfer and fluid mechanics results are given for a swirl chamber whose geometry models an internal passage used to cool the leading edge of a turbine blade. The Reynolds numbers investigated, based on inlet duct characteristics, include values that are the same as in the application (18,000–19,400). The ratio of absolute air temperature between the inlet and wall of the swirl chamber ranges from 0.62 to 0.86 for the heat transfer measurements. Spatial variations of surface Nusselt numbers along swirl chamber surfaces are measured using infrared thermography in conjunction with thermocouples, energy balances, digital image processing, and in situ calibration procedures. The structure and streamwise development of arrays of Go¨rtler vortex pairs, which develop along concave surfaces, are apparent from flow visualizations. Overall swirl chamber structure is also described from time-averaged surveys of the circumferential component of velocity, total pressure, static pressure, and the circumferential component of vorticity. Important variations of surface Nusselt numbers and time-averaged flow characteristics are present due to arrays of Go¨rtler vortex pairs, especially near each of the two inlets, where Nusselt numbers are highest. Nusselt numbers then decrease and become more spatially uniform along the interior surface of the chamber as the flows advect away from each inlet.
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October 1999
Research Papers
Heat Transfer and Flow Phenomena in a Swirl Chamber Simulating Turbine Blade Internal Cooling
C. R. Hedlung,
C. R. Hedlung
Convective Heat Transfer Laboratory, Department of Mechanical Enginering; University of Utah, Salt Lake City, UT 84112
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P. M. Ligrani,
P. M. Ligrani
Convective Heat Transfer Laboratory, Department of Mechanical Enginering; University of Utah, Salt Lake City, UT 84112
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H.-K. Moon,
H.-K. Moon
Solar Turbines Inc., Turbine Cooling Design and Analysis, San Diego, CA 92186
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B. Glezer
B. Glezer
Solar Turbines Inc., Turbine Cooling Design and Analysis, San Diego, CA 92186
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C. R. Hedlung
Convective Heat Transfer Laboratory, Department of Mechanical Enginering; University of Utah, Salt Lake City, UT 84112
P. M. Ligrani
Convective Heat Transfer Laboratory, Department of Mechanical Enginering; University of Utah, Salt Lake City, UT 84112
H.-K. Moon
Solar Turbines Inc., Turbine Cooling Design and Analysis, San Diego, CA 92186
B. Glezer
Solar Turbines Inc., Turbine Cooling Design and Analysis, San Diego, CA 92186
J. Turbomach. Oct 1999, 121(4): 804-813 (10 pages)
Published Online: October 1, 1999
Article history
Received:
February 1, 1998
Online:
January 29, 2008
Citation
Hedlung, C. R., Ligrani, P. M., Moon, H., and Glezer, B. (October 1, 1999). "Heat Transfer and Flow Phenomena in a Swirl Chamber Simulating Turbine Blade Internal Cooling." ASME. J. Turbomach. October 1999; 121(4): 804–813. https://doi.org/10.1115/1.2836734
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