The secondary flows, including passage and other vortices in a turbine cascade, cause significant aerodynamic losses and thermal gradients. Leading edge modification of the blade has drawn considerable attention as it has been shown to reduce the secondary flows. However, the heat transfer performance of a leading edge modified blade has not been investigated thoroughly. Since a fillet at the leading edge blade is reported to reduce the aerodynamic loss significantly, the naphthalene sublimation technique with a fillet geometry is used to study local heat (mass) transfer performance in a simulated turbine cascade. The present paper compares Sherwood number distributions on an endwall with a simple blade and a similar blade having a modified leading edge by adding a fillet. With the modified blades, a horseshoe vortex is not observed and the passage vortex is delayed or not observed for different turbulence intensities. However, near the blade trailing edge the passage vortex has gained as much strength as with the simple blade for low turbulence intensity. Near the leading edge on the pressure and the suction surface, higher mass transfer regions are observed with the fillets. Apparently the corner vortices are intensified with the leading edge modified blade.
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October 2006
Technical Papers
Influence of Blade Leading Edge Geometry on Turbine Endwall Heat (Mass) Transfer
S. Han,
S. Han
Heat Transfer Laboratory, Department of Mechanical Engineering,
University of Minnesota
, Minneapolis, MN 55455
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R. J. Goldstein
R. J. Goldstein
Heat Transfer Laboratory, Department of Mechanical Engineering,
e-mail: rjg@me.umn.edu
University of Minnesota
, Minneapolis, MN 55455
Search for other works by this author on:
S. Han
Heat Transfer Laboratory, Department of Mechanical Engineering,
University of Minnesota
, Minneapolis, MN 55455
R. J. Goldstein
Heat Transfer Laboratory, Department of Mechanical Engineering,
University of Minnesota
, Minneapolis, MN 55455e-mail: rjg@me.umn.edu
J. Turbomach. Oct 2006, 128(4): 798-813 (16 pages)
Published Online: February 1, 2005
Article history
Received:
October 1, 2004
Revised:
February 1, 2005
Citation
Han, S., and Goldstein, R. J. (February 1, 2005). "Influence of Blade Leading Edge Geometry on Turbine Endwall Heat (Mass) Transfer." ASME. J. Turbomach. October 2006; 128(4): 798–813. https://doi.org/10.1115/1.2221326
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