A two-dimensional injection model is used with a two-dimensional low Reynolds number k-ε model boundary layer code. The three-dimensional effects of the discrete hole injection process are introduced in the two-dimensional prediction scheme through an “entrainment fraction” (Υ). An established correlation between Υ and the injection parameters obtained in a previous paper is used to predict the film cooling effectiveness (η) and heat transfer coefficients for multirow injection, injection into a laminar boundary layer, and finally injection on convex curved surfaces. Predictions of η are in good agreement with experimental data for most of the cases tested. Predictions of Stanton numbers defined by St(0) and St(l) are good for low injection ratios (M) but as M increases the values are underpredicted. In spite of some shortcomings, in the authors’ opinion the present two-dimensional prediction scheme is one of the most comprehensive developed so far. It is seen that the entrainment fraction Υ is quite universal in its application to two-dimensional predictions of the discrete hole film cooling process.
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July 1990
Research Papers
Prediction of Heat Transfer Characteristics for Discrete Hole Film Cooling for Turbine Blade Applications
D. K. Tafti,
D. K. Tafti
Department of Mechanical Engineering, West Virginia Institute of Technology, Montgomery, WV 25136
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S. Yavuzkurt
S. Yavuzkurt
Mechanical Engineering Department, The Pennsylvania State University, University Park, PA 16802
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D. K. Tafti
Department of Mechanical Engineering, West Virginia Institute of Technology, Montgomery, WV 25136
S. Yavuzkurt
Mechanical Engineering Department, The Pennsylvania State University, University Park, PA 16802
J. Turbomach. Jul 1990, 112(3): 504-511 (8 pages)
Published Online: July 1, 1990
Article history
Received:
January 23, 1989
Online:
June 9, 2008
Citation
Tafti, D. K., and Yavuzkurt, S. (July 1, 1990). "Prediction of Heat Transfer Characteristics for Discrete Hole Film Cooling for Turbine Blade Applications." ASME. J. Turbomach. July 1990; 112(3): 504–511. https://doi.org/10.1115/1.2927686
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