Film cooling effectiveness and heat transfer are measured downstream of injection through discrete holes into a turbulent mainstream boundary layer. Air is injected through both a single hole and a row of holes spaced at three-diameter intervals and inclined at an angle of 35 deg to the main flow. There is little difference between the heat transfer coefficient with blowing and without blowing at low blowing rates (mass flux ratios). In fact, at low blowing rates, injection is found to decrease somewhat the heat transfer coefficient from that measured without blowing. As the mass flux ratio increases past unity, the heat transfer coefficient increases especially with injection through a row of holes. The peak heat transfer is usually found at the edge of the spreading jets (i.e., between two holes). At a blowing rate near two, the lateral average of the heat transfer is as much as 27 percent higher than the heat transfer with no blowing. The increase in heat transfer is attributed to the interaction between the jets and the free stream, causing high levels of turbulence.
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Heat Transfer and Film Cooling Following Injection Through Inclined Circular Tubes
V. L. Eriksen,
V. L. Eriksen
Research and Development, Harrison Radiator Division, General Motors Corp., Lockport, N. Y.
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R. J. Goldstein
R. J. Goldstein
School of Mechanical and Aerospace Engineering, University of Minnesota, Minneapolis, Minn.
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V. L. Eriksen
Research and Development, Harrison Radiator Division, General Motors Corp., Lockport, N. Y.
R. J. Goldstein
School of Mechanical and Aerospace Engineering, University of Minnesota, Minneapolis, Minn.
J. Heat Transfer. May 1974, 96(2): 239-245 (7 pages)
Published Online: May 1, 1974
Article history
Received:
July 19, 1973
Online:
August 11, 2010
Citation
Eriksen, V. L., and Goldstein, R. J. (May 1, 1974). "Heat Transfer and Film Cooling Following Injection Through Inclined Circular Tubes." ASME. J. Heat Transfer. May 1974; 96(2): 239–245. https://doi.org/10.1115/1.3450171
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