It is necessary to understand how film cooling influences the external convective boundary condition involving both the adiabatic wall temperature and the heat transfer coefficient in order to predict the thermal durability of a gas turbine hot gas path component. Most studies in the past have considered only steady flow, but studies of the unsteadiness naturally present in turbine flow have become more prevalent. One source of unsteadiness is wake passage from upstream components which can cause fluctuations in the stagnation location on turbine airfoils. This in turn causes unsteadiness in the behavior of the leading edge coolant jets and thus fluctuations in both the adiabatic effectiveness and heat transfer coefficient. The dynamics of h and η are now quantifiable with modern inverse heat transfer methods and non-intrusive infrared thermography. The present study involved the application of a novel inverse heat transfer methodology to determine time resolved adiabatic effectiveness and heat transfer coefficient waveforms on a simulated turbine blade leading edge with an oscillating stagnation position. The leading edge geometry was simulated with a circular cylinder with a coolant hole located 21.5° downstream from the leading edge stagnation line, angled 20° to the surface and 90° to the streamwise direction. The coolant plume is shown to shift in response to the stagnation line movement. These oscillations thus influence the film cooling coverage and the time-averaged benefit of film cooling is influenced by the oscillation.
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ASME Turbo Expo 2015: Turbine Technical Conference and Exposition
June 15–19, 2015
Montreal, Quebec, Canada
Conference Sponsors:
- International Gas Turbine Institute
ISBN:
978-0-7918-5672-7
PROCEEDINGS PAPER
Film Cooling Parameter Waveforms on a Turbine Blade Leading Edge Model With Oscillating Stagnation Line
James L. Rutledge,
James L. Rutledge
Air Force Institute of Technology, Wright Patterson AFB, OH
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Tylor C. Rathsack,
Tylor C. Rathsack
Air Force Institute of Technology, Wright Patterson AFB, OH
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Matthew T. Van Voorhis,
Matthew T. Van Voorhis
Air Force Institute of Technology, Wright Patterson AFB, OH
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Marc D. Polanka
Marc D. Polanka
Air Force Institute of Technology, Wright Patterson AFB, OH
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James L. Rutledge
Air Force Institute of Technology, Wright Patterson AFB, OH
Tylor C. Rathsack
Air Force Institute of Technology, Wright Patterson AFB, OH
Matthew T. Van Voorhis
Air Force Institute of Technology, Wright Patterson AFB, OH
Marc D. Polanka
Air Force Institute of Technology, Wright Patterson AFB, OH
Paper No:
GT2015-43283, V05BT12A036; 14 pages
Published Online:
August 12, 2015
Citation
Rutledge, JL, Rathsack, TC, Van Voorhis, MT, & Polanka, MD. "Film Cooling Parameter Waveforms on a Turbine Blade Leading Edge Model With Oscillating Stagnation Line." Proceedings of the ASME Turbo Expo 2015: Turbine Technical Conference and Exposition. Volume 5B: Heat Transfer. Montreal, Quebec, Canada. June 15–19, 2015. V05BT12A036. ASME. https://doi.org/10.1115/GT2015-43283
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