Affiliation:
1. Department of Mechanical Engineering, Texas A&M University, College Station, TX 77843-3123
Abstract
Film cooling effectiveness measurements under rotation were performed on the rotor blade platform using a pressure sensitive paint (PSP) technique. The present study examines, in particular, the film cooling effectiveness due to purging of coolant from the wheel-space cavity through the circumferential clearance gap provided between the stationary and rotating components of the turbine. The experimental investigation is carried out in a new three-stage turbine facility, recently designed and taken into operation at the Turbomachinery Performance and Flow Research Laboratory (TPFL) of Texas A&M University. This new turbine rotor has been used to facilitate coolant injection through this stator-rotor gap upstream of the first stage rotor blade. The gap was inclined at 25deg to mainstream flow to allow the injected coolant to form a film along the passage platform. The effects of turbine rotating conditions on the blade platform film cooling effectiveness were investigated at three speeds of 2550rpm, 2000rpm, and 1500rpm with corresponding incidence angles of 23.2deg, 43.4deg, and 54.8deg, respectively. Four different coolant-to-mainstream mass flow ratios varying from 0.5% to 2.0% were tested at each rotational speed. Aerodynamic measurements were performed at the first stage stator exit using a radially traversed five-hole probe to quantify the mainstream flow at this station. Results indicate that film cooling effectiveness increases with an increase in the coolant-to-mainstream mass flow ratios for all turbine speeds. Higher turbine rotation speeds show more local film cooling effectiveness spread on the platform with increasing magnitudes.
Reference44 articles.
1. Schobeiri, M. T. , 1999, “Efficiency, Performance and Flow Measurement of Siemens-Westinghouse HP-Turbine Blades,” Series 9600 and 5600, Final Report, Westinghouse.
2. Schobeiri, M. T., Gilarranz, J. L., and Johansen, E. S., 2000, “Aerodynamic and Performance Studies of a Three Stage High Pressure Research Turbine with 3-D Blades, Design Points and Off-Design Experimental Investigations,” Paper No. 2000-GT-484.
3. Schobeiri, M. T., Suryanarayanan, A., Jermann, C., and Neuenschwander, T., 2004, “A Comparative Aerodynamic and Performance Study of a Three-Stage High Pressure Turbine With 3-D Bowed Blades and Cylindrical Blades,” Paper No. GT-2004-53650.
4. Fluid Dynamics and Heat Transfer of Turbomachinery
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45 articles.
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