EXPERIMENTAL-DETERMINATION OF STATOR ENDWALL HEAT-TRANSFER

被引：23

作者：

BOYLE, RJ

RUSSELL, LM

机构：

[1] NASA Lewis Research Center, Cleveland, OH

来源：

JOURNAL OF TURBOMACHINERY-TRANSACTIONS OF THE ASME | 1990年 / 112卷 / 03期

关键词：

D O I：

10.1115/1.2927693

中图分类号：

TH [机械、仪表工业];

学科分类号：

0802 ;

摘要：

Local Stanton numbers were experimentally determined for the endwall surface of a turbine vane passage. A six-vane linear cascade having vanes with an axial chord of 13.81 cm was used. Results were obtained for Reynolds numbers based on inlet velocity and axial chord between 73,000 and 495,000. The test section was connected to a low-pressure exhaust system. Ambient air was drawn into the test section; inlet velocity was controlled up to a maximum of 59.4 m/s. The effect of the inlet boundary layer thickness on the endwall heat transfer was determined for a range of test section flow rates. The liquid crystal measurement technique was used to measure heat transfer. Endwall heat transfer was determined by applying electrical power to a foil heater attached to the cascade endwall. The temperature at which the liquid crystal exhibited a specific color was known from a calibration test. Lines showing this specific color were isotherms, and because of uniform heat generation they were also lines of nearly constant heat transfer. Endwall static pressures were measured, along with surveys of total pressure and flow angles at the inlet and exit of the cascade. © 1990 by ASME.

引用

页码：547 / 558

页数：12

共 14 条

[1]

Akino N., Kunugi T., Ichimiya K., Mitsushiro K., Ueda M., Improved Liquid Crystal Thermometry Excluding Human Color Sensation, Part II-Application to the Determination of Wall Temperature Distributions, Pressure and Temperature Measurements, 58, pp. 57-62, (1986)

[2]

Bailey D.A., Study of Mean- and Turbulent Velocity Fields in a Large-Scale Turbine-Vane Passage, (1979)

[3]

Blair M.F., An Experimental Study of Heat Transfer and Film Cooling on Large-Scale Turbine Endwalls, ASME, Journal of Heat Transfer, 96, pp. 524-529, (1974)

[4]

Brooks A.J., Colbourne D.E., Wedlake E.T., Oldfield M.L.G., Schultz D.L., Jones T.V., Loftus P.J., The Isentropic Light Piston Annular Cascade Facility at RAE Pyestock, Heat Transfer and Cooling in Gas Turbines, (1985)

[5]

Crawford M.E., Kays W.M., STAN5-A Program for Numerical Computation of Two-Dimensional Internal and External Boundary Layer Flows, (1976)

[6]

Dunn M.G., Hause A., Measurement of Heat Flux and Pressure in a Turbine Stage, ASME, Journal of Engineering for Power, 104, 1, pp. 215-223, (1982)

[7]

Dunn M.G., Martin H.L., Stanek M.J., Heat-FIux and Pressure Measurements and Comparison with Predictions for a Low-Aspect-Ratio Turbine Stage, ASME Journal of Turbomachinery, 108, (1986)

[8]

Georgiou D.P., Godard M., Richards B.E., Experimental Study of the Iso-Heat-Transfer-Rate Lines on the End-Wall of a Turbine Cascade, (1979)

[9]

Goldstein R.J., Chyu M.K., Hain R.C., Measurement of Local Mass Transfer on a Surface in the Region of the Base of a Protruding Cylinder With a Computer-Controlled Data Acquisition System, Int. J. Heat Mass Transfer, 28, 5, pp. 977-985, (1985)

[10]

Goldstein R.J., Spores R.A., Turbulent Transport on the Region Between Adjacent Turbine Blades, ASME, Journal of Heat Transfer, 110, 4, pp. 862-869, (1988)

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