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A comparative study of the film cooling hole configurationeffects on the leading edge of asymmetrical turbine blade

Published online by Cambridge University Press:  14 March 2011

Mustapha Benabed*
Affiliation:
Laboratoire de Mécanique Appliquée, Faculté de Génie-Mécanique, Université des Sciences et de la Technologie d’Oran, BP 1505 El-Mnouar, Oran, Algeria
*
a Corresponding author: [email protected]
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Abstract

The focus of this comparative-numerical study is to investigate the effects of advancedcooling hole geometries on film cooling effectiveness. Computational results are presentedfor a row of coolant injection holes on each side of an asymmetrical turbine blade modelnear the leading edge. Six film cooling configurations are considered in the presentstudy, namely: (1) a cylindrical film hole, (2) a shaped film hole, (3) a uniform filmslot, (4) a convergent film slot, (5) a crescent film hole, and (6) a trenched film hole.All simulations are conducted for the same density ratio of 1.0 and the same inlet plenumpressure. A new parameter, Rc, is defined to measure the rate of bladecoverage by the film cooling. Results show that, at the suction side, except for thetrenched case, all configurations provide an increase of film effectiveness, specially thecrescent slot case which provides the highest increase over the baseline case. On pressureside, the five configurations produce better quality of cooling and an enhancement whichreaches 60% for the crescent hole case. The best blade coverage by the film cooling isallotted to the two cases: uniform and converge slot configurations.

Type
Research Article
Copyright
© AFM, EDP Sciences 2011

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References

K.D. Walters, J.H. Leylek, A detailed analysis of film-cooling physics, part 1: streamwise injection with cylindrical holes, 1994, ASME Paper, 97-GT-269
Azzi, A., Jubran, B.A., Numerical Modeling of Film Cooling from Short Length Stream-Wise Injection Holes, Heat and Mass Transf. 39 (2003) 345353 CrossRefGoogle Scholar
Azzi, A., Jubran, B.A., Numerical Modelling of Film Cooling from Converging Slot-Hole, J. Heat Mass Transfer 43 (2007) 381388 CrossRefGoogle Scholar
Baheri, S., Alavi Tabrizi, S.P., Jubran, B.A., Film Cooling Effectiveness from Trenched Shaped and Compound Holes, J. Heat Mass Transf. 44 (2008) 989998 CrossRefGoogle Scholar
S. Baheri, B.A. Jubran, S.P. Alavi Tabrizi, The Effect of Turbulence Intensity on Film Cooling of Gas Turbine Blade from Trenched Shaped Holes, ASME Paper # GT2008-50318, Proc. ASME Turbo Expos 2008 Conference, June 9–13
Nemdili, F., Azzi, A., Theodoridis, G., Jubran, B.A., Reynolds Stress Transport Modeling of Film Cooling at the Leading Edge of a Symmetrical Turbine Blade Model, J. Heat Trans. Eng. 29 (2008) 950960 CrossRefGoogle Scholar
Baheri, S., Jubran, B.A., Alavi Tabrizi, S.P., Computational Investigation of Film Cooling from Trenched Holes Near the Leading Edge of a Turbine Blade, J. Numerical Heat Transfer, Part A: Applications 53 (2008) 208322 Google Scholar
F. Nemdili, A. Azzi, B.A. Jubran, Shower Head Film Cooling Effectiveness of a Symmetrical Turbine Blade Model – Effect of Lateral Injection, Proc. HT2007 2007, Paper # HT2007-32081, ASME-JSME Thermal Engineering Summer Heat Transfer Conference, July 8–12
Salcudean, M., Gartshore, I., Zhang, K., McLean, I., An experimental study of film cooling effectiveness near the leading edge of a turbine blade, Trans. ASME J. Turbomachinery 116 (1994) 7179 CrossRefGoogle Scholar
Azzi, A., Jubran, B.A., Influence of leading-edge lateral injection angles on the film cooling effectiveness of a gas turbine blade, Heat and Mass Transf. 40 (2004) 501508 CrossRefGoogle Scholar
G. Wagner, Experimental investigations of showerhead film cooling on the leading edge of a turbine blade, Ph.D. Thesis No: 3755, 2007, Laboratoire de thermique appliquée et de turbomachines, École Polytechnique Fédérale de Lausanne
S. Ardey, L. Fottner, Flow Field Measurements on a Large Scale Turbine Cascade with Leading Edge Film Cooling by Two Rows of Holes, 1997, ASME Paper No. 97-GT-524
S. Ardey, L. Fottner, A Systematic Experimental Study on the Aerodynamics of Leading Edge Film Cooling on a Large Scale High Pressure Turbine Cascade, 1997, ASME Paper No. 98-GT-434
S. Ardey, 3D-Messung des Strömungsfeldes um die filmgekühlte Vorderkante einer Referenzschaufel Ph.D. Thesis, University of the Armed Forces Munich, 1998
Bohn, D., Kusterer, K., Aerothermal Investigation of Mixing Flow Phenomena in Case of Radially Inclined Ejection Holes at the Leading Edge, ASME J. Turbo Mach. 122 (2000) 334339 CrossRefGoogle Scholar
Bunker, R.S., A review of shaped hole turbine film-cooling technology, ASME J. Heat Trans. 127 (2005) 441453 CrossRefGoogle Scholar
Y. Lu, A. Dhungel, S.V. Ekkad, R.S. Bunker, Film Cooling Measurements for Cratered Cylindrical Inclined Holes, ASME Paper, GT2007-27386
Sargison, J.E., Guo, S.M., Oldfield, M.L., Lock, G.D., Rawlinson, A.J., A converging slot-hole film-cooling geometry-part 1: low-speed flat-plate heat transfer and loss, ASME J. Turbomach. 124 (2002) 453460 CrossRefGoogle Scholar
Y. Lu, A. Dhungel, S.V. Ekkad, R.S. Bunker, Effect of Trench Width and Depth on Film Cooling from Cylindrical Holes Embedded in Trenches ASME Paper, GT2007-27388
Lu, Y., Effect of hole configurations on film cooling from cylindrical inclined holes for the application to gas turbine blades, Int. J. Heat Fluid Flow 28 (2007) 922931 CrossRefGoogle Scholar
Sargison, J.E., Guo, S.M., Oldfield, M.L., Lock, G.D., Rawlinson, A.J., A converging slot-hole film-cooling geometry-part 2: transonic nozzle guide vane heat transfer and loss, ASME J. Turbomach. 124 (2002) 461471 CrossRefGoogle Scholar
ANSYS CFX 10.0 (2005) Documentations
Lakehal, D., Theodoridis, G., Rodi, W., Three dimensional flow and heat transfer calculations of film cooling at the leading edge of asymmetrical turbine blade model, Int. J. Heat Fluid Flow 22 (2001) 113122 CrossRefGoogle Scholar
F.R. Menter, Zonal two-equation k-ω turbulence model for aerodynamic flows (1993) AIAA Paper, 93-2906
Bogard, D.G., Thole, K.A., Gas Turbine Film Cooling, J. Propuls. Power 22 (2006) 249270 CrossRefGoogle Scholar
R.S. Bunker, Film Cooling: Breaking the Limits of Diffusion Shaped Holes Turbine 09 Symposium on Heat Transfer in Gas Turbine Systems, 2009, Antalya, Turkey
Z. Gao, D.P. Narzary, J. Han, Film cooling on a gas turbine blade pressure side or suction side with compound angle shaped holes. Paper # HT-2007-32098. In. Proc. of the ASME-JSME thermal engineering summer heat transfer conference, July 8–12, 2007, Vancouver, BC, Canada