A numerical study is performed to simulate the tip leakage flow and heat transfer on the first stage rotor blade tip of GE-E3 turbine, which represents a modern gas turbine blade geometry. Calculations consist of the flat blade tip without and with film cooling. For the flat tip without film cooling case, in order to investigate the effect of tip gap clearance on the leakage flow and heat transfer on the blade tip, three different tip gap clearances of 1.0%, 1.5% and 2.5% of the blade span are considered. And to assess the performance of the turbulence models in correctly predicting the blade tip heat transfer, the simulations have been performed by using four different models (the standard k-ε, the RNG k-ε, the standard k-ω and the SST models), and the comparison shows that the standard k-ω model provides the best results. All the calculations of the flat tip without film cooling have been compared and validated with the experimental data of Azad and the predictions of Yang. For the flat tip with film cooling case, three different blowing ratio (M = 0.5, 1.0, and 1.5) have been studied to the influence on the leakage flow in tip gap and the cooling effectiveness on the blade tip. Tip film cooling can largely reduce the overall heat transfer on the tip. And the blowing ratio M = 1.0, the cooling effect for the blade tip is the best.
Numerical Study of Heat Transfer and Cooling Effectiveness on a Flat-Tip Turbine Blade
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Huang, Q, Wang, J, He, L, & Xu, Q. "Numerical Study of Heat Transfer and Cooling Effectiveness on a Flat-Tip Turbine Blade." Proceedings of the ASME 2013 Turbine Blade Tip Symposium. ASME 2013 Turbine Blade Tip Symposium. Hamburg, Germany. September 30–October 3, 2013. V001T02A004. ASME. https://doi.org/10.1115/TBTS2013-2053
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