Erscheint 18 Ausgaben pro Jahr
ISSN Druckformat: 1064-2285
ISSN Online: 2162-6561
Indexed in
Film Cooling Simulation and Control
ABSTRAKT
Numerical simulation strategies for film cooling flows ranging from time-averaged simulations based on Reynolds-averaged equations to fully unsteady simulations are presented and reviewed. Simulation results are presented for both cylindrical and shaped holes with the key emphasis in this paper on the accuracy of the averaged results and on the film-cooling flow physics. It is shown that the Reynolds-averaged equations with turbulence models need anisotropy and realizability corrections to provide correct predictions for the cooling effectiveness. Spatially filtered unsteady simulations (called large-eddy simulations) appear to provide the needed quantitative accuracy and the rich flow physics representing such flows.
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Oliver Todd A., Bogard David G., Moser Robert D., Large eddy simulation of compressible, shaped-hole film cooling, International Journal of Heat and Mass Transfer, 140, 2019. Crossref
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Stratton Zachary T., Shih Tom I-P., Identifying Weaknesses in Eddy-Viscosity Models for Predicting Film Cooling via Large-Eddy Simulations, Journal of Propulsion and Power, 35, 3, 2019. Crossref
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Mansouri Zakaria, Numerical prediction of heat transfer characteristics on a turbine nozzle guide vane under various combustor exit hot‐streaks, Heat Transfer, 51, 1, 2022. Crossref
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Shangguan Yanqin, Wang Xian, Cao Fei, Zhu Yandan, High resolution simulation of film cooling with blowing ratio and inclination angle effects based on hybrid thermal lattice Boltzmann method, Thermal Science, 26, 4 Part B, 2022. Crossref