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《中国航空学报》2020,33(1):149-160
Accurate predictions of Shock Waves and Boundary Layer Interaction (SWBLI) and strong Shock Waves and Wake Vortices Interaction (SWWVI) in a highly-loaded turbine propose challenges to the currently widely used Reynolds-Averaged Navier-Stokes (RANS) model. In this work, the SWBLI and the SWWVI in a highly-loaded Nozzle Guide Vane (NGV) are studied using a hybrid RANS/LES strategy. The Turbulence Kinetic Energy (TKE) budget and the Proper Orthogonal Decomposition (POD) method are used to analyze flow mechanisms. Results show that this hybrid RANS/LES method can obtain detailed flow structures for flow mechanisms analysis. Strong shock waves induce boundary layer separation, while the presence of a separation bubble can in turn lead to a Mach reflection phenomenon. The shock waves cause trailing-edge vortices to break clearly, and the wakes, in turn, can change the shocks intensity and direction. Furthermore, the Entropy Generation Rate (EGR) is used to analyze the irreversible loss. It turns out that the SWWVI can reduce the flow field loss. There are several weak shock waves in the NGV flow field, which can increase the irreversible loss. This work offers flow mechanisms analysis and presents the EGR distribution in SWBLI and SWWVI areas in a transonic turbine blade. 相似文献
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《中国航空学报》2021,34(11):66-78
In modern gas turbines, the High Pressure Turbine (HPT) is exposed to an extreme thermal environment due to the burned gases leaving the combustor. The burned gases are characterized by flow and temperature distortions that effect the aerodynamics and heat transfer of the turbine. The purpose of this paper is to investigate numerically the effect of the intensity of the swirling flow combined with the temperature non-uniformity “Hot-Streak” (H-S) on the aerothermal performances of a HPT Nozzle Guide Vane (NGV). The investigations are conducted on the solid untwisted NGV annular cascade developed in NASA Lewis Research Center. Four swirl intensities (|Sn| = 0, 0.1, 0.25 and 0.5), two swirl orientations (positive and negative) and two hot-streaks (rounded and radial) at the NGV inlet are considered. The simulations are done by solving the Reynolds Averaged Navier-Stokes (RANS) equations using ANSYS-CFX software. The results show that the H-S with swirl undergoes twisting following the orientation of the swirl. The H-S twist is aggressive under positive swirl compared to the negative swirl case. The inlet swirl generates a new secondary flow structure, so called Swirl Vortex (SV), which induces more aerodynamic losses. The aerodynamic efficiency under negative swirl found to be higher than that under positive swirl. The maximum temperature on the vane surface is controlled by the radial transport of the SV towards the endwalls. 相似文献
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