Transonic turbine blade loading calculations using different turbulence models : effects of reflecting and non-reflecting boundary conditions

Abstract The objective of this study is to simulate the transonic gas turbine blade-to-blade compressible fluid flow. We are interested mainly in the determination of the pressure distribution around the blade. The particular blade architecture makes these simulations more complex due to the variety of phenomena induced by this flow. Our study is based on the experiment performed by Giel and colleagues. Tests were conducted in a linear cascade at the NASA Glenn Research Center. The test article was a turbine rotor with design flow turning of 136° and an axial chord of 12.7 cm. Simulations were performed on an irregular quadratic structured grid with the FLUENT software package which solves the Navier–Stokes equations by using finite volume methods. Two-dimensional stationary numerical simulations were made under turbulent conditions allowing us to compare the characteristic flow effects of Reflecting Boundary Conditions (RBC) and Non-Reflecting Boundary Conditions (NRBC) newly implemented in FLUENT 6.0. Many simulations were made to compare different turbulence models: a one equation model (Spalart–Allmaras), several two-equation models ( k – e , RNG k – e , Realizable k – e , SST k – ω ), and a Reynolds-stress model (RSM). Also examined were the effects of the inlet turbulence intensities (0.25% and 7%), the exit Mach numbers (1.0 and 1.3) and the inlet Reynolds numbers (0.5 × 10 6 and 1 × 10 6 ). The results obtained show a good correlation with the experiment.

[1]  J. Bredberg,et al.  Turbulence Modelling for Internal Cooling of Gas-Turbine Blades , 2002 .

[2]  Juan J. Alonso,et al.  Development and validation of a massively parallel flow solver for turbomachinery flows , 2000 .

[3]  Bengt Sundén,et al.  Heat Transfer in Gas Turbines , 2001 .

[4]  Robert J. Moffat,et al.  Heat transfer with very high free stream turbulence , 1985 .

[5]  Torsten Fransson,et al.  Investigation of the Flowfield in the Transonic VKI BRITE EURAM Turbine Stage With 3D Steady and Unsteady N-S Computations , 2000 .

[6]  Luca Stolcis,et al.  An Efficient and Stable Solution Procedure of Compressible Turbulent Flow on General Unstructured Meshes Using Transport Turbulence Models , 1995 .

[7]  F. Lehthaus,et al.  The Transonic Flow Through a Plane Turbine Cascade as Measured in Four European Wind Tunnels , 1986 .

[8]  Michael B. Giles,et al.  Nonreflecting boundary conditions for Euler equation calculations , 1990 .

[9]  Michael F. Blair An Experimental Study Heat Transfer in a Large-Scale Turbine Rotor Passage , 1994 .

[10]  M. L. G. Oldfield,et al.  An Examination of the Contributions to Loss on a Transonic Turbine Blade in Cascade , 1990 .

[11]  P. W. Giel,et al.  THREE-DIMENSIONAL NAVIER-STOKES ANALYSIS AND REDESIGN OF AN IMBEDDED BELLMOUTH NOZZLE IN A TURBINE CASCADE INLET SECTION , 1996 .

[12]  F. H. Kost,et al.  Shock Boundary Layer Interaction on High Turning Transonic Turbine Cascades , 1979 .

[13]  Isaac Lopez,et al.  Transonic turbine blade cascade testing facility , 1992 .

[14]  Karen A. Thole,et al.  Enhanced Heat Transfer and Shear Stress Due to High Free-Stream Turbulence , 1995 .

[15]  Y. Mei,et al.  Implicit numerical simulation of transonic flow through turbine cascades on unstructured grids , 2005 .