Turbulence anisotropy analysis at the middle section of a highly loaded 3D linear turbine cascade using Large Eddy Simulation

afshar, Nima Fard; Kožulović, Dragan; Henninger, Stefan; Deutsch, Johannes; Bechlars, Patrick

doi:10.33737/jgpps/159784

Cited by 5 publications

(5 citation statements)

References 40 publications

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“…Following the overview of the secondary flow system, we now turn to a more detailed analysis of the turbulence close to the suction side of the blade as potential root cause for the discrepancies in the wake losses discussed earlier. For the midspan region, this has already been discussed extensively by Afshar et al (2023) and our results are consistent with their findings. We, therefore, focus on the end wall region.…”

Section: Secondary Flow Systemsupporting

confidence: 93%

“…Close to the blade, in the statistically two-dimensional part of the flow, the transitional separated shear layer can be observed in the Q-contour (Ⓑ) featuring turbulence distinctively close to the one-component limit, cf. Afshar et al (2023). After transition to turbulence, this area can be found significantly closer to isotropic (3C) turbulence (Ⓒ).…”

Section: Secondary Flow Systemmentioning

confidence: 87%

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Large Eddy Simulation of a Low Pressure Turbine Cascade with Turbulent End Wall Boundary Layers

Morsbach,

Bergmann,

Tosun

et al. 2023

ERCOFTAC Series

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We present results of implicit large eddy simulation (LES) and different Reynolds-averaged Navier-Stokes (RANS) models of the MTU 161 low pressure turbine at an exit Reynolds number of 90 000 and exit Mach number of 0.6. The LES results are based on a high-order discontinuous Galerkin method and the RANS is computed using a classical finite-volume approach. The paper discusses the steps taken to create realistic inflow boundary conditions in terms of end wall boundary layer thickness and freestream turbulence intensity. This is achieved by tailoring the input distribution of total pressure and temperature, Reynolds stresses and turbulence length scale to a Fourier series based synthetic turbulence generator. With this procedure, excellent agreement with the experiment can be achieved in terms of blade loading at midspan and wake total pressure losses at midspan and over the channel height. Based on the validated setup, we focus on the discussion of secondary flow structures emerging due to the interaction of the incoming boundary layer and the turbine blade and compare the LES to two commonly used RANS models. Since we are able to create consistent setups for both LES and RANS, all discrepancies can be directly attributed to physical modelling problems. We show that both a linear eddy viscosity model and a differential Reynolds stress model coupled with a state-of-the-art correlation-based transition model fail, in this case, to predict the separation induced transition process around midspan. Moreover, their prediction of secondary flow losses leaves room for improvement as shown by a detailed discussion of turbulence kinetic energy and anisotropy fields.

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Section: Secondary Flow Systemsupporting

confidence: 93%

Section: Secondary Flow Systemmentioning

confidence: 87%

Large Eddy Simulation of a Low Pressure Turbine Cascade with Turbulent End Wall Boundary Layers

Morsbach,

Bergmann,

Tosun

et al. 2023

ERCOFTAC Series

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“…Afterwards, the distribution of isentropic Mach number M is over the critical region of the blade is shown in Figure 8, along with the total pressure loss profile in the wake of the blade. In both cases, a good agreement with experimental data is obtained, while RANS simulations typically suffer to predict the M is distribution and total pressure loss in the wake, as illustrated by Fard Afshar et al (2023). Not shown here, the outflow angle is also well predicted by these DNS simulations compared to the experiments.…”

Section: Airfoil Cascade Simulationsupporting

confidence: 68%

Direct numerical simulations of airfoil cascades for the improvement of turbulence models through database generation

Rasquin,

Thomas,

Bechlars

et al. 2023

European Conference on Turbomachinery Fluid Dynamics and Thermodynamics

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Direct Numerical Simulations (DNS) of a typical LPT airfoil cascade at a Reynolds number of 120,000 have been carried out with the high-order compressible flow solver Argo developed at Cenaero. The objective of these simulations is to generate highly-refined comprehensive databases in a systematic and reproducible manner, which allows the reconstruction of all terms of the Favre-averaged Navier-Stokes, Reynolds stress, and dissipation equations. These databases can then be exploited to improve the prediction of lower-fidelity approaches such as RANS turbulence models, which allow for an extensive exploration of the design space thanks to their low computational cost. This paper presents a systematic approach for generating such databases. Particular points of interest are the reproducibility of the boundary conditions (e.g. , injection of freestream turbulence) and the completeness of the databases. Comparison between the numerical and experimental results will also be presented as a validation of the numerical setup.

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“…in the wind tunnel [18]. Both mid-span blade loading and the total 93 pressure losses in a plane behind the blade will be shown to be in 94 excellent agreement with the available experimental data [19] and 95 recently published numerical data [15,20]. We assess the mesh in- Since the numerical method used in this paper itself has been 116 extensively described in part 1, we restrain ourselves to the descrip-117 tion of the numerical setup of the MTU T161 (see also [18]).…”

Section: Introductionsupporting

confidence: 60%

“…The midspan blade loading is shown in Fig. 4 against experimental [19] and numerical [14,15,20] available on sampling error. In the following, we will show 68% 345 confidence intervals for all our LES runs [22].…”

Section: Verificationmentioning

confidence: 99%

A Numerical Test Rig for Turbomachinery Flows Based on Large Eddy Simulations With a High-Order Discontinuous Galerkin Scheme—Part III: Secondary Flow Effects

Morsbach,

Bergmann,

Tosun

et al. 2023

Journal of Turbomachinery

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In this final paper of a three-part series, we apply the numerical test rig based on a high-order Discontinuous Galerkin scheme to the MTU T161 low pressure turbine with diverging end walls at off-design Reynolds number of 90,000, Mach number of 0.6 and inflow angle of 41'. The inflow end wall boundary layers are prescribed in accordance with the experiment. Validation of the setup is shown against recent numerical references and the corresponding experimental data. Additionally, we propose and conduct a purely numerical experiment with upstream bar wake generators at a Strouhal number of 1.25, which is well above what was possible in the experiment. We discuss the flow physics at midspan and in the end wall region and highlight the influence of the wakes from the upstream row on the complex secondary flow system using instantaneous flow visualization, phase averages and modal decomposition techniques.

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Turbulence anisotropy analysis at the middle section of a highly loaded 3D linear turbine cascade using Large Eddy Simulation

Cited by 5 publications

References 40 publications

Large Eddy Simulation of a Low Pressure Turbine Cascade with Turbulent End Wall Boundary Layers

Large Eddy Simulation of a Low Pressure Turbine Cascade with Turbulent End Wall Boundary Layers

Direct numerical simulations of airfoil cascades for the improvement of turbulence models through database generation

A Numerical Test Rig for Turbomachinery Flows Based on Large Eddy Simulations With a High-Order Discontinuous Galerkin Scheme—Part III: Secondary Flow Effects

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