Numerical investigation of secondary flows in a high-lift low pressure turbine

The present paper is based on an experimental study of a front-loaded very high lift, low pressure turbine blade designed at the VKI. The experiments have been carried out in a low-speed wind tunnel over a wide operating range of incidence and Reynolds number. The aim of the study is to characterize the flow through the cascade in terms of losses, mean outlet flow angle, and secondary flows. At low inlet freestream turbulence intensity, a laminar separation bubble is present, and a prediction model for a separated flow mode of transition has been developed.

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Large Eddy Simulation of Secondary Flows in an Ultra-High Lift Low Pressure Turbine Cascade at Various Inlet Incidences

International Journal of Turbo and Jet Engines ◽

10.1515/tjj-2017-0020 ◽

2020 ◽

Vol 37 (2) ◽

pp. 195-207

Author(s):

Site Hu ◽

Chao Zhou ◽

Shiyi Chen

Keyword(s):

Large Eddy Simulation ◽

Engine Performance ◽

Low Pressure ◽

Secondary Flows ◽

Turbine Cascade ◽

High Lift ◽

Blade Loading ◽

Low Pressure Turbine ◽

Eddy Simulation ◽

Large Eddy

AbstractIncreasing the blade loading of a low pressure turbine blade decreases the number of blades, thus improving the aero-engine performance in terms of the weight and manufacture cost. Many studies focused on the blade-to-blade flow field of ultra-high lift low pressure turbines. The secondary flows of ultra-high lift low pressure turbines received much less attention. This paper investigates the secondary flows in an ultra-high lift low pressure turbine cascade T106C by large eddy simulation at a Reynolds number of 100,000. Both time-averaged and instantaneous flow fields of this ultra-high lift low pressure turbine are presented. To understand the effects of the inlet angle, five incidences of ‒10°, ‒5°, 0, +5° and +10° are investigated. The case at the design incidence is analyzed first. Detailed data is used to illustrate the how the fluids in boundary layers develops into secondary flows. Then, the cases with different inlet incidences are discussed. The aerodynamic performances are compared. The effect of blade loading on the vortex structures is investigated. The horseshoe vortex, passage vortex and the suction side corner vortex are very sensitive to the loading of the front part of the blade.

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Redesign of High-Lift LP-Turbine Airfoils for Low Speed Testing

Volume 7: Turbomachinery, Parts A, B, and C ◽

10.1115/gt2010-23284 ◽

2010 ◽

Author(s):

Michele Marconcini ◽

Filippo Rubechini ◽

Roberto Pacciani ◽

Andrea Arnone ◽

Francesco Bertini

Keyword(s):

Separated Flow ◽

Low Pressure ◽

High Lift ◽

Low Speed ◽

Low Pressure Turbine ◽

Wide Range ◽

Flow Configurations ◽

Artificial Neural Network Ann ◽

Lp Turbine ◽

Turbine Airfoils

Low pressure turbine airfoils of the present generation usually operate at subsonic conditions, with exit Mach numbers of about 0.6. To reduce the costs of experimental programs it can be convenient to carry out measurements in low speed tunnels in order to determine the cascades performance. Generally speaking, low speed tests are usually carried out on airfoils with modified shape, in order to compensate for the effects of compressibility. A scaling procedure for high-lift, low pressure turbine airfoils to be studied in low speed conditions is presented and discussed. The proposed procedure is based on the matching of a prescribed blade load distribution between the low speed airfoil and the actual one. Such a requirement is fulfilled via an Artificial Neural Network (ANN) methodology and a detailed parameterization of the airfoil. A RANS solver is used to guide the redesign process. The comparison between high and low speed profiles is carried out, over a wide range of Reynolds numbers, by using a novel three-equation, transition-sensitive, turbulence model. Such a model is based on the coupling of an additional transport equation for the so-called laminar kinetic energy (LKE) with the Wilcox k–ω model and it has proven to be effective for transitional, separated-flow configurations of high-lift cascade flows.

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Unsteady fluidic oscillators for active controlling boundary layer separation in an ultra-high-lift low-pressure turbine

Aerospace Science and Technology ◽

10.1016/j.ast.2021.107130 ◽

2021 ◽

pp. 107130

Author(s):

Xiao Qu ◽

Yingjie Zhang ◽

Xingen Lu ◽

Junqiang Zhu ◽

Yanfeng Zhang

Keyword(s):

Boundary Layer ◽

Boundary Layer Separation ◽

Low Pressure ◽

High Lift ◽

Layer Separation ◽

Low Pressure Turbine

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Numerical Investigation of Active Flow Control for Low-Pressure Turbine Blade Separation

42nd AIAA Aerospace Sciences Meeting and Exhibit ◽

10.2514/6.2004-750 ◽

2004 ◽

Cited By ~ 14

Author(s):

Dieter Postl ◽

Andreas Gross ◽

Hermann Fasel

Keyword(s):

Flow Control ◽

Numerical Investigation ◽

Turbine Blade ◽

Active Flow Control ◽

Low Pressure ◽

Low Pressure Turbine ◽

Active Flow

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The Influence of Mach Number on the Boundary Layer Development of High-Lift Low Pressure Turbine in Low Reynolds Number

10.1115/1.0002596v ◽

2021 ◽

Author(s):

Wenhua Duan ◽

Jian LIU ◽

Weiyang Qiao

Keyword(s):

Boundary Layer ◽

Reynolds Number ◽

Mach Number ◽

Low Reynolds Number ◽

Low Pressure ◽

High Lift ◽

Low Pressure Turbine ◽

Boundary Layer Development ◽

Low Reynolds ◽

Layer Development

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Numerical Investigation of Low-Pressure Turbine Flow Control (Invited)

38th Fluid Dynamics Conference and Exhibit ◽

10.2514/6.2008-4159 ◽

2008 ◽

Cited By ~ 5

Author(s):

Andreas Gross ◽

Wolfgang Balzer ◽

Hermann Fasel

Keyword(s):

Flow Control ◽

Numerical Investigation ◽

Low Pressure ◽

Low Pressure Turbine

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Evaluation of RANS Transition Modeling for High Lift LPT Flows at Low Reynolds Number

Volume 6B: Turbomachinery ◽

10.1115/gt2013-95069 ◽

2013 ◽

Cited By ~ 6

Author(s):

Kevin Keadle ◽

Mark McQuilling

Keyword(s):

Reynolds Number ◽

Total Pressure ◽

Current Model ◽

Pressure Coefficient ◽

Low Pressure ◽

Two Dimensional ◽

High Lift ◽

Low Pressure Turbine ◽

Low Reynolds ◽

Turbine Airfoils

High lift low pressure turbine airfoils have complex flow features that can require advanced modeling capabilities for accurate flow predictions. These features include separated flows and the transition from laminar to turbulent boundary layers. Recent applications of computational fluid dynamics based on the Reynolds-averaged Navier-Stokes formulation have included modeling for attached and separated flow transition mechanisms in the form of empirical correlations and two- or three-equation eddy viscosity models. This study uses the three-equation model of Walters and Cokljat [1] to simulate the flow around the Pack B and L2F low pressure turbine airfoils in a two-dimensional cascade arrangement at a Reynolds number of 25,000. This model includes a third equation for the development of pre-transitional laminar kinetic energy (LKE), and is an updated version of the Walters and Leylek [2] model. The aft-loaded Pack B has a nominal Zweifel loading coefficient of 1.13, and the front-loaded L2F has a nominal loading coefficient of 1.59. Results show the updated LKE model improves predicted accuracy of pressure coefficient and velocity profiles over its previous version as well as two-equation RANS models developed for separated and transitional flows. Transition onset behavior also compares favorably with experiment. However, the current model is not found suitable for wake total pressure loss predictions in two-dimensional simulations at extremely low Reynolds numbers due to the predicted coherency of suction side vortices generated in the separated shear layers which cause a local gain in wake total pressure.

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