2019
DOI: 10.1115/1.4045080
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Large-Eddy Simulation and RANS Analysis of the End-Wall Flow in a Linear Low-Pressure Turbine Cascade, Part I: Flow and Secondary Vorticity Fields Under Varying Inlet Condition

Abstract: In low-pressure turbines (LPTs), around 60–70% of losses are generated away from end-walls, while the remaining 30–40% is controlled by the interaction of the blade profile with the end-wall boundary layer. Experimental and numerical studies have shown how the strength and penetration of the secondary flow depends on the characteristics of the incoming end-wall boundary layer. Experimental techniques did shed light on the mechanism that controls the growth of the secondary vortices, and scale-resolving computa… Show more

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Cited by 21 publications
(10 citation statements)
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“…However, a detailed description of unsteady vane/blade interaction in lowpressure turbine stages is out of the scope of this paper. Information on this topic can be found in the selected contributions by Qiu and Simon [105], Stieger et al [106], Hodson and Howell [107], Suzen and Huang [108], Sarkar and Voke [109], Mahallati et al [110], Mahallati and Sjolander [111], Michelassi et al [112], Pichler et al [113], Marconcini et al [114], Simonassi et al [115], Lopes et al [116].…”
Section: Wake/blade Interactionmentioning
confidence: 99%
“…However, a detailed description of unsteady vane/blade interaction in lowpressure turbine stages is out of the scope of this paper. Information on this topic can be found in the selected contributions by Qiu and Simon [105], Stieger et al [106], Hodson and Howell [107], Suzen and Huang [108], Sarkar and Voke [109], Mahallati et al [110], Mahallati and Sjolander [111], Michelassi et al [112], Pichler et al [113], Marconcini et al [114], Simonassi et al [115], Lopes et al [116].…”
Section: Wake/blade Interactionmentioning
confidence: 99%
“…In Figure 9 losses are generally split into profile and endwall, while losses generated by the unsteady stator-rotor interaction are lumped together with profile losses, partly because measurements have large difficulties to accurately resolve the unsteady flow field. The split between profile and endwall losses is somewhat arbitrary, as demonstrated by (Marconcini et al, 2019), who used both LES and RANS to dissect the spanwise loss generation mechanism in a legacy low-pressure turbine. The relative importance of profile and endwall losses is of paramount importance to blend the spanwise airfoil load.…”
Section: Virtual Testing -Virtual Testing Data Base (Vt)mentioning
confidence: 99%
“…The H block, stitched to the outlet boundary of the O mesh, is characterized by uniform mesh spacing in the axial and tangential directions in order to allow optimal resolution in the wake region and a realistic prediction of the mixing phenomenon. The grid structure and density were selected on the basis of previous experience and validation for cascade flows in incompressible and subsonic conditions and low or moderate Reynolds number [4,17,25,26]. For the Reynolds numbers considered in the present work, the y + value of the grid nodes closest to the blade surface is between 1 and 2.…”
Section: Domain Discretizationmentioning
confidence: 99%