Article ID Journal Published Year Pages File Type
655074 International Journal of Heat and Fluid Flow 2015 16 Pages PDF
Abstract

•Ribbed duct reproduces most of the phenomena occurring in internal cooling channels of blade turbines (rotor and stator).•LES analysis of the flow in a ribbed duct was carried out aiming at detecting the influence of rotation on the turbulence.•In destabilizing conditions, rotation enhances turbulence close to the ribbed duct thus enhancing removal of fluid from the wall and improving mixing.•In stabilizing conditions, turbulence is suppressed by rotation close to the ribbed wall.

We report on large-eddy simulations (LES) of fully-developed asymmetric flow in a duct of a rectangular cross-section in which square-sectioned, equally-spaced ribs oriented perpendicular to the flow direction, were mounted on one of the walls. The configuration mimics a passage of internal cooling of a gas-turbine blade. The duct flow at a Reynolds number Re = 15,000 (based on hydraulic diameter Dh and bulk flow velocity U0) was subjected to clock-wise (stabilising) and anti-clock-wise (destabilising) orthogonal rotation at a moderate rotational number Ro = ΩDh/U0 = 0.3, where Ω is the angular velocity. The LES results reproduced well the available experimental results of Coletti et al. (2011) (in the mid-plane adjacent to the ribbed wall) and provided insight into the whole duct complementing the reference PIV measurement. We analyzed the effects of stabilising and destabilising rotation on the flow, vortical structures and turbulence statistics by comparison with the non-rotating case. The analysis includes the identification of depth of penetration of the rib-effects into the bulk flow, influence of flow three-dimensionality and the role of secondary motions, all shown to be strongly affected by the rotation and its direction.

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Physical Sciences and Engineering Chemical Engineering Fluid Flow and Transfer Processes
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