Numerical study of plane Couette flow: turbulence statistics and the structure of pressure–strain correlations

The paper presents the results of direct numerical simulation of turbulent plane Couette flow. The calculations were performed for Reynolds numbers Re = ( is the height of the channel, ± /2 is the motion velocities of the lower and upper walls, respectively, is the kinematic viscosity) from 5200 (wh...

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Bibliographic Details
Published inRussian journal of numerical analysis and mathematical modelling Vol. 34; no. 2; pp. 119 - 132
Main Authors Mortikov, Evgeny V., Glazunov, Andrey V., Lykosov, Vasily N.
Format Journal Article
LanguageEnglish
Published Berlin De Gruyter 01.04.2019
Walter de Gruyter GmbH
Subjects
76F10
76F65
Computational fluid dynamics
Computer simulation
Couette flow
Direct numerical simulation
Kinetic energy
Mathematical analysis
Mathematical models
Momentum
Strain rate
Tensors
Transport
Turbulence
Turbulent flow
Variations
Velocity distribution
Velocity gradient
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Summary:The paper presents the results of direct numerical simulation of turbulent plane Couette flow. The calculations were performed for Reynolds numbers Re = ( is the height of the channel, ± /2 is the motion velocities of the lower and upper walls, respectively, is the kinematic viscosity) from 5200 (where viscous effects significantly affect the flow structure) to 80000 (where a logarithmic layer is clearly observed). Estimates of terms of the equation for the balance of turbulent Reynolds stresses are obtained, which indicate the importance of the kinetic energy transport by velocity fluctuations. The vertical transport of the turbulent momentum flux is less important and partly compensated by the transport of pressure fluctuations. It is shown that in the logarithmic layer the normal components of the ‘pressure–strain rate’ correlation tensor are described in the framework of the ‘isotropization of production’ model, and in the central part of the channel they are described by the linear Rotta model [ ]. The additive model considering both the interaction of the velocity field fluctuation and the influence of the mean velocity gradient is a good approximation only for the off-diagonal component of the tensor entering the balance equation for the turbulent momentum flux.
ISSN:0927-6467
1569-3988
DOI:10.1515/rnam-2019-0010