Multi-Zone Shell Model for Turbulent Wall Bounded Flows
Abstract
We suggested a Multi-Zone Shell (MZS) model for wall-bounded flows accounting for the space inhomogeneity in a "piecewise approximation", in which cross-section area of the flow, S, is subdivided into "j-zones". The area of the first zone, responsible for the core of the flow, S1 S/2, and areas of the next j-zones, Sj, decrease towards the wall like Sj 2-j. In each j-zone the statistics of turbulence is assumed to be space homogeneous and is described by the set of "shell velocities" unj(t) for turbulent fluctuations of the scale 2-n. The MZS-model includes a new set of complex variables, Vj(t), j=1,2,... ∞, describing the amplitudes of the near wall coherent structures of the scale sj 2-j and responsible for the mean velocity profile. Suggested MZS-equations of motion for unj(t) and Vj(t) preserve the actual conservations laws (energy, mechanical and angular momenta), respect the existing symmetries (including Galilean and scale invariance) and account for the type of the non-linearity in the Navier-Stokes equation, dimensional reasoning, etc. The MZS-model qualitatively describes important characteristics of the wall bounded turbulence, e.g., evolution of the mean velocity profile with increasing Reynolds number, , from the laminar profile towards the universal logarithmic profile near the flat-plane boundary layer as ∞.
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