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JOURNALS // Computer Research and Modeling // Archive

Computer Research and Modeling, 2022 Volume 14, Issue 4, Pages 741–753 (Mi crm995)

This article is cited in 1 paper

SPECIAL ISSUE

Numerical modeling of the Kolmogorov flow in a viscous media, forced by the static force periodic in space

V. V. Denisenkoa, A. N. Doludenkob, S. V. Fortovaa, I. V. Kolokolovc, V. V. Lebedevc

a Institute for Computer Aided Design of the RAS, 19/18 2-nd Brestskaya st., Moscow, 123056, Russian Federation
b Joint Institute for High Temperatures of the RAS, 13/2 Izhorskaya st., Moscow 125412, Russia
c Landau Institute for Theoretical Physics of the RAS, 1A Akademika Semenova av., Chernogolovka, Moscow region, 142432, Russia

Abstract: The main feature of a two-dimensional turbulent flow, constantly excited by an external force, is the appearance of an inverse energy cascade. Due to nonlinear effects, the spatial scale of the vortices created by the external force increases until the growth is stopped by the size of the cell. In the latter case, energy is accumulated at these dimensions. Under certain conditions, accumulation leads to the appearance of a system of coherent vortices. The observed vortices are of the order of the box size and, on average, are isotropic. Numerical simulation is an effective way to study such the processes. Of particular interest is the problem of studying the viscous fluid turbulence in a square cell under excitation by short-wave and long-wave static external forces. Numerical modeling was carried out with a weakly compressible fluid in a two-dimensional square cell with zero boundary conditions. The work shows how the flow characteristics are influenced by the spatial frequency of the external force and the magnitude of the viscosity of the fluid itself. An increase in the spatial frequency of the external force leads to stabilization and laminarization of the flow. At the same time, with an increased spatial frequency of the external force, a decrease in viscosity leads to the resumption of the mechanism of energy transfer along the inverse cascade due to a shift in the energy dissipation region to a region of smaller scales compared to the pump scale.

Keywords: Kolmogorov flow, vortex, turbulence.

UDC: 532.5.032, 532.517.3

Received: 13.12.2021
Accepted: 01.03.2022

Language: English

DOI: 10.20537/2076-7633-2022-14-4-741-753



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