The Basic Equations for the Large Eddy Simulation of Turbulent Flows in Complex Geometry

## Abstract In order to reveal unknown characteristics of complex turbulent passive scalar fields, large eddy simulations in forced convection regimes have been performed under several strain conditions, including flow impingement and flow separation. By using the simulation results, relations betw

be avoided if aliasing errors are small compared to truncation errors. Aliased and dealiased numerical simulations of a turbulent channel flow are performed using spectral and finite difference methods. ## The problem of aliasing errors in spectral simulations Analytical and numerical studies sh

In turbulent flow, the normal procedure has been to seek means u of the fluid velocity u rather than the velocity itself. If these means are defined by local spacial averaging with an averaging radius of ␦ the approach is known as large eddy Ž . simulation, and u denotes the eddies of size 0 ␦ and l

## Abstract Three‐dimensional (3‐D), time‐dependent Eulerian‐Lagrangian simulations of the turbulent gas‐solid flow in cyclone separators have been performed. The gas flow is simulated with the lattice‐Boltzmann method. It solves the filtered Navier‐Stokes equations, where the Smagorinsky subgrid‐s