COMSOL 6.4 - The Rotating Machinery, Reacting Flow, Turbulent Flow, k-ω Interface

The -ω version of the interface (

), found under the > branch (

) when adding a physics interface, is used to simulate the turbulent flow and mixing of chemical species in equipment containing one or more rotating parts. Reactions between the participating species can also be studied.

The physics interface combines the functionality of the and the interfaces. The multiphysics coupling, which is added automatically, couples fluid flow and mass transport. The averaged velocity and pressure fields are solved together with an arbitrary number of averaged mass fractions. The momentum balance is governed by the averaged Navier–Stokes equations, and the total mass conservation is governed by the continuity equation. The fluid-flow turbulence is modeled using the Wilcox revised k-ω model with realizability constraints. The k-ω model is a so-called low-Reynolds number model, which means that it can resolve the velocity, pressure, and mass fractions all the way down to the wall. For the chemical species, the governing transport equations include convection, diffusion and, optionally, migration in an electric field. Turbulent reactions are modeled using the eddy dissipation model.

There are two study types available for this physics interface. For the study type the rotation is achieved by moving mesh functionality, also known as sliding mesh. For the study type the rotating parts are kept frozen in position, and the rotation is accounted for by the inclusion of centrifugal and Coriolis forces.

When adding the multiphysics interface, the ω and interfaces are added to the Model Builder. A interface with a node is added automatically in the under the node. In addition, the node is added, which automatically includes the multiphysics coupling feature . The following default nodes are also added in the under ω — , , and ; and under — , , and .

See The Rotating Machinery, Reacting Flow, Laminar Flow Interface for details.