COMSOL Multiphysics^® 6.4 リリースハイライト

For users of the CFD Module, COMSOL Multiphysics^® version 6.4 introduces improved transient turbulence predictions, more accurate near-wall turbulence modeling, and high-fidelity simulation of flow involving chemical reactions. Learn more about these updates below.

Scale-Adaptive Unsteady Turbulent Flow Simulations

The Turbulent Flow, SST interface now supports scale-adaptive simulation (SAS) by incorporating the von Kármán length scale into the turbulence model. This approach resolves a broader range of turbulent scales and provides highly detailed flow fields. SAS can be applied in multiphysics contexts such as fluid–structure interaction, reacting flow, nonisothermal flow, and flow-induced noise, delivering more accurate and insightful results.

Unsteady flow over a tandem cylinder configuration visualized using the Q-criterion, which represents isosurfaces of the difference between the squared vorticity magnitude and the squared strain-rate magnitude.

Elliptic Blending R-ε Turbulence Model with Improved Near-Wall Treatment

By blending expressions for the pressure–strain correlation and the turbulence viscous dissipation rate in the near-wall region with those in the bulk, the new Turbulent Flow, Elliptic Blending R-ε turbulence model provides accurate results for the Reynolds stresses close to walls without compromising the behavior elsewhere.

The settings of the Turbulent Flow, Elliptic Blending R–ε interface, showing the four available Reynolds-stress diffusion models.

LES for Reacting Flow

The new Reacting Flow feature with large eddy simulation (LES) brings unprecedented accuracy to the modeling of turbulent reacting systems. By coupling LES with the Chemistry, Chemical Species Transport, and Heat Transfer in Fluids interfaces, it is possible to capture the detailed interplay of mixing, heat transfer, and chemical reactions in gases and liquids. The approach accounts for heat of reaction, enthalpy diffusion, and mass fluxes, while residual-based LES modeling enhances predictions of heat and mass transport. With temperature-dependent fluid and chemical properties included, this functionality provides highly realistic insights into concentration, reaction rate, and temperature fields. Whether studying catalytic reactors or complex mixing processes, LES-based reacting flow models help reveal critical details that traditional turbulence models may miss.

Concentration of a product computed with the Nonisothermal Reacting Flow feature, coupling LES with species transport and heat transfer. Reactants enter through the vertical pipe and react with a second stream entering from the left in the rectangular duct.

Rotating Frame Feature as an Alternative to Rotating Domains

The new Rotating Frame feature expresses fluid flow equations relative to a stationary or time-dependent rotating frame, providing an inexpensive alternative to rotating domains without having to add equations. It also offers options for using a reduced pressure formulation or including the hydrostatic pressure approximation for the centrifugal force.

Streamlines and pressure in a centrifugal separator rotating at 9550 rpm, modeled using the new Rotating Frame feature.

Algebraic Turbulence Models for High Mach Number Flows in Rotating Machinery

The L-VEL and Algebraic yPlus turbulence models are now available for high Mach number flow in rotating machinery. These algebraic models are primarily used to generate optimal initial conditions for more advanced turbulence models, improving convergence and providing better starting points for time-dependent simulations, for example, when simulating turbomachinery.

The Algebraic yPlus turbulence model shown in the Settings window with the option to change to the L-VEL turbulence model. The Graphics window shows flow streamlines in a plane around two rotating blades, with the color representing the Mach number.

CGNS Flow Data Import and Aeroacoustics

Aeroacoustic and convected acoustic simulations have been improved with several important new features. CFD data stored in the CGNS file format can now be imported into COMSOL Multiphysics^® using the new CFD Data (CGNS) function together with the new Imported Fluid Flow interface. This combination ensures that the data is imported and mapped consistently to the computational mesh. Additionally, the new interface ensures a seamless integration with the existing Background Fluid Flow Coupling and Aeroacoustic Flow Source multiphysics couplings and mapping studies.

Sound radiation from a lined nacelle.

Periodic Condition

A new Periodic Condition feature has been added to the Darcy's Law and Richards' Equation interfaces to easily enforce periodicity for the flow between two or more boundaries. In addition, it is possible to create a pressure difference between source and destination boundaries, either by specifying the pressure jump directly or by prescribing a mass flow. The periodic condition is typically used to model representative volume elements and compute effective properties for use in homogenized porous media.

Using the new Periodic Condition feature to estimate the permeability of a porous medium consisting of a periodic array of spheres.

Pressure Jump Option for the Free and Porous Media Flow Coupling

The Free and Porous Media Flow Coupling has a new option to include a pressure jump across the free–porous boundary. This makes it possible to model, as examples, the osmotic pressure at a semipermeable membrane supported by a porous spacer material or a pressure jump due to capillary pressure in the case of multiphase flow.

Using the new Include pressure jump across free–porous boundary checkbox for the Free and Porous Media Flow Coupling to model the osmotic pressure at a thin semipermeable membrane in a desalination unit.

Marangoni Effect Driven by Concentration Gradients

For microfluidic devices and processes, the classical example of the concentration-gradient-driven Marangoni effect is now included in the Free Surface and Fluid–Fluid Interface features. This functionality enables the modeling of surface-tension-driven phenomena such as the "tears of wine".

New Tutorial Models

COMSOL Multiphysics^® version 6.4 brings the following new tutorial models to the CFD Module.

Production of Antibody–Drug Conjugates in a Stirred Tank Reactor*

A tank bioreactor with a four-blade stirrer modeled using turbulent reacting flow. The concentration of the conjugated antibody produced in the synthesis is shown using isosurfaces and contours.

Application Library Title:
stirred_tank_adc_production
Download from the Application Gallery

*Requires the Chemical Reaction Engineering Module

Reverse Osmosis Water Desalination

Concentration at the surface of the membrane in the reverse osmosis unit. This model describes a reverse-osmosis water desalination unit consisting of a spirally wound semipermeable membrane through which water is forced under high pressure. The membrane retains the salt so that fresh water is produced on the permeate side and a high-salinity brine is obtained on the concentrate side.

Application Library Title:
reverse_osmosis_desalination
Download from the Application Gallery

Axially Rotating Pipe and Swirling Jet Turbulent Flows

Jet streamlines in a swirling jet flow. The Turbulent Flow, SSG–LRR interface is used to analyze fully developed turbulent flow in an axially rotating pipe and in a swirling jet emerging from an axially rotating pipe.

Application Library Title:
rotating_pipe_swirling_jet
Download from the Application Gallery

Spanwise Rotating Turbulent Channel Flow

The Turbulent Flow, Elliptic Blending R–ε interface is used to analyze fully developed turbulent flow in a spanwise rotating channel. Due to the influence of the Coriolis force on the turbulence, the flow variable profiles become skewed at moderate rotation rates, as shown in the velocity and pressure plots.

Application Library Title:
rotating_turbulent_channel
Download from the Application Gallery