COMSOL 6.4 - Fluid Properties

The node contains the material properties for the liquid and the gas. It also contains settings for the slip model.

Fluid properties, such as the gas density and liquid viscosity, can be defined through user inputs, variables, or by selecting a material. For the latter option, additional inputs, for example temperature or pressure, may be required to define these properties.

By default, the model input is set to , and the temperature is controlled from Default Model Inputs under or by a locally defined Model Input. If a Heat Transfer interface is included in the component, it controls the temperature . Alternatively, the temperature field can be selected from another physics interface. All physics interfaces have their own tags (). For example, if a Heat Transfer in Fluids interface is included in the component, the option is available for T.

You can also select from the model input in order to manually prescribe T.

This input appears when a material requires the absolute pressure as a model input. The absolute pressure is used to evaluate material properties, but it also relates to the value of the calculated pressure field. There are generally two ways to calculate the pressure when describing fluid flow: either to solve for the absolute pressure or for a pressure (often denoted gauge pressure) that relates to the absolute pressure through a reference pressure.

The default pA is p+pref, where p is the dependent pressure variable from the Navier–Stokes or RANS equations, and pref is from the user input defined at the physics interface level. When pref is nonzero, the physics interface solves for a gauge pressure. If the pressure field instead is an absolute pressure field, pref should be set to 0.

The field can be edited by clicking (

) and entering the desired value in the input field.

	Model Inputs and Multiphysics Couplings in the COMSOL Multiphysics Reference Manual

Select the materials to use for the material properties of the liquid and the gas (when they are set to take their value from the material). The default is to use the for the and for the . Select another material to use that material’s properties for the liquid or gas as needed.

The default ρl (SI unit: kg/m3) uses values . For enter another value or expression.

The density in a material can depend on temperature and/or pressure and these dependencies are automatically replaced by pref and Tref, which are specified at the physics interface level.

The default μl (SI unit: Pa·s) uses values ; the value is then defined for the material selected in the section for the continuous phase. For enter another value or expression.

The dynamic viscosity describes the relationship between the shear stresses and the shear rate in a fluid. Intuitively, water and air have a low viscosity, and substances often described as thick, such as oil, have a higher viscosity.

The default ρg (SI unit: kg/m3) uses values . For enter another value or expression. Alternatively, select and enter the M (SI unit: kg/mol) of the gas.

Enter the db (SI unit: m). The default value is 10−3 m (1 mm).

Select a — (the default), , or .

Homogeneous flow assumes that the velocity of the two phases are equal; that is, uslip = 0. For enter different values or expressions for the components of the uslip (SI unit: m/s).

For it uses a model based on the assumption that the pressure forces on a bubble are balanced by the drag force:

Here db (SI unit: m) is the bubble diameter, and Cd (dimensionless) is the drag coefficient.

Select a :

to enter a different value or expression for the Cd (dimensionless). The default value is 1.