Fluid Properties

The node adds the momentum and continuity equations solved by the physics interface, except for volume forces, which are added by the Volume Force feature. The node also provides an interface for defining the material properties of the fluid.

For the Turbulent Flow interfaces, the node also adds the equations for the turbulence transport equations.

For the Viscoelastic Flow interface, the node also adds the equations for the components of the elastic stress tensor.

Fluid properties, such as density and 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 choice of pressure variable depends on the system of equations being solved. For example, in a unidirectional incompressible flow problem, the pressure drop over the modeled domain is probably many orders of magnitude smaller than the atmospheric pressure, which, when included, may reduce the stability and convergence properties of the solver. In other cases, such as when the pressure is part of an expression for the gas volume or the diffusion coefficients, it may be more convenient to solve for the absolute 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

The density can either be specified by a material, or by a expression. The density in a material can depend on temperature and pressure, and these dependencies are automatically replaced by pref for weakly compressible flows and pref and Tref for incompressible flows (as specified by the setting at the physics interface level). If density variations with respect to pressure are to be included in the computations, must be set to compressible. Any dependencies in the density on quantities other than temperature and pressure must be consistent with the setting at the interface level.

For laminar flow, the (default) and options are available. Use the default option to either get the dynamic viscosity from a material, or to add a user defined expression. The option includes several inelastic non-Newtonian models for the relationship between the shear stress and shear rate.

If the option is selected, an inelastic non-Newtonian model can be selected by adding the corresponding group as a subnode to a material node.

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

Non-Newtonian fluids are encountered in everyday life and in a wide range of the industrial processes. Examples of non-Newtonian fluids include yogurt, paper pulp, and polymer suspensions. Such fluids have a nonlinear relationship between the shear stress and the share rate. The following inelastic non-Newtonian models are available: Power law, Carreau, Bingham–Papanastasiou, Herschel–Bulkley–Papanastasiou and Casson–Papanastasiou.

The following parameters are required for the :

For the , the following parameters are required:

The default values for the parameters are listed in Table 3-2.

Table 3-2: Default Values for the inelastic non-Newtonian models.
Name	UNIT	Variable	DEFAULT VALUE
Fluid consistency coefficient	Pa·s	m	0.001
Flow behavior index / Power index	Dimensionless	n	1
Flow shear rate limit	s-1		0.01
Reference shear rate	s-1		1
Zero shear rate viscosity	Pa·s	μ0	0.001
Infinite shear rate viscosity	Pa·s	μinf	0
Relaxation time	s	λ	0
Plastic viscosity	Pa·s	μp	0.001
Yield stress	N/m2	τy	0
Model parameter	s	mp	10

For the Turbulent Flow, k-ε, Turbulent Flow, k-ω, and Rotating Machinery, Turbulent Flow k-ε interfaces, an upper limit on the mixing length is required.

When the lmix,lim is set to , it is evaluated to the shortest side of the geometry bounding box. If the geometry is, for example, a complicated system of slim entities, this measure can be too high. In such cases, it is recommended that the mixing length limit is defined manually.

For the Turbulent Flow, Low Re k-ε; Turbulent flow, Algebraic yPlus; Turbulent Flow, L-VEL; Turbulent Flow, SST; Turbulent Flow, Spalart–Allmaras; and Turbulent Flow, v2-f interfaces, a Wall Distance interface is included.

When the lref is set to it is evaluated to one tenth of the shortest side of the geometry bounding box. The solution to the wall distance equation is controlled by the parameter lref. The distance to objects larger than lref is represented accurately, while objects smaller than lref are effectively diminished by appearing to be farther away than they actually are. This is a desirable feature in turbulence modeling because small objects would have too large an impact on the solution if the wall distance were measured exactly. The automatic value is usually a good choice but the value can become too high if the geometry consists of several slim entities. In such cases, it is recommended that the reference length scale is defined manually.