Fluid

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k (SI unit: W/(m·K)) is the fluid thermal conductivity (a scalar or a tensor if the thermal conductivity is anisotropic).

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u (SI unit: m/s) is the fluid velocity field, either an analytic expression or a velocity field from a Fluid Flow interface.

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Q (SI unit: W/m3) is the heat source (or sink). Add one or several heat sources as separate physics features. See the Heat Source node for an example.

For a steady-state problem the temperature does not change with time and the first term disappears.

This section has fields and values that are inputs to expressions that define material properties. If such user-defined property groups are added, the model inputs appear here. For all model inputs, you can select to use a model input defined under .

This section is available when temperature-dependent material properties are used. By default the temperature of the parent interface is used and the section is not editable. To edit the field, click (

). The available options are (default), , and all temperature variables from the physics interfaces included in the model. These physics interfaces have their own tags (the ). For example, if a interface is included in the model, the option is available.

The absolute pressure is used in some predefined quantities that include the enthalpy (the energy flux, for example).

The default pA is taken from . It corresponds to the minput.pA variable, set to 1 atm by default. To edit it, click the button (

), and in the node under , set a value for the in the section. When additional physics interfaces are added to the model, the absolute pressure variables defined by these physics interfaces can also be selected from the list. For example, if a interface is added you can select from the list. The last option is .

From the c (SI unit: mol/m3 or kg/m3) list, select an existing concentration variable from another physics interface, if any concentration variables exist, or select to enter a value or expression for the concentration. This section can be edited anytime a material property is concentration dependent; for example, when the is set to with set to .

The defaultu is . For enter values or expressions for the components based on space dimensions. You can also select an existing velocity field in the component (for example, from a interface).

The thermal conductivity k describes the relationship between the heat flux vector q and the temperature gradient ∇T in q = −k∇T, which is Fourier’s law of heat conduction. Enter this quantity as power per length and temperature.

The default k is taken . For select , , , or based on the characteristics of the thermal conductivity, and enter another value or expression. For enter a scalar which will be used to define a diagonal tensor. For the other options, enter values or expressions into the editable fields of the tensor.

This section defines the thermodynamics properties of the fluid.

The heat capacity at constant pressure Cp describes the amount of heat energy required to produce a unit temperature change in a unit mass.

The ratio of specific heats γ is the ratio between the heat capacity at constant pressure, Cp, and the heat capacity at constant volume, Cv. When using the ideal gas law to describe a fluid, specifying γ is sufficient to evaluate Cp. For common diatomic gases such as air, γ = 1.4 is the standard value. Most liquids have γ = 1.1 while water has γ = 1.0. γ is used in the streamline stabilization and in the variables for heat fluxes and total energy fluxes. It is also used if the ideal gas law is applied.

When the density is not taken from a or a coupling node, you should select a option for the specification of the material properties. The available options are , , and (default). After selecting a from the list, further settings display underneath. See Nonisothermal Mixture Model in the CFD Module User’s Guide for details.

This option automatically detects whether the material applied on each domain selection is an ideal gas or not, and uses the relevant properties from the node for either case.

By using the following definition of the density for an ideal gas:

with Rs the specific gas constant, pA the absolute pressure, and T the temperature, the evaluation of the isobaric compressibility coefficient, αp, and of the isothermal Joule-Thomson coefficient, μJT, is simplified. This may improve efficiency, when computing pressure work in compressible nonisothermal flows for example, or when modeling inflow conditions.

	The Air material, from the Built-in materials database, has an Ideal gas property group, and is thus detected as an ideal gas by the Fluid node. The Liquids and Gases Materials Library, available with some COMSOL products, also provides such materials.

The , the , and the are automatically taken and no further setting is required. For the specification of user defined material properties, the Ideal Gas or Gas/Liquid options should be used instead.

This option uses the ideal gas law to describe the fluid. Only two properties are needed to define the thermodynamics of the fluid:

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The gas constant, with two options for the : Rs or Mn. If is selected the software uses the universal gas constant R = 8.314 J/(mol·K), which is a built-in physical constant, to calculate the specific gas constant.

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Either the Cp or γ by selecting the option from the γ list. For an ideal gas, it is sufficient to specify either Cp or the ratio of specific heats, γ, as these properties are interdependent.

This option specifies the , the , and the for a general gas or liquid.

Physics Tab with interface as , , or selected: