Fracture (Heat Transfer Interface) and Porous Medium (Heat Transfer in Shells Interface)

Use this node to allow heat transfer in fractures on layered materials inside domains. It can also be used to allow heat transfer in films.

Boundary Selection

When the node is added manually in the Heat Transfer in Fractures interface, and for the node, select the check box to make the node applicable only if a layered material is defined on the boundary. If a layered material ( with specified, , , or ) is available, its name is then displayed beside the boundary index (for example, slmat1), otherwise the boundary is marked as not applicable.

When is the default node of the Heat Transfer in Fractures interface, it is applied on all boundaries where the Heat Transfer in Fractures interface is applied, and neither the boundary selection nor the check box are editable.

Note that when the is in the section of the parent interface or node, the check box is not editable.

Shell Properties

Porous Medium (Heat Transfer in Fractures Interface)

Different settings are available, depending on the settings in the Shell Properties section of the parent interface, and whether is the default node or was added manually:

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When the is in the section of the parent interface, the same layered material is used in the node, but you can limit the contribution to individually selected layers by clearing the check box. For a given or , you get access to a list of check boxes for the selection of the individual layers. In this case, both the and options are available in the section.

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When the is in the section of the parent interface, the is taken in the node. This option is not editable when is the default node, but you can change to and override the interface setting with a specific value or expression for Lth when the node was added manually. In this case, only the option is available in the section.

Fracture (Heat Transfer Interface)

Two options are available for the :

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When the is , the Extra Dimension tool is used to solve the equations through the thickness of a layered material. It is possible to consider several layers with different thermal properties varying through the thickness. This makes the and options available for in the section. You can limit the contribution to individually selected layers by clearing the check box. For a given or , you get access to a list of check boxes for the selection of the individual layers.

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Alternatively, set to , and seta user defined value or expression for the Lth. This option should be used for thermally thin layers, for which no through-thickness temperature variation is expected in the layered material. This removes the option from the list in the section.

You can visualize the selected layered materials and layers in each layered material by clicking the and buttons.

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For a general description of layer and interface selections, see Layer and Interface Selection Tools.

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You can provide material parameters with a through-thickness variation by using expressions containing the extra dimension coordinate as described in Using the Extra Dimension Coordinates.


	The desired selection for the node may correspond to boundaries with different layered materials. See Layered Material, Layered Material Link, Layered Material Stack, Layered Material Link (Subnode), and Single-Layer Materials in the COMSOL Multiphysics Reference Manual.

Model Input

This section contains fields and values that are inputs for expressions defining material properties. If such user-defined property groups are added, the model inputs appear here.

Volume Reference Temperature

This section is available when a temperature-dependent density defined in a material is used. On the material frame, the density is evaluated in relation to a reference temperature in order to ensure conservation of the mass in the presence of temperature variations. By default the is used. This corresponds to the variable minput.Tempref, which is set to 293.15 K by default. To edit it, click the button (

), and in the node under , set a value for the in the section.

The other options are and all temperature variables from the physics interfaces included in the model.


	This model input does not override the Reference temperature Tref set in the Physical Model section of the physics interface, which is used to evaluate the reference enthalpy, and a reference density for incompressible nonisothermal flows.

Temperature

This section is available when material properties are temperature-dependent. 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), (the minput.T variable, set to 293.15 K by default) and all temperature variables from the physics interfaces included in the model. To edit the minput.T variable, click the button (

), and in the node under , set a value for the in the section.

Absolute Pressure

Absolute pressure is used in certain predefined quantities that include enthalpy (the energy flux, for example).

It is also used if the ideal gas law is applied. See Thermodynamics, Fluid.

The default pA is . 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 option 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.

Layer Model

The available options for are and . The former is a lumped model that accounts only for tangential temperature gradients (along the fracture), whereas the latter accounts also for the normal gradients of temperature (through the fracture’s thickness).


	Within a layered material selection, a single Layer type should be used. If two layer types are needed for the same layered material, the original material should be duplicated so that one layered material is defined for each layer type. A Shell Continuity (Heat Transfer Interface) and Continuity (Heat Transfer in Shells Interface) node may be added between the two layered materials.

Fluid Material

By default, the is used.

Heat Conduction, Fluid

The settings are the same as for Thin Film (Heat Transfer Interface) and Fluid (Heat Transfer in Shells Interface).

Heat Conduction, Fluid

The settings are the same as for Thin Film (Heat Transfer Interface) and Fluid (Heat Transfer in Shells Interface).

Thermodynamics, Fluid

The settings are the same as for Thin Film (Heat Transfer Interface) and Fluid (Heat Transfer in Shells Interface).

Porous Material

By default, the is used. The θp should be specified. The default is 0.

Heat Conduction, porous matrix

The default kp is taken . For select , , , or based on the characteristics of the thermal conductivity, and enter another value or expression. Select an : (default) or .

Thermodynamics, porous matrix

The default ρp and Cp, p are taken . See Material Density in Features Defined in the Material Frame if a temperature-dependent density should be set. For enter other values or expressions.


	In the Porous Medium node, only in-plane anisotropy is supported for the thermal conductivity of the fracture material.


	Fracture in Theory for Heat Transfer in Thin Structures

Location in User Interface

Context Menus

Ribbon

Physics tab with interface as selected:

Physics tab with interface as , or selected: