The Label is the default physics interface name.
The Name is used primarily as a scope prefix for variables defined by the physics interface. Refer to such physics interface variables in expressions using the pattern
<name>.<variable_name>. In order to distinguish between variables belonging to different physics interfaces, the
name string must be unique. Only letters, numbers, and underscores (_) are permitted in the
Name field. The first character must be a letter.
The default Name (for the first physics interface in the model) is
ht.
In 2D and 1D axisymmetric components, set the Thickness dz, which is the thickness of the domain in the out-of-plane direction. The default value is 1 m.
In 1D components, set the Cross sectional area Ac and the
Cross sectional perimeter Pc of the domain. Default values are 1 m
2 and
, respectively.
Set the Reference temperature Tref. It is used for the evaluation of the reference density
ρref when the Heat Transfer interface is coupled through
Nonisothermal Flow multiphysics coupling to a Fluid Flow interface with
Compressibility set to
Incompressible and
Specify reference temperature set to
From heat transfer interface. When
Specify reference temperature is set to
From fluid flow interface in
Nonisothermal Flow coupling node, this input is synchronized with the corresponding input in the Single Phase Flow interface. It is also used in the definition of the reference enthalpy
Href which is set to 0 J/kg at
pref (1 atm) and
Tref. The corresponding interface variable is
ht.Tref.
The Streamline diffusion check box is selected by default and should remain selected for optimal performance for heat transfer in fluids or other applications that include a convective or translational term.
Crosswind diffusion provides extra diffusion in regions with sharp gradients. The added diffusion is orthogonal to the streamlines, so streamline diffusion and crosswind diffusion can be used simultaneously. The
Crosswind diffusion check box is also selected by default.
The Isotropic diffusion check box is not selected by default. See
Heat Transfer Consistent and Inconsistent Stabilization Methods for details.
When the Thermal Damage subnode is added under
Biological Tissue, select the type of the
Shape function for damaged tissue indicators. The default is
Discontinuous Lagrange. The order is set in the
Discretization section.
To display all settings available in this section, click the Show More Options button (
) and select
Advanced Physics Options in the
Show More Options dialog box. You can choose the type and order of the shape functions used for the variables solved by the Heat Transfer interfaces.
For the temperature, you can choose not only the order of the discretization, but also the type of shape functions: Lagrange or
serendipity. For highly distorted elements, Lagrange shape functions provide better accuracy than serendipity shape functions of the same order. The serendipity shape functions will however give significant reductions of the model size for a given mesh containing hexahedral, prism, or quadrilateral elements. At first order, Lagrange and serendipity shape functions are the same.
The default shape functions used for the temperature are Quadratic Lagrange for the modeling of heat transfer without convection (solids, biological tissue, building materials), and
Linear for the modeling of heat transfer with convection (fluids, porous media, moist air). See each interface description for details.
When the Thermal Damage subnode is added under
Biological Tissue, you can choose the discretization level of the
Damage tissue indicator shape function:
Constant (the default),
Linear,
Quadratic,
Cubic,
Quartic, or
Quintic.
When the Irreversible Transformation subfeature is added under a
Solid node, you can choose the discretization level of the
Irreversible transformation indicator shape function:
Constant (the default),
Linear,
Quadratic,
Cubic,
Quartic, or
Quintic.
The Heat Transfer interfaces have the dependent variable Temperature T. The dependent variable names can be changed. Editing the name of a scalar dependent variable changes both its field name and the dependent variable name. If a new field name coincides with the name of another field of the same type, the fields share degrees of freedom and dependent variable names. A new field name must not coincide with the name of a field of another type or with a component name belonging to some other field.