Use the Thermal Expansion subnode to add an internal thermal strain caused by changes in temperature. It is possible to model bending due to a temperature gradient in the thickness direction of the shell.
Thermal expansion can be modeled for the Linear Elastic Material,
Layered Linear Elastic Material, or
Layered Hyperelastic Material. The thermal expansion can be applied to arbitrary layers in a multilayered shell when the Composite Materials Module analysis is available.
This section is present when this node is added under Layered Linear Elastic Material or
Layered Hyperelastic Elastic Material node. In this section, select the layers in which thermal expansion needs to be modeled.
For a multilayered shell, it is often easiest to add one Thermal Expansion node per layer, if the temperature input is manual.
If the same layer is selected in two Thermal Expansion nodes being active on the same boundary, the second definition will override the previous.
The Volume reference temperature Tref is the temperature at which there are no thermal strains. As a default, the value is obtained from a
Common model input. You can also select
User defined to enter a value or expression for the temperature locally.
The Temperature T is by default obtained from a
Common model input. You can also select an existing temperature variable from a heat transfer interface (for example,
Temperature (htsh/sol1)), if any temperature variables exist, or manually enter a value or expression by selecting
User defined. This is the midsurface temperature of the shell, controlling the membrane part of the thermal expansion. For layered shells, it is the mid-layer temperature for each layer.
Select an Input type to specify how the thermal strain is entered. For the default
Secant coefficient of thermal expansion the thermal strain is given by
where the secant coefficient of thermal expansion
α can be temperature dependent.
When Input type is
Tangent coefficient of thermal expansion, the thermal strain is given by
where αt is the tangential coefficient of thermal expansion.
When Input type is
Thermal strain, enter the thermal strain
dL as function of temperature explicitly.
In all three cases, the default is to take values From material. When entering data as
User defined, select
Isotropic,
Diagonal, or
Symmetric to enter one or more components for a general coefficient of the thermal expansion tensor or the thermal strain tensor. When
Diagonal or
Symmetric input is used, the axis orientations are given by the coordinate system selection in the parent node
Enter the Temperature difference in thickness direction ΔTz. This is the temperature difference between the top and bottom surfaces.
When Temperature difference in thickness direction is selected, enter the temperature difference
ΔTz between the top surface of the topmost of the selected layers and bottom surface of the bottommost of the selected layers.
When Temperature gradient in thickness direction is selected, enter the temperature gradient
T’ in the direction from the bottom surface to the top surface.
Physics tab with Linear Elastic Material,
Layered Linear Elastic Material,
Layered Hyperelastic Material or
Section Stiffness node selected in the model tree: