Creating continuum shell composite layups

This section describes how to create a continuum shell composite layup.

Abaqus models a continuum shell composite layup using continuum shell elements that fully discretize each ply but have a kinematic behavior that is based on shell theory. Continuum shell composite layups are composed of plies made of different materials in different orientations. A layup can contain a different number of plies in different regions. For more information, see Composite layups.

Continuum shell composite layups are expected to have a single element through their thickness, and that single element contains multiple plies that are defined in the ply table. If the region to which you assign your continuum shell composite layup contains multiple elements, each element will contain the plies defined in the ply table, and the analysis results will not be as expected.

You choose the stacking direction of the continuum shell elements in the layup, which allows Abaqus to model the through-thickness response more accurately. In addition, continuum shell composite layups take into account double-sided contact and thickness changes, which provides more accurate contact modeling than conventional shell composite layups. For more information, see Shell Section Behavior.

When you create continuum shell composite layups, you must choose a section integration method. You can choose to provide the section property data before the analysis (a pre-integrated continuum shell composite layup) or to have Abaqus calculate (integrate) the cross-sectional behavior from integration points during the analysis.

Continuum shell composite layups integrated during the analysis allow the cross-sectional behavior to be calculated by numerical integration through the continuum shell thickness, thus providing complete generality in material modeling. Any number of material points can be defined through the thickness, and the material response can vary from point to point. You generally use continuum shell elements integrated during analysis when the composite layup includes nonlinear material behavior. You must use continuum shell elements integrated during analysis to model heat transfer. For more information, see Using a Shell Section Integrated during the Analysis to Define the Section Behavior.

Linear moment-bending and force-membrane strain relationships can be defined using pre-integrated continuum shell composite layups. In this case all calculations are done in terms of section forces and moments. The section properties are specified by an elastic material; optionally, you can also apply an idealization based on assumptions about the expected behavior or makeup of the layup. You should use pre-integrated continuum shell composite layups if the response of the layup is linear elastic, and its behavior is not dependent on changes in temperature or predefined field variables. For more information, see Using a General Shell Section to Define the Section Behavior.

After you have created a continuum shell composite layup, you can use a ply stack plot to view a graphical representation of a core sample through a region of the layup. For more information, see Viewing a ply stack plot.


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