This example uses
several techniques and tools to create the midsurface model for a reinforced
structural component.
The solid model
The model in this example is the structural beam shown in
Figure 1.
The reinforcing ribs, different thicknesses, and asymmetrical shape of the beam
do not allow for a simple beam section representation. The complexity of the
part combined with its thin cross-sections make it a good candidate for
replacement with a midsurface model. As in the previous example, bending
performance will be improved by using a shell model for the mesh instead of
thin solid sections.
Assign the
midsurface region
Use the Assign Midsurface Region tool in the
Part module
to remove geometry from the active representation of the beam and to create a
reference representation of the original solid geometry, as shown in
Figure 2.
The reference representation is an abstract representation of the original
part. It retains the original geometry of the part, but it cannot be used in
the analysis. The reference representation appears by default in the
Part module;
you can toggle it off and on using the Show Reference
Representation tool
located with the visible object tools in the main toolbar. For more
information, see
Understanding the reference representation,
and
Assigning a midsurface region.
Create the
shell representation
You must create a shell representation of the beam that can be analyzed by
Abaqus.
Creating a shell for this part requires multiple steps and tools. There may be
several equally valid ways to produce an accurate shell representation for a
model. See
Creating the shell representation of the beam,
to use tools from the
Geometry Edit toolset
to create the new shell faces.
Assign
thicknesses
All the original solid geometry has now been replaced with shell geometry.
To complete the model, you should verify that the shells have appropriate
thickness information. Click the assign thickness and offset tool
.
Abaqus/CAE
highlights any shell faces that do not have thickness data. In this case, since
the shell faces were all created using the offset, extend, and blend tools, all
of the faces already have thickness data assigned. If there were faces without
thickness data, you would select each face and, using the Compute
thickness from opposite faces method in the Assign
thickness and Offset dialog box, pick appropriate top and bottom
faces from the reference representation to create the missing thicknesses.
To view the model with shell thicknesses, you can toggle on Render
shell thickness in the Part Display Options
dialog box (for more information, see
Visualizing shell thicknesses).
As shown in
Figure 3,
the resulting view includes the variations in thickness that were in the
original solid model.
Assign a shell
section
Use the
Property module
to create a shell section and assign it to the midsurface model. When you
create the shell section, you can enter an arbitrary value for the shell
thickness. When you subsequently assign the section to the shell, you specify
that the thickness and the shell offset are calculated from the geometry in the
Edit Section Assignment dialog box.
Abaqus/CAE
ignores the thickness value that you entered for the shell section and uses the
thicknesses assigned to the faces in the
Part module.
For more information, see
Assigning a section.
Figure 4
shows the completed midsurface model with section thicknesses after section
assignment in the
Property module.
The geometry is identical to that in
Figure 3.
Mesh the
part
Abaqus/CAE
colors the shell part pink in the
Mesh module
to indicate it can be meshed using the free meshing technique, as shown in
Figure 5.
Before seeding and meshing the part, you can apply automatic virtual
topology to remove small details that are not needed in the mesh (for more
information, see
Creating virtual topology automatically).
The default automatic virtual topology settings should remove the blended face
edges and other small details that would unnecessarily constrain the part mesh.
Note:
Automatic virtual topology may fail if neighboring faces have
inconsistent normals. If this occurs, return to the
Part module
and use the
tool in the
Geometry Edit toolset
to repair the face normals.
Apply default seeding and mesh controls, and generate the mesh on the part.
The resulting mesh is shown in
Figure 6
with the shell thickness displayed.