Browsers supply a great deal of view-related functionality by listing the parts of a model in a tabular and/or tree-based
format, and providing controls inside the table that allow you to alter the display of model parts.
FE geometry is topology on top of mesh, meaning CAD and mesh exist as a single entity. The purpose of FE geometry
is to add vertices, edges, surfaces, and solids on FE models which have no CAD geometry.
1D mesh that allows accurate testing of connectors, such as bolts, and similar rod-like or bar-like objects that can
be modeled as a simple line for FEA purposes.
Volume mesh or "solid meshing" uses three-dimensional elements to represent fully 3D objects, such as solid parts
or sheets of material that have enough thickness and surface variety that solid meshing makes more sense than 2D shell
meshing.
Use the Thin Solids tool to create 3D mesh on thin solids. The mesh is created by first generating a 2D mesh on a
selected set of source faces, and then extruding this mesh to generate solid hexa or wedge elements.
Acoustic Cavity meshing generates a fluid volume mesh used to calculate the acoustic modes (or standing waves) inside
the air spaces of a vehicle or similarly enclosed structural model.
Tools and workflows that are dedicated to rapidly creating new parts for specific use cases, or amending existing
parts. The current capabilities are focused on stiffening parts.
Volume mesh or "solid meshing" uses three-dimensional elements to represent fully 3D objects, such as solid parts
or sheets of material that have enough thickness and surface variety that solid meshing makes more sense than 2D shell
meshing.
Use the Thin Solids tool to create 3D mesh on thin solids. The mesh is created by first generating a 2D mesh on a
selected set of source faces, and then extruding this mesh to generate solid hexa or wedge elements.
Use the Thin Solids tool to create 3D mesh on thin solids. The mesh is created by
first generating a 2D mesh on a selected set of source faces, and then extruding this mesh
to generate solid hexa or wedge elements.
In order to create a thin solid mesh, the solid geometry must meet a certain
criteria.
The solid entity should be a sheet metal solid. The thickness should be less
than other the two dimensions (length and width).
You should be able to identify both the Source (start) faces and the Target
faces.
Source and destination faces must be connected by side (along) faces which are
almost 90 degrees to them.
From the Mesh ribbon, click the Thin
Solids tool.
Optional: On the guide bar, click to define meshing options.
Important: There are two types of mesher
provided: one is Batchmesh and the second is General 2D mesh. In the case of
Batchmesh element size, type, and so on used from Param/Criteria, it is
important to use the appropriate param/criteria settings.
Select thin solids in the following ways:
Click Find on the guide bar to automatically check for and select all thin solids.
Manually select each thin solid.
By default, the source and target surfaces for each solid are also
selected. These represent the "beginning" and the "ending" surfaces that define
the direction of the mesh mapping
Optional: Uncheck the Auto detect source and target option to
manually define any source and target hint surfaces.
Adjust the mesh size in the microdialog if needed then
click Mesh.
Tip: If you’d like to have biasing along the
mesh direction, you need to select the biasing method and set up the
appropriate parameters.
The biasing affects element growth in successive
layers, moving away from the source faces.
No Biasing
All layers are equal in thickness.
Exponential Biasing
Successive layers are exponentially thicker.
Bellcurve Biasing
Layers are progressively thicker near the center, but
thinner near the source and destination faces.