For each entity topology-type in the model geometry, Cubit can discretize the entity using one, or several, types of basic elements, for each order entity in the geometry (vertex, curve, etc.). Cubit uses a basic element designator to describe the corresponding entity, or entities, in the mesh, and a given geometric topology entity can be discretized with one, or several, of basic elements types in Cubit. For example, a geometric surface in Cubit is discretized into a number of faces, where faces is the basic element designator for surfaces. These faces can consist of two types of basic elements, quadrilaterals or triangles. The basic element designators corresponding to each type of geometric entity, along with the types of basic elements supported in Cubit, are summarized in the table below.
For each basic element, Cubit also supports several element type definitions, whose use depends on the level of accuracy desired in the finite element analysis. For example, Cubit can write both linear (4-noded) and quadratic (8- or 9-noded) quadrilaterals. The element type definition is specified after meshing occurs, as part of the boundary condition specification. See Exodus Boundary Conditions and Element Types for a description of that process and the various element types available in Cubit.
Each mesh entity is associated with a geometric entity which "owns" it. This associativity allows the user to mesh, display, color, and attach attributes to the mesh through the geometry. For example, setting a mesh attribute on a surface affects all faces owned by that surface.
Starting with a geometric model, the mesh generation process in Cubit consists of four primary steps:
set interval size and count for individual entities or groups. The size or interval is always applied to a specific geometric entity.
set mesh schemes. Cubit supports numerous meshing schemes for meshing solid model entities.
Generate the mesh for the model . Use the mesh command to generate the mesh on a specified geometric entity.
Inspect mesh for quality and suitability for targeted analysis.Cubit provides various quality metrics for the user to verify the suitability of the mesh for analysis. The quality command can be used to check the elements generated on a specific geometric entity.
There are also mechanisms for improving mesh quality locally using smoothing and local mesh topology changes and refinement. For complex models, this process can be iterative, repeating all of the steps above.
The mesh for any given geometry is usually generated hierarchically. For example, if the mesh command is issued on a volume, first its vertices are meshed with nodes, then curves are meshed with edges, then surfaces are meshed with faces, and finally the volume is meshed with hexes. Vertex meshing is of course trivial and thus the user is given little control over this process. However, curve, surface, and volume meshing can be directly controlled by the user. Each of the steps listed are described in detail in the following sections.