|
Product Key Customer Benefits |
|
In addition to the functionalities and benefits provided by Generative Part Structural Analysis (GPS), FEM Surface (FMS) offers: Advanced meshing of surfaces based on geometry simplification The meshing algorithms automatically simplify the geometry ensuring that small geometric features do not adversely affect the size and quality of the resulting mesh, and avoiding difficult, time-consuming clean-up of geometry. Mesh associative with design The mesh is fully associative to the surface geometry from which it was created: any changes to the geometry will automatically cause the mesh to be updated. Controls to maintain the topology are provided to generate a surface and wireframe mesh that is acceptable to the most discriminating analysts. Throughout the meshing process, the referenced geometry is never modified. The mesh works with an exact replica of the geometry as a clone, respecting all the geometric characteristics and adapting those characteristics to the needs of the mesh without impacting the original design geometry. Compatible and incompatible meshing FMS allows both compatible and incompatible meshes between parts in an assembly. The choice to generate a compatible or incompatible mesh for assembly joints depends on the customers' methodologies and the desired balance between computation speed and the accuracy of the results. Spot and seam welds can be defined based on incompatible elements, allowing the weld locations to be adjusted without impacting previously generated meshes. Alternatively, they can be based on compatible elements, when a high level of accuracy is required, such as fatigue analysis, or when a continuous mesh is required, such as for impact analysis. Rapid mesh creation FMS provides a set of tools to quickly generate finite elements directly. This includes the ability to transform mesh parts by translation and rotation, to capture exiting meshes to create new ones while respecting mesh constraints, and to position the mesh at the mid-surface of the geometry by offsetting the mesh. Mesh control Local mesh constraints can be applied quickly and easily to control the meshing of complex surface parts. These constraints can be applied directly to the geometry or to the nodes and elements. Local element sizes can also be assigned to the geometry prior to meshing. Intersections or overlap of meshes can be detected, which is especially useful in large assemblies with multiple meshes. Quality analysis and mesh editing The quality of the mesh can be visualized directly on the mesh and elements not conforming to the selected quality criteria can be grouped, making it easier to modify them. The quality criteria dynamically update as the user edits the mesh by interactively moving nodes on the geometry, editing elements (splitting, swapping, etc.), or smoothing the mesh. The auto-focus capability saves considerable time by automatically identifying the areas to be improved. Knowledge-based technology The specification parameters of FMS (including the meshing domain, node distribution, meshing capture tolerance, meshing size, etc.) are available as knowledge parameters. As a result, they can be used to produce advanced parameterized models to automate the meshing process and to ensure compliancy with corporate standards. Flexible quality analysis reports The analysis of the mesh is provided in charts and text. Users can filter information provided in the report by quality criterion or by finite element type. If the quality criterion is chosen, users can obtain the percentage of the mesh's finite elements that respect the threshold value for each criterion. When sorted by finite element, users will see the results of the quality evaluation for each finite element. This capability enhances communication between users or groups of users which is especially important when working with large part assemblies. |
| |