Run Adaptive Wrapping
Use the Wrap: Adaptive tool to create traditional tight or loose wrap from selected parts.
If local and proximity controls are defined, they will override the default settings defined in this tool.
View new features for HyperMesh CFD 2023.
Learn the basics and discover the workspace.
Discover HyperMesh CFD functionality with interactive tutorials and community resources.
Solution-centric workflows allow you to traverse through modeling environments using a dedicated UI layer.
Create, open, import, and save models.
Use the Convert tool to convert entire models between data types.
Manage CAD, FE, and 2D parametric sketch geometry.
Create and edit 2D parametric sketch geometry.
Create, edit, and cleanup geometry.
Work with discrete geometry like FE Geometry and floating elements.
Use the Cap tools to close openings and gaps between parts/surfaces.
Use the Connect tools to trim, fuse, and stitch your discrete geometry.
In CFD modeling, input parts can have topology issues, like free surfaces and self-intersections, and part assembly issues, such as parts with very close proximity and intersecting parts. Manually connecting these parts can be time consuming and require expertise in certain tools. The Wrap tool can generate a watertight manifold model from dirty input with considerably less manual work.
Use the Wrap: Local tool to define local wrap size settings on selected surfaces.
Use the Wrap: Leak Check tool to detect leaks in your model before wrapping.
Use the Wrap: Proximity tool to define proximity controls for the wrapping process.
Use the Wrap: CAD Wrap tool to create wrap from selected parts. CAD wrapping keeps the original geometry shape as it is and just fixes areas of issue.
Use the Wrap: Adaptive tool to create traditional tight or loose wrap from selected parts.
Use the Remesh to create new surface mesh on converted geometry.
Use the Smooth tool to optimize the mesh quality of parts or surfaces.
Use the Refine tool to split elements and optimize the mesh quality of parts and surfaces.
Use the Decimate tool to coarsen mesh based on a defined element size.
Use the Derived Region tool to create enclosed and offset regions around a selection – which can be used to define volumetric refinement levels – or create projected regions in a given direction.
Convert elements that aren't associated with geometry into FE geometry, or update existing FE geometry.
Use the Organize tool to move or copy entities into their proper destinations.
Use the Repair tool to find, review, and fix issues in the mesh.
The Auto Fix tool is useful for cleaning up non-manifold edges, free edges, intersections, high aspect ratio elements, and proximity distance.
Use the Edit tools to manually improve the quality of surface mesh elements and nodes.
Use the Normals tool to fix element normals using different methods.
Create, organize and manage parts and subsystems.
Generate surface/volume mesh by defining mesh controls, or interactively create and edit 2D surface mesh.
Prepare your model and run the simulation.
Post-process the simulation results by creating visualizations and measurements.
Automate simulation processes with templates and utility scripts.
Once the baseline model is prepared, you can define morph volumes, morph geometry, create design shapes and run DOE studies. These tool work for both AcuSolve and ultraFluidX-based workflows.
More resources for AcuSolve and ultraFluidX solvers.
Manage CAD, FE, and 2D parametric sketch geometry.
Work with discrete geometry like FE Geometry and floating elements.
In CFD modeling, input parts can have topology issues, like free surfaces and self-intersections, and part assembly issues, such as parts with very close proximity and intersecting parts. Manually connecting these parts can be time consuming and require expertise in certain tools. The Wrap tool can generate a watertight manifold model from dirty input with considerably less manual work.
Use the Wrap: Adaptive tool to create traditional tight or loose wrap from selected parts.
Use the Wrap: Adaptive tool to create traditional tight or loose wrap from selected parts.
If local and proximity controls are defined, they will override the default settings defined in this tool.
The accuracy of the output is dictated by the element size. The larger the element size the less detail, the smaller the element size the more detail. This algorithm works differently than the loose wrap in that it projects the nodes of the wrap to the original mesh, hence it is able to more accurately capture features.
A smaller element size generates a wrap mesh that more closely approximates the original representation and adheres to more features; a larger element size produces a more basic mesh which ignores more features. The loose wrap does not project the nodes of the wrap mesh to the original mesh, and typically the wrap mesh will have an offset from the original mesh. Again, the offset is dependent on the target element size used.
© 2023 Altair Engineering, Inc. All Rights Reserved.
Intellectual Property Rights Notice | Technical Support | Cookie Consent