Decomposing complex thin-walled CAD models for hexahedral-dominant meshing

This paper describes an automatic method for identifying thin-sheet regions (regions with large lateral dimensions relative to the thickness) for complex thin-walled components, with a view to using this information to guide the hexahedral (hex) meshing process. This fully automated method has been...

Full description

Saved in:
Bibliographic Details
Published in:Computer aided design 2018-10, Vol.103, p.118-131
Main Authors: Sun, Liang, Tierney, Christopher M., Armstrong, Cecil G., Robinson, Trevor T.
Format: Article
Language:English
Subjects:
Automatic volume decomposition
Automation
Degrees of freedom
Finite element method
Geometric reasoning
Hexahedral-dominant meshing
Interrogation
Manipulation
Mapping
Meshing
Regions
Studies
Sweeping
Thin-sheet identification
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This paper describes an automatic method for identifying thin-sheet regions (regions with large lateral dimensions relative to the thickness) for complex thin-walled components, with a view to using this information to guide the hexahedral (hex) meshing process. This fully automated method has been implemented in a commercial CAD system (Siemens NX) and is based on the interrogation and manipulation of face pairs, which are sets of opposing faces bounding potential thin-sheet regions. Careful consideration is given to the mapping, merging and intersection of face pairs to generate topologies suitable for sweep meshing the thin-sheet regions, and for treating the junctions between adjacent thin-sheet regions. It is proposed that hex meshes be applied to thin-sheet regions by quad meshing one of the faces bounding the thin-sheet region and sweeping it through the thickness to create hex elements. Decisions on the generation and positioning of the cutting surfaces required to isolate thin-sheet regions are made by considering the likely impact on the quality of the resulting mesh. The method delivers a substantial step towards automatic hex meshing for complex thin-walled geometries. A significant reduction of the degrees of freedom (DOF) can be achieved by applying anisotropic hex elements to the identified thin-sheet regions. •A novel approach for decomposing CAD models for hex meshing is described.•The approach has been implemented within a commercial CAD system (NX).•The approach has been tested on industrial aero engine models.•Offsetting of splitting surfaces is performed to provide good quality hex.
ISSN:0010-4485
1879-2685
DOI:10.1016/j.cad.2017.11.004