Automatic surface repairing, defeaturing and meshing algorithms based on an extended B-rep

Automatic surface repairing, defeaturing and meshing algorithms based on an extended B-rep

•A new data structure that combines the continuous and discrete surface representations is proposed.•A sequence of repairing, defeaturing and meshing algorithms that can exploit the strengths of both representations is developed.•The repairing algorithm is defined on the discrete model but can outpu...

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Bibliographic Details
Published in:Advances in engineering software (1992) Vol. 86; pp. 55 - 69
Main Authors: Chen, Jianjun, Cao, Bingwan, Zheng, Yao, Xie, Lijun, Li, Chenfeng, Xiao, Zhoufang
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-08-2015
Subjects:
Algorithms
Boundaries
Boundary representation
Defeaturing
Face clustering
Finite element method
Maintenance
Mathematical models
Mesh generation
Meshing
Repairing
Representations
Virtual topology
Face clustering
Virtual topology
Repairing
Defeaturing
Boundary representation
Mesh generation
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Summary:•A new data structure that combines the continuous and discrete surface representations is proposed.•A sequence of repairing, defeaturing and meshing algorithms that can exploit the strengths of both representations is developed.•The repairing algorithm is defined on the discrete model but can output a correct B-rep.•The output mesh is loyal to the input continuous model and therefore more geometrically accurate. This paper presents an extended surface boundary representation (B-rep), where each topology entity can have dual geometric representations to accommodate various defects (e.g., gaps and overlaps) commonly present in CAD models. Keeping a uniform B-rep and the unsuppressed geometry data enables the use of various existing repairing, defeaturing and meshing algorithms to process CAD models with small gaps and overlaps on surface boundaries. The continuous geometry of the input model remains untouched in the repairing, defeaturing and meshing process, and the output mesh is loyal to this geometry. Such feature is often desirable in numerical simulations that require meshes with high geometry fidelity.
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ISSN:0965-9978
DOI:10.1016/j.advengsoft.2015.04.004