Mill and fold: Shape simplification for fabrication

Mill and fold: Shape simplification for fabrication

•Simplification of Shapes for Fabrication with sheets of rigid materials.•Milling flat sheets of material to produce foldable models.•Smart unfolding for taking into account the manufacturing properties. [Display omitted] We introduce a pipeline for simplifying digital 3D shapes and fabricate them u...

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Bibliographic Details
Published in:Computers & graphics Vol. 80; pp. 17 - 28
Main Authors: Muntoni, Alessandro, Nuvoli, Stefano, Scalas, Andreas, Tola, Alessandro, Malomo, Luigi, Scateni, Riccardo
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-05-2019
Elsevier Science Ltd
Subjects:
3D meshes
Algorithms
Assembly
Dihedral angle
Fabrication
Finite element method
Furrows
Geometry processing
Marching cubes algorithms
Mesh simplification
Milling
Milling (machining)
Milling machines
Numerical controls
Polygons
Shape
Simplification
Triangles
Fabrication
Geometry processing
Mesh simplification
3D meshes
Milling
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Summary:•Simplification of Shapes for Fabrication with sheets of rigid materials.•Milling flat sheets of material to produce foldable models.•Smart unfolding for taking into account the manufacturing properties. [Display omitted] We introduce a pipeline for simplifying digital 3D shapes and fabricate them using 2D polygonal flat parts. Our method generates shapes that, once unfolded, can be fabricated with CNC milling machines using special tools called V-Grooves. These tools create V-shaped furrows at given angles depending on the shape of the used tool. Milling the edges of each flat facet simplifies the manual assembly, which consists only in folding adjacent facets at a constrained angle. Our method generates simplified shapes where every dihedral angle between adjacent facets belongs to a restricted set, thus making the assembly process quicker and more straightforward. Firstly, our method automatically computes a simplified version of the input model, using the marching cubes algorithm on the original mesh and iteratively performing local changes on the resulting triangle mesh. The user can then perform an additional manual simplification to remove unwanted facets. Finally, an unfolding algorithm, which takes into account the thickness of the material, flattens the polygonal facets onto the 2D plane, so that a CNC milling machine can fabricate it from a sheet of rigid material.
ISSN:0097-8493
1873-7684
DOI:10.1016/j.cag.2019.03.003