CoreCavity: Interactive shell decomposition for fabrication with two-piece rigid molds Journal Article


Author(s): Nakashima, Kazutaka; Auzinger, Thomas; Iarussi, Emmanuel; Zhang, Ran; Igarashi, Takeo; Bickel, Bernd
Article Title: CoreCavity: Interactive shell decomposition for fabrication with two-piece rigid molds
Affiliation IST Austria
Abstract: Molding is a popular mass production method, in which the initial expenses for the mold are offset by the low per-unit production cost. However, the physical fabrication constraints of the molding technique commonly restrict the shape of moldable objects. For a complex shape, a decomposition of the object into moldable parts is a common strategy to address these constraints, with plastic model kits being a popular and illustrative example. However, conducting such a decomposition requires considerable expertise, and it depends on the technical aspects of the fabrication technique, as well as aesthetic considerations. We present an interactive technique to create such decompositions for two-piece molding, in which each part of the object is cast between two rigid mold pieces. Given the surface description of an object, we decompose its thin-shell equivalent into moldable parts by first performing a coarse decomposition and then utilizing an active contour model for the boundaries between individual parts. Formulated as an optimization problem, the movement of the contours is guided by an energy reflecting fabrication constraints to ensure the moldability of each part. Simultaneously, the user is provided with editing capabilities to enforce aesthetic guidelines. Our interactive interface provides control of the contour positions by allowing, for example, the alignment of part boundaries with object features. Our technique enables a novel workflow, as it empowers novice users to explore the design space, and it generates fabrication-ready two-piece molds that can be used either for casting or industrial injection molding of free-form objects.
Keywords: fabrication; Decomposition; Molding; Height field
Journal Title: ACM Trans. Graph.
Volume: 37
Issue 4
ISSN: 0730-0301
Publisher: ACM  
Date Published: 2018-08-04
Start Page: article number: 135
DOI: 10.1145/3197517.3201341
Open access: no
IST Austria Authors
  1. Ran Zhang
    3 Zhang
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