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Lightweight Mesh File Format Using Repetition Pattern Encoding for Additive Manufacturing

Article dans une revue avec comité de lecture
Auteur
VAISSIER, Benjamin
CHOUGRANI, Laurent
475262 Poly-Shape
VÉRON, Philippe
ccPERNOT, Jean-Philippe
58355 École Nationale Supérieure des Arts et Métiers [ENSAM]
543315 Laboratoire d’Ingénierie des Systèmes Physiques et Numériques [LISPEN]

URI
http://hdl.handle.net/10985/19955
DOI
10.1016/j.cad.2020.102914
Date
2020
Journal
Computer-Aided Design

Résumé

To facilitate the transfer, storage and manipulation of intricate parts’ geometry whose fabrication has been made possible thanks to the rise of Additive Manufacturing (AM) technologies, an encoding framework reducing the resulting file size has been developed. This approach leverages the fact that many AM parts are presenting repetition patterns, by encoding the repetition of similar geometry chunks. The decomposition of the part into chunks is a complex optimization problem, whose identification as a Weighted Exact Cover (WEC) problem allowed to develop a new heuristic algorithm dedicated to its fast resolution in linear time . The encoding strategy is implemented through a variation of the AMF file standard (for quick adoption of the format by existing software), and also through a new ad-hoc hybrid file format. To demonstrate the efficiency of the approach, the encryption of lattice and support structures through these two encoding strategies are compared to the results of several state-of-the-art encoding approaches. The way this data weight lightening strategy preserves the overall accuracy is discussed while considering different floating points encoding precisions with respect to the AM process requirements. This comparison exhibits file size reductions up to -84% in comparison with file sizes generated by state-of-the-art approaches. Not only the proposed repetition pattern encoding framework allows file size reductions, but it could also be exploited to optimize and speed-up some steps of the Product Development Process (PDP), including process planning phases.

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LISPEN_CAD_2020_VERON.pdf
Taille:
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Format:
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Fin d'embargo:
2021-05-01
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  • Laboratoire d’Ingénierie des Systèmes Physiques Et Numériques (LISPEN)

Documents liés

Visualiser des documents liés par titre, auteur, créateur et sujet.

  • Parametric design of graded truss lattice structures for enhanced thermal dissipation 
    Article dans une revue avec comité de lecture
    VAISSIER, Benjamin; CHOUGRANI, Laurent; ccPERNOT, Jean-Philippe; ccVERON, Philippe (Elsevier, 2019)
    Truss lattice structures are intricate geometries, whose fabrication has recently been simplified by the development of Additive Manufacturing (AM) technologies. These lightweight geometries present great volume densities ...
  • Investigation on reducing geometry files size through floating points indexing 
    Communication avec acte
    VAISSIER, Benjamin; CHOUGRANI, Laurent; ccPERNOT, Jean-Philippe; ccVERON, Philippe (CAD Solutions, LLC, 2019)
    In a context of full cooperative data exchanges, frequent transfers between specialized software and remote design and manufacturing, fluidity is the key. It is thus important to reduce the size of data encoding files in ...
  • Genetic-algorithm based framework for lattice support structure optimization in additive manufacturing 
    Article dans une revue avec comité de lecture
    VAISSIER, Benjamin; CHOUGRANI, Laurent; ccPERNOT, Jean-Philippe; ccVERON, Philippe (Elsevier, 2019)
    The emergence and improvement of Additive Manufacturing technologies allow the fabrication of complex shapes so far inconceivable. However, to produce those intricate geometries, support structures are required. Besides ...
  • Lattice support structure discrete optimization for additive manufacturing 
    Communication avec acte
    VAISSIER, Benjamin; ccPERNOT, Jean-Philippe; ccVERON, Philippe (ACM Digital Library Proceedings, 2018)
    The emergence and improvement of Additive Manufacturing technologies allow the fabrication of complex shapes so far inconceivable. However, to produce those intricate geometries, support structures are required. Besides ...
  • Parts internal structure definition using lattice patterns optimization for mass reduction in additive manufacturing 
    Communication avec acte
    CHOUGRANI, Laurent; ABED, Stéphane; ccPERNOT, Jean-Philippe; ccVERON, Philippe (2016)
    With the rise of additive manufacturing, complex internal structure optimization is now a relevant topic. Additive manufacturing allows designers and engineers to go further in their modeling, designing and optimization ...

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