• DocumentCode
    3514603
  • Title

    Quasi-static evaluation of a modular and Reconfigurable Manufacturing Cell

  • Author

    Das, Aditya N. ; Savoie, S.

  • Author_Institution
    Univ. of Texas at Arlington Res. Inst. (UTARI), Fort Worth, TX, USA
  • fYear
    2013
  • fDate
    6-10 May 2013
  • Firstpage
    258
  • Lastpage
    263
  • Abstract
    Extensive cost, time and effort associated with setting up a production line often inhibits transitioning novel ideas into commercialized products. Sustainable revenue generation in such enterprises requires production in large quantities in order to lower the unit cost, and thus improving the marketability. Although this model has been successful and is being followed by most of the industries today, it also limits the scope for new, non-conventional products; especially in the early stages of development where manufacturing risks are higher. One way of reducing this risk can be through improving the reusability of the manufacturing hardware, thus allowing quick and inexpensive transition among different iterations and even different products with the same set of hardware. In this paper, we present such a novel and revolutionary solution for flexible manufacturing. Consisting of a unique set of hardware and software innovations, our proposed system offers a viable way to low volume manufacturing and low risk prototyping of novel product ideas. Called as the “Modular and Reconfigurable Manufacturing Cell (MRMC)”, this proposed system enables quick and easy setting up of a fully automated robotic manipulation and assembly platform, optimized for specific products. The system relies on a novel and proprietary multifunctional interconnect design, built-in to various hardware modules of the system, and a distributed intelligence based self-locating software architecture to achieve almost any possible assembler configuration that is suitable for a specific set of tasks. Necessary and sufficient precision level is maintained via a novel precision optimized hybrid controller and path planner throughout the automation. Competitive specifications in terms of travel range, resolution, accuracy, repeatability, force output, size, weight, power ratings etc., as compared to standard commercial manipulators, has been experimentally verified for the proposed Modul- r and Reconfigurable Manufacturing Cell (MRMC).
  • Keywords
    cellular manufacturing; flexible manufacturing systems; industrial manipulators; innovation management; mobile robots; path planning; production engineering computing; risk management; robotic assembly; MRMC; assembler configuration; assembly platform; automated robotic manipulation; commercialized products; competitive specifications; distributed intelligence; flexible manufacturing; hardware innovation; low risk prototyping; low volume manufacturing; manufacturing hardware; manufacturing risks; marketability improvement; modular and reconfigurable manufacturing cell; modular manufacturing cell; path planner; precision optimized hybrid controller; production line; proprietary multifunctional interconnect design; quasi-static evaluation; risk reduction; self-locating software architecture; software innovation; sustainable revenue generation; Assembly; Computer architecture; Hardware; Production; Prototypes; Robots;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Robotics and Automation (ICRA), 2013 IEEE International Conference on
  • Conference_Location
    Karlsruhe
  • ISSN
    1050-4729
  • Print_ISBN
    978-1-4673-5641-1
  • Type

    conf

  • DOI
    10.1109/ICRA.2013.6630585
  • Filename
    6630585