• DocumentCode
    137580
  • Title

    Role of compliant leg in the flea-inspired jumping mechanism

  • Author

    Gwang-Pil Jung ; Ji-Suk Kim ; Je-Sung Koh ; Sun-Pil Jung ; Kyu-Jin Cho

  • Author_Institution
    Biorobotics Lab., Seoul Nat. Univ., Seoul, South Korea
  • fYear
    2014
  • fDate
    14-18 Sept. 2014
  • Firstpage
    315
  • Lastpage
    320
  • Abstract
    Jumping locomotion has been widely employed in milliscale mobile robots to help overcome their size limitations by extending their range and enabling them to overcome obstacles. During jumping, the robot´s legs experience acceleration that is up to an order of magnitude greater than the gravitational acceleration. This large force results in bending of the jumping legs. In this paper, we study how the bending of the leg affects the jumping performance of a flea-inspired jumping robot. To judge the effect of the leg compliance, the amount of energy lost during jumping is determined by examining the ratio of kinetic energy to input energy, which we define as the mechanical efficiency. The bending leg is dynamically modeled using a pseudo-rigid-body model in order to precisely analyze the energy transfer. Jumping experiments are performed for five different legs, each with a different stiffness. Shape memory polymer rivets, which are lightweight and compact, were used to easily switch out the legs. The mechanical efficiency of the robot with appropriately chosen leg compliance was 41.27% compared with 36.93% for the rigid case and 21.51% for the much more compliant case. The results show that optimizing the compliance of a jumping leg can improve the performance of a jumping robot.
  • Keywords
    bending; compliant mechanisms; elastic constants; legged locomotion; shape memory effects; compliant leg; dynamic modelling; energy lost; energy transfer analysis; flea-inspired jumping robot mechanism; gravitational acceleration; jumping leg bending; jumping leg compliance optimization; jumping locomotion; jumping performance; jumping robot performance improvement; kinetic energy-input energy ratio; lightweight-compact shape memory polymer rivets; mechanical efficiency; milliscale mobile robots; pseudorigid-body model; robot legs; stiffness; Acceleration; Analytical models; Energy storage; Force; Kinetic energy; Legged locomotion;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Intelligent Robots and Systems (IROS 2014), 2014 IEEE/RSJ International Conference on
  • Conference_Location
    Chicago, IL
  • Type

    conf

  • DOI
    10.1109/IROS.2014.6942578
  • Filename
    6942578