• DocumentCode
    73912
  • Title

    Self-Alignment Mechanisms for Assistive Wearable Robots: A Kinetostatic Compatibility Method

  • Author

    Cempini, Marco ; De Rossi, Stefano M. M. ; Lenzi, T. ; Vitiello, Nicola ; Carrozza, Maria

  • Author_Institution
    Biorobot. Inst., Scuola Super. di Studi Univ. e di Perfezionamento Sant´Anna, Pisa, Italy
  • Volume
    29
  • Issue
    1
  • fYear
    2013
  • fDate
    Feb. 2013
  • Firstpage
    236
  • Lastpage
    250
  • Abstract
    The field of wearable robotics is gaining momentum thanks to its potential application in rehabilitation engineering, assistive robotics, and power augmentation. These devices are designed to be used in direct contact with the user to aid with movement or increase the power of specific skeletal joints. The design of the so-called physical human-robot interface is critical, since it determines not only the efficacy of the robot but the kinematic compatibility of the device with the human skeleton and the degree of adaptation to different anthropometries as well. Failing to deal with these problems causes misalignments between the robot and the user joint. Axes misalignment leads to the impossibility of controlling the torque effectively transmitted to the user joint and causes undesired loading forces on articulations and soft tissues. In this paper, we propose a general analytical method for the design of exoskeletons able to assist human joints without being subjected to misalignment effects. This method is based on a kinetostatic analysis of a coupled mechanism (robot-human skeleton) and can be applied in the design of self-aligning mechanisms. The method is exemplified in the design of an assistive robotic chain for a two-degree-of-freedom (DOF) human articulation.
  • Keywords
    geometry; human-robot interaction; medical robotics; patient rehabilitation; anthropometries; assistive wearable robots; axes misalignment; general analytical method; human chain geometry; human skeleton; kinetostatic analysis; kinetostatic compatibility method; physical human-robot interface; power augmentation; rehabilitation engineering; self-alignment mechanisms; soft tissues; two-degree-of-freedom human articulation; undesired loading forces; user joint; Exoskeletons; Geometry; Humans; Joints; Kinematics; Robots; Torque; Axes misalignment; exoskeleton; kinematics; mechanism design; rehabilitation robotics; wearability;
  • fLanguage
    English
  • Journal_Title
    Robotics, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1552-3098
  • Type

    jour

  • DOI
    10.1109/TRO.2012.2226381
  • Filename
    6359868