The hand of the DLR hand arm system: Designed for interaction

Markus Grebenstein, Maxime Chalon, Werner Friedl, Sami Haddadin, Thomas Wimböck, Gerd Hirzinger, Roland Siegwart

Research output: Contribution to journalArticlepeer-review

183 Scopus citations

Abstract

Physical human-robot interaction implies the intersection of human and robot workspaces and intrinsically favors collision. The robustness of the most exposed parts, such as the hands, is crucial for effective and complete task execution of a robot. Considering the scales, we think that the robustness can only be achieved by the use of energy storage mechanisms, e.g. in elastic elements. The use of variable stiffness drives provides a low-pass filtering of impacts and allows stiffness adjustments depending on the task. However, using these drive principles does not guarantee the safety of the human due to the dramatically increased dynamics of such system. The design methodology of an antagonistically tendon-driven hand is explained. The resulting hand, very close to its human archetype in terms of size, weight, and, in particular, grasping performance, robustness, and dynamics, is presented. The hyper-actuated hand is a research platform that will also be used to investigate the importance of mechanical couplings and, in future projects, be the basis of a simplified hand that would still perform daily manipulation tasks.

Original languageEnglish
Pages (from-to)1531-1555
Number of pages25
JournalInternational Journal of Robotics Research
Volume31
Issue number13
DOIs
StatePublished - Nov 2012
Externally publishedYes

Keywords

  • Humanoid hand
  • antagonism
  • anthropomorphic hand
  • control
  • design
  • pHRI
  • variable stiffness

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