Most traditional robotic mechanisms feature inelastic joints that are unable
to robustly handle large deformations and off-axis moments. As a result, the
applied loads are transferred rigidly throughout the entire structure. The
disadvantage of this approach is that the exerted leverage is magnified at each
subsequent joint possibly damaging the mechanism. In this paper, we present two
lightweight, elastic, bio-inspired tensegrity robotics arms which mitigate this
danger while improving their mechanism's functionality. Our solutions feature
modular tensegrity structures that function similarly to the human elbow and
the human shoulder when connected. Like their biological counterparts, the
proposed robotic joints are flexible and comply with unanticipated forces. Both
proposed structures have multiple passive degrees of freedom and four active
degrees of freedom (two from the shoulder and two from the elbow). The
structural advantages demonstrated by the joints in these manipulators
illustrate a solution to the fundamental issue of elegantly handling off-axis
compliance.Comment: IROS 201