Modeling of a Cable-Based Revolute Joint Using Biphasic Media Variable Stiffness Actuation

This paper proposes a three degrees-of-freedom tensegrity structure with a mechanism inspired by the ligamentous structure of the shoulder. The proposed mechanism simulates the wide motion ranges of the human shoulder joint and is composed of three rigid bodies and sixteen steel wires with three mutually perpendicular rotating axes. Since it belongs to the class 1 tensegrity structure that the rigid bodies do not make any contact with each other, the joint has a certain amount of flexibility, which not only can help protect its mechanism from external impacts but also can prevent human injury that might happen when the mechanism and humans interact each other. Moreover, the proposed mechanism can be manufactured by using fewer materials than a fully rigid mechanism, and thus, it can be made in a lightweight fashion and reduce the inertial effects as well. Finally, to actuate the robotic shoulder, the cables connected to each motor are able to drive the rotating shafts of the joint mechanism.

show abstract

Modeling of a Cable-Based Revolute Joint Using Biphasic Media Variable Stiffness Actuation

Cited by 4 publications

References 12 publications

Performance Evaluation of a Variable Stiffness Joint Based on Electromagnetic Force Attraction

Performance Evaluation of a Variable Stiffness Joint Based on Electromagnetic Force Attraction

Modeling and Stiffness Evaluation Of Tendon-Driven Robot For Collaborative Human-Robot Interaction

Robotic Tensegrity Structure With a Mechanism Mimicking Human Shoulder Motion

Contact Info

Product

Resources

About