Bowden Cable Actuator for Force-Feedback Exoskeletons

Bowden Cable Actuator for Force-Feedback Exoskeletons

This paper introduces a novel type of actuator that is investigated by ESA for force-reflection to a wearable exoskeleton. The actuator consists of a DC motor that is relocated from the joint by means of Bowden cable transmissions. The actuator shall support the development of truly ergonomic and co...

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Bibliographic Details
Published in:2006 IEEE/RSJ International Conference on Intelligent Robots and Systems pp. 3599 - 3604
Main Authors: Schiele, A., Letier, P., van der Linde, R., van der Helm, F.
Format: Conference Proceeding
Language:English
Published: IEEE 01-10-2006
Subjects:
Actuator
Actuators
Bowden cable
Contact resistance
DC motors
Ergonomic kinematics
Ergonomics
Exoskeleton
Exoskeletons
Force control
Hardware
Master-slave
Prototypes
User interfaces
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Summary:This paper introduces a novel type of actuator that is investigated by ESA for force-reflection to a wearable exoskeleton. The actuator consists of a DC motor that is relocated from the joint by means of Bowden cable transmissions. The actuator shall support the development of truly ergonomic and compact wearable man-machine interfaces. Important Bowden cable transmission characteristics are discussed, which dictate a specific hardware design for such an actuator. A first prototype is shown, which was used to analyze these basic characteristics of the transmissions and to proof the overall actuation concept. A second, improved prototype is introduced, which is currently used to investigate the achievable performance as a master actuator in a master-slave control with force-feedback. Initial experimental results are presented, which show good actuator performance in a 4 channel control scheme with a slave joint. The actuator features low movement resistance in free motion and can reflect high torques during hard contact situations. High contact stability can be achieved. The actuator seems therefore well suited to be implemented into the ESA exoskeleton for space-robotic telemanipulation
ISBN:9781424402588
1424402581
ISSN:2153-0858
2153-0866
DOI:10.1109/IROS.2006.281712