Towards a parameterizable exoskeleton for training of hand function after stroke

Patrick Weiss; Lars Heyer; Thomas F Munte; Marcus Heldmann; Achim Schweikard; Erik Maehle

doi:10.1109/ICORR.2013.6650505

Towards a parameterizable exoskeleton for training of hand function after stroke

Patrick Weiss, Lars Heyer, Thomas F Munte, Marcus Heldmann, Achim Schweikard, Erik Maehle

Abstract

This paper describes the mechanical design, actuation and sensing of an exoskeleton for hand function training after stroke. The frame is 3D-printed in one piece including the joints. Apart from saving assembly time, this enables parametrization of the link sizes in order to adapt it to the patient's hand and reduce joint misalignment. The joint angles are determined using Hall effect sensors. They measure the change of the magnetic field of in the joints integrated magnets achieving an average accuracy of 1.25 °. Tendons attached to the finger tips transmit forces from motors. The armature current, which is proportional to the force transmitting tendons is measured using a shunt and controlled by a custom-made current-limiter circuit. Preliminary experiments with a force/torque-sensor showed high linearity and accuracy with a root mean square error of 0.5937 N in comparison to the corresponding forces derived from the motor torque constant.

Originalsprache	Englisch
Zeitschrift	IEEE ... International Conference on Rehabilitation Robotics : [proceedings]
Jahrgang	2013
Seiten (von - bis)	6650505
ISSN	1945-7898
DOIs	https://doi.org/10.1109/ICORR.2013.6650505
Publikationsstatus	Veröffentlicht - 06.2013

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10.1109/ICORR.2013.6650505

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title = "Towards a parameterizable exoskeleton for training of hand function after stroke",

abstract = "This paper describes the mechanical design, actuation and sensing of an exoskeleton for hand function training after stroke. The frame is 3D-printed in one piece including the joints. Apart from saving assembly time, this enables parametrization of the link sizes in order to adapt it to the patient's hand and reduce joint misalignment. The joint angles are determined using Hall effect sensors. They measure the change of the magnetic field of in the joints integrated magnets achieving an average accuracy of 1.25 °. Tendons attached to the finger tips transmit forces from motors. The armature current, which is proportional to the force transmitting tendons is measured using a shunt and controlled by a custom-made current-limiter circuit. Preliminary experiments with a force/torque-sensor showed high linearity and accuracy with a root mean square error of 0.5937 N in comparison to the corresponding forces derived from the motor torque constant.",

author = "Patrick Weiss and Lars Heyer and Munte, \{Thomas F\} and Marcus Heldmann and Achim Schweikard and Erik Maehle",

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AU - Weiss, Patrick

AU - Heyer, Lars

AU - Munte, Thomas F

AU - Heldmann, Marcus

AU - Schweikard, Achim

AU - Maehle, Erik

PY - 2013/6

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JO - IEEE ... International Conference on Rehabilitation Robotics : [proceedings]

JF - IEEE ... International Conference on Rehabilitation Robotics : [proceedings]

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Towards a parameterizable exoskeleton for training of hand function after stroke

Abstract

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