Finger Flexion and Extension Driven by a Single Motor in Robotic Glove Design

Pneumatic and tendon‐driven actuators are widely used in soft robotic glove design. Tendon‐driven robotic gloves are generally better in controllability, dexterity, and force output, but they are less comfortable than pneumatic ones. Most soft gloves focus on only one actuation mode where either mot...

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Bibliographic Details
Published in:Advanced intelligent systems 2023-05, Vol.5 (5), p.n/a
Main Authors: Liu, Hao, Wu, Changchun, Lin, Senyuan, Chen, Yonghua, Hu, Yong, Xu, Tinghan, Yuan, Wenbo, Li, Yunquan
Format: Article
Language:English
Subjects:
Activities of daily living
Actuation
Actuators
Control equipment
Gloves
Hands
Kinematics
Performance evaluation
pneumatic actuators
Pneumatics
Rehabilitation
rehabilitation robotics
Robotics
soft robot applications
Soft robotics
Tendons
Torque
wearable robotics
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Summary:Pneumatic and tendon‐driven actuators are widely used in soft robotic glove design. Tendon‐driven robotic gloves are generally better in controllability, dexterity, and force output, but they are less comfortable than pneumatic ones. Most soft gloves focus on only one actuation mode where either motor‐driven tendon or pump‐driven pneumatic transmission is used. Herein, a double‐acting soft actuator (DASA) that provides both tendon‐driven flexion and pneumatic extension of fingers by a single motor is presented. This is achieved by a smart pulley and bellow system. The kinematic model of the tendon‐driven flexion and the torque model of the fabric‐based pneumatic extension actuator (FPEA) are developed to analyze the DASA performance. The bending angle of the index finger actuated by the tendon and the FPEA extension torque of a joint are characterized by experimental studies. A cycle test of the DASA is conducted 3000 times, demonstrating its high repeatability. A prototype soft glove (68 g) based on the proposed DASA with a control box (835 g) is fabricated to demonstrate finger flexion and extension assistance. Based on electromyography signals, the performance of the robotic glove is evaluated by a squeezing sponge test. Herein, a novel double‐acting soft actuator that provides both tendon‐driven flexion and pneumatic‐driven extension of fingers by a single motor is introduced. The extension actuator placed on the dorsum of the finger is driven by the compressing bellow actuation. The finger flexion angle and speed are directly controlled by a motor.
ISSN:2640-4567
2640-4567
DOI:10.1002/aisy.202200274