Pilwon Heo scite author profile

This paper presents a powered finger exoskeleton with an open fingerpad, named the Open Fingerpad eXoskeleton (OFX). The palmar opening at the fingerpad allows for direct contact between the user's fingerpad and objects in order to make use of the wearer's own tactile sensation for dexterous manipulation. Lateral side walls at the end of the OFX's index finger module are equipped with custom load cells for estimating the wearer's pinch grip force. A pneumatic cylinder generates assistance force, which is determined according to the estimated pinch grip force. The OFX transmits the assistance force directly to the objects without exerting pressure on the wearer's finger. The advantage of the OFX over an exoskeleton with a closed fingerpad was validated experimentally. During static and dynamic manipulation of a test object, the OFX exhibited a lower safety margin than the closed exoskeleton, indicating a higher ability to adjust the grip force within an appropriate range. Furthermore, the benefit of force assistance in reducing the muscular burden was observed in terms of muscle fatigue during a static pinch grip. The median frequency (MDF) of the surface electromyography (sEMG) signal from the first dorsal interosseous (FDI) muscle displayed a lower reduction rate for the assisted condition, indicating a lower accumulation rate of muscle fatigue.

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A Finger Grip Force Sensor with an Open-Pad Structure for Glove-Type Assistive Devices

Park

Heo

Kim

et al. 2019

Sensors

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This paper presents a fingertip grip force sensor based on custom capacitive sensors for glove-type assistive devices with an open-pad structure. The design of the sensor allows using human tactile sensations during grasping and manipulating an object. The proposed sensor can be attached on both sides of the fingertip and measure the force caused by the expansion of the fingertip tissue when a grasping force is applied to the fingertip. The number of measurable degrees of freedom (DoFs) are the two DoFs (flexion and adduction) for the thumb and one DoF (flexion) for the index and middle fingers. The proposed sensor allows the combination with a glove-type assistive device to measure the fingertip force. Calibration was performed for each finger joint angle because the variations in the expansion of the fingertip tissue depend on the joint angles. The root mean square error (RMSE) for fingertip force estimation ranged from 3.75% to 9.71% after calibration, regardless of the finger joint angles or finger posture.

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Robotics for Healthcare

Kim

Heo

2015

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Qualitative Stability Analysis of Soft Hand Exoskeleton Based on Tendon-driven Mechanism

Park

Heo²,

Kim

et al. 2020

Int. J. Precis. Eng. Manuf.

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Pilwon Heo

Current hand exoskeleton technologies for rehabilitation and assistive engineering

Power-Assistive Finger Exoskeleton With a Palmar Opening at the Fingerpad

A Finger Grip Force Sensor with an Open-Pad Structure for Glove-Type Assistive Devices

Robotics for Healthcare

Qualitative Stability Analysis of Soft Hand Exoskeleton Based on Tendon-driven Mechanism

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