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Elastic Electroadhesion with Rapid Release by Integrated Resonant Vibration

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Elastic Electroadhesion with Rapid Release by Integrated Resonant Vibration. / Gao, Xing; Cao, Chongjing; Guo, Jianglong; Conn, Andrew.

In: Advanced Materials Technologies, 26.10.2018.

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Gao, Xing ; Cao, Chongjing ; Guo, Jianglong ; Conn, Andrew. / Elastic Electroadhesion with Rapid Release by Integrated Resonant Vibration. In: Advanced Materials Technologies. 2018.

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@article{b9e8dab0983940a68555d91fccc22583,
title = "Elastic Electroadhesion with Rapid Release by Integrated Resonant Vibration",
abstract = "Soft robotic grippers have gained a growing interest due to their inherent compliance which passively adapts to a variety of object shapes and electroadhesion (EA) has attracted particular attention due to its versatile, low impact adhesion. EA shows potential for the precise manipulation of thin and flexible substrates such as plastic films, which is crucial to the advancement of flexible electronics fabrication. However, the rapid release of substrates is a challenge with EA due to the residual charge and relatively slow dielectric natural relaxation time that exists when the applied voltage switched off. Here, a novel soft gripping technology that integrates a dielectric elastomer actuator with an EA into a soft, monolithic structure to achieve rapid de‐adhesion is presented. This inherently compliant device exploits resonant excitation to minimize the release period to a range of 100–500 ms, which is an improvement of at least two orders of magnitude compared with conventional EA release. The developed end effector demonstrates rapid and robust adhesion/de‐adhesion performance in a lightweight and compact form, with simplified control and low energy consumption and hence has wide application to a variety of robotic manipulation tasks.",
keywords = "Soft robotic gripper, dielectric elastomer actuator, resonant vibration, electroadhesion",
author = "Xing Gao and Chongjing Cao and Jianglong Guo and Andrew Conn",
year = "2018",
month = "10",
day = "26",
doi = "10.1002/admt.201800378",
language = "English",
journal = "Advanced Materials Technologies",
issn = "2365-709X",
publisher = "Wiley",

}

RIS - suitable for import to EndNote

TY - JOUR

T1 - Elastic Electroadhesion with Rapid Release by Integrated Resonant Vibration

AU - Gao, Xing

AU - Cao, Chongjing

AU - Guo, Jianglong

AU - Conn, Andrew

PY - 2018/10/26

Y1 - 2018/10/26

N2 - Soft robotic grippers have gained a growing interest due to their inherent compliance which passively adapts to a variety of object shapes and electroadhesion (EA) has attracted particular attention due to its versatile, low impact adhesion. EA shows potential for the precise manipulation of thin and flexible substrates such as plastic films, which is crucial to the advancement of flexible electronics fabrication. However, the rapid release of substrates is a challenge with EA due to the residual charge and relatively slow dielectric natural relaxation time that exists when the applied voltage switched off. Here, a novel soft gripping technology that integrates a dielectric elastomer actuator with an EA into a soft, monolithic structure to achieve rapid de‐adhesion is presented. This inherently compliant device exploits resonant excitation to minimize the release period to a range of 100–500 ms, which is an improvement of at least two orders of magnitude compared with conventional EA release. The developed end effector demonstrates rapid and robust adhesion/de‐adhesion performance in a lightweight and compact form, with simplified control and low energy consumption and hence has wide application to a variety of robotic manipulation tasks.

AB - Soft robotic grippers have gained a growing interest due to their inherent compliance which passively adapts to a variety of object shapes and electroadhesion (EA) has attracted particular attention due to its versatile, low impact adhesion. EA shows potential for the precise manipulation of thin and flexible substrates such as plastic films, which is crucial to the advancement of flexible electronics fabrication. However, the rapid release of substrates is a challenge with EA due to the residual charge and relatively slow dielectric natural relaxation time that exists when the applied voltage switched off. Here, a novel soft gripping technology that integrates a dielectric elastomer actuator with an EA into a soft, monolithic structure to achieve rapid de‐adhesion is presented. This inherently compliant device exploits resonant excitation to minimize the release period to a range of 100–500 ms, which is an improvement of at least two orders of magnitude compared with conventional EA release. The developed end effector demonstrates rapid and robust adhesion/de‐adhesion performance in a lightweight and compact form, with simplified control and low energy consumption and hence has wide application to a variety of robotic manipulation tasks.

KW - Soft robotic gripper

KW - dielectric elastomer actuator

KW - resonant vibration

KW - electroadhesion

U2 - 10.1002/admt.201800378

DO - 10.1002/admt.201800378

M3 - Article

JO - Advanced Materials Technologies

JF - Advanced Materials Technologies

SN - 2365-709X

M1 - 1800378

ER -