Issue 18, 2017

A variable stiffness dielectric elastomer actuator based on electrostatic chucking

Abstract

Dielectric elastomer actuators (DEA) are one type of promising artificial muscle; however, applications of bending-type DEA for robotic end-effectors may be limited by their low stiffness and ability to resist external loads without buckling. Unimorph DEA can produce large out-of-plane deformation suitable for use as robotic end effectors; however, design of such actuators for large displacement comes at the cost of low stiffness and blocking force. This work proposes and demonstrates a variable stiffness dielectric elastomer actuator (VSDEA) consisting of a plurality of unimorph DEA units operating in parallel, which can exhibit variable electrostatic chucking to modulate the structure's bending stiffness. The unimorph DEA units are additively manufactured using a high-resolution pneumatic dispenser, and VSDEA comprising various numbers of units are assembled. The performance of the DEA units and VSDEA are compared to model predictions, exhibiting a maximum stiffness change of 39.2×. A claw actuator comprising two VSDEA and weighing 0.6 grams is demonstrated grasping and lifting a 10 gram object.

Graphical abstract: A variable stiffness dielectric elastomer actuator based on electrostatic chucking

Supplementary files

Article information

Article type
Paper
Submitted
17 Mar 2017
Accepted
07 Apr 2017
First published
10 Apr 2017

Soft Matter, 2017,13, 3440-3448

A variable stiffness dielectric elastomer actuator based on electrostatic chucking

H. Imamura, K. Kadooka and M. Taya, Soft Matter, 2017, 13, 3440 DOI: 10.1039/C7SM00546F

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