Actuation Response of Polyacrylate Dielectric Elastomers

Polyacrylate dielectric elastomers have yielded extremely large strain and elastic energy density suggesting that they are useful for many actuator applications. A thorough understanding of the physics underlying the mechanism of the observed response to an electric field can help develop improved a...

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Bibliographic Details
Published in:Journal of intelligent material systems and structures 2003-12, Vol.14 (12), p.787-793
Main Authors: Kofod, Guggi, Sommer-Larsen, Peter, Kornbluh, Roy, Pelrine, Ron
Format: Article
Language:English
Subjects:
Application fields
Applied sciences
Exact sciences and technology
General equipment and techniques
Instruments, apparatus, components and techniques common to several branches of physics and astronomy
Physics
Polymer industry, paints, wood
Technology of polymers
Transducers
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Summary:Polyacrylate dielectric elastomers have yielded extremely large strain and elastic energy density suggesting that they are useful for many actuator applications. A thorough understanding of the physics underlying the mechanism of the observed response to an electric field can help develop improved actuators. The response is believed to be due to Maxwell stress, a quadratic dependence of the stress upon applied electric field. Based on this supposition, an equation relating the applied voltage to the measured force from an actuator was derived. Experimental data fit with the expected behavior, though there are discrepancies. Further analysis suggests that these arise mostly from imperfect manufacture of the actuators, though there is a small contribution from an explicitly electrostrictive behavior of the acrylic adhesive. Measurements of the dielectric constant of stretched polymer reveal that the dielectric constant drops, when the polymer is strained, indicating the existence of a small electrostrictive effect. Finally, measurements of the electric breakdown field were made. These also show a dependence upon the strain. In the unstrained state the breakdown field is 20 MV/m, which grows to 218 MV/m at 500 500% strain. This large increase could prove to be of importance in actuator design.
ISSN:1045-389X
1530-8138
DOI:10.1177/104538903039260