High stress actuation by dielectric elastomer with oil capsules
High stress actuation by dielectric elastomer with oil capsules
Though capable of generating a large strain, dielectric elastomer actuators (DEAs) generate only a moderate actuation stress not more than 200kPa, which seriously limits its use as artificial muscles for robotic arm. Enhancement of dielectric strength (greater than 500MV/m) by dielectric oil immersion could possibly enable it a larger force generation. Previously, the immersion was done in an oil bath, which limits portability together with DEAs. In this study, we developed portable capsules to enclose oil over the DEA substrate (VHB 4905). The capsules is made of a thinner soft acrylic membrane and they seals dielectric liquid oil (Dow Corning Fluid 200 50cSt). The DEA substrate is a graphiteclad VHB membrane, which is pre-stretched with pure-shear boundary condition for axial actuation. When activated under isotonic condition, the oil-capsule DEA can sustain a very high dielectric field up to 903 MV/m and does not fail; whereas, the dry DEA breaks down at a lower electric field at 570 MV/m. Furthermore, the oil-capsule DEA can produces higher isometric stress change up to 1.05MPa, which is 70% more than the maximum produced by the dry DEA. This study confirmed that oil capping helps DEA achieve very high dielectric strength and generate more stress change for work.
La, Thanh Giang
58dfddb0-f508-4fe8-b210-9ba8d6dbe71a
Lau, Gih Keong
10df9260-0991-4e50-9e81-d77b5b2e0e7a
Shiau, Li Lynn
ba1643ba-6039-4dea-b725-8aa946902a7d
Tan, Adrian Wei Yee
3d644676-a520-4f41-b7f1-410d1c46689d
8 March 2014
La, Thanh Giang
58dfddb0-f508-4fe8-b210-9ba8d6dbe71a
Lau, Gih Keong
10df9260-0991-4e50-9e81-d77b5b2e0e7a
Shiau, Li Lynn
ba1643ba-6039-4dea-b725-8aa946902a7d
Tan, Adrian Wei Yee
3d644676-a520-4f41-b7f1-410d1c46689d
La, Thanh Giang, Lau, Gih Keong, Shiau, Li Lynn and Tan, Adrian Wei Yee
(2014)
High stress actuation by dielectric elastomer with oil capsules.
In Electroactive Polymer Actuators and Devices, EAPAD 2014.
vol. 9056,
SPIE..
(doi:10.1117/12.2046371).
Record type:
Conference or Workshop Item
(Paper)
Abstract
Though capable of generating a large strain, dielectric elastomer actuators (DEAs) generate only a moderate actuation stress not more than 200kPa, which seriously limits its use as artificial muscles for robotic arm. Enhancement of dielectric strength (greater than 500MV/m) by dielectric oil immersion could possibly enable it a larger force generation. Previously, the immersion was done in an oil bath, which limits portability together with DEAs. In this study, we developed portable capsules to enclose oil over the DEA substrate (VHB 4905). The capsules is made of a thinner soft acrylic membrane and they seals dielectric liquid oil (Dow Corning Fluid 200 50cSt). The DEA substrate is a graphiteclad VHB membrane, which is pre-stretched with pure-shear boundary condition for axial actuation. When activated under isotonic condition, the oil-capsule DEA can sustain a very high dielectric field up to 903 MV/m and does not fail; whereas, the dry DEA breaks down at a lower electric field at 570 MV/m. Furthermore, the oil-capsule DEA can produces higher isometric stress change up to 1.05MPa, which is 70% more than the maximum produced by the dry DEA. This study confirmed that oil capping helps DEA achieve very high dielectric strength and generate more stress change for work.
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Published date: 8 March 2014
Venue - Dates:
Electroactive Polymer Actuators and Devices, EAPAD 2014, , San Diego, CA, United States, 2014-03-10 - 2014-03-13
Identifiers
Local EPrints ID: 475841
URI: http://eprints.soton.ac.uk/id/eprint/475841
ISSN: 0277-786X
PURE UUID: 24e5721e-a747-4e03-98ec-ae327de3c7ba
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Date deposited: 29 Mar 2023 16:39
Last modified: 17 Mar 2024 00:12
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Contributors
Author:
Thanh Giang La
Author:
Gih Keong Lau
Author:
Li Lynn Shiau
Author:
Adrian Wei Yee Tan
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