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Experimental characterization of a dielectric elastomer fluid pump and optimizing performance via composite materials

Experimental characterization of a dielectric elastomer fluid pump and optimizing performance via composite materials
Experimental characterization of a dielectric elastomer fluid pump and optimizing performance via composite materials
Dielectric elastomer is a class of soft actuators with exceptionally high strain capabilities and energy density. It is being studied for wide range of various applications and has been hypothesized to be a good material for biomedical blood pumps. We performed experimental characterization of a simple dielectric elastomer fluid pump to test this feasibility. We achieved substantial flow rates (10 mL/s) and actuation pressure (45 mm Hg) and found that dielectric elastomer fluid pump performance can exhibit significant resonance effects, with drastic reduction in performance at non-resonance frequencies. The elastomer, VHB™, a soft acrylic polymer, is frequently used to fabricate dielectric elastomer due to high deformation abilities and dielectric constant but has a well-known shortcoming of high viscoelasticity, which severely limited the dielectric elastomer pumps’ performance except at very low frequencies. In this study, we demonstrated that the introduction of a thin elastic and non-viscous layer to the VHB, such as latex, to form a composite dielectric elastomer could address this limitation. The composite dielectric elastomer pump has an increased resonance frequency, significantly improved performances at frequencies of 0.75–2 Hz, and higher maximum achievable actuation volume, flow rate, actuation pressures, and power output. Remaining challenges of realizing a dielectric elastomer blood pump are discussed.
1045-389X
3054-3065
Ho, Sheldon
1641f6c6-754b-4659-95fa-ec5e4023c605
Banerjee, Hritwick
4b9527e6-9605-4ad3-bd39-30d1ebb78309
Foo, Yoke Yin
e687a8cf-a589-4bc4-bf3a-c1f48f3a16b7
Godaba, Hareesh
787c1482-6a29-43ad-b49e-a6a2b7175f0c
Aye, Winn Maung Maung
868b856a-f1d8-4071-9564-1304aeaae4f9
Zhu, Jian
d75c9b9d-87ba-45e0-a05f-72631e2b2967
Yap, Choon Hwai
5ead6650-d37a-4c36-a63d-c5b930e0cd3a
Ho, Sheldon
1641f6c6-754b-4659-95fa-ec5e4023c605
Banerjee, Hritwick
4b9527e6-9605-4ad3-bd39-30d1ebb78309
Foo, Yoke Yin
e687a8cf-a589-4bc4-bf3a-c1f48f3a16b7
Godaba, Hareesh
787c1482-6a29-43ad-b49e-a6a2b7175f0c
Aye, Winn Maung Maung
868b856a-f1d8-4071-9564-1304aeaae4f9
Zhu, Jian
d75c9b9d-87ba-45e0-a05f-72631e2b2967
Yap, Choon Hwai
5ead6650-d37a-4c36-a63d-c5b930e0cd3a

Ho, Sheldon, Banerjee, Hritwick, Foo, Yoke Yin, Godaba, Hareesh, Aye, Winn Maung Maung, Zhu, Jian and Yap, Choon Hwai (2017) Experimental characterization of a dielectric elastomer fluid pump and optimizing performance via composite materials. Journal of Intelligent Material Systems and Structures, 28 (20), 3054-3065. (doi:10.1177/1045389x17704921).

Record type: Article

Abstract

Dielectric elastomer is a class of soft actuators with exceptionally high strain capabilities and energy density. It is being studied for wide range of various applications and has been hypothesized to be a good material for biomedical blood pumps. We performed experimental characterization of a simple dielectric elastomer fluid pump to test this feasibility. We achieved substantial flow rates (10 mL/s) and actuation pressure (45 mm Hg) and found that dielectric elastomer fluid pump performance can exhibit significant resonance effects, with drastic reduction in performance at non-resonance frequencies. The elastomer, VHB™, a soft acrylic polymer, is frequently used to fabricate dielectric elastomer due to high deformation abilities and dielectric constant but has a well-known shortcoming of high viscoelasticity, which severely limited the dielectric elastomer pumps’ performance except at very low frequencies. In this study, we demonstrated that the introduction of a thin elastic and non-viscous layer to the VHB, such as latex, to form a composite dielectric elastomer could address this limitation. The composite dielectric elastomer pump has an increased resonance frequency, significantly improved performances at frequencies of 0.75–2 Hz, and higher maximum achievable actuation volume, flow rate, actuation pressures, and power output. Remaining challenges of realizing a dielectric elastomer blood pump are discussed.

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Published date: 20 April 2017

Identifiers

Local EPrints ID: 499289
URI: http://eprints.soton.ac.uk/id/eprint/499289
DOI: doi:10.1177/1045389x17704921
ISSN: 1045-389X
PURE UUID: 570f3dae-fa66-4f08-a785-332fd6df8adf
ORCID for Hareesh Godaba: ORCID iD orcid.org/0000-0001-6600-8513

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Date deposited: 14 Mar 2025 17:31
Last modified: 15 Mar 2025 03:16

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Contributors

Author: Sheldon Ho
Author: Hritwick Banerjee
Author: Yoke Yin Foo
Author: Hareesh Godaba ORCID iD
Author: Winn Maung Maung Aye
Author: Jian Zhu
Author: Choon Hwai Yap

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