Artificial gills for robots: MFC behaviour in water
Artificial gills for robots: MFC behaviour in water
This paper reports on the first stage in developing microbial fuel cells (MFCs) which can operate underwater by utilizing dissolved oxygen. In this context, the cathodic half-cell is likened to an artificial gill. Such an underwater power generator has obvious potential for autonomous underwater robots. The electrical power from these devices increased proportionately with water flow rate, temperature and salinity. The current output at ambient temperature (null condition) was 32 µA and this increased by 200% (∼100 µA) as a result of a corresponding temperature increase (ΔT) of 52 °C. Similarly, the effect of increasing the water flow rate resulted in an increase in the MFC output ranging from 135% to 150%. Furthermore, the same positive effect was recorded when artificial seawater was used instead, in which case the increase in the MFC current output was >100% (from 32 to 65 µA). There was a distinct difference in the MFC performance when operated under low turbulent as opposed to high turbulent flow rates. These findings can be advantageous in the design of underwater autonomous robots.
S83-S93
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Melhuish, Chris
c52dcc8b-1e36-425e-80df-9d05d2b21893
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
22 June 2007
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Melhuish, Chris
c52dcc8b-1e36-425e-80df-9d05d2b21893
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Ieropoulos, Ioannis, Melhuish, Chris and Greenman, John
(2007)
Artificial gills for robots: MFC behaviour in water.
Bioinspiration & Biomimetics, 2 (3), .
(doi:10.1088/1748-3182/2/3/S02).
Abstract
This paper reports on the first stage in developing microbial fuel cells (MFCs) which can operate underwater by utilizing dissolved oxygen. In this context, the cathodic half-cell is likened to an artificial gill. Such an underwater power generator has obvious potential for autonomous underwater robots. The electrical power from these devices increased proportionately with water flow rate, temperature and salinity. The current output at ambient temperature (null condition) was 32 µA and this increased by 200% (∼100 µA) as a result of a corresponding temperature increase (ΔT) of 52 °C. Similarly, the effect of increasing the water flow rate resulted in an increase in the MFC output ranging from 135% to 150%. Furthermore, the same positive effect was recorded when artificial seawater was used instead, in which case the increase in the MFC current output was >100% (from 32 to 65 µA). There was a distinct difference in the MFC performance when operated under low turbulent as opposed to high turbulent flow rates. These findings can be advantageous in the design of underwater autonomous robots.
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Accepted/In Press date: 28 February 2007
Published date: 22 June 2007
Identifiers
Local EPrints ID: 454245
URI: http://eprints.soton.ac.uk/id/eprint/454245
ISSN: 1748-3182
PURE UUID: ebc5255c-cf19-4dcd-9db6-8562ccd5524f
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Date deposited: 03 Feb 2022 17:47
Last modified: 17 Mar 2024 04:10
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Author:
Chris Melhuish
Author:
John Greenman
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