Scaling-up of a novel, simplified MFC stack based on a self-stratifying urine column
Scaling-up of a novel, simplified MFC stack based on a self-stratifying urine column
Background
The microbial fuel cell (MFC) is a technology in which microorganisms employ an electrode (anode) as a solid electron acceptor for anaerobic respiration. This results in direct transformation of chemical energy into electrical energy, which in essence, renders organic wastewater into fuel. Amongst the various types of organic waste, urine is particularly interesting since it is the source of 75 % of the nitrogen present in domestic wastewater despite only accounting for 1 % of the total volume. However, there is a persistent problem for efficient MFC scale-up, since the higher the surface area of electrode to volume ratio, the higher the volumetric power density. Hence, to reach usable power levels for practical applications, a plurality of MFC units could be connected together to produce higher voltage and current outputs; this can be done by combinations of series/parallel connections implemented both horizontally and vertically as a stack. This plurality implies that the units have a simple design for the whole system to be cost-effective. The goal of this work was to address the built configuration of these multiple MFCs into stacks used for treating human urine.
Results
We report a novel, membraneless stack design using ceramic plates, with fully submerged anodes and partially submerged cathodes in the same urine solution. The cathodes covered the top of each ceramic plate whilst the anodes, were on the lower half of each plate, and this would constitute a module. The MFC elements within each module (anode, ceramic, and cathode) were connected in parallel, and the different modules connected in series. This allowed for the self-stratification of the collective environment (urine column) under the natural activity of the microbial consortia thriving in the system. Two different module sizes were investigated, where one module (or box) had a footprint of 900 mL and a larger module (or box) had a footprint of 5000 mL. This scaling-up increased power but did not negatively affect power density (≈12 W/m3), a factor that has proven to be an obstacle in previous studies.
Conclusion
The scaling-up approach, with limited power-density losses, was achieved by maintaining a plurality of microenvironments within the module, and resulted in a simple and robust system fuelled by urine. This scaling-up approach, within the tested range, was successful in converting chemical energy in urine into electricity.
Partially submerged cathodes, Scaling-up, Ammonium abstraction, Microbial fuel cell stack, Bioenergy
Walter, Xavier Alexis
67c83b61-76af-4e37-aec8-79ebc723b807
Gajda, Iwona
943dd6bd-524b-4c7b-b794-dec5ee8014b7
Forbes, Samuel
fe8d0dbd-5af5-450f-a94f-f87c010cd3bd
Winfield, Jonathan
e81f4fad-1433-4c6a-9723-24a14f172896
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
10 May 2016
Walter, Xavier Alexis
67c83b61-76af-4e37-aec8-79ebc723b807
Gajda, Iwona
943dd6bd-524b-4c7b-b794-dec5ee8014b7
Forbes, Samuel
fe8d0dbd-5af5-450f-a94f-f87c010cd3bd
Winfield, Jonathan
e81f4fad-1433-4c6a-9723-24a14f172896
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Walter, Xavier Alexis, Gajda, Iwona, Forbes, Samuel, Winfield, Jonathan, Greenman, John and Ieropoulos, Ioannis
(2016)
Scaling-up of a novel, simplified MFC stack based on a self-stratifying urine column.
Biotechnology for Biofuels, 9, [93].
(doi:10.1186/s13068-016-0504-3).
Abstract
Background
The microbial fuel cell (MFC) is a technology in which microorganisms employ an electrode (anode) as a solid electron acceptor for anaerobic respiration. This results in direct transformation of chemical energy into electrical energy, which in essence, renders organic wastewater into fuel. Amongst the various types of organic waste, urine is particularly interesting since it is the source of 75 % of the nitrogen present in domestic wastewater despite only accounting for 1 % of the total volume. However, there is a persistent problem for efficient MFC scale-up, since the higher the surface area of electrode to volume ratio, the higher the volumetric power density. Hence, to reach usable power levels for practical applications, a plurality of MFC units could be connected together to produce higher voltage and current outputs; this can be done by combinations of series/parallel connections implemented both horizontally and vertically as a stack. This plurality implies that the units have a simple design for the whole system to be cost-effective. The goal of this work was to address the built configuration of these multiple MFCs into stacks used for treating human urine.
Results
We report a novel, membraneless stack design using ceramic plates, with fully submerged anodes and partially submerged cathodes in the same urine solution. The cathodes covered the top of each ceramic plate whilst the anodes, were on the lower half of each plate, and this would constitute a module. The MFC elements within each module (anode, ceramic, and cathode) were connected in parallel, and the different modules connected in series. This allowed for the self-stratification of the collective environment (urine column) under the natural activity of the microbial consortia thriving in the system. Two different module sizes were investigated, where one module (or box) had a footprint of 900 mL and a larger module (or box) had a footprint of 5000 mL. This scaling-up increased power but did not negatively affect power density (≈12 W/m3), a factor that has proven to be an obstacle in previous studies.
Conclusion
The scaling-up approach, with limited power-density losses, was achieved by maintaining a plurality of microenvironments within the module, and resulted in a simple and robust system fuelled by urine. This scaling-up approach, within the tested range, was successful in converting chemical energy in urine into electricity.
Text
s13068-016-0504-3
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More information
Published date: 10 May 2016
Keywords:
Partially submerged cathodes, Scaling-up, Ammonium abstraction, Microbial fuel cell stack, Bioenergy
Identifiers
Local EPrints ID: 454068
URI: http://eprints.soton.ac.uk/id/eprint/454068
ISSN: 1754-6834
PURE UUID: 5540bf4d-acb7-4c3e-b2c1-fdf5ad000b97
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Date deposited: 27 Jan 2022 19:24
Last modified: 17 Mar 2024 04:10
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Contributors
Author:
Xavier Alexis Walter
Author:
Iwona Gajda
Author:
Samuel Forbes
Author:
Jonathan Winfield
Author:
John Greenman
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