Long Term Feasibility Study of In-field Floating Microbial Fuel Cells for Monitoring Anoxic Wastewater and Energy Harvesting
Long Term Feasibility Study of In-field Floating Microbial Fuel Cells for Monitoring Anoxic Wastewater and Energy Harvesting
In the present work different prototypes of floating MFCs have been tested in anoxic water environments of wastewater plants in Italy, over a period of 3 years. Several configurations of horizontal (flat) and vertical (tubular) MFCs were assembled, using low-cost and light-weight materials, such as plastic lunch boxes, polystyrene or wood to keep the systems afloat, and ceramics for the MFCs. Untreated carbon cloth or veil was used for both anode and cathode electrodes. Felt (flat MFCs) or clay (tubular MFCs) was used as the cation-exchange separator. Single flat MFCs generated power up to 12 mW/m2 while a 32 cylindrical MFC stack generated up to 18 mW/m2. The testing lasted for more than 2 years and there was no inoculation other than exposing the MFCs to the denitrification environment. The cathodes of the flat MFCs were spontaneously colonized by algae and plants, and this did not affect the stability of the systems. Natural light increased the power output of the flat MFCs which were smaller than 50 × 50 cm. Diurnal oscillation of temperature and periodic water flow did not significantly affect the performance of the MFCs. The largest flat MFC produced the highest absolute power, although in a disrupted way. A new, simple low-energy remote monitoring system, based on LoRa technology was used for data transmission over distances of >500 m. This is a piece of hardware that could potentially be suitable for remote monitoring as part of a network, as it can be directly powered by the deployed MFCs.
floating microbial fuel cells, wastewaters monitoring, low-energy remote data transmission, in-field MFC tests, anossic wastewater, long term field operation
Cristiani, Pierangela
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Gajda, Iwona
943dd6bd-524b-4c7b-b794-dec5ee8014b7
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Pizza, Francesca
83ad0233-c40c-4ded-9368-6e7c495faa0d
Bonelli, Paolo
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Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
1 November 2019
Cristiani, Pierangela
3cb7a0bc-6dd3-4514-ad96-60dc3578ce80
Gajda, Iwona
943dd6bd-524b-4c7b-b794-dec5ee8014b7
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Pizza, Francesca
83ad0233-c40c-4ded-9368-6e7c495faa0d
Bonelli, Paolo
d7c180f8-247f-4729-b784-bed0259ed804
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Cristiani, Pierangela, Gajda, Iwona, Greenman, John, Pizza, Francesca, Bonelli, Paolo and Ieropoulos, Ioannis
(2019)
Long Term Feasibility Study of In-field Floating Microbial Fuel Cells for Monitoring Anoxic Wastewater and Energy Harvesting.
Frontiers in Energy Research, 7.
(doi:10.3389/fenrg.2019.00119).
Abstract
In the present work different prototypes of floating MFCs have been tested in anoxic water environments of wastewater plants in Italy, over a period of 3 years. Several configurations of horizontal (flat) and vertical (tubular) MFCs were assembled, using low-cost and light-weight materials, such as plastic lunch boxes, polystyrene or wood to keep the systems afloat, and ceramics for the MFCs. Untreated carbon cloth or veil was used for both anode and cathode electrodes. Felt (flat MFCs) or clay (tubular MFCs) was used as the cation-exchange separator. Single flat MFCs generated power up to 12 mW/m2 while a 32 cylindrical MFC stack generated up to 18 mW/m2. The testing lasted for more than 2 years and there was no inoculation other than exposing the MFCs to the denitrification environment. The cathodes of the flat MFCs were spontaneously colonized by algae and plants, and this did not affect the stability of the systems. Natural light increased the power output of the flat MFCs which were smaller than 50 × 50 cm. Diurnal oscillation of temperature and periodic water flow did not significantly affect the performance of the MFCs. The largest flat MFC produced the highest absolute power, although in a disrupted way. A new, simple low-energy remote monitoring system, based on LoRa technology was used for data transmission over distances of >500 m. This is a piece of hardware that could potentially be suitable for remote monitoring as part of a network, as it can be directly powered by the deployed MFCs.
Text
fenrg-07-00094
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Published date: 1 November 2019
Keywords:
floating microbial fuel cells, wastewaters monitoring, low-energy remote data transmission, in-field MFC tests, anossic wastewater, long term field operation
Identifiers
Local EPrints ID: 456215
URI: http://eprints.soton.ac.uk/id/eprint/456215
ISSN: 2296-598X
PURE UUID: 852adcc9-df1a-4f67-bc0b-f5b543138e9f
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Date deposited: 26 Apr 2022 17:49
Last modified: 17 Mar 2024 04:10
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Contributors
Author:
Pierangela Cristiani
Author:
Iwona Gajda
Author:
John Greenman
Author:
Francesca Pizza
Author:
Paolo Bonelli
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