Microbial fuel cells for energy self-sufficient domestic wastewater treatment-a review and discussion from energetic consideration

Authors
Lefebvre, OlivierUzabiaga, ArnaudChang, In SeopKim, Byung-HongNg, How Yong
Issue Date
2011-01
Publisher
SPRINGER
Citation
APPLIED MICROBIOLOGY AND BIOTECHNOLOGY, v.89, no.2, pp.259 - 270
Abstract
As the microbial fuel cell (MFC) technology is getting nearer to practical applications such as wastewater treatment, it is crucial to consider the different aspects that will make this technology viable in the future. In this paper, we provide information about the specifications of an energy self-sufficient MFC system as a basis to extrapolate on the potential benefits and limits of a future MFC-based wastewater treatment plant. We particularly emphasize on the importance of two crucial parameters that characterize an MFC: its electromotive force (E (emf)) and its internal resistance (R (int)). A numerical projection using state-of-art values (E (emf) = 0.8 V and R (int) = 5 Omega) emphasized on the difficulty at this moment to reach self-sufficiency using a reasonable number of MFCs at the laboratory scale. We found that a realistic number of MFCs to provide enough voltage (=5 V) at a sufficient current (=0.8 A) to power a pump requiring 4 W would be of 13 MFCs in series and 10 stacks of MFCs in parallel, resulting in a total number of 130 MFCs. That would result in a treatment capacity of 144 L of domestic wastewater (0.5 g-COD L-1) per day. The total MFC system would be characterized by an internal resistance of 6.5 Omega.
Keywords
CATHODIC OXYGEN REDUCTION; CONTINUOUS ELECTRICITY-GENERATION; INSOLUBLE FE(III) OXIDE; ELECTRON-TRANSFER; AIR-CATHODE; POWER-GENERATION; IMPROVED PERFORMANCE; GEOTHRIX-FERMENTANS; ORGANIC-MATTER; BIOFUEL CELLS; CATHODIC OXYGEN REDUCTION; CONTINUOUS ELECTRICITY-GENERATION; INSOLUBLE FE(III) OXIDE; ELECTRON-TRANSFER; AIR-CATHODE; POWER-GENERATION; IMPROVED PERFORMANCE; GEOTHRIX-FERMENTANS; ORGANIC-MATTER; BIOFUEL CELLS; Electromotive force; Internal resistance; Microbial fuel cells; Scalability; Stack configuration
ISSN
0175-7598
URI
https://pubs.kist.re.kr/handle/201004/130804
DOI
10.1007/s00253-010-2881-z
Appears in Collections:
KIST Article > 2011
Files in This Item:
There are no files associated with this item.
Export
RIS (EndNote)
XLS (Excel)
XML

qrcode

Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.

BROWSE