From single MFC to cascade configuration: The relationship between size, hydraulic retention time and power density

Walter, X. A., Forbes, S., Greenman, J. and Ieropoulos, I. (2016) From single MFC to cascade configuration: The relationship between size, hydraulic retention time and power density. Sustainable Energy Technologies and Assessments, 14. pp. 74-79. ISSN 2213-1388 Available from: http://eprints.uwe.ac.uk/27878

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Publisher's URL: http://dx.doi.org/10.1016/j.seta.2016.01.006

Abstract/Description

Achieving useful electrical power production with MFC technology requires a plurality of units. Therefore, the main objective of a large part of MFC research is to increase the power density of each unit. Collectives of MFCs will inherently include units grouped in cascades, whereby the outflow of one is the inflow to the next unit; such an approach allows for better fuel utilisation. However, such a configuration is subject to some important considerations, including: the size of the MFCs; the number of units i.e. the length of the cascade; hydraulic retention time; fuel quality; and optimisation of anode surface and microbial colonisation. In the present study, optimisation of the aforementioned aspects has been investigated in order to establish the most appropriate cascade design. Results demonstrate that an increased flow rate of treated urine achieved equal power density with the same setup when fed with fresh urine at a lower flow rate. The independent investigations of these parameters have led to the design of a cascade that maintains uniformity with regard to the aforementioned parameters, by incorporating units of decreasing size, thus allowing locally shorter hydraulic retention times and therefore leading to increased power density levels.

Item Type:Article
Uncontrolled Keywords:microbial fuel cell, ceramic membrane, continuous flow, urine, cascade stacks
Faculty/Department:Faculty of Environment and Technology
ID Code:27878
Deposited By: Dr X. Walter
Deposited On:18 Jan 2016 14:30
Last Modified:12 Mar 2017 03:40

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