10.1007/s40095-015-0169-x

Performance of pilot-scale microbial fuel cells treating wastewater with associated bioenergy production in the Caribbean context

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  • Kiran Tota-Maharaj1,
  • Parneet Paul*2,
  1. Department of Engineering Science, Faculty of Engineering and Science, University of Greenwich, Kent, ME4 4TB, GB
  2. Department of Mechanical, Aerospace, and Civil Engineering, Water Sustainability Research Centre, Brunel University London, Middlesex, UB8 3PH, GB
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Published in Issue 2015-03-19

How to Cite

Tota-Maharaj, K., & Paul, P. (2015). Performance of pilot-scale microbial fuel cells treating wastewater with associated bioenergy production in the Caribbean context. International Journal of Energy and Environmental Engineering, 6(3 (September 2015). https://doi.org/10.1007/s40095-015-0169-x
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Abstract

Abstract Microbial fuel cell (MFC) technology represents a form of renewable energy that generates bioelectricity from what would otherwise be considered a waste stream. MFCs may be ideally suited to the small island developing state (SIDS) context, such as Trinidad and Tobago where seawater as the main electrolyte is readily available, and economically renewable and sustainable electricity is also deemed a priority. Hence this project tested two identical laboratory-scaled MFC systems that were specifically designed and developed for the Caribbean regional context. They consisted of two separate chambers: an anaerobic anodic chamber inoculated with wastewater and an aerobic cathodic chamber separated by a proton exchange membrane. Domestic wastewater from two various wastewater treatment plants inflow (after screening) was placed into the anodic chamber, and seawater from the Atlantic Ocean and Gulf of Paria placed into the cathodic chambers, respectively, with the bacteria present in the wastewater attached to the anode. Experimental results demonstrated that the bacterial degradation of the wastewaters as substrate induced an electron flow through the electrodes producing bioelectricity whilst simultaneously reducing the organic matter as biochemical oxygen demand and chemical oxygen demand by 30 to 75 %. The average bioenergy output for both systems was 84 and 96 mW/m 2 , respectively. This study demonstrated the potential for simultaneous bioenergy production and wastewater treatment in the SIDS context.

Keywords

  • Wastewater,
  • Treatment,
  • Bioenergy,
  • Bioelectricity,
  • Microbial fuel cell (MFC),
  • Small island developing state (SIDS)
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