Issue 2, 2017

Maximizing Coulombic recovery and solids reduction from primary sludge by controlling retention time and pH in a flat-plate microbial electrolysis cell

Abstract

Anaerobic digestion (AD) is a mature anaerobic biotechnology that plays a significant role in wastewater treatment in terms of solids reduction and energy recovery as methane. An alternative anaerobic platform, the microbial electrochemical cell (MXC), has shown similar results to AD in terms of solids reduction, but electron recovery as electrical current has been poor, in large part because of undesired production of methane. The aim of this study was to maximize Coulombic recovery (CR) and minimize methanogenesis by controlling the anode hydraulic retention time (HRT) and pH in a flat-plate microbial electrolysis cell (MEC) fed semi-continuously with primary sludge (PS). Although the PS-fed MEC had ∼60% solids reduction for all HRTs tested (6 to 15 days), the HRT had a strong impact on current density and CR. The maximum current density was >2 A m−2 for 6 and 9 day HRTs, while CR was the highest (34%) for a 9 day HRT. A relatively high pH (∼8.1) in the anode chamber also led to an increase in CR by suppressing methanogenesis. Being the first report of long-term MEC operation with PS, this study demonstrates that CR and sludge treatment can be improved by increasing pH and decreasing HRT in a flat-plate MEC.

Graphical abstract: Maximizing Coulombic recovery and solids reduction from primary sludge by controlling retention time and pH in a flat-plate microbial electrolysis cell

Supplementary files

Article information

Article type
Paper
Submitted
02 Nov 2016
Accepted
20 Dec 2016
First published
03 Jan 2017

Environ. Sci.: Water Res. Technol., 2017,3, 333-339

Maximizing Coulombic recovery and solids reduction from primary sludge by controlling retention time and pH in a flat-plate microbial electrolysis cell

D. Ki, P. Parameswaran, S. C. Popat, B. E. Rittmann and C. I. Torres, Environ. Sci.: Water Res. Technol., 2017, 3, 333 DOI: 10.1039/C6EW00305B

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