Abstract
Here, a 12-liter tubular microbial electrolysis cell (MEC) was developed as a post treatment unit for simultaneous biogas upgrading and ammonium recovery from the liquid effluent of an anaerobic digestion process. The MEC configuration adopted a cation exchange membrane to separate the inner anodic chamber and the external cathodic chamber, which were filled with graphite granules. The cathodic chamber performed the CO2 removal through the bioelectromethanogenesis reaction and alkalinity generation while the anodic oxidation of a synthetic fermentate partially sustained the energy demand of the process. Three different nitrogen load rates (73, 365, and 2229 mg N/Ld) were applied to the inner anodic chamber to test the performances of the whole process in terms of COD (Chemical Oxygen Demand) removal, CO2 removal, and nitrogen recovery. By maintaining the organic load rate at 2.55 g COD/Ld and the anodic chamber polarization at +0.2 V vs. SHE (Standard Hydrogen Electrode), the increase of the nitrogen load rate promoted the ammonium migration and recovery, i.e., the percentage of current counterbalanced by the ammonium migration increased from 1% to 100% by increasing the nitrogen load rate by 30-fold. The CO2 removal slightly increased during the three periods, and permitted the removal of 65% of the influent CO2, which corresponded to an average removal of 2.2 g CO2/Ld. During the operation with the higher nitrogen load rate, the MEC energy consumption, which was simultaneously used for the different operations, was lower than the selected benchmark technologies, i.e., 0.47 kW/N·m3 for CO2 removal and 0.88 kW·h/kg COD for COD oxidation were consumed by the MEC while the ammonium nitrogen recovery consumed 2.3 kW·h/kg N.
Highlights
Biogas, the main product of the anaerobic digestion (AD) process, is a gas mixture mainly composed of carbon dioxide and methane [1,2]
The interphase constituted by an electroactive biofilm on an electrode can be named a bioelectrode [19]; in more detail, when the electroactive biofilm uses the electrode as an electron acceptor, the electrochemical interphase acts as a bioanode [20]; on the contrary, if the electroactive biofilm uses the electrode as an electron donor, the interphase is defined as a biocathode [21]
The experimental study demonstrated the feasibility of the bioelectrochemical process for nitrogen recovery and simultaneous chemical oxygen demand (COD) and CO2 removal with the utilization of a 12-L tubular geometry microbial electrolysis cell (MEC)
Summary
The main product of the anaerobic digestion (AD) process, is a gas mixture mainly composed of carbon dioxide and methane [1,2]. To obtain biomethane with a high percentage of methane (>95%), an upgrading operation to increase the CH4 content through CO2 removal and a purification step aimed at impurity removal (NH3 , H2 S) are necessary to increase the gas mixture calorific power [3,4,5]. Along the different hydrogen supply techniques, which includes in situ [15] and ex situ approaches [16], the use of bioelectrochemical systems to supply the reducing power resulted in a more sustainable approach due to the utilization of mild reaction condition as well as the use of a robust and low-cost catalytic material widely present in the AD processes [17]. Biocathode utilization has been investigated for several environmental applications, which includes biofuel production [24,25], CO2 fixation into VFA
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