The anaerobic reduction of azo dye Acid Orange 7 (AO7) was investigated in a continuous upflow packed-bed reactor (UPBR) containing biological activated carbon (BAC). Preliminary batch experiments using graphite
proved the catalytic effect of using a solid electron mediator in the reactor. Before the start of continuous
experiments, AO7 adsorption studies were done to control adsorption effects on initial decolorization rates.
In a continuous UPBR-BAC system, high azo dye conversion rates were achieved during very short space
times (τ) up to 99% in 2.0 min. In order to know which are the crucial and most influencing properties of
BAC in AO7 reduction, other materialsgraphite and aluminawith different properties were also tested in
UPBRs. The results show that both electron-mediating capability and specific surface area of activated carbon
contribute to higher reduction rates. Compared to other continuous and biological processes treating azo
dyes, UPBR-BAC seems to be a very effective and promising system for anaerobic azo dye degradation.
Conventional submerged membrane bioreactors (MBRs) rely on the coarse bubbles aeration to generate shear at the liquid-membrane interface to limit membrane fouling. Unfortunately, it is a very energy consuming method, still often resulting in a rapid decrease of membrane permeability and consequently in higher expenses. In this paper, the feasibility of a novel magnetically induced membrane vibration (MMV) system was studied in a lab-scale MBR treating synthetic wastewater. The effects on membrane fouling of applied electrical power of different operation strategies, of membrane flux and of the presence of multiple membranes on one vibrating engine on membrane fouling were investigated. The filtration performance was evaluated by determining the filtration resistance profiles and critical flux. The results showed clear advantages of the vibrating system over conventional MBR processes by ensuring higher fluxes at lower fouling rates. Intermittent vibration was found a promising strategy for both efficient fouling control and significant energy saving. The optimised MMV system is presumed to lead to significant energy and cost reduction in up-scaled MBR operations.
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