2.3.10. Two stage anaerobic digesti

2.3.10. Two stage anaerobic digestion
Song et al. [56] used two stage anaerobic digestion of sewage sludge. While there is an additional energy requirement required to operate a two stage digester, the advantages of the system is the higher reduction of volatile solids, and increased methane production compared to single stage mesophilic or thermophilic digesters. Likewise the pathogen reduction was similar in the two stage system. More recently Dareioti [57], Sakar et al. [58]; Kara et al. [59]; Parawira et al. [60]; Nishio and Nakashimada [61]; Perez-Elvira et al. [62]; Alatriste-Mondragon et al. [63] and Ke ShuiZhou et al. [64] have reported on the role of and variations to approaches in two stage anaerobic digestion in treating a range of organic wastes. Kumar [49] used two stage anaerobic digestion on piggery effluent. The first stage involved the hydrolytic and acidogenic process and the second stage involved the methanogenic process. The two-stage anaerobic digestion system was configured such that the thermophilic acidification reactors operated with 7 days of hydraulic retention time at 55–70 °C while the mesophilic digesters operated with 22 days of hydraulic retention at ambient temperature. There was a low degree of acidification in the first stage due to the low organic content of the raw piggery effluent which allowed the methanogens to establish and generate methane (>40% methane composition). This was not the desired function of the first-stage reactors, as the majority of methane needs to be generated in the second-stage (methanogenic). Increasing the organic load of the raw piggery effluent was found to be necessary to produce a higher level of volatile fatty acids in the first stage or by adjusting the pH of the effluent by addition of acids.
Kumar [49] reported that increasing digestion temperature from 55–70 C reduced pathogen survival in an exponential pattern with concomitant die-off at longer hydraulic retention time. The pathogens, Clostridium perfringens and Campylobacter jejuni, survived thermophilic digestion at 50 C. At the lower thermophilic temperatures, larger numbers of Clostridium perfringens were found in the mesophilic stage. Other strategies to reduce pathogen survival include aeration, free ammonia, biological control (Tetrahymena spp.) and peractic acid. Free ammonia levels reduced the survival of these pathogens, but it is not clear if the solubilisation would also be reduced if free ammonia levels were manipulated artificially. Peracetic acid, as a strong oxidising agent, effectively reduced the number of these pathogens at very low concentrations.