Presentation1.pdf

Abstract

Biogas production from manure is of particular value in regard of lowering greenhouse gas emissions and enhance nutrient re-circulation. However, the relatively low energy content and the characteristics of manure often result in low degradation efficiency and development of operating strategies are required to improve the biogas yield and the economic benefits. In this study, the potential to enhance the performance in two full-scale biogas plants operating with cattle manure, in mono-digestion or combined with poultry manure, were investigated. Four continuously-fed laboratory-scale reactors were operated in sets of two, in which one reactor in each set was increased from 37-42°C to 52°C. The potential to increase the capacity was thereafter assessed by increasing the organic loading rate (OLR), from ca 3 to 5 kg VS m3/day. The processes were evaluated with both chemical and microbiological parameters and in addition the residual methane potential (RMP) was measured to evaluate the risk of increased methane emissions from digestate. The results showed that both processes could be changed from mesophilic to themophilic temperature without major problems and with a similar shift in the microbial community profile to a typical thermophilic community e.g. an increase in the relative abundance of the phylum Firmicutes. However, the temperature increase in the reactor co-digesting cattle and poultry manure caused slight accumulation of fatty acids ( 2 g/L) and reduced the specific methane production, most likely due to ammonia inhibition (0.4-0.7 g NH3/L). Still, during operation at higher OLR, thermophilic as compared to mesophilic temperature slightly increased the methane yield and specific methane production, in both investigated processes. However, the higher OLR decreased the overall degree of degradation in all processes and this showed a positive correlation with increased RMP values. Chemical analyses suggested that high RMP values (40-98 Nml gVS-1) was related to the degradation of cellulose, hemicellulose and volatile fatty acid enriched in the digestate. Conclusively, increased temperature and load can increase the methane yield from manure but can result in less efficient degradation and increased risks for methane emissions during storage and handling of the digestate.