Abstract
BACKGROUND: This study evaluated the microbial behavior of activated sludge systems operated with an active heterotrophic biomass inflow. The evaluation focused on the possibility of sludge minimization. Thus, related process stoichiometry was derived on the basis of mass balance for essential parameters. RESULTS: Stoichiometric relationships showed that the reactor holds a larger amount of biomass without the controlling impact of the sludge age, which decreases the magnitude of microbial growth compared with endogenous decay. Consequently, the observed yield, YOBS becomes much lower than what may be observed in conventional activated sludge systems. This stoichiometry exactly defines the microbial basis of the OSA (oxic/settling/anaerobic) system and identifies the interchange stream connecting the anaerobic reactor to the aerobic main reactor as the source of the active biomass inflow. Therefore, biomass inflow, largely overlooked in related studies, offers a novel microbial perspective for the merit of the OSA process in minimizing sludge generation. CONCLUSION: The impact of lower YOBS, while explaining lower active biomass production, cannot be extrapolated to cover inert particulate COD fractions, namely a similar reduction in the initial inert COD and the residual particulate microbial products. Future studies should be directed to explore the fate of residual particulate compounds.
Original language | English |
---|---|
Pages (from-to) | 406-412 |
Number of pages | 7 |
Journal | Journal of Chemical Technology and Biotechnology |
Volume | 93 |
Issue number | 2 |
DOIs | |
Publication status | Published - Feb 2018 |
Bibliographical note
Publisher Copyright:© 2017 Society of Chemical Industry
Keywords
- activated sludge
- biomass
- process control
- sludge
- waste treatment and waste minimization