TY - JOUR
T1 - Kinetic and stoichiometric characterization of a fixed biofilm reactor by pulse respirometry
AU - Ordaz, Alberto
AU - Oliveira, Catarina S.
AU - Quijano, Guillermo
AU - Ferreira, Eugenio C.
AU - Alves, Madalena
AU - Thalasso, Frédéric
N1 - Funding Information:
This work has been supported by “Consejo Nacional de Ciencia y Tecnología”, Mexico (proyect 59872). We gratefully acknowledge the financial support to Alberto Ordaz and Guillermo Quijano through Grants #208321 and #164283 , respectively, from “Consejo Nacional de Ciencia y Tecnología”, Mexico . We also acknowledge “Fundação para a Ciência e a Tecnologia”, Portugal , for the financial support to Catarina S. Oliveira (Grant SFRH/BD/32289/2006 ).
Copyright:
Copyright 2012 Elsevier B.V., All rights reserved.
PY - 2012/1
Y1 - 2012/1
N2 - An in situ respirometric technique was applied to a sequential biofilm batch reactor treating a synthetic wastewater containing acetate. In this reactor, inoculated with mixed liquor from a wastewater plant, unglazed ceramic tiles were used as support media while maintaining complete mixing regime. A total of 8 kinetic and stoichiometric parameters were determined by in situ pulse respirometry; namely substrate oxidation yield, biomass growth yield, storage yield, storage growth yield, substrate affinity constant, storage affinity constant, storage kinetic constant and maximum oxygen uptake rate. Additionally, biofilm growth was determined from support media sampling showing that the colonization process occurred during the first 40days, reaching an apparent steady-state afterward. Similarly, most of the stoichiometric and kinetic parameters were changing over time but reached steady values after day 40. During the experiment, the respirometric method allowed to quantify the amount of substrate directed to storage, which was significant, especially at substrate concentration superior to 30mg CODL -1. The Activated Sludge Model 3 (ASM3), which is a model that takes into account substrate storage mechanisms, fitted well experimental data and allowed confirming that feast and famine cycles in SBR favor storage. These results also show that in situ pulse respirometry can be used for fixed-bed reactors characterization.
AB - An in situ respirometric technique was applied to a sequential biofilm batch reactor treating a synthetic wastewater containing acetate. In this reactor, inoculated with mixed liquor from a wastewater plant, unglazed ceramic tiles were used as support media while maintaining complete mixing regime. A total of 8 kinetic and stoichiometric parameters were determined by in situ pulse respirometry; namely substrate oxidation yield, biomass growth yield, storage yield, storage growth yield, substrate affinity constant, storage affinity constant, storage kinetic constant and maximum oxygen uptake rate. Additionally, biofilm growth was determined from support media sampling showing that the colonization process occurred during the first 40days, reaching an apparent steady-state afterward. Similarly, most of the stoichiometric and kinetic parameters were changing over time but reached steady values after day 40. During the experiment, the respirometric method allowed to quantify the amount of substrate directed to storage, which was significant, especially at substrate concentration superior to 30mg CODL -1. The Activated Sludge Model 3 (ASM3), which is a model that takes into account substrate storage mechanisms, fitted well experimental data and allowed confirming that feast and famine cycles in SBR favor storage. These results also show that in situ pulse respirometry can be used for fixed-bed reactors characterization.
KW - Activated sludge
KW - Biofilter
KW - Cellular growth
KW - Fixed-bed
KW - Respirometry
KW - SBR
UR - http://www.scopus.com/inward/record.url?scp=84855250420&partnerID=8YFLogxK
U2 - 10.1016/j.jbiotec.2011.10.015
DO - 10.1016/j.jbiotec.2011.10.015
M3 - Article
C2 - 22100265
AN - SCOPUS:84855250420
SN - 0168-1656
VL - 157
SP - 173
EP - 179
JO - Journal of Biotechnology
JF - Journal of Biotechnology
IS - 1
ER -