TY - JOUR
T1 - Biodegradability and denitrification potential of settleable chemical oxygen demand in domestic wastewater
AU - Tas, Didem Okutman
AU - Karahan, Özlem
AU - Insel, Güçlü
AU - Övez, Süleyman
AU - Orhon, Derin
AU - Spanjers, Henri
PY - 2009
Y1 - 2009
N2 - The effect of settling on mass balance and biodegradation characteristics of domestic wastewater and on denitrification potential was studied primarily using model calibration and evaluation of oxygen uptake rate profiles. Raw domestic wastewater was settled for a period of 30 minutes and a period of 2 hours to assess the effect of primary settling on wastewater characterization and composition. Mass balances in the system were made to evaluate the effect of primary settling on major parameters. Primary settling of the selected raw wastewater for 2 hours resulted in the removal of 32% chemical oxygen demand (COD), 9% total Kjeldahl nitrogen, 9% total phosphorus, and 47% total suspended solids. Respirometric analysis identified COD removed by settling as a new COD fraction, namely settleable slowly biodegradable COD (XSS), characterized by a hydrolysis rate of 1.0 day-1 and a hydrolysis half-saturation coefficient of 0.08. A model simulation to test the fate and availability of suspended (XS) and settleable (XSS) COD fractions as carbon sources for denitrification showed that both particulate COD components were effectively removed aerobically at sludge ages higher than 1.5 to 2.0 days. Under anoxic conditions, the biodegradation of both COD fractions was reduced, especially below an anoxic sludge retention time of 3.0 days. Consequently, modeling results revealed that the settleable COD removed by primary settling could represent up to approximately 40% of the total denitrification potential of the system, depending on the specific configuration selected for the nitrogen removal process. This way, the results showed the significant effect of primary settling on denitrification, indicating that the settleable COD fraction could contribute an additional carbon source in systems where the denitrification potential associated with the influent becomes rate-limiting for the denitrification efficiency.
AB - The effect of settling on mass balance and biodegradation characteristics of domestic wastewater and on denitrification potential was studied primarily using model calibration and evaluation of oxygen uptake rate profiles. Raw domestic wastewater was settled for a period of 30 minutes and a period of 2 hours to assess the effect of primary settling on wastewater characterization and composition. Mass balances in the system were made to evaluate the effect of primary settling on major parameters. Primary settling of the selected raw wastewater for 2 hours resulted in the removal of 32% chemical oxygen demand (COD), 9% total Kjeldahl nitrogen, 9% total phosphorus, and 47% total suspended solids. Respirometric analysis identified COD removed by settling as a new COD fraction, namely settleable slowly biodegradable COD (XSS), characterized by a hydrolysis rate of 1.0 day-1 and a hydrolysis half-saturation coefficient of 0.08. A model simulation to test the fate and availability of suspended (XS) and settleable (XSS) COD fractions as carbon sources for denitrification showed that both particulate COD components were effectively removed aerobically at sludge ages higher than 1.5 to 2.0 days. Under anoxic conditions, the biodegradation of both COD fractions was reduced, especially below an anoxic sludge retention time of 3.0 days. Consequently, modeling results revealed that the settleable COD removed by primary settling could represent up to approximately 40% of the total denitrification potential of the system, depending on the specific configuration selected for the nitrogen removal process. This way, the results showed the significant effect of primary settling on denitrification, indicating that the settleable COD fraction could contribute an additional carbon source in systems where the denitrification potential associated with the influent becomes rate-limiting for the denitrification efficiency.
KW - Biodegradation
KW - Chemical oxygen demand fractions
KW - Denitrification potential
KW - Domestic wastewater
KW - Primary settling
KW - Respirometric modeling
KW - Settleable chemical oxygen demand
UR - http://www.scopus.com/inward/record.url?scp=73349129063&partnerID=8YFLogxK
U2 - 10.2175/106143009X425942
DO - 10.2175/106143009X425942
M3 - Article
C2 - 19691253
AN - SCOPUS:73349129063
SN - 1061-4303
VL - 81
SP - 715
EP - 727
JO - Water Environment Research
JF - Water Environment Research
IS - 7
ER -