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Abstract
A pilot-scale municipal wastewater treatment plant composed of a fixed film activated sludge (IFAS) system with sulfur–limestone autotrophic denitrification (SLAD) was operated for a year and the influence of different operational factors was investigated. Nitrification efficiency was found to be above 91% at temperatures above 25°C even at short hydraulic residence times (HRTs), but declined to 51±2% when the temperature dropped to 22±3°C. The minimum HRT (HRTmin) to achieve nitrification efficiency>90% was found to be 12 h at temperatures above 25°C. Denitrification efficiencies were found to be 89% and 79% at a nitrate loading of 0.36 kg NO-N m−3 d−1 and at 0.18 kg NO
-N m−3 d−1, respectively. The minimum empty bed residence time (EBRT) to achieve denitrification efficiency above 80% without methanol addition was 3 h at a nitrate loading rate of 0.27–0.38 kg NO
-N m−3 d−1. The amount of nitrate removed as a function of the sulfate formed was found to be 0.188 g NO
-N/g SO
. The nitrate load removed by the biofilter as a function of the alkalinity consumed was found to be very close to the theoretical stoichiometric value. The application of the pilot plant was proven to be feasible and the performance of the SLAD system, especially with respect to the minimum EBRT to achieve denitrification efficiency above 80%, the maximum denitrification rate and performance at temperatures below 10°C. To achieve a nitrification efficiency above 90% in the IFAS system, temperature changes and the minimum HRT were found to be the most influential operational parameters.
Acknowledgements
This work was supported by the National Research Foundation of Korea Grant funded by the Korean Government [NRF-2009-351-D00069] and by the Research Institute of Agricultural Sciences at KNU.