Stable operation of aerobic granular sludge continuous flow system——by controlling reflux ratio and organic load
LI Dong1, YANG Jing-wei1, LI Yue1, ZHANG Jie1,2
1. Key Laboratory of Beijing Water Quality Science and Water Environment Recovery Engineering, Beijing University of Technology, Beijing 100124, China; 2. State Key Laboratory of Urban Water Resource and Environment, Harbin Institute of Technology, Harbin 150090, China
Abstract:Inoculate mature aerobic granular sludge at room temperature in an anaerobic/aerobic alternate continuous flow system composed of independent anaerobic tanks and aerobic tanks, control the effect of mixed liquid reflux ratio and organic load on the removal of COD, TN and TP by anaerobic and aerobic alternating continuous flow process. The results showed that the two-stage continuous flow process can achieve better nitrogen and phosphorus removal performance by adjusting a lower reflux ratio when the influent organic load was low. The average concentration of COD, TN and TP in the effluent was 18.78, 5.79 and 0.49mg/L. The average removal rate was 93.76%, 84.3% and 83.12% respectively; when the organic load was higher, the long-term two-stage continuous flow system lacked the environmental stress of feast and famine, resulting in filamentous bacteria growth, deterioration of system performance. The model was used to characterize the granular sludge and system effluent at different stages. The results showed that the organic load has a greater impact on the production of intermediate products related to the utilization of foreign substrates. The influent with lower organic load could effectively reduce the generation of intermediate products in the effluent. In summary, in the actual secondary urban sewage treatment plant, the anaerobic/aerobic alternating continuous flow process was not suitable for long-term operation under the organic concentration (500mg/L) of the emission limit.
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