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Issue
Korean Journal of Chemical Engineering,
Vol.33, No.1, 14-24, 2016
Evaluation of multiloop chemical dosage control strategies for total phosphorus removal of enhanced biological nutrient removal process
Garikiparthy PSN, Lee SC, Liu H, Kolluri SS, Esfahani IJ, Yoo CK
We developed several control algorithms and compare their control performances for controlling the total phosphorous (TP) concentration in wastewater treatment plant, which has strong influent disturbances and the disturbance effects should be removed while maintaining better effluent quality. An anaerobic . anoxic - oxic (AAO) process, which is a well-known advanced nutrient removal process, was selected as a case study, which is modeled with activated sludge model no. 2. Six control strategies for TP control with a polymer addition were implemented in AAO process and evaluated by the plant’s performance, where the costs of the dosed chemical were compared among the six controllers. The experimental work showed that the advanced control techniques with feedback, feedforward and feedratio controllers were able to control the TP concentration in the effluent, which must be less than 1.50 g P/m3 which is the legal limitation, while reducing the necessary chemical cost. The results showed that the best TP removal performance in the effluent TP removal could be achieved by advanced feedback controller with the tuned control parameters, which showed the best effluent quality and control performance index as well as the cheapest cost of chemical dosage among the six TP control strategies.
Keywords: Activated Sludge Model; Chemical Dosage Control; Eutrophication; Feedforward Control; Multiloop Control; Total Phosphorous (TP)
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[Cited By]
  1. KiM DW, Jacome G, Lee SC, Moya W, Nam Kj, Yoo CY, Korean Journal of Chemical Engineering, 34(12), 3054, 2017
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