	US 12,221,370 B2
	Device and method for enhancing nitrogen and phosphorus removal based on multistage AO partial denitrification coupled with anammox in combination with sludge hydrolytic acidification
Yongzhen Peng, Beijing (CN); Qi Zhao, Beijing (CN); Ruitao Gao, Beijing (CN); Jianwei Li, Beijing (CN); and Liyan Deng, Beijing (CN)
Assigned to Beijing University of Technology, Beijing (CN)
Appl. No. 17/642,146
Filed by Beijing University of Technology, Beijing (CN)
PCT Filed Jul. 21, 2021, PCT No. PCT/CN2021/107609 § 371(c)(1), (2) Date Mar. 10, 2022, PCT Pub. No. WO2022/121321, PCT Pub. Date Jun. 16, 2022.
Claims priority of application No. 202011460641.7 (CN), filed on Dec. 12, 2020.
Prior Publication US 2024/0067546 A1, Feb. 29, 2024
Int. Cl. C02F 3/00 (2023.01); C02F 3/30 (2023.01); C02F 3/34 (2023.01); C02F 11/04 (2006.01); C02F 101/10 (2006.01); C02F 101/16 (2006.01)

CPC C02F 3/308 (2013.01) [C02F 3/006 (2013.01); C02F 3/305 (2013.01); C02F 3/307 (2013.01); C02F 3/341 (2013.01); C02F 11/04 (2013.01); C02F 2101/105 (2013.01); C02F 2101/163 (2013.01); C02F 2101/166 (2013.01); C02F 2203/006 (2013.01); C02F 2209/10 (2013.01); C02F 2209/22 (2013.01); C02F 2209/40 (2013.01)]

1 Claim

1. A method for enhancing nitrogen and phosphorus removal based on a multistage AO partial denitrification coupled with an Anammox process in combination with a sludge hydrolytic acidification mixture, comprising the following steps:

adding excess sludge in a secondary sedimentation tank of a municipal wastewater treatment plant (WWTPs) into a biochemical reaction zone as seed sludge, a ratio of water inlet volumes of a first anaerobic zone to a second anoxic zone to a third anoxic zone of a reactor being 4:3:3;

controlling a reflux ratio of the excess sludge to a sludge hydrolytic acidification mixed liquid to be 100%-150%, the excess sludge and the sludge hydrolytic acidification liquid synchronously flowing back to the anaerobic zone, and maintaining mixed liquid suspended solids (MLSS) in the reactor to be 4000-5000 mg/L;

at a start stage of a hydrolytic acidification tank, adding a carbon source into a raw water tank, controlling a C/N ratio of raw water within the raw water tank to be 3-5, and stopping adding of the carbon source after starting of the sludge hydrolytic acidification tank is completed;

monitoring dissolved oxygen (DO) of a first aerobic zone, a second aerobic zone and a third aerobic zone of the reactor through a real-time monitoring system, controlling DO of the first aerobic zone to be 1-1.5 mg/L, and controlling DO of the second aerobic zone and the third aerobic zone to be 2-3 mg/L;

adjusting hydraulic retention time (HRT) by controlling flow of raw water from the anaerobic zone, the second anoxic zone and the third anoxic zone into the biochemical reaction zone, so as to maintain the HRT of the biochemical reaction zone at 12-14 h and at a ratio of anaerobic zone HRT:anoxic zones HRT:aerobic zones HRT=1:3:3;

by controlling a direct sludge discharging amount of the excess sludge in the secondary sedimentation tank, maintaining sludge retention time in the biochemical reaction zone to be 13-15 days; and

controlling a submersible mixing speed to make the biofilm carrier and active sludge in the anaerobic zone and a first anoxic zone, the second anoxic zone and the third anoxic zone mix evenly and fully contact each other.