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1. A method for removing antibiotic resistance genes (ARGs), the method comprising the following steps:
1) coagulation and sedimentation
introducing waste water into a coagulation and sedimentation tank; coagulating and depositing the waste water using polyaluminumchloride (PAC) as a flocculate and polyacrylamide (PAM) as a coagulant, a dosage of the flocculate being 3-5 mg per liter of the waste water, and a dosage of the coagulant being 1-3 mg per liter of the waste water; and introducing a supernatant after deposition into a sand filter for further lowering a water turbidity; 2) biochemical treatment
conducting an anaerobic-anoxic-oxic (A2/O) activated sludge process to remove nitrogen and phosphorus from the waste water after sand filtering in step 1) and to lower a chemical oxygen demand (COD); and introducing the water into a secondary sedimentation tank for slurry separation; 3) disinfection by peracetic acid
pumping the waste water after the biochemical treatment from the secondary sedimentation tank into a sterilization tower; and disinfecting the water using peracetic acid for 10 min, a dosage of peracetic acid being 80-100 mg/L, and a preparation of peracetic acid comprising the following steps: inputting glacial acetic acid into a barrel, mixing glacial acetic acid with 2% of sulfuric acid; adding 30% of hydrogen peroxide, a dosage ratio between hydrogen peroxide and glacial acetic acid being 1:2, and adding 1 g/L of phosphoric acid having a concentration of 0.1% as a stabilizer to form peracetic acid; and preserving peracetic acid at a room temperature for 2 days; 4) sterilization by high pressure CO2 injecting CO2 gas having a pressure of 0.5-1.5 mPa into the sterilization tower, and maintaining the high pressure CO2 to sterilize for 5-10 min, the CO2 gas being output from a high pressure CO2 cylinder, passing through a pressure reducing valve and a high pressure pipeline, and finally into the sterilization tower from microporous aeration tubes arranged at a bottom of the sterilization tower; 5) photocatalysis by nano-titanium dioxide (TiO2)
introducing the water after the sterilization into a nano-TiO2 photocatalytic oxidation pool, and tilting a plurality of three-layered nano-TiO2 meshes for 30° in the sedimentation tank to oxidize, decompose, degrade, and remove resistant genes from the waste water under daylight or ultraviolet irradiation, the photocatalytic oxidation pool being provided with a spherical nano-TiO2 suspension filler comprising a nuclear body and a coating; a nano-TiO2 coating being coated on the nuclear body; the nuclear body being made of a polyethylene material by one step injection molding; a radius of the nuclear body being between 3 and 10 cm; the coating being formed by dip coating TiO2 powder having a grain size of not exceeding 100 nm; a thickness of the coating being between 0.05 and 0.45 mm; and a gravity of the spherical nano-TiO2 suspension filler being 95-99.8% of a gravity of water; and the nano-TiO2 mesh being formed by coating a layer of nano-TiO2 onto a stainless steel mesh; and 6) depositing the water for 1 h after step 5), finely filtering the water to remove impurities. |
