SU1765123A1 - Method of sewage purification - Google Patents

Abstract

SUMMARY OF THE INVENTION: Wastewater is mixed with activated sludge, aerating the flow of sludge mixture in the aeration tank is dispersed along the length of the aerotank with alternation due to periodic switching of air supply to the aerated and non-aerated zones, while the sludge mixture is taken from the last aerated zone at the outlet of the air and returned to the non-aerated zone 1 dw., 2 tab.

Description

The invention relates to the field of water treatment and can be used in the biological treatment of industrial and domestic wastewater in aeration tanks.

A known method of wastewater treatment, including mixing them with activated sludge and aerating the stream of sludge mixture in the aeration tank with periodic shutdown of the air supply and its regulation depending on the concentration of dissolved oxygen in the sludge mixture.

The disadvantage of this method is the difficulty of automatically adjusting the air supply depending on the concentration of dissolved oxygen in the sludge mixture, which, when entering the wastewater of unstable composition, reduces the efficiency of the cleaning process.

The closest to the proposed method is wastewater treatment, with activated sludge and aeration of the sludge mixture stream in the aeration tank with periodic shutdown of the air supply. The sludge mixture at the outlet of the stream is taken periodically during

off time and return air dispersed in the stream.

The disadvantage of this method is the low efficiency of the process, due to the impossibility of maintaining homogeneity of the sludge mixture during periods when the air supply is turned off, which requires an increase in the processing time.

The purpose of the invention is to reduce the processing time.

To carry out the process, the wastewater is mixed with activated sludge and fed to the aeration tank. Aeration of the sludge mixture is carried out dispersed along the length of the aerotank, a series of aerated and non-aerated zones. The alternation of zones is carried out by periodically switching the air supply. The intake of the sludge mixture is made at the exit of the aerotank from the zone aerated at the time of the fence, and returned to the zones that are not aerated at the moment.

The drawing shows a diagram of the cleaning process according to the proposed method.

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The initial waste water and circulating activated sludge through pipelines 1 and 2, respectively, enter the nitrogen tank 3, where biochemical oxidation of contaminants occurs. The pipeline 4 in the chamber 5 enters the air. In chamber 5, air ducts 6 or 7 are switched, through which air enters the aerators, respectively, 8 or 9. Aerators 8 and 9, which are not interconnected and staggered in staggered order, divide the aeration tank 3 into independent aeration zones. Due to this, dispersed air supply with alternation of aerated zones is carried out, so that it comes either through aerators 8 or through aerators 9. Changing aeration zones provides intensive stirring up of precipitated sludge flakes and soils and their involvement in the oxidation process, which allows to maintain homogeneity of the sludge mixture throughout the aeration zone and the aero tank as a whole,

At the outlet of the aero tank 3, the sludge mixture is taken, for example, by pump 10. In a preferred embodiment, pump 10 is provided with two suction lines 11 and 12 located in the last two aeration zones and chamber 13 where they are switched. Due to this, the sludge mixture is always taken from the zone where the air enters at the time of the intake through the aerators 8 or 9, which allows maintaining the necessary oxygen regime in the non-aerated zones of the aero-tank,

The aerated sludge mixture through pipelines 14 or 15, which is connected to chamber 16, where they are switched, is returned to the aeration tank 3. Moreover, the mixture is always returned to only those areas where air does not flow at the time of return. Due to this, the recoverable sludge mixture maintains the oxygen regime in non-aerated zones, and also slows down the process of precipitation of silt flakes and contaminations, and prevents separation. Thus, in all zones

Aeration tank 3 is a continuous process for the oxidation of contaminants.

Switching pipelines 6 and 7, 11 and 12, as well as 14 and 15, is performed in chambers 5.13 and 16 synchronously, for example, using a time relay.

Example. Laboratory studies of the method and its comparison with the prototype are carried out on the wastewater of the pig-breeding complex, which have passed the preliminary separation of large particles of manure on low-speed drum sieves and clarification in vertical sedimentation tanks. Water is evenly fed into a horizontal aeration tank, where circulating activated sludge is evenly introduced after 8 hours of regeneration. The specific air flow rate in the aeration zone is 42 m3 / m per hour. The parameters of the cleaning process, calculated on the actual flow of wastewater (50 m3 per 1 aeration tank per hour), are given in Table. 1. In table. 2 presents comparative data on the effectiveness of the wastewater treatment process by known and proposed methods.

Using the proposed method makes it possible to reduce the total processing time by about 2 hours and increase the degree of purification by the MIC, by 16%, COD by 26%, phosphate by 9%, ammonium nitrogen by 19%.

Claims (1)

Claims of the method of wastewater treatment, including mixing them with activated sludge, aerating the stream of sludge mixture in the aeration tank, collecting the mixture at the outlet of the aeration tank. and returning it dispersedly to the flow, characterized in that, in order to reduce processing time and increase the degree of purification, the flow is aerated dispersedly along the length of the aerotank with alternation due to periodic switching of air supply to the aerated and non-aerated zones, while the sludge mixture is taken out aeration tank from the last aerated zone and returned to the non-aerated zone. Table 1 without taking into account the power consumption for the regeneration of activated sludge, which is the same in both methods. J 15 table 2 The continuation of the table.2. I /