EA013671B1 - Process for biologic treatment of domestic ang industrial waste waters and a plant therefor - Google Patents

Abstract

The invention relates to a biologic treatment of domestic and industrial waste waters and is aimed at providing continuous, effective and high-standard operation of a water treatment plant for volley sewage and reducing construction costs. The inventive process comprises a cyclic treatment of waste water plant with sludge, the plant comprises compartments as a receiving chamber, an airtank chamber with a secondary settling basin, a settling sludge basin, inflows with increased discharge are pumped from the receiving chamber to the sludge settling basin and from airotank chamber to the sludge settling basin, mixed with sludge and the produced water-sludge mixture and use thereof as absorbent and nutrient medium for aerobic microorganisms, feed to a floatation chamber where the sludge is separated from the water-sludge mixture which recirculates in the settling sludge basin, and the purified water is supplied to the airtrank chamber. For realization the process the waste water treatment plant comprises said chambers, an airation system, with airators, airlifters and sensors of waste water levels connected to a plant control block. The flotation chamber is equipped with lines of the water-sludge mixture and clarified water. The settling sludge basin has a labyrinth with an airator arranged at the labyrinth inlets; outlets of the airlifter discharge lines for pumping sludge from the receiving chamber and the airtank chamber are positioned at of the labyrinth inlets, wherein the outlet the purified water discharge line from the flotation chamber is positioned in the airtank chamber. In an embodiment, the secondary settling basin is executed as a truncated pyramid with an accelerator branch pipe and a Z-shaped pipeline discharging purified water fixed to the pyramid walls. A U-shaped fat collector is fixed on the outer wall of the secondary settling basin. The accelerator branch pipe comprises a blow off connecting branch for pumping water-sludge mixture from the receiving chamber to the sludge settling basin and equipped with a tubular filter with a means for cleaning thereof; the receiving chamber is additionally connected to a bypass pipeline; the floatation chamber comprises a deflector baffle and two airlifters for discharging water-sludge mixture and purified water. The proposed inventive effect provides a reliable operation of the biological water treatment plant in case of unequal including emergency volley sewage inflows and a considerable low costs in manufacturing and operation of the water treatment plant.

Description

The invention relates to the biological treatment of wastewater using activated sludge in suspension and is intended for the treatment of wastewater (effluent) of residential buildings.

A known method of cleaning wastewater and device for its implementation, containing the aeration tank, a cylindrical shaft, a clarifier, aeration system with a compressor, see 8I number 1174385, M.cl. C02E 3/02, 1984

This method and device are characterized by increased power consumption and low efficiency.

A similar method and device for biological wastewater treatment is known, which contains an aeration chamber with aerators, a two-tier sludge settling tank, wastewater inlet, pipelines for pumping wastewater between the chambers and a wastewater disposal unit, see VI No. 819069, M.cl. C02E 3/02, 1978 and No. 2057085, cl. С02Е 3/02, 1994

The disadvantage of this analogue is that with elevated or rapid salvo discharges of wastewater volumes, they are not cleaned, and there is no protection against silt with the flow of these discharges.

The closest analogue adopted for the prototype of the invention (in terms of the method and installation) is the method of biological wastewater treatment and installation for its implementation according to the patent VI No. 2201405, M.cl. С02Е 3/02, 2002

According to this method, when biological wastewater treatment is carried out, wastewater is supplied to the surge tank of a biological treatment plant (UBO) and waste water is treated with activated sludge successively in a surge tank and activation tanks with recirculation and trapping of the spent sludge in the sludge collector; a chamber where it is filtered in a bulk filter made of granular material with the discharge of purified waste water from the purification device, while the water is being cleaned by a cycle with pauses between cycles.

UBO for the implementation of this method contains a surge tank with a nozzle input wastewater, aerator and level sensor; the activation tank is equipped with an aerator, level sensor, sludge recirculation pump; in addition, there is a sludge settling chamber connected via an overflow pipeline to a cleaning chamber with a filter equipped with cleaning means and a pump for pumping the treated waste water; The sludge settling chamber (or sludge stabilization) is equipped with an aerator and communicated with a surge tank by means of an overflow pipe. The UBO is also equipped with a control unit connected to aerators, pumps and level sensors.

The disadvantage of this method and UBO is inefficiency with increased inflows and salvo discharges of effluent, due to the uneven load on the biofilter (activated sludge) with its possible loss and loss of cleaning ability of the plant for the long term necessary to restore sludge. At the same time, the UBO has a complex and cumbersome design, is energy-intensive and unreliable in operation due to the rapid silting of the filter, equipped with an inefficient means of cleaning. However, the main disadvantage of the prototype is the need for a filter that significantly complicates the design and operation of the UBO.

In the part of the flotation chamber of the prior art known flotation agent, made in the form of a tank containing means of supplying water-sludge mixture and drainage of purified water, as well as bunkers for collecting circulating and excess sludge. The upper edges of the tank walls are located above the level of the water-drink mixture. The tank is also equipped with a belt conveyor with scrapers, and each of the bunkers is equipped with an iodroben and a pipeline for supplying the transporting fluid, see No. ϋ No. 1763391, C02E 3/12, 1992.

To ensure the operation of the flotation cell in its capacity, it is necessary to maintain a vacuum, which greatly complicates the design of the flotation cell and increases energy consumption during operation.

As the closest analogue chosen for the prototype, is a flotation device, comprising a housing with means for supplying a water-sludge mixture, as well as means for discharging sludge-rich water-sludge mixture and discharging clarified water, as well as a dispersant connected to the compressed air supply line, a mixer, water distributor, collecting trays and aeration means, as well as lightening chambers with a floating load and a collection of compacted sludge, see VI No. 8351, CO2 1/5, 1998

This flotation device is not used due to the complexity of the design and inefficiency at work.

The problem solved by the claimed invention is to ensure the preservation of the performance of the UBO in the conditions of uneven inflows, as well as efficient and high-quality wastewater treatment with reduced costs in the construction and operation of UBO of this type, as well as simplifying the design of UBO.

The solution of this problem (in terms of the method) is due to the fact that the method of biological treatment of household and industrial waste water, including cyclic treatment of waste water with activated sludge in standby and active cleaning modes in the UBO containing compartments in the form of a receiving chamber, an aerotank chamber and according to the invention, the settling tank of sludge according to the invention is purified by mixing with the sludge in the receiving chamber, from where the resulting water-sludge mixture is simultaneously pumped into the sludge chamber and the aeration chamber, from which The o-sludge mixture is also fed into the sludge chamber, in which an aerated saturated water-sludge mixture is created, consisting of young and dead sludge, used as an absorbent and nutrient medium for aerobes.

- 1 013671 of microorganisms, and this mixture is fed into the flotation chamber, which is additionally equipped with a UWO, where partial separation of sludge from the water-sludge mixture is carried out with recirculation of the water-sludge mixture enriched in sludge and supply of clarified water to the after-treatment in the aero cell tank. where in the secondary sedimentation tank it is finally cleaned and fed to the discharge from the UBO. In embodiments of the method to increase the processing time of the water-sludge mixture in the sludge settling chamber, they are fed to the entrance to the receiving maze with an aerated zigzag channel made in the form of one or more partitions with overflows between them, while the water-sludge mixture from the chamber flotation served on another entrance to the receiving labyrinth.

As part of the installation, the solution of this task was carried out in that the installation for biological treatment of domestic wastewater (UBO), containing a reservoir divided by partitions into process compartments-chambers, including a receiving chamber, an aeration chamber, a sludge settling chamber, and an aeration system with aerators, airlifts and sewage level sensors in the receiving chamber, connected to the control unit of the plant, according to the invention are additionally equipped with a flotation chamber equipped with an airlift of drainage sludge rich in sludge mixing and airlift removal of clarified water, while the sludge settling chamber is made in the form of a buffer tank for receiving and processing increased and volley sewage inflows and is equipped with a labyrinth channel with aerators located at the entrances to this channel, while the outlets of airlifts for pumping Sludge from the receiving chamber and the aerotank chamber are located at one of the entrances to the labyrinth channel, and the outlet of the airlift outlet line for the removal of silt-rich water-sludge mixture from the flotation chamber is located at the other entrance to the labyrinth anal, the output of the airlift pump discharge line for the clarified water from the flotation chamber is situated in the chamber-aeration tank. In embodiments of the UBO, the sump contains a body in the form of a truncated pyramid with open larger and smaller bases and sloping walls on which the snubber pipe is fixed and an I-shaped airlift installed on the outside of the sump the volume of the sump, while the specified knee-shaped inlet is located in the upper part of the sump in the zone of accumulation of water-fat mixture in it. A pipe with a fitting for connecting to a pressure air supply line and a blowing port installed in the lower part of the damper is placed in the pipe of the damper, while the outlet of the blowing port is placed on the outer surface of the damper on the side diametrically opposite to the arrangement of the knee-shaped I-shaped airlift inlet, and the input in the-shaped drain for removal of purified water is provided with a filter and is located inside the sump, below the entrance to the grease catcher; the output of the grease trap is located in the aeration chamber; The airlift for pumping the sludge mixture from the receiving chamber to the sludge chamber is equipped with a tubular filter for coarse sewage treatment, containing a tubular partially perforated housing with a means for cleaning perforations, while the suction nozzle of the airlift is placed in the housing, the lower section of which is made deaf with a plug, while perforation is located on the filter housing in the form of a belt with a width of at least 0.19 L, the lower edge of which is located from the lower edge of the housing at a distance of at least 0.19 L, where b - the length of the housing, with the filter cleaning means made in the form of at least one pipeline attached to the surface of the housing, the pipeline is provided with fittings for connecting to the air supply line and air supply to the housing cavity, while the fitting for air supply to the housing cavity is located below the perforation belt on the side of the airlift suction inlet; the nozzle for supplying air to the cavity of the perforated body is located below the lower section of the air intake manifold of the airlift; the receiving chamber is additionally connected to the bypass discharge pipeline.

In the part of the UFO flotation chamber, the solution of this task is carried out due to the UBO flotation chamber, comprising a housing with means for supplying and discharging a water-sludge mixture enriched in sludge and clarified water, as well as a mixer connected to the compressed air supply line, according to the invention for removal of sludge enriched sludge and clarified water, they are made in the form of airlifts, while the flotation chamber is equipped with a fender visor located above the inlet bottom slit, through which the flotation chamber communicates with and UBO, with suction slices of airlifts for pumping clarified water and sludge enriched sludge mixture, respectively, above and below the said visor, while the mixer is made in the form of an aerator located under the said visor at the bottom of the chamber, opposite the entrance slit. In an embodiment, the visor is made shaped with a triangular in plan sectional shape.

The technical effect of the use of the proposed invention is to ensure reliable operation of the UBO under uneven conditions, including emergency salvo inflows of waste water, as well as simplifying the design and a significant reduction in costs in the manufacture and operation of the UBO.

The invention is illustrated in the drawings.

FIG. 1 shows a general view (in plan) of the proposed installation;

in fig. 2 - the same, section A-A of FIG. one;

in fig. 3 - general view (longitudinal section of the flotation cell);

- 013671 in FIG. 4 is a view of C in FIG. 3;

in fig. 5 is a front view of the secondary clarifier;

in fig. 6 is a side view of the secondary clarifier;

in fig. 7 - a general view of the tubular filter.

The proposed method is explained on the basis of the description of the operation of the UBO.

The UBO contains cameras (compartments) 1-4, of which camera 1 is a receiving (averaging) camera; chamber 2 — sludge chamber (sludge collector); chamber 3 - flotation cell; chamber 4 aero tank with a secondary settler 5.

Chamber 1 is equipped with an inlet nozzle 6 for the input of waste water, chamber 4 is equipped with a nozzle 7 for the withdrawal of purified water. The UBO is also equipped with an aeration system in the form of compressors (conventionally not shown) connected to aerators 8а, 8б, 8в, 8г, 8д, 8ж and airlifts 9а, 9б, 9в, 9г, 9д, 9е, 9ж and 9з. In the dividing wall between chambers 2 and 3, see FIG. 4, the bottom 10 slot for transferring the water-sludge mixture from chamber 2 to chamber 3 is made. Below inlet 6 (chambers 1) is an outlet 11 for resetting emergency inflows into the bypass pipeline 12. Chamber 1 is also equipped with float level sensors 13 and 14, which can be located at levels a, b, c, b and connected to a control unit (conventionally not shown) for automatic switching of UBO operating modes depending on the positions of the level of drains in chamber 1 relative to the established levels a, b, c, b. In chamber 2, longitudinal partitions 15a and 15b are installed, forming a labyrinth channel for the flow of wastewater, while aerators 8d and 8d are installed at the entrances to this channel. It is advisable that the body of the secondary clarifier 5 was made in the form of a rectangular truncated pyramid consisting of interconnected inclined walls made of polymer trapezoidal plates, while the said pyramid is made with open large and smaller bases; in the working position the smaller base is located below. On the outer side of the housing, a grease catcher is fixed in the form of a ϋ-shaped airlift 16, the suction inlet of which is located inside the sump and is made in the form of a knee-shaped choke 17 installed in the wall of the sump in its upper part. A damper 18 is installed inside the sump 5, equipped with an air duct 19 with a purge fitting 20 (see FIG. 6) located in the lower part of the damper with access to its outer surface. It is advisable that the nozzle 20 be diametrically opposed to the suction inlet of the airlift 16. On the housing wall of the UBO, a “figurative” outlet 21 of clean water from the secondary clarifier 5 is fixed. It is advisable that the airlift 9a be equipped with a tubular filter, see FIG. 7, containing a tubular body 22 in the form of a perforated pipe with perforations 23 in the form of, for example, round holes, while the lower section of the perforated pipe must be made deaf and closed by a plug 24. The perforation is located on the body in the form of a belt with a width of B1, which is at least 0.19b to ensure minimum hydraulic resistance of the filter. The lower end of the perforation belt is located from the lower edge of the body at a distance of b ₂ , which is at least 0.19 b, where b is the length of the casing, which ensures that the airlift is not contaminated. An airlift 9a is installed in the tubular body 22, a pipe 25 is fixed to the outside of the tubular body 22 (conventionally not shown in the form of a flexible hose connected to a pressure air supply line) with a blow-out elbow fitting 26 passing through the wall of the tubular body 22 and an outlet opening located in internal cavity of the tubular filter. It is advisable that the airlift 9a be located near the wall of the tubular body 22, while the outlet of the fitting 26 should be located under the lower cut of the airlift, due to the fact that the contaminants that have penetrated through the perforations are floated by air bubbles in the upper part of the filter, as a result of which the lower cut Airlift 9a must be located below the bottom edge of the perforation belt and above the outlet of the fitting 26.

When cleaning waste water with a variable flow, the calculation of communications and facilities is usually carried out taking into account the maximum inflow, so that it is advisable that chamber 2 should be at least 1/3 of the total volume of chambers 1, 3-4, which provides averaging of incoming effluent and stabilization conditions of their cleaning in the UWO. Accordingly, the performance of the aforementioned airlifts (as well as their quantities and pipe diameters) should be selected from the condition for ensuring the smooth operation of the UBO under the conditions of maximum inflows. Since the airlifts 9a and 9g are designed for pumping saturated water-sludge mixture, the inlet bottom sections of their nozzles should be located above the inlet lower sections of the airlift pipes 9b, 9c, 9d. In the flotation chamber 3 above the entrance slit 10 is located the fender visor 27, made contoured with a triangular shape. Above the baffle 27 is a suction inlet airlift 9zh for pumping clarified water. Below the visor 27, at the bottom of the chamber 3, is located the suction inlet of the airlift 9z for pumping the sludge-rich water-sludge mixture. Opposite the entrance slit 10 there is an aerator-mixer 8g. Airlift 9zh and 9z are connected respectively to the pressure lines 28 and 29 of the compressed air supply. Chamber 4, equipped with an outlet nozzle 7, is connected on one side to the “drain” 21, and on the other, via the mixer 30 to the bypass pipeline 12. For disinfection of purified water and improving the quality of cleaning, the mixer 30 can be equipped with an ultraviolet radiator (not shown conventionally). To regulate the amount of sludge in the UBO, it is advisable that the UBO would be equipped with a viscosity sensor of sludge 31 placed in chamber 3, with occasional airlift 9v for pumping excess sludge into the sludge receptacle (conventionally not shown) at a signal from this sensor. It is also advisable that camera 1 be equipped with a 32 effluent discharge sensor to automatically set the time delay for transferring the UBO to the active sludge conservation mode during periods of absence or rare inflow of fresh effluent. In these cases, a time delay is automatically set in the control unit, which (according to the signal from sensor 32) is measured from the time of the last arrival of drains. An overflow pipe 33 is installed in the housing wall between chambers 1 and 2, and a filter 34 is installed at the inlet of the слив-shaped drain for drainage of purified water. Polyethylene, or polypropylene, or vinyl plastic, or other similar materials can be used as the polymer material.

UBO works as follows.

With a long absence of receipt of drains and lowering the level of drains in chamber 1 to a predetermined minimum level (a), i.e. both floaters 13 and 14 of the level sensors are omitted, sludge vital activity is maintained by automatically switching the UBO to standby mode (this reverse mode is conventionally called the first mode) with periodic (in a closed loop) transfer of the water-sludge mixture from chamber 1 to chambers 2, 4 and back to chamber 1 during the entire period of lack of drains with automatic periodic inclusions of the aerator 8b and airlifts 9d, 9c, 9e, 9g with the purge of the tubular filter 22, while the fluid does not flow into the drain. The first operation of the UBO is ensured by a predetermined time delay (which is conventionally not shown in the control unit). If the liquid level in chamber 2 rises to the level of the location of the overflow pipe 33, then the excess liquid is drained from chamber 2 into chamber 1 along this pipe.

For tributaries, the volume of which does not raise the level of runoff in chamber 1 above the established level (b), airlifts 9a, 9g are included in the UBO; aerators 8a, 8b, 8g and purge filter 22 (this mode is conventionally called the second). In the second mode, the purified water enters the drain in the nozzle 7. As soon as the liquid level in chamber 1 drops to level (a), the UBO moves to the first mode.

For tributaries, the volume of which raises the level of waste in chamber 1 to the established level (6), i.e. Both the floaters 13 and 14 of the level sensors are raised, the first mode of operation is superimposed on the second mode, while the UBO turns on aerators 8a-f and airlifts 9a-3, 16, except for airlift 9e and airlift 9c, which is activated by a signal from sensor 31 (this mode the work is conventionally called the third).

It should be noted that the water-sludge mixture entering through the bottom slit 10 from chamber 2 into chamber 3 is mixed and aerated with an aerator-mixer 8g, while due to the fender 27, the water-sludge mixture moves in the direction from the slit. Due to the shape of the visor, the channel through which the water-sludge mixture moves is constantly expanding, which leads to a drop in its velocity and the deposition of large particles of sludge in the lower section of the airlift 9z, while the clarified water containing fine sludge particles with rising air bubbles enters in the area located above the visor 27 and pumped airlift 9zh. When the airlift 9G works, the clarified water enters the chamber 4 and mixes with the contents of this chamber, from where the airlift 9g is pumped to the damper 18 of the secondary clarifier 15, where sludge accelerates sedimentation (see below) to form a clarified water layer, which is discharged through the Ζ-shaped an outlet 21 (due to an increase in the water level in the chamber 4 above the installation level of the шту-shaped discharge inlet fitting) and enters the outlet from the UBO through the outlet 7.

During the operation of airlifts 9b and 9d, the water-sludge mixture is pumped to the entrance of the labyrinth channel in chamber 2 (near the location of the aerator 8d). This achieves intensive mixing of effluent with stabilized sludge located in chamber 2, and activated sludge from chamber 4. At the same time, due to the length of the labyrinth canal and placement of the airlift outlets 9b and 9d above the aerated inlet section of this canal, the length of the path of the pumped sludge mixture from chambers 1 and 4 into chamber 2 and, accordingly, the time of contact of sewage with sludge increases until it enters chamber 3, where it enters as a saturated water-sludge mixture through a slot 10 in the partition between chambers 2 and 3. When the airlift 9z is operating, the water-sludge mixture is pumped to another entrance of the labyrinth channel in chamber 2 (in the vicinity of the aerator 8g), which promotes the mixing of active and stabilized sludge and increases the contact time of sewage with sludge before entering the chamber 3.

In case of emergency salvo tributaries, the volume of which increases the level of effluent in chamber 1 to the established level - (1), i.e. the installation level of the drain pipe 11, part of the effluent is discharged through this pipe into the bypass pipe 12, while at the outlet of this pipeline the waste water is mixed in the mixer 30 with purified water and diluted, partially purified by reducing the concentration of contaminants. If necessary, the mixer 30 can be equipped with an ultraviolet emitter (conventionally not shown) to disinfect the treated wastewater. In the mode of draining part of the effluent into the bypass pipeline 12, another part of the effluent enters chambers 2, 3, 4 and the UBO operates as described above in the third mode. Thus, the camera 2 is functionally a buffer chamber with the provision of receiving and cleaning a salvo discharge, the volume of which raises the level of waste in chamber 1 to

- 4 013671 levels e- £.

Upon receipt of clarified water inside the sump 15 through the pipe of the damper 18, due to coagulation (see below) there is an accelerated sedimentation of sludge from the sludge mixture, while the sedimented sludge leaves the secondary sump 15 through its open bottom base. Purified sludge water in the form of a clarified layer formed in the sump, is discharged through the Ζ-shaped drain 21 and is fed into the outlet 7 to the release of the UBO. In the process of wastewater treatment, the fat mixture accumulating in the sump 15 floats on the surface of the liquid in the sump 15 and is periodically sucked off by an airlift 16 with feed into the chamber 4 for further oxidation and decomposition, while due to the purge of the damper 18, the fat mixture is fitted to the suction inlet of the airlift 16. by placing the airlift 16 on the outside of the sump, its useful volume is increased. When pumping a water-based mixture by an airlift 9a, it is partially filtered by a tubular filter 22, which this airlift is equipped with. The air supply to the purge of the tubular filter 22 through the nozzle 20 ensures uninterrupted operation of this airlift with partial filtration of the fluid that the airlift pumps. In this case, due to the fact that the lower section of the intake pipe of this airlift is located below the lower holes of the perforations 23, when the cleaned fluid enters the filter, coagulated (see below) large sewage is retained by its perforations 23, and small impurities penetrating through these holes, flotation to the surface of the liquid air bubbles emanating from the nozzle 20.

In the process of research, it was unexpectedly found that the installation, designed for cleaning wastewater from 20 people, in the peak load mode handles drains from 70 people, while even without filtering, the treated wastewaters are transparent and meet the MPC requirements. It was also found that the amount of sludge generated in the installation at peak loads is reduced by 1.5 times, which indicates that the cell material of dead sludge is a nutrient medium for activated sludge.

Leaving open the question of the true processes occurring during such water treatment, it can be assumed that the accumulation of stabilized sludge in the sludge chamber in it occurs decomposition processes with the metamorphism of the cells that make up the sludge. At the same time, fibrillary covers formed by extracellular biopolymers are separated from the surface layer of microorganism cells, and bioflocculants are released from the cell contents. In the process of mixing (due to aeration) with wastewater coming from the receiving chamber, the concentration of bio-coagulant increases, which leads to the formation of well-deposited large flocs of contaminants in the waste liquid, which are formed by creating conditions for adhesion of dispersed colloidal and fine particles. A similar process is described, for example, in VI No. 2073649, С02Р 3/02, 1995.

Thus, in the absence or at uneven (within the established levels) inflows, the UBO is automatically translated into the most economical - periodic operation with wastewater treatment cycles. Salvo or elevated inflows are processed with the inclusion of intensive processing with the inclusion of the flotation chamber 3 and a temporary increase in the productivity of the installation. With a decrease in the level of the sludge mixture in chamber 1 to the set value, the intensive processing mode is turned off and the installation is translated into an economical mode of operation.

It is advisable that the UBO was equipped with a viscosity sensor of sludge 31 placed in chamber 3, with intermittent airlift 9c for pumping excess sludge into the receiver by the signal of this sensor. It is also advisable that camera 1 be additionally equipped with a 32 effluent discharge sensor to automatically set the time delay for transferring the UBO to the active sludge life saving mode during periods of absence or rare inflow of fresh effluents. In these cases, a time delay is automatically set in the control unit, which (according to the signal from sensor 32) is measured from the time of the last arrival of drains.

Thus, for any tributaries, including emergency ones, the proposed UBO does not lose active sludge and remains operational with ensuring the established indicators (MAC) of wastewater treatment. As mentioned above, the accelerated sedimentation of sludge makes it possible to refuse to filter the liquid altogether. At the same time, even in peak UBO operating modes, the liquid layer at the level of the entrance to the discharge 21 from the secondary clarifier 15 is completely lightened, i.e. sedimentation of the sludge is completely completed by the time of discharge of purified water, which ensures reliable operation of the UBO under uneven conditions, including emergency salvage inflows of wastewater. The design of the UBO is also simplified and the costs for the manufacture and operation of the UBO are significantly reduced.

Claims (10)

1. The method of biological treatment of domestic wastewater, including cyclic treatment of wastewater with activated sludge in standby and active treatment modes in a biological treatment plant (UBO) containing compartments in the form of a receiving chamber, aeration tank and a sludge settling chamber, characterized in that elevated and volley tributaries are cleaned by mixing them with sludge in a receiving chamber, from where the resulting water-sludge mixture is simultaneously pumped into the sludge chamber and aeration tank, from which the water-sludge mixture is also fed into the sludge chamber, into which second create - 5 013671 aerated saturated water-sludge mixture, consisting of young and dead sludge, used as an absorbent and a nutrient medium for aerobic microorganisms, and this mixture is fed into the flotation chamber, which is additionally equipped with UBO, where the sludge is partially separated from water-sludge mixtures with recirculation into the sludge chamber of the water-sludge mixture enriched with sludge, and the supply of clarified water for purification to the aeration tank, where it is finally cleaned in the secondary sump and fed to the exhaust from the UBO. 2. The method according to claim 1, characterized in that to increase the processing time of the effluents in the sludge trap, the effluent is fed to the entrance to the receiving labyrinth with an aerated zigzag channel made in the form of one or more partitions with flows between them, while the water-silted mixture from the chamber flotations are fed to another entrance to the receiving labyrinth. 3. Installation for biological treatment of domestic wastewater (UBO), containing a tank divided by partitions into technological compartments chambers, including a receiving chamber, aeration chamber, sludge settling chamber, as well as an aeration system with aerators, airlifts and level sensors in the receiving chamber connected to the control unit of the operation of the installation, characterized in that the installation is additionally equipped with a flotation chamber, equipped with a drain airlift enriched sludge water-sludge mixture and airlift drain of clarified water, while the cam The settling tank is made in the form of a buffer tank for receiving and treating elevated and volley inflows of wastewater and is equipped with a labyrinth channel with aerators located at the entrances to this channel, while the outlet of airlift exhaust lines for pumping sludge from the receiving chamber and the aeration tank is located on one from the entrances to the labyrinth channel, and the exit of the airlift drainage line for the removal of silt-enriched water-water mixture from the flotation chamber is located at the other entrance to the labyrinth channel, and the exit of the airlift drainage line for pumping lightens -water from the flotation chamber is situated in the chamber-aeration tank. 4. The installation according to claim 3, characterized in that the sump contains a truncated pyramid body with open larger and smaller bases and inclined walls, on which a soothing pipe and a Ζ-shaped drain are mounted to drain purified water, as well as an I-shaped airlift mounted on the outside of the sump, made in the form of a grease trap, the suction pipe of which is equipped with a knee-shaped inlet to the volume of the sump, while the specified knee-shaped inlet is located in the upper part of the sump in the accumulation zone of water-fat containing mixtures, while in the damper nozzle there is a pipe with a fitting for connecting to the pressure line of the air supply and a purge nozzle installed in the bottom of the damper, while the outlet of the blower nozzle is placed on the outer surface of the damper from the side diametrically opposite to the position of the I- shaped airlift, and the entrance to the Ζ shaped drain for the removal of purified water is equipped with a filter and is located inside the sump, above the entrance to the grease trap. 5. Installation according to claim 4, characterized in that the outlet of the grease trap is located in the aeration chamber. 6. Installation according to claim 3, characterized in that the airlift for pumping sludge mixture from the receiving chamber to the sludge chamber is equipped with a tubular filter for rough cleaning of effluents, containing a tubular partially perforated body with means for cleaning perforations, while the airlift suction pipe is located in the case, the lower cut of which is made blind with a plug, while the perforation is located on the filter housing in the form of a belt with a width of at least 0.19b, the lower edge of which is located from the lower cut of the housing a melting factor of at least 0.19 b, where b is the length of the casing, while the filter cleaning agent is made in the form of at least one pipe fixed to the surface of the casing, and the pipeline is equipped with fittings for connecting to the air supply line and supplying air to the housing cavity while the fitting for supplying air to the cavity of the housing is located below the perforation belt from the location of the suction nozzle of the airlift. 7. Installation according to claim 6, characterized in that the air supply fitting into the cavity of the perforated body is located below the lower cut of the airlift suction pipe. 8. Installation according to claim 3, characterized in that the receiving chamber is additionally connected to a bypass discharge pipe. 9. UBO flotation chamber, comprising a housing with means for discharging a water-sludge mixture enriched with sludge and a water-sludge mixture with a low sludge content, as well as a mixer connected to a compressed air supply line, characterized in that the means for discharging water-sludge a mixture enriched in sludge and a water-sludge mixture with a low content of sludge are made in the form of airlifts, while the flotation chamber is equipped with a bump visor placed above the entrance bottom slit, by means of which the flotation chamber is in communication with the sludge chamber of UBO, Airlift lifts for pumping a sludge-rich water-sludge mixture and a low-sludge-water sludge mixture are located above and below the said visor, the mixer being made in the form of an aerator located under the said visor at the bottom of the chamber, opposite the entrance slit. 10. The flotation chamber according to claim 9, characterized in that the pick-up visor is shaped with a triangular sectional plan.