RU106615U1 - COMPACT VERTICAL OXIDIZATION CHANNEL FOR EFFECTIVE WASTE WATER TREATMENT - Google Patents

Abstract

The utility model relates to compact individual biological systems for treating household wastewater with activated sludge in suspension and can be used in stand-alone buildings, for example, cottages, homesteads, schools, clubs, etc., as well as in small villages, and is a compact device with a vertical oxidation channel for effective wastewater treatment, containing located in a common housing with a vapor barrier and interconnected receiving aerotank with a system with the aeration topic, an activation primary settler located under it and connected with openings in the intermediate bottom, equipped with bottom-mounted coarse-bubble mixers, and a secondary settler separated from the receiving aeration tank and activation primary settler by an internal partition equipped with a dosed withdrawal system of purified water outside the unit, and located in a vapor-insulated casing, a compressor, the openings of the intermediate bottom separating the receiving aerotank and activation urea settler, located in its lateral zones in the wall region near the vertical inner partition of the secondary settler, while the vertical inner partition is made with at least one hole located above the intermediate bottom and connected by means of airlift recirculation of activated sludge with the lower zone of the secondary settler, and at least one hole located in the lower zone of the vertical internal partition and intended for the flow of fluid from the activation primary settling tank into the secondary sump, with coarse-bubble mixers located under the openings of the intermediate bottom with a slight lateral displacement. And also the fact that the mixing system of the intake aeration tank includes a linear aerator located in the wall zone near the internal partition to create a protective bubble wall between the linear aerator and the internal partition, an airlift of recirculation of activated sludge with an outlet located between the bubble wall and the inner partition, and coarse bubbles mixers providing the formation of a protective bubble block flow between the receiving aeration tank and the primary activation sump for cut-off tion of large fractions of pollution. The secondary settler is equipped with a device for collecting and degassing biofilms from the water surface, made in the form of a U-shaped pipe with multilevel elbows, an inlet end made in the form of a side bell, and an outlet end connected with an additional vertical pipe, while the upper end of the additional vertical pipe located above the maximum level of wastewater and is designed to remove the exhaust air from degassing outside the secondary sump, and the lower end is located under water, below the minimum ur sewage water, and is designed to divert a degassed biofilm of activated sludge towards the cone-shaped zone of the secondary sump, and the secondary sump is equipped with a bubble dispenser at the outlet of the purified water from the installation, made in the form of a U-shaped pipe with multilevel elbows, with the inlet elbow in the lower zone equipped with an air injector and a narrowed neck in the upper zone located under the water of the secondary sump and designed to form a pulsating air valve bubble. The bubble dispenser is equipped with a vertical emergency overflow pipe adjacent to its outlet bend in the zone of purified water exit from the installation, while the upper end of the emergency overflow pipe is located in the zone of maximum water level in the secondary sump. The utility model helps to significantly increase the reliability of operation, reduce energy costs for wastewater treatment, simplify the design while increasing its compactness, increase the strength of internal partitions while increasing the efficiency of wastewater treatment due to the intensification of the effect on wastewater in the overflow zone between communicating adjacent chambers with gravity flow of fluid between them in a single-tank compact tank, improving the quality of cleaning while maintaining a stable operating mode s, reducing the cost of construction of a sewage treatment plant, increasing the environmental friendliness of the device by improving the quality of treatment and reducing sanitary protection zones; 3 s.p. f-ly, 2 ill.

Description

The utility model relates to compact individual biological systems for treating household wastewater with activated sludge in suspension and can be used in stand-alone buildings, for example, cottages, homesteads, schools, clubs, etc., as well as for small villages.

A device for wastewater treatment is known, comprising a closed housing in which a leveling compartment with activated sludge, an inlet pipe and aerators is located, an activation compartment connected to it by a bypass channel with a fine-bubble aerator installed in its bottom part, communicating with the activation compartment through the main aeration tank pump, in which a fine-bubble aerator is also installed, connected to the aeration tank through a sludge pump, the sludge stabilization compartment with the mixer aerator located in it and connected the outlet compartment with the filter, located in front of the outlet pipe, is connected to the aeration tank by means of a circulation pump, while the sludge stabilization compartment is connected to the equalizing compartment by an overflow pipe, and all aerators and pumps made in the form of airlifts are connected to the compressor through pneumatic distributors connected to the control unit, and the outlet part of the equalizing compartment in front of the bypass channel is separated from its input part by an inclined delaying grating, on both sides of which in the bottom part of the compartment is installed The aerators are agitators, the aeration tank is connected to the activation compartment by a recirculation pump made in the form of an airlift, while the oxygen sensor in the liquid is connected to the control unit in the aeration tank, and a valve is installed on the air supply pipe to the fine bubble aerator located in the bottom part of the aeration tank, also associated with the control unit, while the filter located in the output compartment is made in the form of a frame filter for ultrafiltration cleaning (see Patent for invention RU No. 2355649, Cl. С02F 3/02, op. in 2009). This compact device is designed for cottages and vehicles and provides for the maximum use of communicating tanks with gravity overflow of liquids, but has a complex interaction scheme of communicating tanks, which does not always cope with large portions of wastewater.

A known device for wastewater treatment, containing a tank with a vertical pipe having an internal biological load and a fine bubble aerator, two pairs of tangentially located airlifts and an upper pipe for supplying wastewater to a vertical pipe, a sump equipped with an aerator, a sludge recirculation pump and an exhaust valve for exiting purified water, a chamber with a porous filter, a system of pipelines and pumps that provide forced pumping of water, and a control unit (see patent for invention RU No. 23599 22, Cl. CO2F 3/02, op. In 2008). This technical solution is more compact than the previous, but a complex wastewater treatment system in a tank with a vertical pipe requires a fairly uniform flow of wastewater, which is rarely achievable in practice.

A known device for wastewater treatment, comprising a housing with a sealed lid, which contains an activated sludge equalizing tank, equipped with an inlet sewage pipe, an emergency sensor, aerators-agitators and communicating with the activation tank through an overflow pipe located in the bottom zone of the dividing wall of the equalizing and activation tanks, while in the activation tank there is a fine bubble aerator, a tubular well with a main pump and an internal air a torus, a coarse-bubble aerator of external blowing of a tubular well, the walls of the tubular well in the middle zone being perforated and surrounded by an outer shell made in the form of a cylinder with a lower end located in the socket, the smaller base of which is hermetically fixed to the outer wall of the body of the tubular well, aeration tank, equipped with a fine bubble aerator, a sludge recirculation pump and a partially purified water circulation pump, a secondary settling tank in communication with it, equipped with a flow damper of partially purified water, an output filter, an outlet pipe of clean water, a biofilm aerator-breaker, a biofilm removal pump made in the form of a J-shaped pipeline, one end of which is located below the outlet filter zone, and the second end is above the outlet filter zone in the upper part of the aeration tank, a sludge stabilization chamber equipped with a sludge damper and aerator-mixers located in its bottom region, while the sludge stabilization chamber is interconnected with a leveling tank by means of an overflow piping, control unit, compressor and turbophase distributors, first and second phases, connected by air ducts for supplying air to aerators and pumps (see Patent for invention RU No. 2305662, Cl. С02F 3/12, op. in 2007). The known device is more versatile than previous technical solutions, but has a rather complicated expensive design that does not justify the cost of manufacturing and use in conditions of limiting the amount of wastewater and the location of the treatment plant.

The closest technical solution to the claimed utility model is a device for wastewater treatment, including a receiving and oxidizing channel with an upper overflow pipe connecting with other oxidizing channels, the bottom of each channel being mesh, a fine-bubble linear aerator with separation of the oxidizing channel and the activation tank is placed above it while the secondary sump in the lower part is made in the form of a truncated tetrahedral pyramid, installed with a smaller base down and up its parts - in the form of a rectangular well, the sides of which are located relative to the sides of the body with a 45-degree turn to form three triangular vertical oxidizing channels and an output storage tank with a float pump (see patent for the invention RU No. 2406700, Cl. С02F 3 / 12, op. In 2010). In the known device, the outlet pipe is provided with a slit-like channel for dosed water drainage. This technical solution allows you to more effectively control the liquid level in the installation and improve the quality of wastewater treatment. However, the rather complicated design of such an installation is not justified in conditions of a limited amount of wastewater (for example, in an individual single-family house). Installation is laborious in installation, takes up a lot of space and has an increased power consumption.

This utility model is aimed at solving the technical problem of simplifying the design while increasing its compactness and increasing the strength of internal partitions, reducing energy costs for wastewater treatment and increasing the reliability of the device while increasing the efficiency of wastewater treatment due to the intensification of the impact on wastewater in the overflow zone between communicating adjacent chambers with gravity flow of fluid between them.

The solution of the stated technical problem is achieved by the fact that in a compact device with a vertical oxidizing channel for effective wastewater treatment, it contains a receiving aeration tank with an aeration system located in a common housing with a vapor barrier and located under it and connected with openings in the intermediate bottom activation primary sump equipped with bottom-mounted coarse-bubble mixers, and separated from the receiving aerotank and activation primary from a secondary partition, equipped with a dosed withdrawal system of purified water outside the unit, and a compressor located in a vapor-insulated casing, the openings of the intermediate bottom separating the intake aeration tank and the activation primary clarifier are located in its lateral zones in the wall region near the vertical inner partition of the secondary clarifier while the vertical inner partition is made with at least one hole located above the intermediate and connected by means of an airlift of recirculation of activated sludge to the lower zone of the secondary sump, and with at least one hole located in the lower zone of the vertical internal partition and designed to transfer liquid from the activation primary sump to the secondary sump, with coarse-bubble mixers located under the holes of the intermediate bottom with a slight shift to the sides. And also the fact that the mixing system of the intake aeration tank includes a linear aerator located in the wall zone near the internal partition to create a protective bubble wall between the linear aerator and the internal partition, an airlift of recirculation of activated sludge with an outlet located between the bubble wall and the inner partition, and coarse bubbles mixers providing the formation of a protective bubble block flow between the receiving aeration tank and the primary activation sump for cut-off tion of large fractions of pollution. The secondary settler is equipped with a device for collecting and degassing biofilms from the water surface, made in the form of a U-shaped pipe with multilevel elbows, an inlet end made in the form of a side bell, and an outlet end connected with an additional vertical pipe, while the upper end of the additional vertical pipe located above the maximum level of wastewater and is designed to remove the exhaust air from degassing outside the secondary sump, and the lower end is located under water, below the minimum ur sewage water, and is designed to divert a degassed biofilm of activated sludge towards the cone-shaped zone of the secondary sump, and the secondary sump is equipped with a bubble dispenser at the outlet of the purified water from the installation, made in the form of a U-shaped pipe with multilevel elbows, with the inlet elbow in the lower zone equipped with an air injector and a narrowed neck in the upper zone located under the water of the secondary sump and designed to form a pulsating air valve bubble. The bubble dispenser is equipped with a vertical emergency overflow pipe adjacent to its outlet bend in the zone of purified water exit from the installation, while the upper end of the emergency overflow pipe is located in the zone of maximum water level in the secondary sump.

The utility model is illustrated by drawings. Figure 1 schematically shows a compact device with a vertical oxidizing channel for efficient wastewater treatment. Figure 2 is the same, section aa in figure 1.

A compact device with a vertical oxidation channel for effective wastewater treatment includes a housing 1 with a vapor barrier 2. In the housing 1 there is a receiving aeration tank 3, an activation primary sump 4 is located under it. The secondary sump 5 is separated from the receiving aeration tank 3 by the upper part 6 of the vertical internal partition 7 , and from the activation primary settler 4 - the lower part 8 of the vertical inner partition 7. In the housing 1 is a vapor-insulated casing 9 with a compressor 10. In the upper zone of the receiving air Rotenka 3 is the inlet pipe 11 of the wastewater. A pneumatic distributor 12 is located under the cover 2 in the vapor-insulated casing 9 with the compressor 10. The casing 9 isolated from the wastewater has a hole 13 in the cover 2 connected to the side holes 14 of the protective tent 15, made in the form of a mushroom above the cover 2. The receiving aeration tank 3 is connected with the activation the primary sump 4 holes 16 in the intermediate bottom 17. The holes 16 of the receiving aeration tank 3 are located in the lateral zones of the intermediate bottom 17 in the wall region near the lower part 6 of the internal partition 7 separating the receiving aeration tank 3 and the second ary sump 5.

The aeration system for creating a circular vertical recirculation of activated sludge in the intake aeration tank 3 includes a linear aerator 18 located at the junction of the upper part 6 of the vertical inner partition 7 and the intermediate bottom 17 and designed to create a protective bubble wall between the linear aerator 18 and the partition 7. Also, the system the aeration of the intake aeration tank 3 includes an airlift 19 of activated sludge recirculation, the inlet end of which is located in the lower cone-shaped zone 20 of the secondary sump 5 near the bottom of the vert the inner wall 7 separating the activation primary sump 4 and the lower zone 20 of the secondary sump 5. The aeration system for the intake aeration tank 3 also includes coarse bubbles 21 located in the lower lateral zones of the activation primary sump 4 under the holes 16 of the intermediate bottom 17 with a slight lateral shift with aeration directed upward from the activation primary sump 4 to the intake aeration tank 3 through openings 16. The output end of the airlift 19 of activated sludge recirculation is connected with a verst 22 of the vertical internal partition 7 located in the area of the linear aerator 18. Moreover, the hole 22 is located so that the liquid and air bubbles supplied by the airlift 19 fall into the receiving aeration tank 3 above the bubble wall from the linear aerator 18.

The secondary sump 5 is equipped with a device for collecting and degassing biofilms from the water surface, made in the form of a U-shaped pipe 23 with multilevel elbows. The inlet end of the U-shaped pipe 23 is made in the form of a side socket 24 located at the working water level in the installation. The U-shaped pipe 23 is equipped with an air injector 25 located in the lower part of the output bend of the U-shaped pipe 23, turning it into an airlift. The output end of the U-shaped pipe 23 is connected under water with an additional vertical pipe 26. The upper end of the additional vertical pipe 26 is located above the maximum level of wastewater 27 and is designed to remove exhaust air during degassing outside the secondary settler 5. The lower end of the additional vertical pipe 26 is located under water, below the minimum level of wastewater, and is designed to drain the degassed biofilm of activated sludge towards the cone-shaped zone 20 of the secondary sump 5. Secondary sludge nick system 5 is provided with a metered removal of purified water outside the plant including bubble dispenser configured as a U-shaped pipe 28, and bends with different levels of air injector 29 in the lower region of the input of the knee. The inlet elbow of the U-shaped pipe 28 in its upper zone is provided with a narrowed neck 30 located under the water of the secondary sump 5 and designed to form a bubble pulsating air valve. The narrowed neck 30 has an opening commensurate with the size of the air bubbles of the injector 29. The bubble dispenser is equipped with a vertical pipe 31 emergency overflow adjacent to its outlet bend in the area 32 of the outlet of purified water from the installation. The upper end of the emergency overflow pipe 31 is located in the zone of maximum water level in the secondary sump 5.

Linear aerator 18 is connected by air duct 33 to compressor 10. Coarse-bubble mixers 21 located in the bottom zone on the sides of the primary activation sump 4 are connected by air ducts 34 to the air distributor 12. Injectors 25 and 29 are connected to the air distributor 12 of the compressor 10 via air ducts 35 and 36. Airlift 19 equipped with an injector 37 connected to the pneumatic distributor 12 of the compressor 10 by means of air ducts 38. At least one opening 39 is made in the lower part 8 of the vertical internal partition 7 Fifth, for the flow of liquid from the activation primary sump 4 to the secondary sump 5. Optimal is the presence of two holes 39, shifted to the Central zone of the partition 7 so as not to interfere with the work of coarse-bubble mixers 21.

A compact device with a vertical oxidizing channel for effective wastewater treatment works as follows. A portion of wastewater entering the aerobic zone of the intake aeration tank 3 is mixed with a mass of water and activated sludge, which is in suspension. In the receiving aeration tank 3 is the main treatment of wastewater. Due to the lateral arrangement of the linear aerator 18, the wastewater in the aeration tank 3 is always in rotational motion, rising up along with air bubbles along the partition 7 and dropping down along the opposite wall of the aeration tank 3. This contributes to the active mixing of wastewater, activated sludge and air flows, breaking biofragments and biofilms, activating the processes of enzymatic decomposition and oxidation of organic pollutants and nitrification of ammonium nitrogen compounds, as well as creating a protective bubble of the wall from the penetration of contaminants to the hole 16. It is important that in the intake aeration tank 3 in the area of the openings 16 of the intermediate bottom 17 provide additional protection against the penetration of large contaminants into the activation primary settler 4 by means of large bubbles from coarse-bubble mixers 21. All this greatly simplifies the design of the intake aeration tank 3, excluding the installation of special barriers. The constant "suction" of activated sludge with airlift 19 from the secondary sump 5 and the inclusion of sludge in the rotational movement in the intake aeration tank 3, significantly activate its interaction with biofragments.

A mixture of water with activated sludge that has passed through the lateral openings 16 of the intermediate bottom 17 is uniformly and at a low speed fed to the lower anoxic zone of the activation primary sump 4 (with oxygen deficiency but with living aerobic sludge). The barrier from the penetration of large fragments to the bottom of the activation primary sump 4 is carried out when meeting with air bubbles from the coarse bubble mixer 21. At the same time, the liquid supplied from the intake aeration tank 3 is mixed. A large amount of activated sludge falling along with the sediment to the bottom of the activation primary sump 4, in the anoxic zone, loses dissolved oxygen and activates denitrification, decomposition of difficultly oxidized compounds and other biochemical reactions with the removal of oxygen from oxides to oxidize the decomposition products of pollution. In the lower sediment zone, in addition, self-oxidation (selective lysis) of activated sludge also occurs, which helps to reduce its growth and improve the species composition (the strongest survives). In the lower zone of the primary settler 4, the direction of the gravity flow of the mixture of water and activated sludge changes. If the liquid moves from top to bottom in the upper zone of sump 4, then lateral movement begins closer to the bottom of sump 4, which passes into the feed of the mixture through openings 39 into zone 20 of the secondary sump 5, where activated sludge is sedimented and taken into the airlift inlet 19. Airlift 19 directs activated sludge for recycling to the intake aeration tank 3 in the area of the hole 22, protected by a bubble wall of aeration. Moreover, in the area of the openings 39, activated sludge is “sucked” together with the liquid to the secondary sump 5, where it is captured by the airlift 19 and is recycled. In the lateral stagnant zones of the primary sump 4, activated sludge picks up air bubbles from the coarse-bubble mixer 21, lifts it up to the hole 16 into the aeration zone of the intake aeration tank 3, also providing additional recirculation.

In the secondary settling tank 5, the effect of flotation of activated sludge from gas evolution of nitrogen and carbon dioxide during denitrification and the emergence of activated sludge is possible. The collection of the surfaced sludge from the mirror of the surface of the secondary sump is carried out by means of a suction neck located in the zone of the working water level — a lateral socket 24 of the U-shaped degasser pipe 23 with additional bubbling of the collected impurities in its outlet channel. The exhaust air is removed through a vertical pipe 26 connected to the outlet bend of the U-shaped pipe 23. The activated sludge that has surfaced in the outlet pipe of the degasser is freed from floating gases and directed downward. The sludge is sedimented into the lower zone 20 of the secondary sump 5 to the suction pipe of the airlift 19 of the recirculation. Purified water is supplied from the upper layers of the secondary sump 5 through the neck 30 of the bubble meter to the exit of the installation, while air bubbles rising from the neck 30 of the bubble meter, destroy and feed the pop-up biofilm to the bell 24 of the degasser. Through the narrowed neck 30 of the bubble dispenser, purified water in separate portions, determined by the size of the metering dynamic bubble formed by the air bubbles of the injector 29 before the narrowed neck 30, enters the inlet elbow of the U-shaped pipe 28. The bubbles leaving the air through the neck 30 from the top of the metering bubble repel any bioparticles and bio-formation from the bubble dispenser, not allowing them to block the exit from the installation. The amount of purified water discharged is controlled by changing the amount of air supplied to the injector 29. The larger the size of the dynamic metering bubble formed in the inlet bend of the U-shaped pipe 28 from the small bubbles of the injector 29, the less liquid they pass down to exit the installation. This design of the bubble dispenser allows you to adjust the speed of the outlet of the purified liquid from the installation, the working level of wastewater in the intake aeration tank 3, the working level 40 and the maximum level 27 of the liquid in the sump 5, the flow rate of the liquid from the sump 4 to the sump 5. In fact, the operation of the bubble meter determine the performance of the installation and the uniformity of wastewater treatment. Moreover, when the pressure of the liquid located above the inlet elbow of the U-shaped tube 28 of the bubble meter is insufficient to push water into the neck 30 through the resistance created by the air bubbles, the bubble meter does not work on the duct. This ensures that a stable lower level of wastewater is maintained in the installation until a new portion of wastewater arrives. The supply of the bubble dispenser with a vertical emergency overflow pipe 31 adjacent to its outlet bend in the zone 32 of the purified water exit from the installation, with the upper end located in the zone of maximum water level 27 in the secondary clarifier 5, eliminates overfilling of the installation with liquid and ensures its stable reliable operation in any conditions.

Due to the fact that all the communicating capacities of the compact wastewater treatment device: receiving aeration tank 3, activation primary sump 4 and secondary sump 5 have a self-leveling wastewater level that does not create excessive pressure on the partition 7, the design of the installation is simplified, the amount of energy consumed for circulation is reduced . The collection of purified water through a bubble dispenser occurs by gravity and does not require energy consumption.

The synergistic effect of the use of a multifunctional linear aerator 18 with a protective bubble wall along the vertical partition 7, an intermediate bottom 17 with side openings 16 for the passage of liquid into the sump 4 in conjunction with an upward protective block-flow of bubbles from coarse-blended mixers 21, which provide protection against the passage of large particles and the reverse partial migration of activated sludge back to the intake aeration tank 3, and holes located in the Central zone of the lower part 8 of the internal partition 7 39 for the gravity flow of the treated liquid with activated sludge into the sump 5 with further sedimentation of sludge to the suction end of the airlift 19, consists in increasing the efficiency of the installation and eliminating the pressure of the liquid on the vertical inner partition 7, achieved by simple means. In combination with the use of structurally simple and reliable degasser and bubble dispenser in the secondary clarifier 5, the installation can significantly reduce energy consumption, providing high quality purified water.

The use of this compact device will significantly simplify the treatment of wastewater in individual domestic plants while reducing the energy consumption for their treatment and increasing the reliability of work, and reduce the area occupied by wastewater treatment plants. The device is simple to perform, economical in operation and maintenance.

Thus, the technical result achieved using the claimed utility model is to significantly increase the reliability of operation, reduce energy consumption for wastewater treatment, simplify the design while increasing its compactness, increase the strength of the internal partitions while increasing the efficiency of wastewater treatment due to the intensification of the impact on wastewater in the zone of flows between communicating adjacent chambers with gravity flow of fluid between them in a single-tank compact d capacity, improve the quality of cleaning with maintaining a stable operating mode, reducing the cost of construction of the treatment plant, increasing environmental devices by improving the quality of cleaning and reducing buffer zones.

Claims (4)

1. A compact device with a vertical oxidizing channel for effective wastewater treatment, containing located in the common housing with a vapor barrier and interconnected receiving aeration tank with an aeration system, located below it and connected with openings in the intermediate bottom, an activation primary sump equipped with bottom located coarse mixers, and separated from the receiving aerotank and the activation primary settler by the internal partition, the secondary settler, provided a system for dosed withdrawal of purified water outside the installation, and a compressor located in a vapor-insulated casing, the openings of the intermediate bottom separating the receiving aeration tank and the activation primary settler are located in its lateral zones in the wall region near the vertical inner partition of the secondary settler, while the vertical inner partition made with at least one hole located above the intermediate bottom and connected by means of airlift active recirculation and with the lower zone of the secondary sump, and with at least one hole located in the lower zone of the vertical internal partition and intended for the flow of liquid from the activation primary sump to the secondary sump, with coarse-bubble mixers located under the holes of the intermediate bottom with a slight lateral displacement. 2. A compact device for effective wastewater treatment according to claim 1, characterized in that the mixing aeration tank mixing system includes a linear aerator located in the wall zone near the vertical internal partition to create a protective bubble wall between the linear aerator and the internal partition, airlift of activated sludge recirculation with an outlet located between the bubble wall and the inner partition, and coarse bubble mixers, providing the formation of a protective bubble Lock-flow between the inlet and the primary activation aeration tank sump for clipping large fractions contaminants. 3. The compact device for effective wastewater treatment according to claim 1, characterized in that the secondary sump is equipped with a device for collecting and degassing biofilms from the water surface, made in the form of a U-shaped pipe with multilevel elbows, the input end made in the form of a side bell and the output end associated with the additional vertical pipe, while the upper end of the additional vertical pipe is located above the maximum level of wastewater and is designed to remove the exhaust air during degassing the limits of the secondary sump, and the lower end is located under water, below the minimum level of wastewater, and is designed to divert the degassed biofilm of activated sludge towards the cone-shaped zone of the secondary sump, and the secondary sump is equipped with a bubble dispenser at the outlet of the purified water from the installation, made in the form of U- shaped pipe with multilevel elbows, while the inlet elbow in the lower zone is equipped with an air injector and a narrowed neck in the upper zone located under the water of the secondary sedimentation tank, etc. dnaznachennoy for generating pulsating air bubble valve. 4. A compact device for efficient wastewater treatment according to claim 1, characterized in that the bubble dispenser is equipped with a vertical emergency overflow pipe adjacent to its outlet bend in the zone of purified water exit from the installation, with the upper end of the emergency overflow pipe water level in the secondary sump.