WO2007089168A1

WO2007089168A1 - Self-regulatng method for sewage water treatment and a device for carrying out said method

Info

Publication number: WO2007089168A1
Application number: PCT/RU2006/000448
Authority: WO
Inventors: Jury Olegovich Bobylev
Original assignee: Jury Olegovich Bobylev
Priority date: 2006-01-31
Filing date: 2006-08-28
Publication date: 2007-08-09
Also published as: EA200601389A1; CZ17047U1; UA93050C2; RU2305662C1; EA009182B1

Abstract

The invention relates to self-regulating systems for the integrated biological waste water treatment by activated sludge in the suspension state thereof. The inventive method consists in presetting time intervals of two alternating phases of a device operation. The first operation phase consists in carrying out the aeration of a sludge stabilising chamber and an aeration tank and in actuating a large-bubble aerator of the external blow unit of a tubular deep shaft for intermixing water and sludge in an activation reservoir and for supplying said mixture to the aeration tank. The second phase consists in carrying out the aeration of an equalising reservoir and the activation reservoir, in actuating sludge and water recirculating and circulating pumps, a pump-eliminator and aerator for breaking a biofilm for recirculating the sludge and cleaning a secondary settling basin. The invention makes it possible to obtain high-quality purified reusable sewage waters and to reduce the energy consumption for treatment intensification.

Description

SELF-REGULATING METHOD FOR SEWAGE TREATMENT AND DEVICE FOR ITS IMPLEMENTATION

The invention relates to self-regulating systems, including a method and device for deep biological treatment of domestic wastewater with activated sludge in suspension, used both in stand-alone cottages, homesteads, and in hotel complexes, schools, sports clubs, towns, catering establishments, and t .d.

In biological wastewater treatment, activated sludge is used, which is a mixture of various bacteria and small microorganisms, but the activation process is possible only with the continuous presence of atmospheric oxygen with varying degrees of saturation, which ensures continuous interaction of wastewater with sludge in its suspended state and, therefore oxidation process.

Known installations for wastewater treatment, in which there are aeration chambers, two-tier sedimentation tanks, sludge collectors, pneumatic aerators, sewage nozzles, flow of treated water from one chamber to another and drainage of purified water (patent RU Ne 819069 and patent RU Ns 2057085). Known plants are complex in structural design, which complicates their manufacture and efficient use with periodic uneven flow of wastewater.

A known method of deep biochemical wastewater treatment and installation for its implementation (patent RU N ° 2060967). According to the method according to the patent RU JMe 2060967, feed wastewater is supplied, primary wastewater sedimentation, aeration, sludge secondary sedimentation, ozonation, sludge recirculation and the release of purified water. Installation for implementing this method consists of a primary sump, aeration tank with aerator, secondary sump, sewage supply pipelines, sludge removal, activated sludge recycling, purified water discharge, and ozonation in the primary sump, and is equipped with an additional sump connected to the primary sump, the purified water tank, and sludge and activated sludge pipelines, connecting the lower parts of all sedimentation tanks. However, this technical solution, both in part of the method and in the part of the device is very complicated and cluttered with unnecessary pipelines, and ozonizers are installed in inefficient places of the tanks.

Known methods of wastewater treatment and devices for their implementation, protected by patents RU ЖНа 2201405, 2220112, 2228915. Devices according to these patents form a model range of plants under the general name "UBAC". These are fully automated systems of various difficulty levels. All these technical solutions contain an accumulative equalizing tank, where preliminary aerobic-anoxide biological treatment is carried out with aerobic activated sludge and the process of enzymatic decomposition of organic pollutants takes place. Next, pre-treated water with sludge enters the aeration tank-activation tank, where the final destruction of organic pollution occurs, after which the water enters the sump. The settled sludge accumulates at the bottom of the sump, and water, having passed a series of purifications through porous filters, is removed from the plants.

The closest analogue to the present invention is the “Wastewater treatment method and device for its implementation)) according to patent RU Ns 2228915. The device includes an equalizing tank, an activation tank, a sump, a sludge stabilization chamber, a piping system and pumps that allow water to flow or force it pumping, and control unit. This device and method for wastewater treatment provides for more thorough filtration of water after the sump, but water from the equalizing tank with not completely decomposed organic pollutants enters the activation tank, which complicates the work activation tank and sump. The device is complicated by a large number of chambers with a porous filter, which complicates its manufacture and operation.

The objective of the present invention is to provide a self-regulating system, including a method and a compact installation, which ensure the achievement of a technical result consisting in obtaining high-quality treated wastewater suitable for reuse, in reducing energy consumption during intensification of treatment, and in organizing a rational scheme of the process of enzymatic decomposition of organic pollution with the accumulation of free carbon, as well as the process of nitrification, denitrification and de otfotatsii at all stages of wastewater treatment, which facilitates the work of cleaning in each subsequent tank, and consequently, increases the effective degree of wastewater treatment, and also simplifies the design, which increases the operational reliability of the device and reduces the complexity of both its manufacture and and during its operation.

To achieve the technical result, a self-regulating method of wastewater treatment is proposed, characterized in that, based on the composition of the wastewater, the duration of two alternating phases of the device is pre-set, air is supplied to the constantly working main pump and internal aerators of the tubular well from the turbo phase distributor, and the time of the interval of the first phase, air is also supplied to the distributor of the first phase, from the distributor of the first phase, the air is distributed into a fine bubble aerate p aeration tank, aerator-agitators of the sludge stabilization chamber and coarse-bubble aerator of external blowing of a tubular well, the method provides for the constant supply of various portions of wastewater through the inlet port to an equalizing tank containing activated sludge periodically aerated in the second phase, followed by overflow of wastewater into the aerated second phase an aspiration tank, also containing activated sludge, then, during the first phase interval, a suspension of partially purified water with activated sludge lifted by a coarse-bubble aerator by external blowing of the tubular well into the aerated tubular well, from the bottom zone of which water is pumped by the main pump into the aerated aeration tank, flowing into the secondary sump according to the law of communicating vessels, where it is defended, and after the water level in the secondary sump rises above the cut of the outlet filter pipe, gravity drain cleaned water through an outlet filter with an outlet pipe outside the device, and after lowering the level of treated wastewater in the activation and equalization tanks to the working level and stopping the flow of water into the tubular well, its contents are pumped out and the main pump is switched to idle mode, as a result why they stop the removal of purified water outside the installation and continue the process of water purification autonomously in all capacities of the device, until the next portion of wastewater is supplied to the equal the reservoir, and resume the operation of the main pump, which leads to the removal of purified water outside the installation, in the amount of not more than the portion of the wastewater received, after the interval of the first phase has ended, as a result of which the device is switched to the beginning of the second phase, the air supply to the distributor is stopped of the first phase and supply air to the distributor of the second phase, stop aeration in the aeration tank, turn off the aerators-agitators of the sludge stabilization chamber, coarse-bubble aerator of external blowing of the tubular well, turn on the aerate stirrers in the equalization tank and finely bubbled aerator in the activation tank supply air to the recirculation pump, to the secondary sump circulation pump, to the biofilm aerator-breaker and biofilm remover pump, and the water recirculation pump is pumped with a recirculation pump to remove excess air from the silt from the bottom of the bottom sludge stabilization chambers, contributing to the gravity flow of displaced water from the stabilization chamber or into an equalizing tank, and then by gravity to activation tank, which either leads to the restoration of the main pump operating mode from idle mode or to the continued operation of the main pump in operating mode, water is pumped from the tubular well, while the main and recirculation pumps work counter-clockwise, while the secondary sump is cleaned during the second phase by turning on the biofilm remover pump, the secondary sump circulation pump and the biofilm aerator-breaker, and when lowering the level in the secondary sump below the cutoff pat a biofilm remover pump pump, this pump goes into idle mode, the process of settling the sludge and squeezing it into the aeration tank begins with the secondary sump circulation pump by pumping clarified water from the middle zone of the aeration tank into the secondary settler, moreover, the secondary sump circulation pump is switched on at the beginning of the second phase, this, the internal aeration of the tubular pump and the operation of the main pump are always on during all phases of the device’s operation, when a large volume of incoming wastewater is supplied, Aries in the equalizing tank is increased, which triggers the safing sensor and it leads to involuntary transfer device operation in the first phase and the first phase zeroing interval timer.

The set result is additionally achieved by the fact that the performance of the recirculation pump for transferring sludge from the aeration tank to the sludge stabilization chamber at the beginning of the second phase is chosen to be greater than the capacity of the main pump, and during the second phase the lower water level in the secondary sump and aeration tank is fixed when the productivity of the main and recirculating pumps.

To achieve the technical result and to implement the method, a device for wastewater treatment is proposed, comprising a housing with a sealed cover, in which an equalizing reservoir containing an activated sludge is provided, equipped with an inlet of wastewater, an emergency sensor, a coarse-bubble aerator-mixer, and communicating by means of an overflow pipe located in the bottom zone of the separation wall of the equalization and activation tanks, with fine-bubble aerators, a tubular well with a main pump and an internal aerator, a coarse-bubble aerator for external blowing of a tubular well, the tubular well in the middle part being provided with a perforation covered outside by a shell made in the form of a cylinder, the lower end of which is located in the bell of a conical bowl, less than the base of which covers and is hermetically fixed on the outer wall of the tubular well body, an aeration tank equipped with a fine bubble aerator, a sludge recirculation pump, a secondary sump circulation pump and a secondary sump communicating with it, equipped with a damper for incoming partially purified water, an output filter, an outlet pipe for clean water and - a biofilm breaker, a biofilm remover pump, made in the form of a pipeline, J - shaped, one end of which is located below the zone filter, and the second end is higher than the zone of the output filter in the upper part of the aeration tank, the sludge stabilization chamber equipped with a sludge damper and aerators-mixers located in its bottom part, while the sludge stabilization chamber is interconnected with the equalization tank through an overflow pipe, control unit, compressor and valve distributor associated with air ducts for supplying air to reservoir and chamber aerators during operation of the device in the first, second and turbo phases.

The set result is additionally achieved by the fact that the device’s body is made of plastic and has the shape of a cylindrical cup, the walls of which are made of two concentrically mounted coaxial nozzles, internal and external, interconnected by stiffeners, while the end zone of the internal nozzle covers an adapter with a through hole, the outer side of which is made with a rectangular flange, and the cavity between the outer and inner nozzles is filled with layers of fillers, the lower layers are heavier, such as concrete, and the upper one is light and heat-saving, such as polyurethane, as well as the case can be made in the form of a rectangular glass.

The invention is illustrated by drawings, where in FIG. 1 - a device for wastewater treatment; in FIG. 2 is a top view of a wastewater treatment apparatus when the body is cylindrical; in FIG. 3 is a section A-A of FIG. 2; in FIG. 4, 5 is a top view of the device when the case is made rectangular.

A device for wastewater treatment comprises a housing 1 and a lid hermetically closing it (not shown in the drawing). In the housing 1 there are several containers for the sequential movement of wastewater, as a result of which the wastewater is treated. Initially, the wastewater flows through the inlet pipe 2 of the wastewater supply into the equalizing tank 3. In the bottom part of the equalizing tank 3, large-bubble aerators are installed - mixers 4, which are turned on in the second phase of the device and process the wastewater with rising air flow, while maintaining a high concentration of enzymes for decomposition of organic pollutants. From the equalizing tank 3, water flows by gravity through the overflow pipe 5, located in the bottom zone of the separation wall 6, separating equalizing 3 and activation 7 tanks, enters the activation tank 7, where the water is subjected to subsequent processing.

A fine bubble aerator 8 is located in the activation tank 7, but several can be installed. Since the fine bubble aerator 8 is located in the bottom zone, air bubbles penetrate the entire column of water in the tank 7, and the fine bubbles provide a more reliable and thorough dissolution of air oxygen for use biomass in the oxidation of decaying organic waste water pollution.

In the activation tank 7 there is a tubular well 9 with a closed bottom 10. In the tubular well 9 there is an internal aerator 11, the main pump 12, which is an airlift. The walls 13 of the tubular well 9 in the middle zone are made with a perforation 14, below which a conical bowl 15 is fixed, the smaller base of which covers and is fixed on the wall 13 of the tubular well 9, and the larger base, made in the form of a bell 17, is directed upward.

An emergency sensor 16 is installed in the equalizing tank 3.

A cylindrical shell 18 is fixed above the bell 17 on the tubular well, so that its lower end enters the bell 17 with the formation of a gap 19 between the shell 18 and the bell 17. When the column of treated water in the activation tank 7 is above the gap 19, it communicates according to the law vessels enters the bell, and with its further increase, it flows by gravity through the perforation 14 in the walls of the tubular well, falling into it. Outside, the tubular well 9 is blown by a coarse bubble aerator 20, due to which large inclusions are distilled off from the cone-shaped bowl 15, but sludge is mixed with water when water is supplied from the well 9 to the aerotank 21 in the first phase. Inside the tubular well, water is constantly exposed to air through an internal aerator 11, and the main pump 12 pumps partially purified water from it to the aerotank 21.

A fine bubble aerator 8, a secondary sludge recirculation pump 22 for transferring sludge to a settler 23 of the sludge stabilization chamber 24, and a secondary sludge circulation pump 25 for pumping water into a settler 26 of the secondary sump 27 are located in the aeration tank 21.

The secondary sump 27 is made in the form of a cone, the smaller base of which is facing down, while in the wall 28 at the lower smaller base 29, the neck 30 is made, and the base 29 in the area of the neck 30 is provided with a visor 31. In the secondary sump 27, purified water settles, sludge settles on the base 29, and due to the presence of the neck 30 and the secondary pump 25 of the secondary sump, it is squeezed out of the secondary sump 27 and precipitated in aeration tank 21.

The secondary sump 27 is equipped with an outlet filter 32 with an outlet pipe 33 for draining completely purified water, an aerator-breaker

34 biofilms, as well as a biofilm remover pump 35, made J - shaped with uneven knees. In this case, the open end 36 of the low elbow 37 is located in the secondary sump 27 at a level slightly lower than the cutoff of the outlet filter 32, and the end 38 of the high elbow 39, equipped with an air-injection pump 40, is located above the aeration tank 21.

The sludge stabilization chamber 24 is equipped with coarse-bubble aerators 4 and is connected to the equalizing tank 3 by an overflow pipe 41, which allows gravity to move the water displaced when the mixture of sludge and water enters the aeration tank 24 from the aeration tank 21. The recirculation pump 22, which transfers the excess sludge to the settler of the sludge stabilization chamber 24 , is installed just below the level of the neck 30, and the circulation pump 25 of the secondary sump for pumping water into the damper of the secondary sump 27 is installed at the level of perforation 14 tubular 9 of the well.

The control unit 42 is installed in the housing 1, the compressor 43 is connected by an air duct 44 to the turbo phase distributor 45 and with a switching distribution valve 46, which provides air to the distributor 47, which ensures the operation of the device in the first phase and the distributor 48, which ensures the operation of the device in the second phase.

The housing 1 of the proposed device can be made both cylindrical in the form of a glass (Fig. 2), and rectangular (Figs. 4, 5) in the form of a glass, the walls of which are made of two concentrically mounted coaxial nozzles of the inner 49 and outer 50, interconnected by ribs stiffness 51. The entire body is made of polypropylene, while end zone, i.e. the neck of the inner pipe 49 covers an adapter 52 made with a through hole; the outer side of the adapter is made with a rectangular flange 53, which is included in the rectangular cover, providing reliable tight closing of the housing 1. When installing the housing in the place of its constant location in the ground, the walls of the glass serve as formwork, and the space 54 between the inner 49 and outer 50 nozzles are filled with a combined filler. So the lower part is filled with heavy concrete 55 for strength and weight, and the upper part with lighter polyurethane foam 56 for thermal insulation. Since the secondary settling tank 27 is made conical and located in the center of the body, and the equalizing, activation tanks, aeration tank and the sludge stabilization chamber are located on the periphery of the secondary settling tank “on”, the walls separating all the tanks perform the function of additional stiffeners, and in connection with the secondary the sump form a single rigid frame structure.

The self-regulating method proposed according to the invention, providing self-regulation of the operation of the device, is carried out as follows by the proposed device for wastewater treatment.

When choosing the size of a device, they always know in advance how much wastewater it should be designed for. Based on the estimated composition of the wastewater, set the duration of two alternating phases of operation of the device, sequentially alternating first and second phases. The contaminated wastewater through the inlet pipe 2 of the wastewater supply of the housing 1 is fed portionwise to the equalization tank 3, in which the process of treating wastewater with activated sludge begins, due to the supply of air to the second phase of the device through aerators 4. The wastewater flows by gravity as it flows in communicating vessels, from the equalization tank 3 to the activation tank 7 through the overflow pipe 5. The activation tank 7 is an activation tank, so how water undergoes fine bubble aeration in the second phase created by the aerator 8.

From the reservoir 7, the water flows by gravity into the tubular well 9, where it is also aerated and pumped into the aerotank 21, where the water undergoes fine bubble aeration, which is included in the first phase of the device. The air is constantly supplied to the tubular well into the continuously working main pump and the internal aerator of the tubular pump from the turbo phase distributor.

According to the law of communicating vessels, water flows from the aeration tank 21 by gravity into the lower part of the secondary sump 27, where the level gradually rises and, reaching the output filter 32, is discharged through the outlet pipe 33 for use in household needs. After stopping the flow of water into the tubular well, the water is completely pumped out, which leads to the main pump switching to idle mode, as a result of which the purified water is discharged outside the installation and the water treatment process is continued independently in all tanks until the next portion of wastewater is delivered to equalization tank through the inlet pipe or before the recirculation pump starts in the second phase. As a result of these revenues, the main pump and the discharge of treated water outside the installation are resumed in the amount of no more than a portion of the wastewater.

After the interval of the first phase has passed, the air supply to the first phase distributor is stopped, the second phase is turned on, i.e. air is supplied to a second phase distributor. At this time, aeration in the aeration tank is turned off, the aerators of the mixer of the sludge stabilization chamber and the large-bubble aerator of external blowing of the tubular well are turned off. In the second phase, they include agitators-aerators in the equalizing tank, and the aerator in the activation tank, supply air to the recirculation pump, the aerator-separator biofilm and the biofilm remover pump, pump the suspension of water from the recirculation pump, excess sludge from the bottom of the aeration tank into the sedimentation chamber of the sludge stabilization chamber. All this contributes to a rise in the water level in this chamber and contributes to the gravity flow of displaced water into the equalizing tank via the overflow pipe 41, and then through the overflow pipe 5 by gravity to the activation tank.

When the water reaches the gap 19 and above it, water will enter the tubular well, which will lead to the restoration of the operating mode of the main pump, i.e. the main pump will pump water from the tubular well. At this moment, the two airlift pumps, the main and the recirculation ones, will work counter-clockwise, and initially the performance of the recirculation pump is slightly higher than the performance of the main pump, but due to changes in levels in the aeration tank and the activation tank, the performance of the main pump increases and the recirculation pump decreases. This leads to a decrease in the rate of change of levels and their stabilization at a certain point, where the performance of these two pumps becomes the same. At the same time, the biofilm remover pump, the biofilm aerator-breaker, i.e. the clarification of the secondary sump occurs. This leads to the filling of the secondary sump with activated sludge from the bottom area of the aeration tank according to the law of communicating vessels and the activation of denitrification processes in the secondary sump. This process ends when the secondary sump level decreases below the suction end 36 of the biofilm remover pump and it goes into idle mode, sludge settling begins and it is forced into the aeration tank by the secondary sump circulation pump 25, which has not previously had a significant effect on the device processes. The circulation pump pumps clarified water from the middle zone of the aeration tank to the secondary settler sedimentation tank, and from it to the bottom outlet zone of the secondary sedimentation tank, squeezing sedimentary sludge, since the end of the settler is located in the lower zone of the secondary sedimentation tank, where silt settles and cleans the secondary sedimentation tank from it. In the second phase, the main and recirculation pumps are turned on in the opposite direction. The ratio of their performance allows you to determine the lower level of the aeration tank, at which the performance of the two pumps are equal, because airlift pumps greatly change their performance when the height of the liquid column is changed, and the working level is not determined by the sensor, but by the design of the tubular well and it is impossible to pump water from the equalization and activation tanks below the gap 19. This action is the self-regulation of the process of the device in the second phase.

For the correct operation of the device, it is necessary to select the capacity of the recirculation pump at operating levels slightly more than the performance of the main pump. The first phase includes aeration of the sludge stabilization chamber and aeration of the aeration tank, as well as a coarse-bubble aerator of external blowing of the tubular well for mixing water with sludge in the activation tank and supplying this mixture to the aeration tank, which eliminates the ingress of large inclusions into the tubular well. The second phase includes aeration of the equalization tank, activation tank, sludge and water recirculation and circulation pumps, and a biofilm remover pump and aerator-breaker for sludge recirculation and cleaning of the secondary sump.

With a large simultaneous discharge of wastewater, which leads to a rise in the leveling tank to the emergency sensor., The device is forcibly transferred to the first phase, and the timer of the first phase is reset. This leads to an increase in the productivity of the treatment plant, since due to the peculiarities of the operation of airlift pumps, i.e. the main pump, with a high height of the liquid column, their productivity is significantly increased. This happens very rarely, but if the emergency sensor triggered, it leads to the forced activation of the first phase and the zeroing of the timer for the interval timer of the first phase. Airlift - the main pump at this level, according to experimental data, has a capacity of more than three times large relative to the operating level, which will quickly automatically lower the level below the emergency.

Experimental work on the implementation of the method, carried out with a percentage level of wastewater pollution, showed the achievement of the technical task and ensuring the production of clean water without suspended solids, suitable for use in household needs and for subsequent cleaning and disinfection in recycled water supply systems. The device very well tolerates the presence of animal hair, fat and various debris in waste water, which previously was the reason for the failure of many wastewater treatment plants.

The device and the method of its operation according to the invention are energy-saving, and the device is reliable in operation and easy to manufacture and maintain. Devices made in accordance with the invention and operating according to the proposed method have shown effective operation in any situations involving the loading of waste water.

Claims

CLAIM

1. A self-regulating method of wastewater treatment, characterized in that, based on the composition of the wastewater, the intervals of the duration of two alternating phases of operation of the device are pre-set, air is supplied to the constantly working main pump and internal aerators of the tubular well from the turbo phase distributor, and during the interval of the first phase air is also supplied to the first phase distributor, from the first phase distributor the air is distributed into a fine bubble aeration tank aerator, aerators-mixers of the sludge stabilization chamber and large a bubbler aerator of the external blowing of a tubular well, and consisting of a constant supply of various wastewater portions through the inlet port to an equalizing reservoir periodically aerated in the second phase containing activated sludge, then flowing it into the activation tank aerated in the second phase, also containing activated sludge, then during the interval of the first phase, the suspension of partially purified water with activated sludge lifted by the coarse-bubble aerator of the external blowing of the tubular well into the aerated a tubular well, from the bottom zone of which the main pump pumps water into an aerated aeration tank, flows into the secondary sump according to the law of communicating vessels, where it is defended, and after the water level in the secondary sump rises above the cut of the outlet filter pipe, purified water is drained by gravity through the outlet filter with the outlet pipe outside the device, and after lowering the level of treated wastewater in the activation and equalization tanks to the working level and stopping the flow of water into the tubular the well pump out its contents and transfer the main pump to idle, as a result of which the withdrawal of purified water outside the installation is stopped and the water purification process continues autonomously in all capacities of the device until supplying the next portion of wastewater to the equalization tank, as a result of which the main pump resumes and the treated water is drained outside the installation, in the amount of no more than the portion of wastewater received, after the interval of the first phase is completed, as a result of which the device is switched to the beginning of the second phase stop the air supply to the distributor of the first phase and supply air to the distributor of the second phase, stop aeration in the aeration tank, turn off the aerators-agitators of the sludge stabilization chamber, large-bubble aerator external blowing of the tubular well, include aerators-mixers in the equalizing tank and a fine bubble aerator in the activation tank, supply air to the recirculation pump, to the secondary sump circulation pump, to the biofilm aerator-breaker and biofilm remover pump, recycle and recycle water from the pump from the bottom of the aeration tank into the sedimentation chamber of the sludge stabilization chamber, facilitating the flow of gravity displaced water from the stabilization chamber or into an equalizing tank, and by gravity to the activation tank, which either leads to the restoration of the main pump operating mode from idle mode, or the main pump continues to operate in the operating mode, water is pumped from the tubular well, while the main and recirculation pumps work counter-clockwise, at the same time they are cleaned during the second phase secondary sump by turning on the biofilm remover pump, the secondary sump circulation pump and the biofilm aerator-breaker, and when lowering the level in the secondary sump at the same time, when the nozzle of the biofilm remover pump is cut off, this pump goes into idle mode, the process of settling the sludge and squeezing it into the aeration tank begins with the secondary settling pump by pumping the clarified water from the middle zone of the aeration tank into the sedimentation tank, and the secondary settling pump is switched on at the beginning of the second phase while the internal aeration of the tubular pump and the operation of the main pump are switched on continuously at all phases of operation of the device, with a large volume of incoming wastewater, the level in the equalization tank rises, which leads to the triggering of the emergency sensor and this leads to the forced transfer of the device to the first phase and reset the interval timer to the first phase

2. The self-regulating method according to claim 1, characterized in that the productivity of the recirculation pump for transferring sludge from the aeration tank to the sludge stabilization chamber at the beginning of the second phase is chosen more than the capacity of the main pump.

3. The self-regulating method according to claim 1, characterized in that during the second phase the lower water level in the secondary sump and aeration tank is fixed with equal performance of the main and recirculation pumps.

4. A device for wastewater treatment, comprising a housing with a sealed cover, which contains an activated sludge equalizing tank, equipped with an inlet wastewater, an emergency sensor, a large-bubble aerator-mixer, and communicating by means of an overflow nozzle located in the bottom zone of the dividing wall of the equalizing and activation tanks, while in the activation tank there are fine-bubble aerators, a tubular well with a main pump and an internal aerator, a large bubble a shaped aerator for external blowing of the tubular well, the tubular well body in the middle part being provided with perforations enclosed on the outside by a shell made in the form of a cylinder, the lower end of which is located in the bell of the conical bowl, the smaller base of which covers and is hermetically fixed on the outer wall of the tubular well body, aeration tank equipped with a fine bubble aerator, a sludge recirculation pump, a secondary sump circulation pump and a secondary sump communicating with it, equipped with a damper partially flowing purified water, an output filter, an outlet pipe of clean water and an aerator-breaker biofilm, pump biofilm remover, made in the form of a pipeline, J-shaped, 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, the sludge stabilization chamber equipped with a sludge damper and aerators-mixers, located in its bottom part, while the sludge stabilization chamber is interconnected with the equalizing tank by means of an overflow pipe, a control unit, a compressor and a valve distributor associated with the supply air ducts air to reservoir and chamber aerators when the device is in the first, second, and turbo phases.

5. The device according to claim 4 is characterized in that the housing is made of cylindrical plastic in the form of a cup, the walls of which are made of two concentrically mounted coaxial pipes, internal and external connected by stiffeners, while the end zone of the internal pipe covers an adapter with a through hole, the outer side of which is made with a rectangular flange, and the cavity between the outer and inner nozzles is filled with layers of fillers, the lower layers are heavier, such as concrete, and Upper light and heat-saving, such as polyurethane.

6. The device according to p. 4 or 5, characterized in that the casing can be made rectangular in the form of a glass.