RU109120U1 - UNILOS-OPTIMA BIOLOGICAL CLEANING STATION - Google Patents

Abstract

The utility model relates to the field of biological wastewater treatment, the UNILOS-OPTIMA biological treatment station, contains a housing in which there is a receiving chamber separated by partitions, an aeration tank), a secondary sludge settler and stabilizer, as well as connected to the control unit and connected to at least one to the compressor through an electromagnetic valve, an aeration system consisting of a turbo mode subsystem, a direct cleaning phase subsystem and a reverse cleaning phase subsystem, and the turbo mode subsystem includes a turbo redelitel air, a main pump with filter large fractions of the main air duct of the pump, the main pump purging air pipe in the receiving chamber, and a pump circulator aeration tank with pump-duct circulator; the subsystem of the direct phase of cleaning includes an air distributor, an air duct for external aeration of the filter of large fractions and an aeration tank aerator with an air duct; and the subsystem of the reverse phase of cleaning includes an air distributor, an aerator of the receiving chamber with an air duct, an aeration tank recirculator with an air duct, a sludge stabilizer pump with an air duct, a secondary sump pump with an air duct), as well as a secondary sump purge air duct; at the same time, a flow damper and a purge nozzle are located in the secondary sump; wherein the housing consists of a conical base, a cylindrical middle part and a cover with stiffeners, the height of the conical part refers to the joint height of the middle part and the cover in the range from 3: 1 to 4: 1.

Description

The utility model relates to the field of biological wastewater treatment, and can be used in installations for biological wastewater treatment of small settlements, cottages and detached buildings.

A device for wastewater treatment is known, including, among other things, an activation tank (aeration tank or aeration chamber) with a water supply unit for treatment, an aerator and an activated sludge removal pump, a settling tank with a purified water outlet made in the form of a truncated pyramid is installed in the activation tank , the smaller base of which is facing down, and equipped with an exhaust nozzle with a soothing chipper and a protective visor. The sump is also equipped with a damper and a large-bubble aerator with an airlift made in a V-shape, with the open end of one elbow located below the water mirror in the sump, and a nozzle for air supply is installed in the lower part of the other elbow, and the end of this elbow is discharged into the sump. In the activation tank, a biological charge and a pump for pumping purified water with activated sludge to the sedimentation tank are installed (RF patent No. 2201405, 2003).

The disadvantages of this device are also the complexity of its design and, as a result, the complexity of its maintenance.

A WATER PURIFICATION INSTALLATION is also known (RF patent No. 97362, 2010), which contains a housing divided by partitions into four chambers: a receiving chamber, aeration tank, a secondary sump and a sludge stabilizer. The installation also includes a control unit, a compressor and an aeration system connected to it through an electromagnetic valve. A constructive installation option is possible with two compressors operating simultaneously or alternately.

The disadvantages of this device is the lack of compactness of the device and, consequently, the inability to use in a number of technical projects.

The technical result of the utility model is to eliminate this drawback.

The technical result is achieved due to the fact that the biological treatment plant UNILOS-OPTIMA contains a housing divided by partitions into four chambers: a receiving chamber, aeration tank, a secondary settling tank and a sludge stabilizer. The installation also includes a control unit, a compressor and an aeration system connected to it through an electromagnetic valve; the housing is vertically oriented, consisting of three mating parts: the base in the form of a truncated cone tapering to the bottom, having a thickening of a cylindrical shape in its upper part; located above the middle part, the lower diameter of which is equal to the upper diameter of the upper thickening of the base; the middle part is a sequential pairing of the hollow bottom cylinder, a truncated cone with a small angle, and the two upper cylinders, the diameter of the upper cylinder being related to the lower diameter of the middle part in a ratio of 1 to 3 to 2 to 3; a cap is put on the middle part, which is the pairing of the hollow cylinder and part of the sphere, on top of the cap there are 2 diametrical recesses that act as stiffeners; the height of the base (conical part) refers to the joint height of the middle part and the cover in the range from 3: 1 to 4: 1, which ensures the compactness of the treatment plant, its stability and the ability to install the station without the use of additional devices.

All elements of the device, including the housing, are made of polymeric materials, polypropylene is preferred.

A constructive installation option is possible with two compressors operating simultaneously or alternately.

The aeration system includes three subsystems: a turbo-mode subsystem, a direct cleaning phase subsystem, and a reverse cleaning phase subsystem. The turbo-mode subsystem includes an air turbo distributor, a main pump with a filter of large fractions, an air duct for the main pump, an air duct for purging the main pump in the intake chamber, and a pump-aeration tank circulator with an air duct for the pump-circulator.

The subsystem of the direct cleaning phase includes an air distributor, an air duct for external aeration of the filter of large fractions, and an aeration tank aerator with an air duct. The reverse phase of the cleaning subsystem includes an air distributor, an aerator of the receiving chamber with an air duct, a pump - aeration tank recirculator with an air duct, a sludge stabilizer pump with an air duct, a secondary sump pump with an air duct, and a secondary sump purge air duct. The secondary settler also contains a flow damper and a purge nozzle.

After the secondary sump, usually near its upper part, there may be a tank of purified water with a pump for pumping purified water.

In addition, the installation can be equipped with equipment for filtering and disinfecting water (for example, in the form of a sand filter and a UV disinfection lamp), placed in a separate compartment inside the station building.

The station case is made integral, consisting of three parts: the base in the form of a truncated cone tapering to the bottom, having a thickening of a cylindrical shape in its upper part; located above the middle part, the lower diameter of which is equal to the upper diameter of the upper thickening of the base; the middle part is a sequential pairing of the hollow bottom cylinder, a truncated cone with a small angle, and the two upper cylinders, the diameter of the upper cylinder being related to the lower diameter of the middle part in a ratio of 1 to 3 to 2 to 3. A cover is worn on the middle part, which is the pairing of the hollow cylinder and part of the sphere, on top of the cover there are 2 diametrical recesses, which act as stiffeners. The height of the base (conical part) refers to the joint height of the middle part and the cover ranging from 3: 1 to 4: 1, which ensures the stability of the case and the possibility of its installation without the use of additional devices.

Figure 1 schematically shows the biological treatment station UNILOS-OPTIMA in expanded form. It indicates:

1 - receiving chamber;

2 - aeration tank;

3 - secondary sump;

4 - sludge stabilizer;

6 - capacity of purified water;

7 - flow damper;

8 - filter of large fractions;

10 - pump purified water;

11 - the main pump;

12 - aeration tank pump - circulator;

13 - aeration tank pump - recirculator;

14 - sludge stabilizer pump;

15 - aerator of the receiving chamber;

16 - aeration tank aerator;

17 - secondary sump pump - grease remover;

18 - nozzle purge secondary sump;

20 - level sensor receiving chamber - working;

21 - level sensor of the receiving chamber - control;

22 - compressor;

23 - the electromagnetic valve;

24 - air distributor - turbophase;

25 - air distributor - direct phase;

26 - air distributor - reverse phase;

27 - air pipe - the main pump;

28 - air duct - purge the main pump;

29 - air pipe - circulator;

30 - air duct - aeration tank aerator;

31 - air pipe - sludge stabilizer pump;

32 - air duct - aerator of the receiving chamber;

33 - air duct - purge filter of large fractions;

34 - air pipe - recirculator;

35 - air duct - grease extractor;

36 - air duct - purge the secondary sump;

37 - control unit;

38 - installation casing.

Biological treatment station UNILOS-OPTIMA operates as follows. Wastewater, mainly domestic water, enters the receiving chamber 1, where large fractions of contaminants (garbage) are separated using a filter 8. The receiving chamber 1 will allow to take a salvo discharge of wastewater and average them over the composition, without violating the mode of operation of the remaining chambers of the installation. In the receiving chamber 1, the biological treatment of wastewater begins using activated sludge coming in from the sludge stabilizer 4 during the reverse phase and air coming in through the aerator of the receiving chamber 15 and duct 32. The level of wastewater in the receiving chamber 1 is monitored using a working sensor 20 and the control sensor 21. Periodically, to clean from contaminants clogging the main pump 11 and the filter 8, purge through the air ducts 27 and 33, respectively. Air is supplied to all installation chambers from compressor 22.

From the receiving chamber 1, the wastewater via the main pump 11 enters the aeration tank 2, in which intensive biological treatment occurs using activated sludge. Aerotank 2 operates in two modes, which are set by the control unit 37 by switching the solenoid valve 23. In the first mode, the wastewater is intensively mixed and saturated with oxygen by air duct 30 and an aerator 16. At the same time, the air distributor 25 works. In the second mode, the air supply and mixing are stopped and the settled sludge is pumped out to the sludge stabilizer 4 using the aeration tank pump 13 and the air duct 34 thereto.

From the aeration tank 2, the mixture of purified water and activated sludge is pumped through the flow damper 7 through a flow damper 7 to a secondary sump 3, where water is clarified and activated sludge is deposited. The grease film floating on the surface in the secondary sump 3 is removed by the pump 17 during the reverse phase by supplying air to it through the air duct 35. The cleaned and clarified secondary sump is removed by gravity outside the unit or into the tank 6, from which the purified water is further pumped out 10.

Excess activated sludge from aeration tank 2 is pumped out by pump 13 into sludge stabilizer 4. Air is supplied to pump 13 through air duct 34.

During operation of the reverse phase, air is supplied through the air duct 36 to the blower nozzle of the secondary sump 18, which ensures the direction of fluid flow towards the grease trap 17. Also, in the reverse phase, air is supplied through the air duct 31 to the sludge stabilizer pump 14 (a variant with an aerator instead of a pump is possible).

The turbofase air distributor 24 operates independently of the activation of the magnetic valve 23. It is designed to distribute air to the aeration tank pump 12 and the air duct 29 thereto, the main pump 11 and the air duct 27 thereto, as well as a purge 28 of the main pump.

If sewage does not enter the unit, it operates autonomously with constant recirculation of water. When the main pump 11 pumps water from the intake chamber 1 to the minimum permissible level, the control unit 37 switches the electromagnetic valve 23 to the reverse phase of cleaning, and the air distributor 26 enters into operation.

The housing and all the elements of the installation are made of polymeric materials, for example, polypropylene or polyethylene, or vinyl plastic, etc.

The preferred housing dimensions are: total height from 2000 to 2500 mm, at which the height of the base is from 1500 to 1800 mm; the diameter of the lower part of the base is from 1100 mm to 1300 mm, the maximum diameter of the case (maximum diameter of the middle part): from 1400 to 1500 mm.

Thus, the proposed technical solution allows to intensify the work of a compact and easy to install and operate device for biological wastewater treatment.

Claims (9)

1. Biological treatment station UNILOS-OPTIMA, comprising a housing (38), in which there is a receiving chamber (1) separated by partitions, an aeration tank (2), a secondary sump (3) and a sludge stabilizer (4), as well as connected to the control unit ( 37) and connected to at least one compressor (22) through an electromagnetic valve (23) an aeration system consisting of a turbo mode subsystem, a direct cleaning phase subsystem and a reverse cleaning phase subsystem, the turbo mode subsystem including an air turbo distributor (24), a main pump (11) with filter ohm (8) of coarse fractions, an air line (27) of the main pump, an air line (28) to purge the main pump in the receiving chamber, and also a circulation pump (12) of the aeration tank with an air line (29) of the circulating pump; the subsystem of the direct phase of cleaning includes an air distributor (25), an air duct (33) of an external aeration filter (8) of large fractions, and an aerator (16) of an aeration tank with an air duct (30); and the subsystem of the reverse phase of cleaning includes an air distributor (26), an aerator (15) of the receiving chamber with an air duct (32), a recirculation pump (13) of an aeration tank with an air duct (34), a stabilizer pump (14) of a sludge with an air duct (31) ), a pump (17) for the secondary sump (3) with an air duct (35), as well as an air duct (36) for blowing the secondary sump; at the same time, a flow damper (7) and a purge nozzle (18) are located in the secondary settler, characterized in that the housing consists of a conical base, a cylindrical middle part and a cover with stiffeners, the height of the conical part refers to the joint height of the middle part and the cover within from 3: 1 to 4: 1. 2. Biological treatment station UNILOS-OPTIMA according to claim 1, characterized in that next to the upper part of the secondary sump is a container (6) of purified water with a pump (10) for pumping purified water. 3. The biological treatment plant UNILOS-OPTIMA according to claim 1, characterized in that it is additionally equipped with equipment for filtering and disinfecting water, located in a separate compartment inside the station building. 4. Biological treatment station UNILOS-OPTIMA according to claim 1, characterized in that all the elements of the station are made of polymer materials. 5. The biological treatment plant UNILOS-OPTIMA according to claim 1, characterized in that the middle part of the housing is a serial pairing of a hollow cylinder, a truncated cone with a small angle and two upper cylinders. 6. Biological treatment station UNILOS-OPTIMA according to claim 1, characterized in that the middle part of the body is a serial pairing of the hollow bottom cylinder, a truncated cone with a small angle and two upper cylinders, and the diameter of the upper cylinder corresponds to the diameter of the lower cylinder in relation to 1: 3 to 2: 3. 7. Biological treatment station UNILOS-OPTIMA according to claim 1, characterized in that the height of the hull is from 2000 to 2500 mm 8. The biological treatment plant UNILOS-OPTIMA according to claim 1, characterized in that the height of the base of the housing is from 1500 to 1800 mm. 9. The biological treatment plant UNILOS-OPTIMA according to claim 1, characterized in that the maximum diameter of the housing is from 1400 to 1500 mm.