RU2593257C1 - Plant for cleaning oil-containing and waste water - Google Patents

Abstract

FIELD: treatment plants.

SUBSTANCE: invention relates to water treatment systems and can be used for cleaning oil-containing and waste water. Plant for cleaning oil-containing and waste water comprises at least two cleaning stages, connected in series along flow of purified water and separated from each other by means of partition walls 7. Each cleaning stage consists of a flotation reactor 1, 2, 3 and floatation separator 4, 5, 6 separated by partition 8. Aeration unit 10 of first stage is communicated via pump 9 with bottom part of floatation separator 6 of last purification stage. Output of purified water feed pipeline 11 is connected with bottom part 16 of floatation reactor 1 of first purification stage. First output of aeration unit 10 is connected through throttling valve 26 with input of floatation reactor 1 of first purification stage. Second and subsequent purification stages are equipped with deaeration units 31, 32. Output of each of deaeration units 31, 32 is located in bottom 33, 34 and communicated via throttle valve 26 to input of corresponding floatation reactor 2, 3 and, via pressure regulator 35 with input of upper part of dearation unit 36, 37 of next purification stage. Second output of aeration unit 10 is connected through pressure regulator 35 to input of upper part 36 of dearation unit of second purification stage. Output of each throttling valve 26 is arranged at input of corresponding floatation reactor 1, 2, 3. Cross-sectional area of bottom of each floatation reactor 1, 2, 3 uniformly decreases in direction from top to bottom. Cross-sectional area of floatation reactor 4, 5, 6 is not less than cross-sectional area of corresponding floatation reactor. Partitions 8, separating floatation reactors 1, 2, 3 from floatation separators 4, 5, 6 are configured for free movement of purified water flow in upper parts of floatation reactors 1, 2, 3 and floatation separators 4, 5, 6 of one purification stage. Partitions 7, separating purification stage, are configured for free flow of purified water in bottom parts of floatation separators 4, 5, 6 and floatation reactors 1, 2, 3 of various purification stages. Aeration unit 10 is designed to maintain saturation pressure is 0.3-0.6 MPa. Deaeration units 31, 32 can maintain saturation pressure of 0.1-0.3 MPa.

EFFECT: invention increases efficiency of cleaning oil-containing and waste water.

7 cl, 1 dwg

Description

The invention relates to water purification systems and can be used for purification of oil-containing and waste water in oil refining and oil producing complexes, in the energy sector, in the food industry, etc.

A device for purifying oil-containing and wastewater is known, comprising at least two purification stages connected in series along the stream of purified water, each of which consists of a flotation reactor and a flotation separator, a recirculation pump, the suction pipe of which is connected to the purified water section, and a pressure pipe through taps connected to the flotation reactors of each stage, an air supply ejector located between the suction and pressure pipelines of the recirculation pump, the pipeline for supplying cleanable and pipes removal of the purified water is carried out (see. BV Derjaguin, SS Dukhin et al. "microflotation. Water purification, enrichment," 1986, at p.82).

In this device, water saturated with air using an ejector enters a pressure saturator tank, in which air is dissolved, as well as large undissolved bubbles are separated, which leads to their release in the upper zone of the saturator.

The disadvantage of this device is the difficulty of debugging the flotation mode, which is expressed in the need to accurately control the amount of air supplied by the ejector, and the discharge of excess air from the saturator. Another disadvantage of the device is the presence of a saturation border of water with dissolved air, which is the reason for the low efficiency of such devices, which is determined by the limited size range of the floating bubbles.

As the closest analogue, an installation for the purification of oily wastewater containing at least two stages of purification, connected in series along the flow of treated water and separated by partitions, each of which consists of a flotation reactor and a separator separated by a partition, an aeration unit of the first stage, is adopted purification, communicated through the pump with the bottom part of the last separator flotation separator, the pipeline for supplying the cleaned and the pipeline for discharging purified water (see RF patent 2367622, IPC C02F9 / 00, 2009).

The disadvantage of the closest analogue is the low degree of purification of oil and wastewater due to the following factors:

- the flotation process is carried out by germinal vesicles of the same average diameter;

- purified water after all stages of purification is mixed with contaminated water.

The problem to which the claimed invention is directed, is to increase the efficiency of purification of oily wastewater from fine impurities by pressure flotation.

The technical result achieved by solving the problem is expressed in increasing the efficiency of treatment of oily wastewater due to the following factors:

- the flotation process is carried out by germinal vesicles of various average diameters;

- the exception of mixing the source of purified water with already purified;

- the formation and distribution of germinal vesicles occurs more evenly;

- an increase in the volume of purified water subjected to a one-time flotation.

The problem is solved in that in an installation for the purification of oily and wastewater containing at least two stages of purification, connected in series along the flow of purified water and separated by partitions, each of which consists of a flotation reactor and a separator, separated by a partition, aerating the node of the first purification stage, communicated through the pump with the bottom part of the flotation separator of the last purification stage, the supply pipe to be cleaned and the discharge pipe to be cleaned in The outlet of the pipeline for supplying purified water is communicated with the bottom part of the flotation reactor of the first purification stage, the inlet of the aeration unit is communicated through a pump with the bottom part of the flotation separator of the last purification stage through the pipeline of supplying water to the aeration, the first outlet of the aeration unit is communicated through a throttling valve with an entrance to the flotation reactor of the first stage purification, located at the lower point of its bottom, by means of a pipe for supplying aerated water, in addition, the second and subsequent stages of purification are equipped with a deaeer nodes, and the outlet of each of them is located in the bottom and communicated through a throttling valve with an inlet to the corresponding flotation reactor located at the lower point of its bottom through a deaerated water supply pipeline, and through a pressure regulator with an entrance to the upper part of the deaerating unit of the next cleaning stage through a pipeline water supply for deaeration, while the second outlet of the aeration unit is communicated through a pressure regulator with an entrance to the upper part of the deaerating unit of the second cleaning stage by means of pipes aeration water discharge wires, in addition, the output of each throttling valve is located at the entrance to the corresponding flotation reactor, and the cross-sectional area of the bottom of each flotation reactor uniformly decreases from top to bottom, in addition, the cross-sectional area of the flotation separator is not less than the cross-sectional area of the corresponding flotation reactor, in addition , partitions separating the flotation reactors from the flotation separators are made with the possibility of free movement of the flow of purified water in the upper parts flotation reactors and flotation separators of one purification stage, and partitions separating the purification stages are made with the possibility of free movement of the stream of purified water in the bottom parts of flotation separators and flotoreactors of various purification levels, in addition, the aeration unit is configured to maintain a saturation pressure of 0.3-0.6 MPa, and deaerating units are configured to maintain a saturation pressure of 0.1-0.3 MPa.

In addition, the aeration unit is equipped with a nozzle for supplying compressed air.

In addition, the deaerating units are equipped with exhaust air outlet pipes with safety relief valves.

In addition, the deaerating units are made in the form of closed tanks, in the cavity of which, in the upper part, nozzles are installed directed to the bottom.

In addition, the inlet, outlet and nozzle of each donating unit are located along the longitudinal axis of the tank.

In addition, the inlet of the purified water drainage pipe is in communication with the aeration water supply pipe.

In addition, the installation for the purification of oily and wastewater further comprises a flotopene receiver equipped with a branch pipe for its discharge.

A comparative analysis of the features of the claimed solution with the signs of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

In this case, the distinguishing features of the claims solve the following functional tasks.

The sign “the outlet of the pipeline for supplying purified water is communicated with the bottom part of the flotation reactor of the first stage of purification” provides a more effective cleaning in the first stage, because the volume of purified water subjected to a one-time flotation increases.

The sign “the inlet of the aeration unit is communicated through a pump with the bottom part of the last separator flotation separator by means of a pipeline for supplying water to aeration” ensures the supply of a part of already purified water to the aeration unit, thereby eliminating mixing of the source purified water with already purified

The signs “the first exit of the aeration unit has been communicated ... with the entrance to the flotation reactor of the first purification stage, by means of the aerated water supply pipe” allows water to be supplied with a large supersaturation to the flotation reactor of the first purification step, which makes it possible to obtain germinal bubbles of maximum average diameter.

The signs “the second and subsequent stages of cleaning are equipped with deaerating units” provide the possibility of reducing the saturation pressure in each subsequent stage of cleaning.

Signs “the output of each [deaerating unit] is communicated ... with the entrance to the corresponding flotation reactor through the pipeline for supplying deaerated water and through the pressure regulator with the entrance to the ... deaerating unit of the next cleaning stage, through the pipeline for supplying water to the deaeration, while the second exit of the aeration unit is communicated through the regulator pressure with the inlet ... into the deaerating unit of the second stage of treatment by means of the aeration water drainage pipeline "provide a reduction in the pressure of the purified water after the aeration unit and poses olyayut flotoreaktory fed to each the following stage of the water purification with less supersaturation, resulting in the formation of germinal vesicles smaller the average diameter.

The signs “the first exit of the [aeration unit] is communicated through the throttling valve”, “the output of each [deaerating unit] is communicated through the throttling valve”, “the output of each throttle valve is located at the inlet of the corresponding flotation reactor” provide a reduction in water pressure to hydrostatic and prevent the formation of germ bubbles in pipelines, which allows to reduce the coalescence of germinal vesicles.

The signs “the exit of each [deaerating unit] is located in the bottom ... and communicated ... with the entrance to the upper part of the deaerating unit of the next cleaning stage”, “the second exit of the aerating unit is communicated ... with the entrance to the upper part of the deaerating unit of the second cleaning stage”, “the deaerating units are equipped with exhaust air outlet pipes with safety relief valves ”,“ deaerating units are made in the form of closed tanks, in the cavities of which, at the top, nozzles are directed toward the bottom ”,“ exit and nozzle of each de riruyuschego node located along the longitudinal "axis of the tank provide a cleaning fluid is sprayed at a pressure less than its saturation pressure, enabling to effectively remove water from the air dissolved in it and take it into the atmosphere.

The signs “the entrance to the corresponding flotation reactor is located at the lower point of its bottom”, “the cross-sectional area of the bottom of each flotation reactor uniformly decreases from top to bottom” ensures a uniform distribution of the supplied water along the bottom of each flotation reactor.

The signs "the cross-sectional area of the flotation separator is not less than the cross-sectional area of the corresponding flotation reactor, in addition, the partitions separating the flotation reactors from the flotation separators are made with the possibility of free movement of the stream of water to be purified in the upper parts of the flotation reactors and flotators of one cleaning stage, and the partitions separating the cleaning steps are made with the possibility of free movement of the flow of purified water in the bottom parts of the flotation separators and flotoreactors of various levels sources ”ensure uniform movement of the flow of purified water, in which the flotopen floats up, and aerated and deaerated water is supplied from below, without creating additional hydraulic resistance and the formation of a turbulent flow.

The signs "the aeration unit is configured to maintain a saturation pressure of 0.3-0.6 MPa, and the deaerating units are configured to maintain a saturation pressure of 0.1-0.3 MPa" and "the aeration unit is equipped with a nozzle for supplying compressed air" provide the optimal value the average diameter of the germinal vesicles in each stage of purification, the decrease of which, as the flow of purified water advances, increases the efficiency of extraction of smaller particles.

It is known that during wastewater treatment by pressure flotation, the cleaning efficiency is maximum at a certain saturation pressure, which lies in the range of 2-3 kgf / cm ² (Andreev S.Yu. New technology for reagentless flotation treatment of wastewater containing oil products / Andreev S.Yu. , Grishin B.M., Alekseeva T.V., Shirshin I.B. // Regional architecture and construction, 2011. No. 1. P. 148-152). If the saturation pressure is higher than the specified range, then the average diameter of the germinal bubbles will be higher (see Andreev S.Yu. Use of pressure and pressureless flotation methods for wastewater treatment from oil products / Andreev S.Yu., Grishin BM, Shisters A. S., Davydov G.P., Kulapin V.I., Koldov A.S. // Proceedings of the International Symposium Reliability and Quality. 2011. T. 1. S. 350-353), which in turn will reduce the cleaning efficiency because the smaller average diameter of the bubbles contributes to their fixation on the flocs (MI Alekseev, Technical Handbook for Water Treatment: in 2 vols. T.1: trans. from FR. - St. Petersburg: Novyi Zhurnal, 2007. p. 239). If the saturation pressure is below the specified range, then the bubbles have a small diameter, but their number is reduced, which is associated with a smaller amount of dissolved air.

The sign "entrance of the purified water drain pipe is connected with the aeration water supply pipeline" allows to withdraw a part of the purified water with its parallel supply to the aeration unit.

The sign "installation for the purification of oily and wastewater additionally contains a flotopene receiver equipped with a branch pipe for its removal", allows you to remove flotopen.

The drawing schematically shows a vertical section of the installation with three stages of cleaning.

The drawing shows flotation reactors 1, 2, 3 and flotation separators 4, 5, 6 of the first, second and third cleaning stages, respectively, partitions 7 between the cleaning stages, partitions 8 separating flotation reactors 1, 2, 3 from flotation separators 4, 5, 6, pump 9, aeration unit 10 of the first purification stage, a pipeline for supplying purified water 11, a pipeline for discharging purified water 12, the upper 13, 14, 15 and bottom 16, 17, 18 parts of the flotation reactors 1, 2, 3, upper 19, 20, 21 and bottom 22, 23, 24 parts of the fleet separators 4, 5, 6, a pipeline for supplying water to aeration 25, throttling valves 26, d looking for flotation reactors 1, 2, 3, 27, 28, 29, aerated water supply pipe 30, deaerating units 31, 32 of the second and third cleaning stages, respectively, bottoms 33, 34 of deaerating units 31, 32, respectively, pressure regulators 35, upper parts 36, 37 deaerating units 31, 32, respectively, deaerated water supply pipe 38, deaeration water supply pipe 39, aerated water pipe 40, compressed air pipe 41, exhaust air pipe 42 with safety relief valves 43, nozzles 44, 45 and longitudinal s axle 46, 47 is deaerated nodes 31, 32 respectively, flotopeny receiver 48, retraction tube 49 flotopeny.

Installation for the purification of oily and wastewater is made in the form of a horizontally oriented container, which is divided by means of partitions 7 into stages of purification connected in series along the flow of purified water.

In this case, the partitions 7 are made with the possibility of free movement of the flow of purified water in the bottom parts 22, 23 of the flotation separators 4, 5 and the bottom parts 17, 18 of the flotation reactors 2, 3 of various cleaning stages.

Each of the steps consists of flotation reactor 1, 2, 3 and flotation separator 4, 5, 6, separated by partitions 8, and the cross-sectional area of flotation separators 4, 5, 6 is not less than the cross-sectional area of the corresponding flotation reactors 1, 2, 3.

In this case, the partition 8 is made with the possibility of free movement of the flow of purified water in the upper parts 13, 14, 15 of the flotation reactors 1, 2, 3 and in the upper parts 19, 20, 21 of the flotation separators 4, 5, 6 of one cleaning stage.

The outlet of the pipeline for supplying purified water 11 is in communication with the bottom part 16 of the flotation reactor 1 of the first purification stage.

The aeration unit 10 can be implemented according to any existing method of saturating a liquid with air (pressure tank, spray absorber, etc.) and is equipped with a pipe for supplying compressed air 41.

The inlet of the aeration unit 10 is communicated through the pump 9 with the bottom part 24 of the separator 6 by means of a pipeline for supplying water to the aeration 25.

The first exit of the aeration unit 10 is communicated through a throttling valve 26 with an entrance to the flotation reactor 1 of the first cleaning stage, located at the lower point of its bottom 27, through the aerated water supply pipe 30.

The second and subsequent cleaning stages are equipped with deaerating units 31, 32 of the second and third cleaning stages, respectively, which are equipped with exhaust air outlet pipes 42 with safety relief valves 43.

Deaerating units 31, 32 are made in the form of closed reservoirs, in the cavity of which, in the upper parts 36, 37, nozzles 44, 45 are installed, directed to their bottoms 33, 34.

To increase the degree of purification, it is necessary that the saturation pressure in each subsequent stage be less than in the previous one, in this case the average diameter of the germinal vesicles decreases, and they are able to capture smaller particles of contaminants.

In order to increase the amount of dissolved air and, as a result, the number of germinal bubbles supplied to the first stage of purification, the saturation pressure in the aeration unit 10 is 0.3-0.6 MPa, and the saturation pressure in the deaerating units 31, 32 is 0.1 -0.3 MPa.

The entrances to the upper parts 36, 37, the exits located on the bottoms 33, 34, and the nozzles 44, 45 are located along the longitudinal axes 46, 47 of the deaerating units 31, 32, respectively.

The outputs of the deaerating units 31, 32 are communicated through throttling valves 26 with entrances to the flotation reactors 2, 3 located at the lower points of their bottoms 28, 29 through the pipeline for supplying deaerated water 38.

In addition, the output of the deaerating unit 31 of the second cleaning stage is communicated through a pressure regulator 35 with an entrance to the upper part 37 of the deaerating unit 32 of the third cleaning stage, by means of a water supply pipe for deaeration 39.

The second outlet of the aeration unit 10 is communicated through a pressure regulator 35 with an entrance to the upper part 36 of the deaerating unit 31 of the second cleaning stage by means of a pipe for draining aerated water 40.

The outputs of the throttling valves 26 are located at the entrances to the flotation reactors 1, 2, 3 located at the lower point of their bottoms 27, 28, 29.

The cross-sectional area of the bottoms 27, 28, 29 of the flotation reactors 1, 2, 3 decreases uniformly in the direction from top to bottom.

The inlet of the purified water drainage pipe 12 is in communication with the aeration water supply pipe 25.

The claimed installation works as follows.

The purified water is supplied to the bottom part 16 of the flotation reactor 1 of the first purification stage through the pipeline for supplying the purified water 11.

Purified water from the bottom part 24 of the flotation separator 6 of the third cleaning stage is supplied by pump 9 to the aeration unit 10.

In the aeration unit 10, according to any known method, the liquid is saturated with air at a pressure of 0.3-0.6 MPa, for which purpose compressed air is supplied to the aeration unit 10 through the pipe 41.

Part of the aerated water enters through the throttling valve 26 into the inlet of the flotation reactor 1, located at the lower point of its bottom 27, through the aerated water supply pipe 30. Moreover, when aerated water passes through the throttling valve 26, its pressure decreases to hydrostatic and in the aerated water supply pipe 30 germinal vesicles are not formed, which reduces their coalescence. As a result, germinal vesicles are formed and evenly distributed along the bottom 27 of the flotation reactor 1, due to the fact that the cross-sectional area of the bottom 27 of the flotation reactor 1 is uniformly reduced from top to bottom.

According to experimental studies to determine the average bubble diameter as a function of pressure (see Andreev S.Yu., Grishin B.M., Shisterov A.S., Davydov G.P., Kulapin V.I., Koldov A.S. // Proceedings of the International Symposium Reliability and Quality. 2011. T. 1. P. 350-353), the average size of the bubbles increases with increasing supersaturation of the liquid, and at a pressure of 0.4 MPa, the average diameter of the germinal bubbles is 70 μm, at a pressure of 0.6 MPa - 95 μm, 0.3 MPa - 57 μm, at a pressure of 0.2 MPa - 45 μm, and at a pressure of 0.1 MPa - 30 μm.

Floating from the bottom 16 to the top 13 of the flotation reactor 1, the germinal bubbles with an average diameter of 70 μm capture the largest particles of contaminants and carry them to the surface of the water in the form of flotopen.

After treatment with germinal bubbles in the flotoreactor 1 is completed, water from the upper part 13 of the flotation reactor 1 enters the upper part 19 of the flotation separator 4 and then moves to its bottom part 22.

From the aeration unit 10, part of the water through the aeration pipe 40 through the first pressure regulator 35 enters the upper part 36 of the deaerating unit 31 of the second cleaning stage.

When water passes through the first pressure regulator 35, the saturation pressure decreases to an average value (0.3-0.2 MPa) and part of the air dissolved in it begins to stand out from the water being purified. When spraying the liquid to be cleaned in the cavity of the deaerating unit 31 using the nozzle 44, the desorption process intensifies, while the released air is discharged through the outlet pipe 42 through the safety relief valve 43, which is set to the same pressure level as the pressure regulator 35, and the deaerated water accumulates in the bottom of the deaerating unit 31.

A part of the water that has been deaerated in the deaerating unit 31 is supplied through a throttling valve 26 to the inlet of the flotation reactor 2 located at the lower point of its bottom 28 through the inlet pipe of the deaerated water 38.

As a result, germinal vesicles are formed and evenly distributed along the bottom 28 of the flotation reactor 2, due to the fact that the cross-sectional area of the bottom 28 of the flotation reactor 2 is uniformly reduced from top to bottom.

Floating from the bottom 17 to the top 14 of the flotation reactor 2, the germinal bubbles with an average diameter of 57-45 microns capture smaller particles of contaminants compared to the first stage of purification and carry them to the surface of the water in the form of flotopen.

After treatment with germinal bubbles in the flotoreactor 2 is completed, water from the upper part 14 of the flotation reactor 2 enters the upper part 20 of the flotation separator 5 and then moves to its bottom part 23.

The other part of the fluid that has been deaerated in the deaeration unit 31, through the water supply pipe to the deaeration 39 through the second pressure regulator 35, enters the upper part 37 of the deaeration unit 32 of the third cleaning stage.

When water passes through the second pressure regulator 35, the saturation pressure decreases to a minimum value (0.2-0.1 MPa) and part of the air dissolved in it begins to stand out from the water being purified. When spraying the liquid to be cleaned in the cavity of the deaerating unit 32 using the nozzle 45, the desorption process is intensified, and the released air is discharged through the outlet pipe 42 through the safety relief valve 43, which is set to the same overpressure as the second pressure regulator 35, and the deaerated water accumulates in the bottom of the deaerating unit 32.

A part of the liquid that has been deaerated in the deaerating unit 32 is supplied through the throttling valve 26 to the inlet of the flotation reactor 3 located at the lower point of its bottom 29 through the inlet pipe of the deaerated water 38.

As a result, germinal vesicles are formed and evenly distributed along the bottom 29 of the flotation reactor 3, due to the fact that the cross-sectional area of the bottom 29 of the flotation reactor 3 is uniformly reduced from top to bottom.

Floating from the bottom 18 to the top 15 of the flotation reactor 3, germinal vesicles with an average diameter of 45-30 μm capture the smallest particles of contaminants and carry them to the surface of the water in the form of flotopen.

After treatment with germinal bubbles in the flotoreactor 3 is completed, water from the upper part 15 of the flotation reactor 3 enters the upper part 21 of the flotation separator 6 and then moves to its bottom part 24.

Next, part of the purified water is discharged from the installation through the pipeline for the removal of purified water 12, part is supplied to the aeration unit 10 using the pump 9 through the pipeline for supplying water to the aeration 25, and the particles of pollution of all stages of treatment accumulated on the surface of the water in the form of flotopen are collected in a receiver flotopen 47 and removed through the pipe outlet flotopen 48.

Next, the cycle repeats.

The claimed technical solution provides an increase in the efficiency of treatment of oily wastewater.

Claims (7)

1. Installation for the purification of oil and wastewater, containing at least two stages of purification, connected in series along the flow of purified water and separated by partitions, each of which consists of a flotation reactor and a separator, separated by a partition, an aeration unit of the first stage of treatment, communicated through the pump with the bottom part of the last separator flotation separator, the feed pipe to be cleaned and the purified water drain pipe, the output of the clean supply pipe water flow is communicated with the bottom part of the flotation reactor of the first purification stage, the inlet of the aeration unit is communicated through a pump with the bottom part of the flotation separator of the last purification stage through the aeration water supply line, the first outlet of the aeration unit is communicated through a throttling valve with the inlet of the flotation reactor of the first purification stage located at the bottom point of its bottom, through the aerated water supply pipe, in addition, the second and subsequent cleaning stages are equipped with deaerating units, and the output of each they are located in the bottom and communicated through a throttling valve with an inlet to the corresponding flotation reactor located at the lower point of its bottom through a pipeline for supplying deaerated water, and through a pressure regulator with an entrance to the upper part of the deaerating unit of the next cleaning stage through a pipeline for supplying water to deaeration, the second outlet of the aeration unit is communicated through a pressure regulator with an entrance to the upper part of the deaerating unit of the second cleaning stage by means of a pipe for draining aerated water, to In addition, the output of each throttling valve is located at the entrance to the corresponding flotoreactor, and the cross-sectional area of the bottom of each flotation reactor is uniformly reduced from top to bottom, in addition, the cross-sectional area of the flotation separator is not less than the cross-sectional area of the corresponding flotation reactor, in addition, the partitions separating the flotation reactors from flotation separators, made with the possibility of free movement of the flow of purified water in the upper parts of flotation reactors and flotation separators the bottom of the purification stage, and the partitions separating the purification stages are made with the possibility of free movement of the stream of purified water in the bottom parts of the flotation separators and flotoreactors of various purification levels, in addition, the aeration unit is configured to maintain a saturation pressure of 0.3-0.6 MPa, and deaerating units are configured to maintain a saturation pressure of 0.1-0.3 MPa. 2. Installation according to claim 1, characterized in that the aeration unit is equipped with a nozzle for supplying compressed air. 3. Installation according to claim 1, characterized in that the deaerating units are equipped with exhaust air outlet pipes with safety relief valves. 4. Installation according to claim 1, characterized in that the deaerating units are made in the form of closed reservoirs, in the cavities of which nozzles directed to the bottom are installed in the upper part. 5. Installation according to claim 1, characterized in that the inlet, outlet and nozzle of each donating node are located along the longitudinal axis of the tank. 6. Installation according to claim 1, characterized in that the inlet of the purified water discharge pipe is connected to the aeration water supply pipe. 7. Installation according to claim 1, characterized in that it further comprises a flotopene receiver equipped with a branch pipe for its discharge.

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