EA023425B1 - Apparatus for deep biochemical wastewater treatment - Google Patents

Abstract

The technical result achieved in the process of solution of the set problem is high degree of purification of wastewater and of used air, and production of valuable pelleted fertilizer. The essence of the invention is an apparatus for deep biochemical wastewater treatment comprising a pipeline for wastewater and sludge supply, a sludge discharge pipeline, a fine mechanical treatment device, a sand trap, a wastewater-sludge mixing chamber with a circulation pump, and a combined biological treatment device comprising a flat-charge biofilter and air-tank settlers separated by a partition defining a biofilter space and an air tank settler space, a spraying system comprising spraying trays, drain pipes, collecting pans and drain collectors having connected to them water-jet aeration columns sunk in aeration zones of the air tank settler, wherein aeration zones are separated from settling zones by partitions, and a polishing device comprising polishing bioreactors, in particular, a wastewater advanced polishing bioreactor; in the combined biological treatment device of 5 to 15,000 m/day capacity, the biofilter spray system comprises trays with discharge pipes and reflecting disks, the distance from top ends of discharge pipes of the trays to reflecting disks is 0.8-2 m, and the distance between tray centres and the distance between axes of pipes in the trays is 0.6-1.8 m; for aeration columns of diameters between 25 and 100 mm, column height above the liquid level in air-tank settlers is 1.2-3.5 m, and the depth of sinking under the liquid level is 1.5-4 m, the distance between edges of the aeration columns in the top part being 50-500 mm, and the distance between bottom edges of the aeration columns is 0.5-3 m.

Description

The invention relates to the treatment of domestic and industrial wastewater with an organic pollution content of BOD from 50 to 3000 mg / dm ³ , suspended solids from 50 to 1500 mg / dm ³ , fats up to 300 mg / dm and can be used in wastewater treatment waters, for example, houses, towns, cities, meat processing plants, fish factories, canneries, livestock farms, yeast, breweries, sugar factories, pulp and paper mills, chemical and microbiological industry enterprises, etc. The invention is also intended for the treatment of wastewater with a high content of hydrosulphides and hydrogen sulfide (5-100 mg / dm ³ ), ammonium nitrogen (50-100 mg / dm ³ ), formed during the decay of organic impurities in the collectors and receiving tanks of pumping pumping stations, wastewater from septic tanks and cesspools and methane fermentation in anaerobic bioreactors.

State of the art

A device for biochemical wastewater treatment containing a biofilter located above the sump aeration tank with feed pipes for jet aeration of liquids attached to the biofilter collecting pan, a mixing chamber and a circulation pump (USSR Author's Certificate No. 1020379, MKI СО2Р 3/02, publ. 30.05 .1983). The operation of the device is as follows: waste water after pre-treatment (removal of coarse impurities) is sent to the mixing chamber, where the sludge mixture from the aeration tank also flows under hydrostatic pressure. Next, the mixture of wastewater and sludge is circulated using a pump through a biofilter, feed pipes (aeration columns) and aeration tank settler. Biochemical oxidation of contaminants is carried out by a biocenosis attached to the biofilter charge, and by activated sludge microorganisms in the aeration tank. During irrigation and passage through a biofilter, the sludge mixture is saturated with atmospheric oxygen. Additional saturation of the liquid with oxygen in the aeration tank and mixing of its contents is carried out due to the process of air entrainment in the supply pipes (aeration columns), the movement of gas-liquid flows and the rise of air bubbles. The advantage of this device is a high degree of wastewater treatment due to the combination of the oxidizing and sorption properties of the biocenosis of the biofilter and the microflora of activated sludge of the aeration tank; the use of a simple low-pressure pump as the main equipment and low energy costs (up to 0.5 kW / kg of removed BOD). In biofilters, hydrogen sulfide is blown off and hydrosulfides are sorbed by adapted sludge, which contributes to the effective treatment of wastewater with a high content of these compounds. At the same time, the use of one combined device in the form of a single unit is irrational in wastewater treatment for productivity ranges of 100-50000 m ³ / day, since the process of adjusting the hydrodynamic operation mode of the structure is complicated and it is impossible to turn off individual elements during repair.

An increase in the specific gravity of a biofilter in the overall cleaning effect of a combined device and, accordingly, a reduction in energy consumption can be facilitated by a constructive device of a biofilter loaded with elements in the form of ceramic balls with recesses in a spherical surface (RF patent No. 2310499 ΒΘ1Ό 53/18, published on November 20, 2007). ), developed for mass transfer apparatus of the chemical industry.

Also known installation for biochemical treatment of highly concentrated wastewater according to the patent of the Russian Federation No. 2139257, MKI CO2R 3/02, publ. 10.10.1999, in the device which in the aeration tank and the bioreactor used biological loading units from plates with holes and bristles, allowing to increase the total amount of active biomass, including nitrification.

The closest set of essential features to the claimed invention (prototype) is the installation for biochemical wastewater treatment, given in the description of the patent of the Russian Federation No. 2220915, MKI CO2R 3/02, publ. January 10, 2004. The uniformity of irrigation of the biofilter of the combined device depends not only on the shutoff valves on the supply lines of the mixture of wastewater and sludge into the trays, but also on the availability of devices for damping the pressure when supplying liquid to the trays, since when liquid enters the initial sections sharp wave motion. The uniformity of the irrigation of the biofilter loading at the minimum energy cost of supplying the liquid to the irrigation system depends both on the height from the upper ends of the drain pipes to the reflective disks 1-1.5 m, but also on the distances between the trays and the distances between the drain pipes. The dimensions of the drain pipes of 4-10 diameters indicated in this patent provide the compactness of the falling liquid jets and the variety of reflection paths of liquid droplets. At the same time, when a layer of attached microflora appears on the inner surface of the nozzles (β and 1.5 mm) with nozzle diameters of 20-35 mm and their lengths exceeding six diameters, as well as due to straightening protrusions, the throughput of the nozzles sharply decreases and the likelihood increases their clogging, which requires frequent cleaning.

The efficiency of oxidation of organic pollutants in biofilters of combined devices depends on the design of the loading device. Flat loading is made in the form of blocks of corrugated sheets with different roughness, which contributes to the growth of biomass in the upper part of the load and eliminates siltation in the middle and lower part.

However, the use of artificial materials (fiberglass, ceramic, plastic), which are dielectrics, does not provide sufficient adhesion of microflora to the loading surface. IN

- 1 023425 the process of industrial research found that the best properties of adhesion of biomass to the loading surface are ceramic products.

The water-jet aeration unit in the combined device provides effective oxygen saturation of the liquid and mixing of the contents of the aeration tank only at certain diameters of the aeration columns and certain ratios between the heights of the columns above the surface and the heights of the buried parts of the columns. The right choice of parameters minimizes the energy costs of wastewater treatment. The efficiency of the process of air entrainment in the columns is affected by the conditions for the mixture of wastewater and sludge to enter the collectors, the horizontal distance between the upper edges of the aeration columns and the accuracy of the installation of the upper edges of the aeration columns according to the water level. The prototype installation of biochemical wastewater treatment indicates that for mixing the contents of the aeration tank, the lower ends of the pipes are evenly spaced above the flat part of the bottom of the aeration tank with a height of 0.2-0.3 m above it.

At the same time, the exclusion of the possibility of bedding and decay of the sludge with minimal energy consumption for the circulation of the sludge mixture, maintaining the active biomass in the aeration zone in suspension depends on both the adopted diameter of the aeration columns, the flow rate (m ³ / h) and the ratio of the heights of the aeration columns above and below the liquid level, and from the distances between the upper and lower edges of the columns, the distances from the ends of the columns to the angle of articulation of the flat and conical parts of the bottom and uniform drainage of sludge.

In the sewage sludge in an optimal ratio are carbon, nitrogen, phosphorus and trace elements. But the possibility of using the sediment as a fertilizer is constrained by the vitality of helminths and the appearance of unpleasant odors when it is introduced into the soil. The use of microwave installations provides complete deworming of sediment. Excess sludge removed from combined devices has an optimal ratio of nutrients, good moisture loss and a high degree of mineralization. The absence of primary sedimentation tanks in the treatment schemes with combined devices, the blocking of aeration tanks and secondary sedimentation tanks eliminates the possibility of sedimentation and decay of the sediment and, accordingly, the appearance of unpleasant odors, in contrast to traditional structures, in which sediment putrefactive enzymes remain. Therefore, excess sludge can be used as fertilizer.

The main factors influencing the biological treatment of wastewater is the temperature of the source wastewater and outdoor air. The average temperature of wastewater in Russian cities during the cold season ranges from 15-17 ° C, the water temperature in medium and small villages is 9-14 ° C. In aeration tanks with a normal aeration mode at an air temperature of minus 10-20 ° C, the temperature of the liquid during processing decreases by 1-3 ° C, in aeration tanks with a prolonged aeration mode at 49 ° C, which leads to a slowdown or complete cessation of the biological treatment process . In countries with a hot climate, high temperatures of wastewater and air and direct sunlight contribute to an increase in the treated liquid to 35 ° С and higher, which also negatively affects the solubility of air and the speed of the cleaning process. The implementation of closed sewage treatment facilities partially solves the problems of cooling or heating the liquid, but the main direction of optimizing the temperature regime of the facilities and reducing energy costs for air treatment is to increase the oxygen oxygen utilization rate.

In the process of wastewater treatment, a huge number of gas bubbles with a high content of СО ₂ and Н ₂ § are formed in aeration tanks, the rupture of which is accompanied by the formation of droplets that are carried away into the atmosphere, capturing pathogenic microflora. Thus, there is air pollution by pathogens of infectious and invasive diseases. For disinfection, degassing and deodorization of the air used in technological processes, the plants must be equipped with air treatment devices. Three or four-stage air treatment schemes at sewage treatment plants in Monaco, Nice, and Antibes use wet cleaning with hypochlorite and caustic soda, and the elimination of odorous odors is carried out using ozone, and therefore the air cleaning process is expensive to operate.

The task set by the developers of the new installation for biochemical wastewater treatment was to create such plant options that would ensure effective and stable quality of wastewater treatment with low and high concentrations of organic pollutants, high levels of hydrogen sulfide and hydrosulfides, ammonium nitrogen and would improve the environmental safety of treated wastewater, in particular, the reduction of the sanitary protection zone around the installation.

The technical result achieved in the process of solving the task posed to the developers was to increase the efficiency and stability of its work at various concentrations of pollutants. Improving the efficiency and stability of the installation predetermined a reduction in energy costs for wastewater treatment, disinfection and deodorization of used air. At the same time, the installation also made it possible to dispose of waste products to obtain granular fertilizers.

- 2 023425

Disclosure of invention

The essence of the invention lies in the fact that in the installation for deep biochemical wastewater treatment, containing mechanical treatment devices, a chamber for mixing wastewater with sludge with a circulation pump and a combined biological treatment device, including a biofilter with a flat charge, an irrigation system, prefabricated trays and collectors, to which aeration columns with water-jet aeration are connected, buried in aeration zones, and after-treatment devices; in the device of combined biological treatment with a productivity of 5 to 15,000 m ³ / day. the biofilter irrigation system includes trays with drain pipes and reflective disks, the distance from the upper ends of the drain pipes of the trays to disk reflectors is 0.8-2 m, and the distance between the centers of the trays and the distance between the axes of the pipes in the trays is 0.6-1, 8 m. When the diameter of aeration columns is from 25 to 100 mm, their height above the liquid level in aeration tanks is 1.2-3.5 m, and the depth of penetration under the liquid level is 1.5-4 m. In this case, the distance between the ends of the columns in the upper part is 50-500 mm and of the sawn-off between lower aeration columns is 0.5-3 m.

In addition, the invention consists in the fact that the length of the drain pipes installed in the trays of the irrigation system is in the range from two to six of their diameters. The diameter of the reflective discs is 80-200 mm. On the pipelines for the supply of a mixture of wastewater and sludge into the biofilter irrigation trays, valves are installed and, additionally, gates are mounted at the beginning of the trays, and in front of the initial drain pipes, directional plates are installed.

In addition, the essence of the invention lies in the fact that the biofilter loading elements are made in the form of balls with a diameter of 35-100 mm with 4-10 recesses, the axes of which converge in the center of the ball. Balls have protrusions on the surface of 0.1-1.5 mm. The composition of the material elements included metal compounds.

However, the essence of the invention lies in the fact that the loading of the biofilter is made of corrugated ceramic sheets with a width of 0.5-1.5 m, a height of 0.5-3 m, a thickness of 2-4 mm, with protrusions (roughness) on the surface 0.1-2 mm, with a frame of parallel and longitudinal wavy strips with a width and thickness of 3-10 mm. Part of the longitudinal stripes is made in the form of protruding wavy partitions 10-35 mm wide. The composition of the sheet material includes metal compounds.

In addition, the essence of the invention lies in the fact that the drain pan of the biofilter tray is equipped with a directional reflector. The upper part of the aeration columns is made in the form of nozzles screwed into couplings attached to the bottom of the drain pan. The stock collector is equipped with a flap for mounting pipes and pipes.

However, the essence of the invention lies in the fact that in the drain pipes of the irrigation systems of biofilters and in the pipes of the upper parts of the aeration columns, recesses are made in the form of spirals with a length of 1 to 1.5 turns and a height not exceeding 0.7 of the diameter of the pipe.

In addition, the invention consists in the fact that along the external perimeter of the partition separating the biofilter from the room of the aeration tank-sump, holes are made at a distance of 0.5-1.5 m from each other or valves for air bypass are installed.

However, the essence of the invention lies in the fact that for diameters of aeration columns from 25 to 100 mm, the height of the lower edges of the columns above the bottom of the aeration zone is 0.05-0.4 m, and the distance from the bottom of the extreme aeration columns to the angle of articulation is flat and the conical parts of the bottom of the aeration tank settler is 0.5-1.2 m

In addition, the essence of the invention lies in the fact that the length of the lower leg of the conical part of the aeration tank settler is half the width of the settling zone plus 0.1-1.0 m. The height from the bottom of the conical part of the partition separating the aeration and settling zone to the bottom is 0.5-1.5 m. The width of the triangular rollers placed on the flat part of the bottom of the aeration zone is 0.52.0 m and their height is 0.5-1.5 m. The sludge discharge pipe is installed along the outer perimeter of the conical part of the bottom aeration tank-settler and has holes or nozzles located at an angle of 0-90 ° to the horizontal axis of the pipeline and at a distance of 0.2-1.0 m from each other.

At the same time, the essence of the invention consists in the fact that biologically loaded blocks are installed above the rollers, made of plastic plates with holes of 3-30 mm and bristles 5-50 mm long or ceramic plates, including metal compounds, with attached rods or plates different lengths of 5-40 mm and a roughness on them in the form of protrusions (0.1-1.5 mm).

In addition, the essence of the invention lies in the fact that the installation consists of two to four devices of combined biological treatment connected to a common mixing chamber by pipelines for the removal of sludge from aeration tanks settling tanks. The pressure line of the circulation pump of the mixing chamber is connected to the irrigation systems of the biofilters of combined biological treatment devices.

However, the essence of the invention lies in the fact that in the installation for deep biochemical wastewater treatment with an organic pollution content of BOD up to 3000 mg / dm ³ and fats up to 300 mg / dm ³ , including bio-coagulators-flotators, combined biological treatment devices the pressure pipe of the circulation pump installed in the mixing chamber of the second combined 3,023,425 device is simultaneously connected to the irrigation system of this device, to the mixing chamber of the first combined device; to a water-jet aerator of a biocoagulator-flotator or to a device for processing excess sludge, as well as the fact that aeration columns are attached to the aeration chamber of 0.3-1.5 m long, angles of inclination to the vertical axis from 0 to 50 ° and tangentially directed nozzles.

In addition, the essence of the invention lies in the fact that the installation further includes a device for processing excess sludge, to the thickener of which pipelines are connected from a combined biological treatment device and / or from a biocoagulator and / or anaerobic bioreactor. The thickener is connected to a belt filter press, in which the dehydrated cake drainage device is connected to a granulator, which also has a feed line (organic and / or mineral additives). The pellet removal device is connected to a roller conveyor equipped with heating elements, and / or with microwave emitters arranged in series above the conveyor, connected, in turn, to the storage tank.

And finally, the essence of the invention lies in the fact that in the installation for deep biochemical wastewater treatment, air ducts from combined biological treatment devices, excess sludge treatment devices, bioreactors, rooms for fine mechanical cleaning and sand traps are connected to the suction pipe of the high pressure fan, pressure duct which, in turn, is connected to an irrigation chamber of an air treatment device. The device is equipped with an irrigation system, which is connected to a circulation pump, the suction pipe of which is connected to the bubbling part of the device. Above the bubbling part, the nozzle part of the device is filled, filled with artificial loading, a collection tray, in which are mounted direct air supply pipes 1.2-2.5 m long, buried 0.4-0.7 m deep in the bubbling liquid and filled in the lower parts with small diameter pipes, as well as water-jet air ejection pipes that are attached to the collector, are installed at a height of 0.6-1.8 m above the liquid and are buried in the liquid by 1-3 m.

Evidence of the feasibility of the claimed invention is given by specific examples in plant options for deep biochemical wastewater treatment with different contents of organic pollutants, hydrogen sulfide and hydrogen sulfides and ammonium nitrogen. These characteristic examples in no way limit other various embodiments of the invention, but merely explain its essence.

Brief Description of the Drawings

The plant embodiments for biochemical wastewater treatment given as specific examples of the invention are explained graphically, where in FIG. 1 - schematically depicts a variant of the technological scheme of the installation for deep biochemical wastewater treatment with a concentration of contaminants according to BOD up to 1000 mg / dm ³ and suspended solids up to 700 mg / dm ³ ;

in FIG. 2 shows, on an enlarged scale, a section through the biofilter shown in FIG. one; in FIG. 3 is a section AA in FIG. 2;

in FIG. 4 shows, on an enlarged scale, a sectional view of the biofilter prefabricated pan and the drain pan shown in FIG. one;

in FIG. 5 is a section BB in FIG. 4;

in FIG. 6 - the foreground of the corrugated ceramic biofilter loading sheet is given; in FIG. 7 shows a section of one corrugated ceramic sheet; in FIG. 8 - shows a section of several sheets assembled;

in FIG. 9 shows an enlarged view of a fragment of a ceramic sheet; in FIG. 10 shows a section through a spherical biofilter loading element;

in FIG. 11 shows, on an enlarged scale, a section A - A of an aeration tank-settler with triangular rollers, blocks with biological loading, aeration columns and a sludge discharge pipe;

in FIG. 12 is a section BB in FIG. 2;

in FIG. 13 - schematically depicts a variant of the technological scheme of the installation for deep biochemical wastewater treatment with an organic pollutant content of BOD up to 3000 mg O ₂ / dm ³ , suspended solids up to 700 mg / dm ³ , the total content of hydrogen sulfide and hydrosulfides, ammonium nitrogen up to 100 mg / dm ³ ;

in FIG. 14 - a flow chart of the processing of excess sludge;

in FIG. 15 is a process diagram of a used air treatment device;

in FIG. 16 is an enlarged view showing a section through a pipe of direct air supply.

The best embodiments of the invention

The claimed installation for deep biochemical wastewater treatment with a concentration of contaminants according to BOD up to 1000 mg / dm ³ and suspended solids up to 700 mg / dm ³ consists of a sewage supply pipe 1 connected to a fine mechanical treatment device 2, which, in turn, connected by a pipeline to the vertical sand trap 3. The collecting tray of the vertical sand trap 3 is connected by a drain pipe to the mixing chamber of 4 combined biological devices

- 4,023,425 purification 5. Combined biological purification devices 5 consist of biofilters 6 with loading 7, equipped with irrigation systems 8, prefabricated pallets 9 and drain collectors 10. Aeration columns 11 are connected to the drain collectors, which are buried in the aeration zones 12 of the aeration tanks 13. On the partition, separating the premises of the biofilter from the premises of the aeration tank, provides for the installation of valves or holes for air bypass 14. In aeration tanks 13, the aeration zones 12 are separated from the settling zones by 15 partitions 16. Along the outer perimeter of the conical part of the bottom of the aeration tank-sump 13, a sludge discharge pipe 17 is mounted.

The sludge discharge pipes 17 are connected to the mixing chamber 4, in which the circulation pump 18 is installed. The pressure pipe 19 is simultaneously connected to the irrigation systems 8 of the combined biological treatment devices 5 and to the excess sludge treatment device 20.

The collecting chutes located in the settling zones 15 are connected by gravity to the bioreactors 21. The bioreactor includes an aeration chamber 22 with a water-jet aerator 23 and a pump 24. In turn, the pump 24 is connected by a pressure pipe 25 with a water-jet aerator 23, a mixing chamber 4, and a bioreactor irrigation system 26 21. The aeration chamber 22 is separated by a partition from the flooded filter with a load of 27. Combined biological treatment devices 5 and bioreactors 21 are connected by ducts 28 to the fan 29 of the processing device using 30 vannogo air.

The design of the biofilter 6 irrigation system includes a pressure pipe with a valve 31, distribution trays 32 with gates 33, drain pipes 34 and reflective disks 35. In front of the initial drain pipes 34, directional plates 36 are installed. Helium-neon lasers 37 are mounted on trays 32.

Couplings 38 are welded to the bottom of the drain pan 10, into which aeration columns 11 are screwed in from below and nozzles 39 on top. During the period of hydraulic tests on clean water, a water level mark is applied to the nozzles, then they are unscrewed and chamfered, and then they are screwed again in the coupling 38. In the nozzles 39 are made recesses in the form of spirals. The collector is equipped with a jet reflector 40 and a flap 41.

The loading of biofilters consists of corrugated ceramic sheets 42 with a frame of parallel and wavy longitudinal strips 43. Part of the longitudinal strips 44 has the form of protruding wavy partitions. The surface of the sheets 42 with the exception of strips 43 is made with a developed roughness in the form of protrusions 45.

As an artificial loading of biofilters, loading elements 46 made in the form of balls with recesses in a spherical surface 47 whose axes intersect in the center of the ball can be used.

In combined biological treatment devices, the bottom of the aeration tank 13 is divided into cells by triangular rollers 48, above which the biological loading units 49 are installed. Aeration columns 50 are placed above the flat parts of the bottom of the aeration tank 13. A drain pipe is mounted along the outer perimeter of the conical part of the bottom of the aeration tank 13. sludge 17 with evenly spaced holes or nozzles 51.

The claimed version of the installation for deep purification of domestic and industrial wastewater with an organic pollution content of BOD up to 3000 mg O ₂ / dm ³ , suspended solids up to 700 mg / dm ³ , the total content of hydrogen sulfide and hydrosulphides, ammonium nitrogen up to 100 mg / DM ³ also includes a sewage supply pipe 1, a bio-coagulator-flotator 52. The mixing chamber 4 is connected by gravity to the first combined biological treatment device 53. In turn, the collection tray of the combined device 53 is connected inen pipeline to the mixing chamber 54 of the second biological treatment device 55. The pressure pipe 56 of the circulation pump 18 installed in the mixing chamber 4 is simultaneously connected to the biofilter irrigation system of the combined biological treatment device 53, to the mixing chamber 54 of the device 55. Pressure piping 57 of the circulation pump 18, mounted in the mixing chamber 54, are connected to the irrigation system of the biofilter of the device 55, to the mixing chamber 4 and to the water-jet aerator of the biocoagulator-flotator 52. Pressure tube water 57 connected to a sludge treatment apparatus 20.

The pipes for the removal of excess sludge, depending on the adopted technological scheme, are connected from combined biological treatment devices 5, 53, 55, the bio-coagulator 52 to the thickener 58 of the device for processing excess sludge 20. A reagent supply line (coagulant and / or flocculant) is connected there 59. compacted sludge is connected to a belt filter press 60, which, in turn, is connected to a granulator 61, to which a feed line for organic and / or mineral additives 62 is also connected. It is connected to the conveyor with rollers 63 provided with heating elements 64 located under the conveyor. Microwave emitters 65 are installed above the conveyor. A storage tank 66 for collecting granules is provided.

The used air treatment device 30 includes air ducts 28 that are connected to the suction pipe of the high pressure fan (VVD) 29. Pressure duct VVD 29,

- 5 023425, in turn, is connected to the irrigation chamber 67 of the air treatment device 30. The device 30 is equipped with an irrigation system 68 with acoustic ultrasonic dispersers (AUD), which is connected to a circulation pump 69, the suction pipe of which is connected to its bubbler part 70. Above the bubbler part 70 contains a nozzle part 71 filled with artificial loading 46, as well as a collection tray 72, into which direct air supply pipes 73 are mounted. The pipes 73 are 1.2-2.5 m long, 0.4-0.7 deepened m in bubbler liquid and and are filled in the lower part with pipes of small diameter 74. Pipes for water-jet ejection of air 75 are connected to the drain pan of the pallet 72, are installed at a height of 0.6-1.8 m above the liquid and are buried in the liquid on

1-3 m. An air exhaust duct 76, a reagent supply pipe 77 and an exhaust solution pipe 78 are connected to the air processing device 30.

The described installation for deep biochemical wastewater treatment works as follows.

When deep cleaning of domestic and industrial wastewater with an organic pollution content of BOD up to 1000 mg O ₂ / dm ³ , suspended solids up to 700 mg / dm, wastewater is piped 1 to a fine mechanical treatment device 2 with 2-4 mm openings where coarse suspension is held. Then the wastewater enters the vertical sand trap 3, where sand is deposited. Next, the wastewater enters the mixing chamber 4, and then into the combined biological treatment devices 5. Under hydrostatic pressure, the sludge chamber 4 receives 17 sludge from gravity aeration zones 12 through gravity pipelines. If two to two wastewater treatment plants are used in the described biochemical treatment plant of four combined biological treatment devices, it is performed with one circulation pump 18. This condition is based on design considerations for the construction of treatment facilities, and control of hydrodynamic E fluid flows in biofilters and aeropack and temporarily disable individual elements. With a larger number of combined biological treatment devices, having one circulation pump 18, it is extremely difficult to regulate the hydrodynamic mode of operation of biofilters and aeration tanks settlers. Half-production studies have shown that with the number of combined biological treatment devices from four to six, it is advisable to carry out a mixing chamber of the treatment plant unit with two pumps operating simultaneously, and separate them with partitions with switchboards behind the seams.

From the mixing chamber 4, the wastewater is pumped through the pressure pipe 19 using the circulation pump 18 to the irrigation system 8 biofilters 6. The excess sludge is also pumped to the device 20 through the pipe 19. Using the valves 31 installed on the pressure pipes, the wastewater flow rate is adjusted in each distribution tray 32. When the sludge mixture enters the narrow distribution trays 32 in the initial sections, especially when the circulation pump 18 is turned on, a sharp wave-like motion e in the trays and the possible overflow of fluid through the edges. The quenching of the pressure and the equalization of the fluid flow in the trays is carried out using the sliders 33. Due to the high fluid velocities at the beginning of the trays, it is difficult to drain the liquid into the first drain pipes 34. To reduce the turbulence of the flows, guide plates 36 are installed in front of the initial pipes, which facilitate the discharge of liquid into nozzle holes.

Adjusting the uniform outflow of fluid through the nozzles is done by changing the height of the nozzles above the bottoms of the trays. It is necessary to strive to reduce the length of the nozzles, as this reduces the amount of biomass attached inside the nozzles, and, accordingly, increases their throughput. Recommended length of nozzles installed at the beginning and end of the trays

2-6 diameters. Increasing the compactness of the falling jets of liquid contribute to the recesses in the drain pipes 34, made in the form of spirals 1-1.5 turns with a height of less than 0.7 diameter.

The optimal ratio between energy costs for irrigation system operation and irrigation uniformity is determined by the following system parameters: when the distance from the upper ends of the drain pipes of the irrigation system trays to the reflective discs is 0.8-2 m, the distances between the centers of the trays and the distances between the pipe axes are accepted within 0, 6-1.8 m.

The loading of biofilters in devices 5 is made of corrugated ceramic plates 42. The inclusion of metal compounds in the composition of the material increases the electrokinetic potential of the adsorption layer of the material. Electrostatic attraction promotes the immobilization of colonies of microorganisms. The frame of thickenings in the form of parallel and longitudinal strips 43 and longitudinal strips with protruding wavy partitions 44 provides structural strength while increasing the weight of the growing layer of biomass. The size of the attached microflora layer is directly affected by the roughness in the form of protrusions 45 (0.1-1.5 mm). Reducing the roughness in the bands 43 to 0.1-0.5 mm reduces the adhesion forces to the material of the boot, which, along with the wavy partitions 44, helps to reduce the size of the possible siltation zones and the removal of excess biomass.

A layer of attached biomass up to 10 mm thick is formed on the loading surface, in which, in addition to microflora, which sorb and oxidize the organic substrate (50-70% dissolved organics), nitrifying and denitrifying microorganisms develop.

The inclusion of 7 metal particles in the composition of the loading material increases the electrokinetic effect, which consists in increasing the potential of the adsorption layer of the loading. During the semi-production tests, a dense accumulation of biomass (up to 5-7 mm thick) was observed on sheets with electro-acoustic spraying of metal compounds due to implantation of various compounds, such as carbides, carbonitrides, intermetallics, etc. into the surface layer of the charge. Metallic inclusions are catalysts that increase the dynamic activity of microorganisms. At the active loading centers, the molecules of the reacting substances are sorbed, their concentration becomes higher, which positively affects the adhesion adhesion of the surface layer. The combination of structural, mechanical, kinetic, and electrical factors stabilizes the processes of nitridenitrification, which increases the degree of degradation of nitrogen-containing contaminants in the installation.

The mixture of wastewater and sludge that passed through the loading of 7 biofilters 6 is collected using prefabricated pallets 9 and sent to the collectors 10. Fugitive discharge of liquid, insufficient distance between the centers of the upper edges of the aeration columns 11, deviations in the heights of the nozzles above the bottoms of the collectors causes a random movement of liquid as a result of which the efficiency of the process of air intake in aeration columns is reduced. Therefore, in the upper part of the collectors, it is necessary to install flow guiding reflectors 40, which are hit and merge down the fluid flows. The quenching of the pressure contributes to a uniform flow of fluid to the upper edges of the aeration columns. The recommended distance between the cutoffs of columns with a diameter of 25-100 mm in the upper part within the range of 50-500 mm reduces the turbulence of fluid flows in the collectors 10 and contributes to its uniform distribution between the columns. The exact installation of the upper edges of the columns according to the water level is made by screwing and unscrewing the pipes 39 and removing the chamfers. The formation of well-developed vortex funnels for sucking air into the aeration columns 11 is facilitated by the internal recesses in the nozzles 39, which are in the form of spirals, since they stabilize the formation of circular rotations (clockwise) when draining the liquid into the pipes. As shown by semi-industrial studies, the optimal height of the application of slices varies within 0.5 diameter. The installation of the nozzles 39 and the cleaning of the aeration columns 11 is carried out through the hatches 41.

The efficiency of the process of mass transfer of air oxygen to a liquid and mixing of the contents of the aeration zone depends on the following main factors: diameter of aeration columns, liquid throughput (m ³ / h), the relationship between the height of aeration columns above a liquid and the height of the buried part of columns, depth of aeration zone, parameters arrangement of columns in the aeration zone and configuration of the aeration tank settler.

The internal diameters of aeration columns are recommended to be taken within 40-70 mm. It is possible to use diameters of 25-40 mm for small ranges of plant capacities, but in this case the appearance of fouling β and 1.5 mm on the inner surface of the pipe surface biocenosis is especially negatively affected by the flow rate of m ³ / h and the amount of air drawn in, in connection , it is necessary to periodically clean them. Application diameters of 70-100 mm (i.e., pass through a column of large costs) also ensures a high mass transfer coefficient (K) within the bandwidth pipe (for example, when used with a ₇₀ mm |. = 9 - 19 m ³ / h ), but this reduces the efficiency of mixing the entire volume of the aeration zone. In order to ensure sufficient impact of water-air torches on the bottom, the recommended estimated flow rate (m ³ / h) of liquid through the columns should be at least half the sum of the minimum and maximum flow rates at which vortex funnels are formed.

Based on the optimal values: energy costs for the circulation of the liquid through the biofilter aeration columns - aeration tank - mixing chamber, construction height of treatment plants and conditions for servicing aeration columns, the recommended column height above the liquid level in the aeration tank for the range of capacities of combined biological treatment devices 5-50 m ³ / day is 1.2-1.8 m, while the height of the deepened part of the columns is recommended to be taken within 1.52 m, and the height of the lower cuts of the columns above the bottom within 0.05-0.2 m; for the range of productivity of devices 100-15000 m ³ / day. the height of the upper part of the columns is recommended to be taken within 2-3.5 m, the height of the deepened part of the columns is 2.5-4 m, and the height of the lower edges of the columns above the bottom is 0.150.4 m.The distance between the lower edges of the adjacent aeration columns (25- 100 mm) and columns installed diagonally, it is taken 0.5-3 m. To reduce the size of the area of the bottom of the aeration tank, it is recommended to arrange triangular rollers 48, which are placed on the flat part of the bottom of the aeration zone. The optimal sizes of the rollers 48, based on the conditions for ensuring the maximum volume of the reaction zone, the efficiency of mixing of the sludge liquid and the exclusion of sludge, are: width 0.5-2.0 m; height of 0.5-1.5 m. When sediment pops of sludge in the sedimentation zone 15 of the aeration tank-settler 13, stagnant zones may appear along the perimeter of the junction of the conical and flat parts of the bottom of the aeration tank with further decay and ascent of dead mud. Therefore, it is recommended that the minimum distance from the lower ends of the extreme columns with a diameter of 25-50 mm to

- 7 023425 of the angle did not exceed 0.5-0.7 m, and for diameters of 50-100 mm did not exceed 0.7-1.2 m. The length of the lower leg of the conical part of the settling zone 15 should be half the width of the settling zone plus 0, 1-1.0 m. In this case, the distance from the bottom of the conical part of the partition separating the aeration and settling zones to the bottom should be 0.5-1.5 m. To prevent shock absorption of gas-liquid flows exiting the lower ends of the aeration columns 11 , the pipeline discharge of the sludge mixture, and, accordingly, the deterioration of the hydrodynamic conditions sewing the contents of the aeration tank-settler 13, the pipe 17 is mounted behind the outer perimeter of the conical part of the bottom of the aeration tank-settler with holes or nozzles 51 located at an angle of 0-90 ° to the horizontal axis of the pipeline and at a distance of 0.2-1.0 m from each other .

Subject to the specified parameters of the arrangement of aeration columns and the design of the aeration tank-settler, the impact of water-air torches on the bottom of the aeration zone, the hydrodynamic movement of fluid flows and the emergence of air bubbles exclude the possibility of bedding and decay of activated sludge.

To fix and develop microflora, which carries out the oxidation of organic substances and nitrification, in the tanks of aeration zones of aeration tanks-settlers of combined biological treatment devices, installation of 48 biological loading units 49 from plastic plates with holes of 3-30 mm and bristles 5-50 mm long is provided over the rollers. Blocks 49 can also be made of ceramic sheets with holes of 3-30 mm and protrusions in the form of rods or plates with a length of 5-40 mm. Sheets, rods or plates have a developed roughness in the form of protrusions.

The roughness helps to fix immobilized microflora on the loading surface. The inclusion of metal compounds in the composition of the material increases the electrostatic attraction of microflora, which, along with a decrease in the turbulence of fluid flows inside the load, contributes to the development of nitrifying sludge with a great age. Reducing the turbulence of fluid flows in the load reduces the removal of adapted activated sludge. The concentration of active biomass in the volume of the flooded load 49 can reach 10 g / DM ³ .

In the reaction volumes of the aeration and settling zones, the rest of the organic pollutants are oxidized (30-50%) at low loads on sludge of 0.1-0.2 g-BOD / g _sludge- sut, and the spent biomass is mineralized from the biofilter loads. The ash content of the sludge developed during nitrification and denitrification partial stavlyaet with 33-42% average resistivity water yielding 38-45-10 ^-10 cm / g. Excess sludge contains carbon, nitrogen, phosphorus and trace elements, has a high degree of mineralization, good moisture loss, is not susceptible to decay and therefore, after additional processing, can be used as fertilizer.

The purified water from the settling zones 15 enters the collection trays and is discharged into the bioreactors for deep wastewater treatment 21, where in the aeration chambers 22 additional water is saturated with dissolved oxygen using water-jet aerators 23 and circulation pumps 24. The pumps 24 are equipped with flexible hoses that allow you to adjust the depth immersion. Then, water passes through the loading layer 27.

The liquid coming from the devices 5 into the bioreactors 21 also contains light pops of dead sludge. When water moves through the load 27, their physical retention occurs due to the filtration of the liquid through the biocenosis layer.

The attached microflora formed on the surface of the load 27 carries out sorption and oxidation of residual organic pollutants and further transformation of nitrogen-containing compounds. The biochemical processes are provided with the necessary oxygen by means of a pump 24 and a water-jet aerator 23. As the suspended solids accumulate, the bioreactors 21 are partially emptied and the charge is regenerated using the irrigation system 26 and pump 24. Then the pump is lowered into the pit of the bioreactor and the pumped liquid is piped 25 into the mixing chamber of 4 devices 5.

Pipeline 19 feeds excess sludge to the excess sludge treatment device 20. Air from rooms of fine mechanical cleaning devices 2, sand traps 3, combined biological treatment devices 5, bioreactors 21 and device 20 is taken by a fan 29 and sent to the device for processing used air 30 .

When deep cleaning of domestic and industrial wastewater with an organic pollution content of BOD up to 3000 mg O ₂ / dm ³ , suspended solids up to 1500 mg / dm ³ , the content of hydrogen sulfide and hydrosulphides, ammonium nitrogen up to 100 mg / dm ³ wastewater after mechanical cleaning through a pipe 1 is fed into the mixing chamber 4, where they are mixed with the circulating sludge liquid of the first combined biological treatment device 53. Then, the mixture of wastewater and sludge is pumped through a pressure pump 18 through a pressure pipe ode 56 in irrigation device biofilter 53. Further liquid passes through loading the biofilter, is drained to the aeration column, and then mixed with activated sludge aeropack.

With repeated irrigation and contact of the waste fluid with the biocenosis formed on the biofilter loading surface and with activated sludge in the reaction zone of the aeration tank-settler (1-3 hours), hydrogen sulfide is degassed, biochemical oxidation of reduced sulfur compounds, biodegradation of organic pollutants by BOD by 50-70% and the process of partial denitrification (10-15%). The formation of specific microflora (sulfur bacteria, filamentous, thionic microorganisms, anammox bacteria), which provides sorption and oxidation of hydrosulfides, as well as partial denitrification in the biofilter of device 53, is facilitated by the construction of spherical elements 46 with 8 recesses 47, whose axes converge in the center of the ball. The fixing and development of microflora is facilitated by the surface roughness of the loading elements (0.1-1.5 mm), a decrease in the turbulence of the flows and an increase in the contact time of the flowing liquid with biomass in the loading containers. It is also advisable to use elements with 4-10 recesses. During many years of industrial research, the optimal diameter of spherical elements was established - 70 mm, at which siltation of the load does not occur. However, when treating wastewater with an organic pollutant content of less than 100 mg / dm ³ by BOD, it is possible to use loading elements with a minimum diameter of up to 35 mm and with BOD concentrations above 300 mg / dm ³ up to 100 mm. In the manufacture of elements for electrostatic attraction and catalytic effects on microflora, it is advisable to use clays with a high content of iron and aluminum. The composition of the ceramic loading material may additionally include refractory metalloid compounds.

Transferring to the receiving chamber 4 of the first device 53 a part of the circulating fluid from the pressure pipe 57 of the second device 55 helps to reduce the load of organic substances on the biocenosis of the first device 53 (i.e., microflora overload is eliminated). Mineralization of excess biomass with a significant amount of adsorbed unoxidized organics from the device 53 is carried out in the device 55. To do this, the output of sludge through a pipe 56 is pumped into the mixing chamber 54 of the device 55.

Next, the clarified liquid from the settling zone of the device 53 is sent to the mixing chamber 54 of the device 55. Then, the mixture of wastewater and sludge is pumped through the pressure pipe 57 using a circulation pump 18 to the irrigation system of the biofilter of the device 55, in which further sorption and oxidation of the rest of the organic pollutants takes place . At this stage, at low loads of sludge for organic substances (0.05-0.2 kg / BOD per 1 kg of ash-free substance), the process of complete oxidation of organic pollution and deep nitrification and partial denitrification of nitrogen-containing compounds are carried out. The period of stay of wastewater is 4-7 hours. In order to activate biological treatment processes when microflora is overloaded, device 53 transfers 10-30% of the circulating liquid from the pressure pipe 57 of the second combined biological treatment device 55 to the mixing chamber 4 of device 53. A portion of the sludge liquid is also drained into the excess processing device silt 20.

Loading biofilters devices 53, 55 can be made of spherical elements 46 and / or corrugated ceramic plates 42.

To fix and develop microflora, carrying out the oxidation of hydrosulfides and nitrification, in the tanks of aeration zones of aeration tanks-settlers of devices 53 and / or 55, installation of biological loading units 49 is provided.

When treating industrial wastewater with an organic pollutant content of BOD from 1500 to 3000 mg O ₂ / dm ³ , suspended solids up to 1500 mg / dm ³ (with an ash content of over 30%) and fats up to 300 mg / dm ³ wastewater after mechanical treatment pumped into the bio-coagulator-flotator 52.

The feasibility of using biocoagulators in the technological scheme of purification is due to the following: sedimentation of suspended solids - 50-70%; the removal of part of organic pollution (1520%) due to the sorption properties of the removed excess sludge, flocculation and flotation process; compaction of excess biomass and contaminants (up to 7-15 g / dm ³ ) before feeding to the mechanical dehydration section; partial averaging of organic loads and pH.

Active sludge is also supplied to the receiving chamber of the water-jet aerator of the biocoagulator-flotator 52 from the mixing chamber 54 through the pipe 57. Aeration columns are attached to the receiving chamber with a length of 0.3-1.5 m, tilt angles to the vertical axis from 0 to 50 ° and tangentially directional nozzles. With the flow of fluid through the aeration columns, air “0.8 m ³ / m ^{3 of} fluid (for one column) is drawn in.” In the biocoagulator-flotator 52 with the help of columns with tangentially directed nozzles, the rotational movement of the mixture of wastewater and sludge is carried out. The duration of contact of sludge with water in the flocculation chamber is 8-20 minutes. The fat particles rising with air bubbles are discarded by the wave motion of the liquid to the collecting tray. The efficiency of fat removal in the biocoagulator-flotator is 60-80%. From the flocculation chamber, the sludge mixture through the expansion cone enters the settling zone, where the sludge mixture is separated. Next, the settled wastewater is sent to the mixing chambers with a bin biological treatment device 53 and 55, where the remaining part of fats (60-100 mg / dm ³ ) and dissolved organic substances are sorbed and oxidized.

Design features of combined biological treatment devices, application

- 9 023425 two-stage scheme with series-connected devices of combined biological treatment provide complete removal of hydrogen sulfide and hydrosulfides.

The negative effect of pH on the aerobic purification process is successively reduced by diluting the wastewater several times with circulating activated sludge in the mixing chambers and contacting the sludge mixture first with biofilms of biofilters adapted to lower pH values.

Depending on the accepted version of the cleaning process flow diagram, devices for connecting excess sludge from combined biological treatment devices 5, 55 are connected to the device 20. It is also possible to connect a biocoagulator 52 to the device 20. The pipelines are connected to the thickener 58 of the device 20. There, if necessary, to increase the thickening effect sludge and sludge connected to the supply line of coagulants and / or flocculants 59. Then, the compacted sediment is discharged into a belt filter press 60, where cake is formed with a given moisture by 75-85%. Dehydrated cake is fed to a granulator 61, which also has a feed line for organic and / or mineral additives 62. Sawdust, sunflower seed husks and mineral fertilizers can be used as organic and mineral additives. Granules of 61 are fed onto conveyor rollers 63, which are equipped with heating elements 64. Using them, the granules are heated. The rotating rollers are provided with protrusions for moving the granules. Using microwave emitters 65 mounted above the conveyor, additional drying and deworming of the contents of the granules is carried out. Next, the granules are discharged into the storage tank 66.

Air from rooms with mechanical, biological, and after-treatment devices with a fan 29 is supplied to an air treatment unit 30, where the air first passes through an irrigation chamber 67, where it is in contact with the reagent solution supplied to the irrigation system 68 by a circulation pump 69. During irrigation and the movement of air and droplets of the reagent solution through artificial loading 46 of the nozzle portion 71 interfacial contact occurs. Further, air through direct supply pipes 73 is forced into the bubbler part 70, where secondary contact of air bubbles with the solution takes place. The presence in the lower part of the pipes 73, of mounted pipes of small diameter 74, ensures the separation of the outgoing air flow into small bubbles and helps to increase the contact surface of the phases. The treated air is removed through the duct 76. When draining the fluid through the collecting pan 72 into the drain pan and then into the water-jet ejection tubes of the air 75, some of the air (0.5-0.7 m ³ / m ³ ) of the air received in the device is sucked into the pipes. The subsequent ascent of air bubbles provides mixing of the contents of the bubbler portion 70 and intensive updating of the gas-liquid phase contact surface of the entire volume. Make-up with a new solution is carried out through pipeline 77. The used solution is discharged through pipeline 78.

It is advisable to use the installation for deep biochemical wastewater treatment in the treatment of domestic and industrial wastewater of residential buildings, villages, cities, butchers, binoculars, fish factories, canneries, livestock farms, yeast, brewing, sugar factories, pulp and paper mills, chemical enterprises and microbiological industry, etc.

The degree of treatment of municipal and industrial wastewater with a BOD of 100-1500 mg / dm ³ , suspended solids up to 700 mg / dm ³ is 98-99%. When treating wastewater with a low BOD content of 50 to 100 mg / dm ³ in the biofilters of plants, the process of sorption and oxidation of 70-80% of organic pollutants is carried out. The detached biomass from the loading of the biofilter replenishes the layer of suspended sludge in the sump aeration tank, which makes it possible to bring the purification effect to 99%.

As shown by the semi-production and production tests, the inventive installation for deep biochemical treatment provides complete removal of hydrogen sulfide and hydrosulfides, reducing the concentration of ammonia nitrogen from 100 to 0.5 mg / dm ³ .

The inclusion of biocoagulators-flotators in the technological scheme of a two-stage biological wastewater treatment with combined facilities allows the treatment of concentrated wastewater with a BOD content of up to 3000 mg / dm ³ , fats up to 300 mg / dm ³ and suspended solids up to 1500 mg / dm ³ to the values indicated indicators of 10-15 mg / DM ³ .

The proposed installation solves the complex problem of wastewater treatment, used air treatment and obtaining valuable granular fertilizer.

Moreover, in comparison with traditional aeration structures, the energy costs of the biochemical cleaning process are reduced by 2-3 times; the number of service personnel is reduced by 50-70%; the area of treatment facilities is reduced by 3 times, and the size of the sanitary protection zone, depending on the capacity of the facilities, can be 50-100 m.

Claims (14)

CLAIM 1. Installation for deep biochemical wastewater treatment, comprising a sewage and sludge supply pipe, a sludge removal pipe, a fine mechanical cleaning device, a sand trap, a wastewater-sludge mixing chamber with a circulation pump and a combined biological treatment device including a biofilter with a flat loading, and aeration tanks-settlers, separated by a partition that defines the biofilter room and the premises of the aeration tank-settler, an irrigation system, including irrigation trays, drain pipes, prefabricated pallets and drainage collectors, to which aeration columns with water-jet aeration are connected, buried in the aeration zones of the aeration tank-settler, in which the aeration zones are separated from the settling zones by partitions, and a post-treatment device, in particular a bioreactor for deep wastewater treatment, characterized in that in the combined device biological treatment with a productivity of 5 to 15000 m ³ / day. The biofilter irrigation system includes trays with drain nozzles and reflective disks installed under the nozzles, moreover, the distance from the upper ends of the drain nozzles of the trays to the reflective disks is 0.8-2 m, and the distance between the centers of the trays and the distance between the axes of the nozzles in the trays is 0.6 -1.8 m, as well as the fact that with aeration columns of 25 to 100 mm in diameter, their height above the liquid level in aeration tanks-settlers is 1.2-3.5 m, and the depth of penetration under the liquid level is 1.5- 4 m, while the distance between cuts aeration columns in the upper portion is 50-500 mm and the distance between the lower aeration columns sawn-off is 0.5-3 m. 2. Installation according to claim 1, characterized in that the length of the drain pipes installed in the trays of the irrigation system is in the range from two to six of their diameters, while the diameter of the reflective disks is 80-200 mm, and on the pipelines for the supply of wastewater mixture and sludge, valves are installed in the biofilter irrigation trays and, additionally, gates are mounted at the beginning of the trays, and in front of the initial drain pipes, directional plates are installed. 3. Installation according to claim 1, characterized in that the biofilter loading elements are made in the form of balls with a diameter of 35-100 mm with 4-10 recesses, the axes of which converge in the center of the ball; the balls have protrusions on the surface of 0.1-1.5 mm and metal compounds are included in the composition of the material of the elements. 4. Installation according to claim 1, characterized in that the loading of the biofilter is made of corrugated ceramic sheets with a width of 0.5-1.5 m, a height of 0.5-3 m, a thickness of 2-4 mm, a roughness in the form of protrusions (roughness) on the surface of 0.1-2 mm, with a frame of parallel and longitudinal wavy strips with a width and thickness of 3-10 mm, and some of the longitudinal strips are made in the form of protruding wavy partitions with a width of 10-35 mm, and metal compounds are included in the composition of the sheet material. 5. Installation according to claim 1, characterized in that the drain pan of the biofilter pan is equipped with a directional reflector, the upper part of the aeration columns is made in the form of nozzles screwed into the couplings attached to the bottom of the drain pan, and the drain pan is equipped with a hatch for mounting the nozzles and pipe cleaning. 6. Installation according to claim 1, characterized in that in the drain pipes of the irrigation systems of biofilters and in the pipes of the upper parts of the aeration columns, recesses are made in the form of spirals with a length of 1 to 1.5 turns and a height not exceeding 0.7 of the diameter of the pipe. 7. Installation according to claim 1, characterized in that along the external perimeter of the horizontal partition separating the biofilter from the room of the aeration tank-sump, holes are made at a distance of 0.5-1.5 m from each other or valves for air bypass are installed. 8. Installation according to claim 1, characterized in that for the diameters of the aeration columns from 25 to 100 mm, the height of the lower edges of the columns above the bottom of the aeration zone is 0.05-0.4 m, and the distance from the bottom of the extreme aeration columns to the angle of articulation is flat and the conical parts of the bottom of the aeration tank is 0.5-1.2 m 9. Installation according to claim 1, characterized in that the aeration tank-settler is designed so that the length of the lower leg of the conical part of the aeration tank-settler is half the width of the settling zone plus 0.1-1.0 m, the height from the bottom of the conical part of the partition separating aeration and settling zone to the bottom of 0.5-1.5 m, the aeration tank-settler additionally contains triangular rollers placed on a flat part of the bottom of the aeration zone, and the width of the triangular rollers is 0.5-2.0 m and a height of 0.5- 1.5 m, while the sludge discharge pipe is installed on the outer perimeter conical bottom portion aeropack and has openings or nozzles disposed at an angle of 0-90 ° to the horizontal axis of the pipeline and at a distance of 0.2-1.0 m from each other. 10. Installation according to claim 9, characterized in that the biologically loaded blocks are installed above said triangular rollers, made of plastic plates with holes of 3-30 mm and bristles 5-50 mm long or ceramic plates, including metal compounds, with attached rods or plates of different lengths of 5-40 mm and a roughness on them in the form of protrusions of 0.11.5 mm. 11. Installation according to claim 1, characterized in that it consists of two to four combined biological treatment devices connected to a common mixing chamber by piping for sludge removal from aeration tanks-settlers, and the pressure pipe of the mixing chamber circulation pump is connected to the biofilter irrigation systems of combined devices biological treatment. 12. Installation according to claim 11, characterized in that for deep biochemical wastewater treatment with an organic pollution content of BOD up to 3000 mg / dm ³ and fats up to 300 mg / dm ³ - 11 023425 includes biocoagulators-flotators and a device for processing excess sludge, while the pressure pipe of the circulation pump installed in the mixing chamber of the second combined device is simultaneously connected to the irrigation system of this device and to the mixing chamber of the first combined device; aeration columns of 0.3-1.5 m long, tilt angles from 0 to 50 ° and tangentially directed nozzles are attached to the biocoagulator-flotator water-jet aerator or to the excess sludge treatment device, to the receiving chamber of the biocoagulator-flotator aerator 13. Installation according to claim 12, characterized in that the excess sludge treatment device is designed so that pipelines are connected to the thickener of the excess sludge treatment device from the combined biological treatment device and / or from the biocoagulator and / or anaerobic bioreactor; in turn, a belt filter press is connected to the thickener, in which the dehydrated cake drainage device is connected to the granulator, where the feed line for organic and / or mineral additives is also connected, the pellet removal device is connected to a roller conveyor equipped with heating elements, and / or with microwave emitters placed in series above the conveyor, connected, in turn, to the storage tank. 14. The installation according to item 13, characterized in that it further comprises a used air treatment device, where air ducts from combined biological treatment devices, excess sludge treatment devices, bioreactors, fine mechanical cleaning devices and sand traps are connected to the suction pipe of the high pressure fan, pressure air duct which, in turn, is connected to the irrigation chamber of the used air treatment device equipped with an irrigation system, which is connected to the circulation a pump, the suction nozzle of which is connected to the bubbling part of the used air treatment device, over which the nozzle part of the device filled with artificial loading is placed, a collection tray, in which direct air supply pipes 1.2 to 2.5 m long are inserted, deepened by 0.4 -0.7 m into the bubbling liquid and filled in the lower part with small diameter pipes, as well as water-jet air ejection pipes that are attached to the drain pan, are installed at a height of 0.6-1.8 m above the liquid and are buried in the liquid 1-3 m.