RU2196742C1 - Aeration system - Google Patents

Abstract

FIELD: biological treatment of sewage water; applicable in saturation of liquids with gases, for instance, in saturation of sludge mixture with oxygen. SUBSTANCE: aeration system has aerator with air duct or many aerators with many successively communicated air duct section. For local protection of aerator or many sections from hydrophenumatic impacts installed inside air duct or its part, or inside the first and/or the last section of air duct or its part, or in each of many sections of air duct where removable air damper is arranged along their axes. EFFECT: provided local protection of aerator or many sections from hydropneumatic impacts due to installation of air damper inside air duct. 5 cl, 28 dwg

Description

 The invention relates to the field of biological wastewater treatment and can be used to saturate liquids with gases, for example, to saturate a sludge mixture with oxygen.

 A known aeration system containing an aerator with an air duct or a plurality of aerators with a plurality of consecutive segments of a duct (see Meshengisser Yu.M., Galich R.A., Marchenko Yu.G. Tubular pneumatic aerators and aeration systems Ecopolymer // Water supply and sanitary equipment , 2000, 12, part 2, pp. 5-7 or see Meshengisser Yu.M., Marchenko Yu.G., Chernukha V.A. AKVA-TOR aerators and combined aeration systems.Water supply and sanitary equipment, 2000, 12 , part 2, pp. 11-13).

 As aerators, tubular, ring or disk aerators are used.

 The duct or piece of duct may be plastic pipes with holes or perforated plastic pipes. The duct or duct sections may pass through or outside the aerator, ducts or duct sections are connected to the aerators through air vents in the form of nozzles or punch holes such as perforations or simply holes. The first duct section is considered to be the duct section from the air inlet side of the duct.

 Aeration systems are manufactured by Ecopolimer in the form of separate aerators and elements of aeration systems. When installing aeration systems, the aerator ducts are interconnected by threaded couplings. The Ecopolimer company produces tube aerators of the AQUA-PRO, AQUA-LINE type, ring aerators of the AQUA-TOR type, disk aerators of the AQUA-PLAST type.

 The AKVA-PRO type aerator contains an internal air duct in the form of a pipe, the outer surface of which contains uniformly alternating longitudinal ribs and recesses. A two-layer dispersant coating is applied to the outer surface of the duct pipe. For the formation of the inner layer of the dispersion coating, a knotless mesh of high pressure polyethylene is used. The grid, elongated in the form of a bundle, is wound onto the outer surface of the duct pipe without gaps. The number of layers of winding is determined based on the required resistance of the aerator. The outer layer of the dispersion coating is a porous shell of a polymeric material having randomly laid fibers fused at the points of mutual intersection. This layer is performed by pneumatic extrusion of a polymer melt onto the outer surface of the inner layer. The inner layer of the dispersion coating and the outer surface of the ribs and recesses of the duct pipe form longitudinal channels, in each of which holes are made for venting air from the duct pipe. The duct pipe at the opposite ends has an external thread for coaxial connection with couplings with a similar thread and with which aerators are mounted in aeration systems.

 The AKVA-LINE aerator contains an internal air duct, the opposite ends of which are equipped with threaded couplings with an external thread or couplings with an external and internal thread. The dispersion coating is rigidly fixed to the outer surface of the couplings. The inner surface of the dispersion coating forms a cylindrical gap with the outer surface of the duct. The dispersion coating is made in the form of a cylindrical shell of porous polyethylene. There are openings in the duct for air exhaust from it.

 The AKVA-TOR type aerator contains a ring aerator with a central hole for suction of water and sludge and an external duct located under it in the form of composite pieces of plastic pipe, which are interconnected through the cavity of the connecting pipe. The dispersing coating of the aerator is made in the form of a horizontal ring of porous material.

 The AQUA-PLAST type aerator contains a disk aerator with a perforated elastic membrane and an external air duct located under it in the form of composite pieces of plastic pipe that are interconnected through the cavity of the connecting pipe. The dispersing coating of the aerator is made in the form of a horizontal disk of porous material.

 The air duct of the aeration system is composed of separate sections of plastic pipes connected in series with each other, where the input of each subsequent segment of the duct is connected to the outlet of the previous segment of the duct. The inlet of the lash duct is communicated with a source of compressed air. The whip duct outlet is plugged with a plug. The lashes are installed at the bottom of the aeration tank basin, which is filled with liquid in the form of a sludge mixture.

 During operation, compressed air is continuously supplied to the aeration system duct.

 At the time of starting, the air duct is filled with water and when air is introduced into the system inside the air duct, a hydro-pneumatic shock is possible in the form of a longitudinal traveling wave along the internal cavity of the air duct. A hydro-pneumatic blow to the duct plug can lead to its separation and air to escape directly into the liquid, bypassing the aerators of the aeration system, which is unacceptable.

 The invention is based on a PROBLEM, AERATION SYSTEM, comprising an aerator with an air duct or a plurality of aerators with a plurality of consecutive sections of a duct, TO BE IMPROVED IN ACCORDANCE WITH THE INVENTION, DIFFERENT THAN for a plurality of air ducts or an aeration of the aeration or inside along the first and / or last segment of the duct or part thereof, or in each of the plurality of duct sections, a removable air damper is installed fer.

TECHNICAL RESULT: the improvement allows to achieve local protection of the aerator or multiple aerators from hydropneumatic impacts;
the air damper is designed to extinguish in the duct the energy of a hydropneumatic wave traveling along it and to partially filter water and air or a mixture thereof.

 A FIRST ADDITIONAL DIFFERENCE according to the invention consists in the fact that the removable air damper is made in the form of a permeable to air and / or water single-layer or multilayer flexible shell with at least one inlet in a flexible shell for the entry of air into it.

TECHNICAL RESULT: quenching in the duct of the energy of a hydropneumatic wave traveling along it with partial filtration of water and air or a mixture thereof; the shell when exposed to hydropneumatic shocks of the air-water mixture when starting the aeration system, or stopping it, or changing the operating mode is able, due to its flexibility, to oscillate in the air duct to the beat of a wave traveling along it, which leads to the movement of suspended dust particles and other particles delayed by the shell the opposite end from the inlet of the shell with the cleaning of most of its filter holes, which can significantly reduce the increase in resistance of the aerators during operation; in the shell of the filter cartridge, the energy of the air-air medium is quenched by separating large masses of the water-air medium into many small ones, followed by throttling of the small masses of water and air through the filtering openings of the shell;
A SECOND ADDITIONAL DIFFERENCE according to the invention concludes that at least one elastic sealed container filled with compressed air is located inside the cavity of the removable air damper.

 TECHNICAL RESULT: the improvement allows to protect the aerator from hydro-pneumatic impacts of a water-air wave running along the length of the air duct; under the influence of the hard pressure of an incompressible liquid of water on the air damper in the above form, the container and the air medium are compressed with an increase in the internal air pressure in the vessel due to the accumulation of traveling wave energy, followed by the rejection of the mass of water in the opposite direction and the return of the container to its original volume and shape.

 A THIRD ADDITIONAL DIFFERENCE according to the invention is that the flexible shell of the air damper is surrounded by an outer plastic and / or water permeable plastic bandage.

TECHNICAL RESULT: the improvement makes it possible to provide the air damper design with some rigidity with partial preservation of the filtration and flexible properties of their shell;
the plastic bandage can be applied on the outside and / or inside of the shell in the form of a winding with the formation of a spiral or mesh along the shell in increments of the type "universal" in one or more layers of molten polyethylene rod obtained by extruding a polyethylene melt and surfacing the rod on a rotating inner and / or the outer side surface of the shell; in the areas between the plexus of the rod flexible sections of the shell are formed with many filter holes for the passage of air and / or water.

 A FOURTH ADDITIONAL DIFFERENCE according to the invention CONCLUDES THAT the flexible shell of the air damper is provided with a device for its longitudinal or longitudinal-transverse tension.

TECHNICAL RESULT: the improvement makes it possible to provide longitudinal or longitudinal-transverse tension of the flexible shell and thereby maintain its original shape during operation, while ensuring the possibility of realizing the properties of the flexible shell for dropping dust and particles adhering to its walls under the influence of traveling wave energy, the shape of which the shell partially tracks , which leads to the dropping of dust from the walls of the shell and moving them to a dead end zone opposite to the entrance end of the shell stocking;
the device of longitudinal or longitudinal-transverse tension of the shell is made, for example, in the form of a spring with a bracket fixed by the middle of the bracket to one end of the spring, where the second end of the spring is hooked to the hole for tensioning the shell, for example, a hole for tensioning the shell framed by a grommet at the dead end of the shell, where the ends of the bracket are hooked over the edges of the duct pipe or holes in the walls of the duct pipe; in the working position, the spring is in a tense state, and during hydropneumatic impacts, the shell stretches and the spring tension partially decreases and resumes again when the traveling wave returns during hydropneumatic impact.

 The inlet of the sheath stocking is surrounded by an annular pocket that encloses an o-ring made of elastic material, such as rubber or rubber, to gently expose the o-ring to the sheath during jerking of the sheath during hydropneumatic impacts in the air duct cavity and in the sheath.

 The shell is equipped with a removable annular flange, on which it is freely put on and removed from the first side of the flange, and on its other side the flange has the ability to abut against the end of the duct; the middle flange has an annular transverse groove in which a first pocket with a first sealing ring is placed; between the first side of the flange and the groove parallel to the groove there is an annular board of rounded cross-section, which forms an annular gap between the inner wall of the duct and itself; the width of the gap is greater than the thickness of the sheath material, but less than the width of the longitudinal section of the first pocket with the first sealing ring inserted into it, which is necessary to hold the shell on the flange after it is inserted into the duct with the shell; from the removed flange, the shell is freely pulled off and put on freely by stretching the elastic first sealing ring and the flexible first pocket, which is convenient when installing and removing the aeration system.

The flexible shell of the air damper on the opposite side of the inlet has a second pocket, similar to the first inlet pocket, with a similar second o-ring located in it, but smaller; the second pocket tightly encloses the annular groove on the leg of the hollow hemisphere of the bowl, where the leg of the bowl ends with a ring for attaching one of the ends of the spring; the cup itself is located at the end of the shell and when the spring is tensioned, hooked onto the ring on the leg, or when the cup is pulled out of the shell by the ring, the cup cannot pull out freely from the shell, which is necessary to keep the shell in tension;
The external shape of the elastic container can be made in the form of a sphere that can freely fit in the cavity of the bowl, but does not have the ability to spontaneously jump out of it, for example, the diameter of the inlet of the bowl is less than the diameter of the inner cavity of the bowl.

 Other objectives, features, advantages and possibilities of using the invention are apparent from the following description of exemplary embodiments based on the figures. Moreover, all described and / or graphically presented features in themselves or in any reasonable combination constitute the subject of the invention, regardless of general requirements or feedback.

 The list of figures of drawings and other materials.

 FIG. 1. Aeration system. End tubular aerator type AKVA-PRO. Side view.

 FIG. 2. Aeration system. AQUA-PRO type through-flow aerator. Side view.

 FIG. 3. Aeration system. AQUA-LINE type pipe aerator. Side view.

 FIG. 4. Aeration system. AQUA-LINE type pipe aerator. Coupling design option. Side view.

 Figure 5. Aeration system. Node A in figure 1.

 6. Aeration system. Node B in figure 3.

 7. Aeration system. Node G in figure 4.

 Fig. 8. Aeration system. Section AA in figures 1, 2.

 Fig.9. Aeration system. Section bb in figures 3, 4.

 FIG. 10. Aeration system. Air damper or filter cartridge in the form of a shell with a shell tension device. Side view.

 11. Aeration system. The same as in figure 10, but with views of the details of the air damper or filter cartridge.

 Fig. 12. Aeration system. Air damper or filter cartridge without tensioner. Lengthwise cut.

 FIG. 13. Aeration system. Air damper or filter cartridge. Side view.

 FIG. 14. Aeration system. Tubular aerator type AKVA-PRO. Option. The arrows indicate the direction of air movement. Lengthwise cut.

 FIG. 15. Aeration system. Filter cartridge. Option. Side view. The arrows indicate the direction of air movement.

 Fig.16. Aeration system. The same as in figure 15. A longitudinal section. The arrows indicate the direction of air movement.

 FIG. 17. Aeration system. The same as in figure 16. Option. Lengthwise cut.

 FIG. 18. Aeration system. A lot of tubular aerators type AKVA-PRO. Option. Side view.

 FIG. 19. Aeration system. A lot of tubular aerators type AKVA-PRO. Option. Side view.

 FIG. 20. Aeration system. A lot of tubular aerators type AKVA-PRO. Option. Side view.

 Fig.21. Aeration system. Many tubular aerators type AKVA-PRO in combination with many ring aerators type AKVA-TOR. Side view.

 Fig.22. Aeration system. Many tubular aerators type AKVA-PRO in combination with many disk aerators type AKVA-PLAST. Side view.

 Fig.23. Aeration system. Many tubular aerators type AKVA-PRO in combination with many ring aerators type AKVA-TOR. View from above.

 Fig.24. Aeration system. Many tubular aerators type AKVA-PRO in combination with many disk aerators type AKVA-PLAST. View from above.

 Fig.25. Aeration system. Many ring aerators AQUA-TOR. Side view.

 FIG. 26. Aeration system. Many disk aerators AQUA-PLAST. Side view.

 Fig.27. Aeration system. Many ring aerators AQUA-TOR. View from above.

 FIG. 28. Aeration system. Many disk aerators AQUA-PLAST. View from above.

The list of symbols in the drawings:
1 - aerator;
2 - air duct;
3 - filter cartridge;
4 - air damper;
5 - shell;
6 - inlet in the shell 5;
7 - elastic sealed container filled with compressed air;
8 - plastic bandage frame;
9 - a device of longitudinal or longitudinal-transverse tension;
10 - spring;
11 - a bracket;
12 - hole for tensioning the shell 5;
13 - annular first pocket of the shell 5;
14 - the first sealing ring of the shell 5;
15 - annular flange removable from the shell;
16 - the inner side of the flange 15;
17 - the other inner side of the flange 15;
18 - end of the duct 2;
19 is an annular transverse groove of the flange 15;
20 - annular side of the flange 15;
21 - an annular gap;
22 - the second pocket of the shell 5;
23 - the second sealing ring of the second pocket of the shell 5;
24 - an annular groove;
25 - leg;
26 - a bowl;
27 - a ring with a hole 12;
28 - the cavity of the bowl 26;
29 - inlet cavity 28 of the bowl 26;
30 - hard filter;
31 - pipe;
32 - a lot of holes;
33 - a layer of filter material;
34 - input flange of the hard filter 30;
35 - ring with grooves;
36 - groove;
37 - a sealing ring;
38 - plug pipe 31;
39 - plug duct 2;
40 - hole for air exhaust from the duct 2;
41 - coupling with external thread;
42 - coupling with internal thread;
43 - a sealing ring of the coupling;
44 - a sealing ring of a gap;
45 - horizontal plane;
46 - connecting sleeve.

 Examples of the implementation of the aeration system are shown in the figures (see figures 1-28). The aeration system may contain at least one aerator 1 with an air duct 2 inside (see Figures 1-4) or outside of the aerator 1. The aeration system may contain many aerators 1 with a plurality of consecutive sections of duct 2 inside and / or outside of many aerators 1 (see figures 18-28). As aerators 1, tubular, ring or disk aerators are used.

 The aeration system can be composed of a consecutive set of aerators 1, which can cover a pipe with a tube dispersing surface from sections of duct 2, such aerators include tubular aerators 1 of the type AQUA-PRO (see Figs. 1, 2) or AQUA-LINE (see Fig. .3, 4). Air duct 2 or sections of duct 2 may be located below the aerators 1, for example, disk aerators 1 of the type AKVA-PLAST (see Fig. 22, 24, 26, 28) with a disk pneumatic disperser with a perforated elastic membrane or ring aerators AQUA-TOR (see Fig. 21, 23, 25, 27) with an annular dispersant with a through hole inside the porous dispersing surface.

 The aeration system can be combined, that is, composed of many series-connected segments of the duct 2 with various types of aerators 1, for example, of segments of the duct 2 with tubular aerators 1 of the type AQUA-PRO or AQUA-LINE, which alternate in series with the segments of the duct 2 with above it, ring aerators of type 1 AKVA-TOR or disk aerators of type 1 AKVA-PLAST (see Fig. 21-24).

 The aeration system can be composed of a plurality of consecutively connected duct sections 2 only with top-mounted or side-mounted disk aerators 1 of the AQUA-PLAST type (see Figs. 26, 28) or only with ring aerators of the AQUA-TOR type 1 (see Fig. 25 , 27).

 Inside the duct 2 or part thereof, or inside along the first (from the air inlet to the duct) and / or the last segment of duct 2 or part thereof, or in each of the plurality of duct sections 2, a removable filter cartridge 3 and / or air damper 4 is installed.

 The installation of the filter cartridge 3 and / or air damper 4 inside the duct 2 allows you to achieve local protection of the aerator from dust, corrosion and erosion products, hydropneumatic shock.

 Filter cartridge 3 is intended for: filtering air from the shell 5 into the duct 2 and separating the air from the accompanying water with separation from the last dust particles and other particles, for example, corrosion products, erosion of the ducts (meaning ducts in front of the aeration system); for filtering water both from the filter cartridge 3 into the air duct 2, and back from the air duct 2 to the filter cartridge 3, depending on the operating mode of the aerator 1 and for partial damping of hydropneumatic shocks.

 The air damper 4 is designed to extinguish in the duct 2 the energy of a hydropneumatic wave traveling along it and to partially filter water and air or a mixture thereof.

 The removable filter cartridge 3 is made in the form of a flexible permeable to air and / or water single-layer or multilayer shell 5 and at least one inlet 6 in the shell 5 for the entry of air into it.

 The filter cartridge 3 in the form of a flexible permeable to air and / or water single-layer or multilayer shell 5 allows for increased dust absorption of the aerator 1, allows it to work with a slight increase in the initial resistance to the passage of compressed air through the aerator 1.

 In the filter cartridge 3, dust and other particles are captured by the inlet 6 of the shell 5, followed by filtration of water and air or an air-water mixture through the filter holes of the shell 5. The cross sections of the filter holes in the shell 5 may be the same for all segments of the duct 2, may be in the first section of the duct more or less than in the last. The length of the shell stocking 5 may decrease or increase in proportion to the number of pieces of duct 2 or aerators 1 in the aeration system, which is necessary for uniform atomization of air along the length of the aeration system.

 The length of the filter cartridge 3 or air damper can be from 0.1 to 0.9, the length of the duct 2 or the length of the length of the duct 2 or the sum of the lengths of the lengths of the duct 2 in the aeration system.

 The outer diameter of the cross section of the filter cartridge 3 or air damper 4 along the shell 5 may be from 0.3 to 0.95 of the inner diameter of the duct 2.

 The shape of the shell 5 in the form of a long flexible stocking is necessary for dropping dust particles and other particles from the inner walls into the shell 5 and redistributing their masses from the filtration holes to the opposite end of the shell 5 from the inlet 6 of the shell 5 with an accumulation of dust particles in the dead end zone inside the shell 5 , which increases not only the dust absorption of the aerator 1, but also allows it to work with a slight increase in the initial resistance to the passage of compressed air through the aerator 1.

 Shell 5 when exposed to hydropneumatic shocks of a water-air mixture when starting the aeration system or stopping it or changing the operating mode, is able, due to its flexibility, to oscillate in air duct 2 per wave running along it, which leads to the movement of suspended dust particles 5 and others particles to the opposite end from the inlet 6 of the shell with the cleaning of most of its filter holes, which can significantly reduce the increase in resistance of the aerators 1 during operation; in the shell of the filter cartridge 3, the energy of the water-air medium is quenched by separating large masses of the water-air medium into many small ones, followed by throttling of the small masses of water and air through the filtering holes of the shell 5.

 The air damper 4 is made in the form of a flexible permeable to air and / or water single-layer or multilayer shell 5 and at least one inlet 6 in the shell 5 for the entry of air and with an elastic sealed inside it filled with compressed air at least one tank 7.

 Since the air damper 4 is designed to protect the aerators 1 from hydro-pneumatic shocks running along the length of the air duct 2 of the air-water wave, when the pressure of the incompressible liquid of water exerts hard pressure on the air damper 4 in the above form, the container 7 and the air medium are compressed with increasing internal the air pressure in the tank 7 due to the accumulation of energy of the traveling wave, followed by the rejection of the mass of water in the opposite direction and the return of the tank to its original volume and shape, which reduces the damage flax ability hydropneumatic shock in the aeration system.

 The shell 5 of the filter cartridge 3 or air damper 4 is covered outside and / or inside by a plastic bandage frame 8 that is permeable to air and / or water.

 The plastic bandage frame 8 can be applied externally and / or from the inside of the sheath 5 in the form of a winding with the formation of a spiral or mesh along the sheath 5 in increments of the “universal” type in one or more layers of a molten polyethylene rod obtained by extruding a polyethylene melt and welding the rod onto a rotating the inner and / or outer side surface of the shell 5. In the frame 8 in the areas between the fused plexus of the rod are formed flexible sections of the shell with many filter holes for the passage of air and / or odes.

 The shell 5 of the filter cartridge 3 or air damper 4 is equipped with a device 9 for longitudinal or longitudinal-transverse tension.

 The device 9 longitudinal or longitudinal-transverse tension allows for longitudinal or longitudinal-transverse tension of the flexible shell 5 and thereby maintain its original shape during operation, while ensuring the possibility of realizing the properties of the flexible shell 5 for dropping dust and particles adhering to its walls under the influence of traveling wave energy , the shape of which the shell 5 partially tracks, which leads to the dropping of dust from the walls of the shell 5 and moving them to the dead end zone opposite the entrance from the end of the shell stocking chki 5.

 The device 9 of longitudinal or longitudinal-transverse tension of the shell is made, for example, in the form of a spring 10 with a bracket 11 (see Fig. 10.11), fixed by the middle of the bracket 11 to one end of the spring 10, where the second end of the spring 10 is hooked to the hole 12 for sheath tension, for example (not shown in the drawings), a hole 12 for sheath tension 5, framed by a grommet at the dead end of sheath 5, where the ends of the bracket 11 are hooked to the edges of the duct pipe 2 or the holes in the walls of the duct pipe 2. In the working position, the spring 10 is in a tense state and, during hydropneumatic impacts, the shell 5 stretches and the tension of the spring 10 partially decreases and resumes again when the traveling wave returns during a hydropneumatic impact.

 The inlet 6 of the shell stocking 5 is surrounded by an annular first pocket 13, which covers the first sealing ring 14 of the shell 5. The ring 14 is made of an elastic material, such as rubber or rubber, for the soft action of the first sealing ring 14 on the shell 5 during jerking of the shell 5 during hydropneumatic impacts in the cavity of the duct 2 and in the shell 5.

 The shell 5 is equipped with a removable annular flange 15, on which it is freely put on and removed from the inner side 16 of the flange 15, and on the other side of its inner side 17, the flange 15 is able to abut against the end face 18 of the duct 2; the flange 15 in the middle has an annular transverse groove 19, in which the first pocket 13 is placed with the first sealing ring 14. Between the first side 16 of the flange 15 and the groove 19 parallel to the groove 19 there is an annular side 20 of a rounded cross section, which forms an annular gap 21 between the inner wall duct 2 and them. The width of the slit 21 is greater than the thickness of the material of the sheath 5, but less than the width of the longitudinal section of the first pocket 13 with the first sealing ring 14 inserted into it, which is necessary to hold the sheath 5 on the flange 15, after it is inserted with the sheath 5 into the duct 2. From the removed flange 15 the shell 5 is freely pulled off and freely put on by stretching the elastic first sealing ring 14 and the flexible first pocket 13, which is convenient for mounting and dismounting the aeration system (see Fig. 5, 6, 7, 11).

 The flexible shell 5 of the filter cartridge 3 and the air damper 4 on the opposite side of the inlet 6 has a second pocket 22 similar to the first pocket 13 of the inlet 6 and also has a similar second sealing ring 23, but smaller; the second pocket 22 tightly covers the annular groove 24 on the leg 25 of the hollow hemisphere of the bowl 26, where the leg 25 of the bowl 26 ends with a ring 27 with an opening 12 for attaching one of the ends of the spring 10. The cup 26 itself is located at the end of the shell 5 and when the spring 10 is engaged for the ring 27 on the leg 25, or when pulling the bowl 26 from the shell 5 for the ring 27, the bowl 26 is not able to pull out freely from the shell 5, which is necessary to keep the shell 5 in tension.

 The external shape of the elastic container 7 can be made in the form of a sphere that can freely fit in the cavity 28 of the bowl 26, but is not able to spontaneously jump out of it, for example, the diameter of the inlet 29 into the cavity 28 of the bowl 26 is less than the diameter of the internal cavity 28 of the bowl 26 ( see Fig. 12).

 The filter cartridge can be made in the form of a rigid filter 30 (see Fig. 14-17) in the form of a perforated pipe 31 or a filter cartridge pipe with many holes 32, where the pipe is covered by one or more layers 33 of filter material. The air inlet end of the pipe 31 of the filter cartridge of the rigid filter 30 is equipped with an inlet flange 34, which is adjacent to the ring 35 with one or two grooves 36 with concentric elastic sealing rings 37 inserted into them, which, when inserted into the grooves 36, can fit tightly and exit the duct 2 pipe; the opposite end of the pipe 31 of the hard filter 30 is plugged with a plug 38.

 An additional filter cartridge or an air damper, similar to a filter cartridge 3 or an air damper 4 (see FIG. 17) of the air duct 2, but smaller, can be installed inside the pipe 31 of the hard filter 30.

 Duct 2 may have a plug 39 at the end. Duct 2 has vents in the form of holes 40. Duct 2 may have removable couplings 41 with external threads or couplings 42 with internal threads or different couplings: one sleeve 42 with internal thread, and another coupling 41 with external thread. To speed up the assembly, any of the couplings 41, 42 can be combined with a plug or made in the form of a plug. Clutches 41, 42 have O-rings 43 to eliminate threaded air leaks. O-rings 44 are installed between each of the couplings 41, 42 and the duct to seal the landing gap and eliminate air leaks into the gap between the couplings 41 and / or 42 and the duct 2.

 The device operates as follows.

 Insert the filter cartridge 3 into the duct 2. The filter cartridge 3 is oriented in the duct so that the flange 15 of the filter cartridge 3 abuts against the end face 18 of the duct 2. The sheath 5 is stretched and elastic enough to maintain a cylindrical shape. The spring 10 of the shell tensioning device 9 is compressed, and the ends of the clamp 11 are hooked to the end of the duct 2 opposite the end 18. A container 7 can be inserted into the bowl 26, then the filter cartridge turns into an air damper 4.

 The aeration system is immersed in an aeration tank or reservoir (not shown in the drawings), which is filled with water with sludge or water. The aeration system is filled with water before starting. Compressed air is supplied to the opening 6 of the filter cartridge. Compressed air enters the cavity of the shell 5 and gradually displaces water from it, which is squeezed out under pressure of compressed air through the filtering openings of the shell 5 into the air duct 2, from which it is automatically squeezed out through a plurality of aerators 1 into the aeration tank. Compressed air in one gulp at a speed of 1-2 m / s moves along the cylinder of the inner cavity of the shell 5 and strikes into the bowl 26 at the end of the shell 5 muffled by it. The shell swells and throws many small air bubbles into the air duct through the upper part of the filtering openings of the shell 5, and the rest part of the filtering holes of the shell of the filter cartridge 3 throws water into the duct 2. At the same time, many air bubbles formed in the duct 2 around the side surface of the shell 5 soften the force of the hydro-pneumatic shock of the water wave traveling through the stocking to the end of the shell 5. If a container 7 is placed in the bowl 26, then it is possible to soften the impact of this wave at the end of the shell. With a capacity of 7, it is possible to generate counterpropagating waves to quench the waves incident on the capacitance 7, for example, the pressure force of the incident waves compresses the container 7, and the compressed air in the sealed elastic container is compressed even more, accumulates the energy of the incident wave and automatically uses the stored energy to generate counterpropagating waves wave deviations, which partially suppress the force of incident waves with additional extrusion of water from the cavity of the sheath 5 into the cavity of the duct and further from the aerator, providing compressed air fill the shell cavity 5 the filter cartridge.

 After starting, the aeration system goes into stationary mode, and the filter cartridge works like a regular filter, that is, it retains dust and other suspended solids, corrosion and erosion products that may accidentally enter the aeration system from the outside.

 TECHNICAL RESULT: the improvement allows to achieve local protection of the aerator or many aerators from hydropneumatic impacts.

Claims (5)

 1. An aeration system comprising an aerator with an air duct or a plurality of aerators with a plurality of consecutive sections of a duct, characterized in that for local protection of the aerator or a plurality of aerators from hydro-pneumatic impacts inside along the duct or part thereof, or inside along the first and / or last piece of duct or parts thereof, or in each of a plurality of duct sections, a removable air damper is installed.  2. The aeration system according to claim 1, characterized in that the removable air damper is made in the form of a permeable to air and / or water single-layer or multi-layer flexible shell with at least one inlet in a flexible shell for air to enter into it.  3. The aeration system according to claim 1, characterized in that at least one elastic sealed container filled with compressed air is located inside the cavity of the removable air damper.  4. Aeration system according to one of paragraphs. 1 to 3, characterized in that the flexible shell of the air damper is covered outside and / or inside by a plastic bandage permeable to air and / or water.  5. Aeration system according to any one of the above items, characterized in that the flexible shell of the air damper is equipped with a device for its longitudinal or longitudinal-transverse tension.

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