RU2338695C2 - Airlift (versions) and method of its operation - Google Patents

Abstract

FIELD: water purification.

SUBSTANCE: airlift contains fixed to each other and coaxially-mounted inlet 1 and outlet 2 sections, made from pipes of different diameter. In place of pipe connection seal 3 is located. End of section 1 pipe, fixed in end part of section 2 pipe, is equipped with disperser 4. According to first version of invention free end of inlet section 1 pipe is fixed in passage canal 9 ┤ -shaped tee 8, supplied with side boss 11 in form of connecting pipe for connection to pipeline 12 of compressed air supply, fixed along airlift length by means of clamps 13. According to second version of invention free end of inlet section 1 pipe is fixed in passage canal of ⊥ -shaped tee, supplied with side bosses with connected passage canals, one of which is made in form of connecting pipe for connection to pipeline of compressed air supply, the second being made in form of shut-off valve seat. Shut-off valve is supplied with tie and float and is movably fixed on inlet and outlet sections. According to third version of invention free end of inlet section 1 pipe is fixed in passage canal of running-water vortical chamber, supplied with tangent connecting pipe for introduction of compressed air.

EFFECT: increase of efficiency and reliability of airlift with ensuring possibility of its use as means for saturation of transferred liquid with air.

36 cl, 6 dwg

Description

The invention relates to structural elements of biological wastewater treatment plants.

The prior art designs of airlifts with a ring or central circuits for supplying compressed air to a liquid, the rise of which is due to the energy of the air mixed with it (see "Polytechnical Dictionary", ed. "Soviet Encyclopedia", Moscow, 80, p. one hundred).

The disadvantage of airlifts made according to the indicated schemes is their low efficiency, due to the fact that the bore of the water pipe is reduced by the size of the cross-sectional area of the pipe for supplying compressed air.

The closest analogue adopted for the prototype of the proposed invention is an airlift with a side circuit for supplying compressed air. With this scheme, air is supplied to the water-lifting pipe through a nozzle cut into the wall of this pipe near its inlet section (see the description to RU No. 2201405, С02F 3/02, 2002).

The disadvantage of this airlift is the unreliable fastening of the nozzle on the water-lifting pipe, and bends of the pipeline for supplying compressed air are possible, which generally reduces the reliability of the airlift. In addition, when installing the airlift, difficulties arise in controlling the accuracy of the installation by the height of the lower (suction) section of the water-lifting pipe, and there are no means of fixing it in the required position.

The technical problem solved by the invention is to increase the efficiency and reliability of the airlift with the possibility of its use as a means to saturate the pumped liquid with air.

The solution to this problem is ensured by the fact that the airlift, comprising a body in the form of a water-lifting pipe (VP) with a curved outlet section, equipped with a nozzle located in the region of its inlet slice and equipped with a fitting for connecting to the compressed air supply pipe, according to the invention, the VP is made of pipes of different diameters, the ends of which are interconnected with the formation of at least two, coaxial, inlet (BC) and outlet sections (HIGH), while a dispersant (D) is installed at the entrance to the HIGH, and the free end of the BC pipe is fixed in the by-pass channel of the ┤ -shaped tee (T), equipped with a lateral tide in the form of a fitting for connecting to the compressed air supply pipe, equipped with a nozzle channel in communication with the passage channel T, while the curved outlet section is made with a diameter smaller than the HIGH diameter.

In an embodiment of the invention, the VP is made of pipes of different diameters, the ends of which are interconnected with the formation of at least two, coaxial, aircraft and high, while at the entrance to the high and at its height installed D, the free end of the pipe BC is fixed in the passage channel ⊥- shaped T equipped with lateral tides with communicated passage channels, one of which is made in the form of a fitting for connecting to the compressed air supply pipe, and the other is made in the form of a shut-off valve seat, which is equipped with a draft and a float and is movably fixed to the inlet oh and output sections, while the curved output section is made with a diameter smaller than the diameter of the output section.

In another embodiment of the invention, the VD is made of pipes of different diameters, the ends of which are interconnected with the formation of at least two, coaxial, aircraft and high, while at the entrance to the high and at its height installed D, the free end of the pipe BC is fixed in the flow passage a vortex chamber equipped with a tangential fitting for introducing compressed air, while the curved outlet section is made with a diameter smaller than the diameter of the outlet section.

In embodiments, the vortex chamber is provided with a coaxially arranged cylindrical shell mounted to form a circular vortex channel closed at the bottom, above which the vortex screen is located; the dispersant is made in the form of a metal mesh fixed to the outlet pipe section of the inlet section; the dispersant is made in the form of longitudinal slots in the blind end part of the pipe of the inlet section and a turbulator in the form of a plate mounted in the output section above the blind end of the pipe of the inlet section; a piece of pipeline is fixed on the fitting for introducing compressed air, which is fixed along the height of the airlift, while the free end of this pipeline is equipped with an adapter; the diameter of the curved outlet section is 0.3-0.6 dimeters of the main part of the outlet section; the inner diameter of the inlet section is 0.4-0.6 of the inner diameter of the outlet section; a plate stop is fixed on the lower end part of the airlift, with a protrusion behind the lower edge of the end face for a length of at least 1 cm; the length of the inlet section is not less than 0.3 of the length of the outlet section; Dispersants are located along the height of the aircraft BC and HF form a telescopic connection; thrust of the valve is adjustable; section pipes and tee are made of polymer material; as the polymeric material used is polyethylene, or propylene, or vinyl plastic, or other similar materials.

The solution to this problem is also ensured by the fact that the airlift operation method includes supplying air to the inlet region of the water-lifting nozzle, according to the invention, the water-lifting nozzle is made in the form of a ∩-shaped siphon with a shut-off valve and dispersers located in the input branch of the ∩-shaped siphon, while the airlift is carried out until the knee of the ∩-shaped siphon is filled with a gas-liquid mixture, and the airlift is turned off by landing the shut-off valve on the seat equipped on the inlet slice ∩ -shaped siphon, while the output slice of the ∩-shaped siphon is located below the location of the valve float in the closed position.

In the proposed versions of airlifts due to the dispersion of the gas phase during pumping, a sharp increase in the contact surface of the gas and liquid phases with the saturation of the liquid phase with air is provided. In addition, due to a more uniform distribution of the gas phase in the liquid, the pumping efficiency is increased and energy consumption is reduced.

The invention is illustrated by drawings, where in Fig.1, 2, 4, 6 shows a General view of the options for airlift (longitudinal section); figure 3 is a section aa of figure 2, figure 5 is a section bb of figure 4.

Airlift contains fixed between itself and located coaxially inlet 1 and outlet 2 sections made of pipes of different diameters. These pipes can be telescopically interconnected, i.e. with the possibility of shifting relative to each other. In the place of the telescopic connection there is a seal 3. The end of the pipe of section 1, fixed to the end of the pipe of section 2, is equipped with a dispersant 4, made, for example, in the form of a metal mesh. In addition, the dispersant can be made in the form of longitudinal slots 5 in the blind end part of the pipe of section 1 and a turbulator in the form of an annular protrusion 6 installed in section 2 above the blind end of the pipe 1. It is also advisable that section 2 be equipped with dispersants made in the form alternating in height of this section of the annular protrusions 6 and plates 7. Section 2 in section a is curved and made in the form of a drain, the diameter of which is less than the diameter of the main part of section 2. In the first embodiment of the invention, at the free end of the pipe of section 1 is closed captive ┤-shaped tee 8 with a passage channel 9 in communication with a nozzle channel 10 made in the side tide 11. The side tide 11 is made L-shaped with an inlet located parallel to the pipe section 1, and made in the form of a fitting on which is fixed a piece of pipe 12 for air supply, fixed along the length of the airlift by means of clamps 13. At the free end of the pipe 12, an adapter (not shown conventionally) is fixed for connection to the pressure line of the air supply. On the end of the tee 8, a plate stop 14 is installed, partially protruding beyond the end of this tee by at least 1 cm. The pipes of sections 1 and 2, as well as the tee 8 and the stop 14 can be made of polymer material, which can be used as polyethylene, or propylene, or vinyl plastic, or other similar materials, i.e. materials having a long service life due to the fact that they are not subject to corrosion and decay.

In another embodiment of the invention, the free end of the section pipe is equipped with a ⊥-shaped tee having lateral tides 15 and 16 with channels 17 and 18 connected to each other, which are connected to each other. The tide 16 is made in the form of a fitting for connecting to the compressed air supply pipe, and the tide 15 is made in the form of a shut-off valve seat 19, which is equipped with an adjustable rod 20 with a float 21. The rod 20 is movably fixed to sections 1 and 2. Otherwise, this option is similar to the above .

The next embodiment of the invention is similar to those described above with the only difference being that a flow vortex chamber 22 is provided at the free end of the pipe of the first section 1, equipped with a tangential fitting 23 for introducing compressed air. The vortex chamber is also provided with a coaxially arranged cylindrical shell 24, which is installed to form a circular vortex channel 25 closed from below, above which a vortex screen 26 is located.

In all embodiments of the invention, it is advisable that the inner diameter of the inlet section 1 be 0.4-0.6 of the inner diameter of the outlet section 2. This is necessary to prevent the confluence of air bubbles crushed on the dispersants. At lower or higher values of this parameter, respectively, either the air bubbles merge (crushed on the dispersant), or the dimensions of the airlift increase significantly, and it unnecessarily clutters the internal volume of the biological treatment plant (UBO). It is also advisable that the length of the inlet section 1 is at least 0.3 of the length of the outlet section 2, because the main saturation of water with oxygen occurs in the outlet section. A lower value of this parameter is impractical due to the fact that with a lower value of this parameter, the gas-liquid flow does not have time to form by the time it enters section 2, while the dispersion efficiency decreases and irregularities arise in the operation of the airlift. It is also advisable that the plate stop 14 partially protrudes beyond the end of the tee (or vortex chamber) by at least 1 cm. This follows from the design features, as in the place of installation of the airlift at the bottom of the UBO chamber there is a slotted clamp in which the stop is fixed 14. The telescopic connection of sections 1 and 2 allows you to adjust the length of the airlift depending on the height of the UBO chambers.

The work of the proposed device options and the method of operation of one of the options are as follows.

During installation, the airlift is located in the UBO chamber in a vertical operating position, while due to the plate stop 14, the lower end of the airlift is located at a certain distance from the bottom of the UBO chamber. At the bottom of the UBO chamber, a plate stopper latch 14 is provided, which simplifies the installation of the airlift. During the operation of the airlift, compressed air is supplied to the pipe 12, from where it enters the nozzle channel 10, at the outlet of which the air stream is crushed into a liquid with the formation of a gas-liquid mixture with a specific gravity less than the specific gravity of the liquid filling the UBO chamber from which the liquid is pumped out, this gas-liquid mixture, due to the emergence of air bubbles, rises along the inlet section 1. The size of the air bubbles as they rise increases due to the reduction of hydrostatic pressure, with a corresponding increase in their volume ema. When the dispersant 4 passes, the bubbles break into smaller bubbles, which enter the outlet section 2. Due to the fact that section 2 has a larger inner diameter than the inner diameter of section 1, the gas-liquid mixture flow rate at the entrance to section 2 decreases, while due to the increase in the number of bubbles, the contact area of the gas and liquid phases increases, which creates favorable conditions for the saturation of the latter with air, and, in addition, increases the efficiency of airlift due to more efficient use of air, ku section 2 bubbles have a larger section than 1, the surface with a corresponding increase in their transport capacity. Practice has established that the inner diameter of the inlet section should be 0.4-0.6 of the inner diameter of the outlet section; for smaller or larger values of the indicated ratios of diameters - either the saturation of the liquid with air is not enough, or the effect of the value of the difference in diameters on the efficiency of the airlift is insignificant and leads to excessive cumbersome airlift. Due to the fact that the length of the inlet section 1 is at least 0.3 of the length of the outlet section 2, the effect on the pumping ability of the airlift and the increase in the size of the bubbles when they float are reduced. This is due to the fact that due to the implementation of the input section 1 is shorter than section 2, the size of the bubbles suitable for the dispersant 3, still does not reach critical sizes. If the length of the inlet section is less than 0.3 of the length of section 2, then by the end of section 2 the size of the bubbles will be increased, respectively, the liquid partitions (lamellas) between them will be thinned, which reduces the volume of liquid transported by the bubbles. The execution of the section a section 2 curved, with a smaller diameter than the diameter of the main part of the output section 2, provides an increase in the flow rate in this section and the discharge of the pumped gas-liquid mixture of liquid, for example, in the adjacent chamber of the UBO. The implementation of the lateral tide 11 L-shaped curved with the inlet section in the form of a fitting located parallel to the pipe of the inlet section 1, provides the possibility of fixing on this fitting pipe section 8 without kinks.

The work of the second version of the airlift is similar to the first option, i.e. when pumping liquid, it is saturated with air. At the same time, this variant of the device can be used for siphon overflow of liquid, for example, from chamber B to chamber U of the UBO, while briefly turning on the air supply to the airlift to fill the input branch of the ∩-shaped siphon and knee with a gas-liquid mixture, and after filling them the air supply is stopped and further discharge of the liquid occurs in a siphon mode. The siphon is switched off automatically when the liquid level in chamber B decreases due to the valve 19 landing on the seat (tide 15). Turning on / off the air supply can be incorporated into the programmer, which is equipped with modern UBO. Due to the fact that the output section of the ∩-shaped siphon is located below the location of the valve float in the closed position, i.e. the outlet section of the siphon is located below the liquid level in chamber B, gravity draining the liquid from chamber B to chamber G is provided (with a higher level of liquid in chamber B compared to chamber D), while the pumped liquid is saturated with oxygen only at the initial stage of pumping. It should be noted that if this embodiment of airlift is used mainly as a siphon overflow, then the presence of dispersants is impractical.

The operation of the next embodiment with the vortex chamber 22 is similar to the first variant, however, due to the fact that the free end of the pipe of section 1 is located in the passage channel of the flow vortex chamber 22, the suction capacity of the airlift is increased. This is due to the fact that when the air is tangentially introduced through the tangential fitting 23, a vortex air flow develops in the volume of the vortex chamber, while the axial region of the vortex with reduced pressure closes on one side, on the vortex screen 26, and on the other, on the bottom of the UBO chamber. The supply of the vortex chamber with a coaxially arranged cylindrical shell 24, which is installed with the formation of a circular vortex channel closed at the bottom, provides the development of an annular vortex air flow that traps the liquid with the formation of a water-air emulsion, which enters the inlet section 1. Next, the work is carried out as the above-described work according to the first embodiment.

The use of the proposed airlifts is most appropriate for cases when it is necessary to pump it between the chambers of the wastewater in the UBO during wastewater treatment. In these cases, along with pumping, the wastewater is saturated with oxygen, which reduces energy consumption for its aeration. In addition, due to more efficient use of air, the effectiveness of airlifts is increased, which reduces operating costs. The implementation of the proposed airlift from a polymeric material, which can be used, for example, polyethylene, or propylene, or vinyl plastic, or other similar materials, simplifies their manufacture with long-term trouble-free operation.

Claims (36)

1. An airlift comprising a body in the form of a water-lifting nozzle with a curved outlet section equipped with a nozzle located in the region of its inlet slice and equipped with a fitting for connecting to the compressed air supply pipe, characterized in that the water-lifting nozzle is made of pipes of different diameters, the ends of which are connected with each other with the formation of at least two, coaxial, input and output sections, while a disperser is installed at the entrance to the output section, and the free end of the pipe of the input section is fixed in the passage channel ┤ -shaped tee, provided with lateral tide a fitting for connection to a compressed air supply conduit provided with a nozzle channel communicating with the passageway of the tee, and the bent outlet portion formed with a diameter less than the diameter of the outlet section. 2. Airlift according to claim 1, characterized in that the dispersant is made in the form of a metal mesh fixed to the outlet pipe section of the inlet section. 3. Airlift according to claim 1, characterized in that the dispersant is made in the form of longitudinal slots in the blind end part of the pipe of the inlet section and a turbulator in the form of an annular protrusion installed in the output section above the blind end of the pipe of the inlet section. 4. Airlift according to claim 1, characterized in that a section of the pipeline is fixed on the fitting for introducing compressed air, which is fixed along the height of the airlift, while the free end of this pipeline is equipped with an adapter. 5. Airlift according to claim 1, characterized in that the diameter of the curved outlet section is 0.3-0.6 dimeters of the main part of the outlet section. 6. Airlift according to claim 1, characterized in that the inner diameter of the inlet section is 0.4-0.6 of the inner diameter of the outlet section. 7. Airlift according to claim 1, characterized in that a plate stop is fixed on its lower end part, with a protrusion behind the lower edge of the end face for a length of at least 1 cm 8. Airlift according to claim 1, characterized in that the length of the inlet section is not less than 0.3 of the length of the outlet section. 9. Airlift according to claim 1, characterized in that the inlet and outlet sections form a telescopic connection. 10. Airlift according to claim 1, characterized in that the pipe sections and tee are made of polymer material. 11. Airlift according to claim 10, characterized in that the polyethylene material used is polyethylene, or propylene, or vinyl plastic, or other similar materials. 12. An airlift comprising a body in the form of a water-lifting nozzle with a curved outlet section, equipped with a nozzle located in the region of its inlet slice and equipped with a fitting for connecting to the compressed air supply pipe, characterized in that the water-lifting nozzle is made of pipes of different diameters, the ends of which are connected with each other with the formation of at least two, coaxial, input and output sections, while dispersants are installed at the entrance to the output section and along its height, the free end of the pipe of the input section is fixed in the passage channel of the ⊥-shaped tee, equipped with lateral tides with communicated passage channels, one of which is made in the form of a fitting for connecting to the compressed air supply pipe, and the other is made in the form of a shut-off valve seat, which is equipped with a thrust and a float and is movably fixed to the input and output sections, while the curved output section is made with a diameter smaller than the diameter of the output section. 13. Airlift according to claim 12, characterized in that the dispersant is made in the form of a metal mesh fixed to the outlet pipe section of the inlet section. 14. Airlift according to claim 12, characterized in that the dispersant is made in the form of longitudinal slots in the blind end part of the pipe of the inlet section and a turbulator in the form of an annular protrusion installed in the output section above the blind end of the pipe of the inlet section. 15. Airlift according to claim 12, characterized in that a section of the pipeline is fixed on the fitting for introducing compressed air, which is fixed along the height of the airlift, while the free end of this pipeline is equipped with an adapter. 16. Airlift according to claim 12, characterized in that the diameter of the curved outlet section is 0.3-0.6 dimeters of the main part of the outlet section. 17. Airlift according to item 12, wherein the inner diameter of the inlet section is 0.4-0.6 of the inner diameter of the outlet section. 18. Airlift according to claim 12, characterized in that a plate stop is fixed on its lower end part, with a protrusion behind the lower edge of the end face, at least 1 cm long. 19. Airlift according to item 12, wherein the length of the inlet section is not less than 0.3 of the length of the outlet section. 20. Airlift according to item 12, characterized in that the thrust of the valve is adjustable. 21. An airlift according to claim 12, characterized in that the section pipes and tee are made of polymer material. 22. Airlift according to item 21, characterized in that the polyethylene material used is polyethylene, or propylene, or vinyl plastic, or other similar materials. 23. An airlift comprising a body in the form of a water-lifting nozzle with a curved outlet section, equipped with a nozzle located in the region of its inlet slice and equipped with a fitting for connecting to the compressed air supply pipe, characterized in that the water-lifting nozzle is made of pipes of different diameters, the ends of which are connected with each other with the formation of at least two, coaxial, input and output sections, while dispersants are installed at the entrance to the output section and along its height, the free end of the pipe of the input section is fixed in the passage channel of the flowing vortex chamber provided with a tangential fitting for introducing compressed air, while the curved outlet section is made with a diameter smaller than the diameter of the outlet section. 24. Airlift according to claim 23, characterized in that the vortex chamber is provided with a coaxially arranged cylindrical shell mounted to form an annular vortex channel closed at the bottom, above which the vortex screen is located. 25. Airlift according to item 23, wherein the dispersant is made in the form of a metal mesh fixed to the outlet pipe section of the inlet section. 26. Airlift according to item 23, wherein the dispersant is made in the form of longitudinal slots in the blind end part of the pipe of the inlet section and a turbulator in the form of an annular protrusion installed in the output section above the blind end of the pipe of the inlet section. 27. Airlift according to claim 23, characterized in that a section of the pipeline is fixed on the fitting for introducing compressed air, which is fixed along the height of the airlift, while the free end of this pipeline is equipped with an adapter. 28. Airlift according to item 23, wherein the diameter of the curved outlet section is 0.3-0.6 diameter of the main part of the outlet section. 29. Airlift according to item 23, wherein the inner diameter of the inlet section is 0.4-0.6 of the inner diameter of the outlet section. 30. An airlift according to claim 23, characterized in that a plate stop is fixed on its lower end part, with a protrusion for the lower edge of the end face, at least 1 cm long. 31. Airlift according to item 23, wherein the length of the input section is not less than 0.3 of the length of the output section. 32. Airlift according to item 23, wherein the height of the input and output sections are dispersants. 33. Airlift according to item 23, wherein the inlet and outlet sections form a telescopic connection. 34. Airlift according to item 23, wherein the section pipes and tee are made of polymer material. 35. Airlift according to item 23, wherein the polymer material used is polyethylene, or propylene, or vinyl plastic, or other similar materials. 36. The method of operation of the airlift, including the supply of air to the input region of the lifting pipe, characterized in that the lifting pipe is made in the form

-shaped siphon with shut-off valve and dispersers located in the input branch

-shaped siphon, while air supply to the airlift is carried out until the input branch with the knee is filled

-shaped siphon with a gas-liquid mixture, and the airlift is turned off by landing the shut-off valve on the saddle equipped on the inlet section

-shaped siphon, with the output slice

-shaped siphon is located below the level of the valve float in the closed position.

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