HU186738B - Method and apparatus for inducting gas into fluid particularly air into sewage - Google Patents

Abstract

An aeration process consists in introducing liquid under pressure into a rotatable hollow body provided with discharge openings and which is rotating in a space containing gas, jets of liquid discharging through the openings impinging on the wall of a container in which the hollow body is located, the liquid being reduced to drops in the space containing gas. The apparatus is characterized in that it has a rotatable hollow body 8 provided with rows of openings 17 from which extend atomizing nozzles 9. Liquid supplied via pipe 10 to the body 8 is subsequently discharged from the nozzles radially outward to the container wall 3. The resulting aerated mixture is discharged via pipe 6 from the bottom of the container. <IMAGE>

Description

The present invention relates to a method and apparatus for introducing gas into a liquid, in particular air into waste water containing organic impurities.

There are many different methods for biological treatment of wastewater containing organic contaminants.

The most widely used are rotary brush (Kessener) equipment, vertical axis mechanical surface aeration equipment, and air blower aeration equipment. With these devices, oxygen is introduced into the mechanically pretreated wastewater by increasing the free surface in contact with the air (partially flowing) stored in the pool. With the supplied oxygen, the biological oxygen demand of the wastewater is eliminated.

A large amount of energy is required to move known rotary devices to increase the free water surface, i.e. to supply the required amount of oxygen per unit of water. The same applies to air blown aeration systems. The high energy demand is, of course, a disadvantage, as it is to the detriment of the cost-effectiveness of the water purification operation, and the further disadvantage is that these solutions achieve up to 90-95% reduction in biological oxygen demand.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a solution for introducing gas into liquids, particularly air into wastewater, which has a significantly lower energy requirement and a higher gas input efficiency than currently known methods or devices.

The invention is based on the discovery that if air is not injected into the wastewater mass, but the wastewater is circulated in an air containing space, the gas in the liquid can be provided with better efficiency and with significantly less energy input.

Based on this discovery, the object of the present invention has been solved by a method of contacting liquid and gas, preferably waste water and air, and mechanically raising the surface of the liquid. The essence of the process is to introduce the liquid under pressure into a hollow body rotating in the gas containing space with openings in its masonry, and also to collide the liquid in the gas containing space by colliding the jets of liquid passing through the openings with rotating solid bodies. It is noted that "spraying" in the context of the present invention is understood to mean the breaking (splitting) of water jets into smaller or larger particles (droplets), but is not limited by the size of the droplets.

The device according to the invention is characterized in that it has a rotatable hollow body with openings in its masonry, into which a fluid supply pipe is inserted; in line with the openings in the wall of the hollow body, atomising organs spaced from said openings in the direction of rotation of the hollow body, behind the openings; and the rotatable hollow body is disposed in a space containing the gas to be introduced into the fluid, wherein there are devices for collecting and discharging the atomized liquid (droplets).

The shape and position of the hollow body in the space may, in principle, be arbitrary, but it is desirable to have a cylindrical, drum-like configuration. Therefore, according to a further feature of the invention, the rotatable body is designed as a nozzle (orifice) having a geometric axis of rotation that is either vertical or substantially vertical, and preferably has a height greater than the diameter of the nozzle.

In the hollow rotary masonry, the openings may in principle be formed in any position and arrangement, but it is desirable that the openings in the wall of the hollow body, in particular the drum-like cylindrical nozzle, extend in spaced rows. Advantageously, the holes in the bowl of the hollow body are sewn conically from the outside to the inside. Particularly when using a cylindrical nozzle, it is advantageous to have a spray nozzle extending laterally between two through holes in each row of holes for attachment to the nozzle.

The most effective atomisation, i.e. the liquid jet splitting, can be achieved by the formation of jets of fibers, preferably of elastic material, such as plastic fibers. These ready-made fiber fibers ("mustaches") are dispersed in a fan-like shape as a result of their rotation with the hollow body, thereby significantly increasing the solidity of the solid surface which causes the water jets to break and drop, which naturally increases. For example, each beam may comprise 30-60 pieces of synthetic fibers of about 1 mm diameter, 10-40 cm, preferably about 20 cm long, preferably in holes formed in the walls of a rotating body such as a spray cylinder by means of rubber rings! recorded. These holes may have the same, i.e. conical, shape as the through-holes that emit the liquid. All useful cross-sections of the latter are equal to or substantially equal to the useful flow cross-section of the rotating hollow body.

According to a further feature of the invention, the nozzle is connected to a pivot shaft of a propulsion motor in the region of its first end and connected to a mouthpiece sealed on its outer surface with a bearing sealed on its outer surface. recorded.

Especially for solving wastewater treatment tasks, it is obvious that the space containing the gas to be injected, such as a basin made of reinforced concrete with a bottom plate and a side wall, is exposed to the air! is made up of a connected inner space. From a functional point of view, it is most desirable to have a circular plan view from the top of the pool, inclined inwardly to its vertical geometric center axis, and bypassing the rotating hollow body to collect fluid in an annular passageway the pipe for draining the liquid flows out. For the treatment of wastewater, the embodiment is also obvious, in which the pool is at least partially open. Thus, the effluent and the sprayed (sprayed) waste water are in constant contact with fresh air. Preferably, the pool is of reinforced concrete and has a drive bridge for suspending the drive motor, which is anchored to and / or rests on the pool side wall.

Advantageous effects of the invention may be summarized as follows:

No wastewater pre-storage is required, mechanically pre-treated wastewater can be continuously fed into the unit, where every drop of wastewater is

Get 186,738 oxygen, what! by spraying the air, the surface of the wastewater is maximized. The fact that, contrary to prior art, air is not introduced into stored water but radically reduces the amount of energy required for oxygen adjustment and increases the efficiency of oxygen delivery. However, the installation cost of the equipment is relatively low and their construction can be simple and industrialized, both from the point of view of construction and operation of the atomizer. The process can be applied to any volume of water and can be used as a new stand-alone treatment plant or can be connected to an existing plant.

The invention will now be described in more detail with reference to the accompanying drawings, which show a preferred embodiment of a sewage aeration device according to the invention. In the drawings, Figure 1 is a top plan view of the apparatus, Figure 2 is a sectional view taken along line A-A in Figure 1, Figure 3 is a sectional view taken along line Β-B in Figure 1, Figure 5 is a sectional view taken along line CC of Figure 4, partly in vertical axis and partly in side view.

As shown in FIGS. In Figures 1 to 4, the apparatus for biological treatment of wastewater containing organic contaminants in its entirety has a reinforced concrete basin with an open top plan, denoted by reference numeral 1, the bottom plate of which slopes inwards from the wall 3 towards the central O axis (arrows C). Conical design. In the lower part of the central region of the basin 1 there is a concrete bracket 4, which is surrounded by an annular channel 5. A pipe 6 protrudes from the channel 5, which is led through the bottom plate 2 and slopes outwardly from the basin 1. The bottom plate of the channel 5 is inclined towards the outlet opening of the tube 6; the slope direction is indicated by b arrows (Figures 1 and 2).

In the interior of the basin 1 there is a centrally located atomizer, which is referred to as 7, whose vertical geometric axis of rotation X coincides with the central central axis O of the whole apparatus. A. The nebulizer 7 has a rotatable upright nozzle 8, the wall of which has through holes (not shown in Figures 2 and 3) and through which the holes 9 are externally aligned. At the bottom of the nozzle 8 there is a tube 10 which runs through the bottom plate 2 of the basin 1. On the side wall 3 of the basin 1 there is a support bridge 11 with two ends, made of U-section steel beams. On the support bridge 11 the nebulizer 7 is suspended. The

Underfloor concrete under baseplate 2 of basin I is denoted by 12 and gravel bed is designated by reference numeral 13. Levels of t-level organized terrain lead to 14 steps of concrete

II has a bridging bridge and has a sloping soil filling 15 around the wall 3.

Figures 4 and 5 illustrate the atomizer 7 in greater detail in greater detail. As can be seen, the wall 16 of the nozzle 8 has, in rows above one another, through holes 17, which are conical in shape, that is, slightly expanded from the outside to the inside.

The total flow cross-section of the holes 17 is equal to the useful flow cross-section of the nozzle or drum 8. Each row of holes 17 is in common horizontal plane In each row, at least two holes 9 are provided with nozzles. The nozzles 9 are formed by bundles of plastic fibers 18. Rubber rings 19 are provided to secure the beams in the holes 17, which are located inside the wall 16 of the nozzle 8. The inner diameter D of the nozzle 8 is e.g. It is 140 mm long, 75 cm long, 17 mm in diameter 17 mm and has a diameter of 20 mm and can consist of forty-five plastic fibers of 1 mm diameter. The inner diameter D _{z of the} inlet tube 10, which is inserted from below into the atomiser tube 8, is 80 mm. The distance / distance between the rows of holes 17 is e.g. 110 mm. In the present embodiment, there are sixteen holes 17 per row, so that each row consists of eight to eight beams 9. The holes 17 are radially distributed, and the y-axes connecting the center of the holes to the X axis have an angle of 22.5 ° (Figure 5).

The explosion-proof electric motor 20 mounted on the support bridge 11 is used to rotate the nozzle 8, which is connected to the nozzle 8 by welded connections by means of the nozzle 21 and the discs 22-24. The electric motor of the 20 motors requires, in addition to the dimensions given above, 8-10 kW.

The drainage pipe 10 is connected to the nozzle 8 with an outer double bearing 25 with a sealing seal, i.e. the nozzle 8 is rotatably mounted around the pipe 10.

Pool 1 has a useful volume of about 20 m ^{3 in} the present embodiment and requires a wastewater pump (not shown) of about 1000 l / min.

The apparatus described in detail above operates as follows;

The wastewater pump (not shown) is mechanically cleaned of the wastewater pumped through the pipe 10 into the nozzle 8 (arrow m, Figures 1-3), and simultaneously or even before, the electric motor 20 is started to rotate about its own longitudinal axis X 8 nozzles. The speed of the nozzle or drum is adjusted in sync with the pump power.

Under pressure, the water introduced into the rotating nozzle 8 through the open holes 17 in the direction of arrows A (Figures 4 and 5 exits in the form of rays from the nozzle 8. These jets of water are sprayed by the sprinklers 9 immediately after exiting). the plastic strands 18 of the beams forming the atomising organs 9 are opened from the rotation by centrifugal force, take a fan-like shape and spray the water jet on droplets. The resistance of each jet of water is very low, the oxygen uptake (oxygen delivery to water) is maximal, The water sprayed into droplets, after taking up oxygen from the air, collides with the inner surface of the 3 walls of basin I (arrows k in Figures 2 and 3) and partly falls on the 2 'plate. , accumulate in 5 channels, and from pool 1 a It is discharged through 6 pipes (Figures 1 and 2, open) The discharged oxygen-rich effluent can be further treated or may be discharged directly to the recipient.

With the above-described equipment, at the indicated sizes, about 600-800 m ³ / day

The 186,738 required oxygen supply was provided with low energy consumption.

The invention is, of course, not limited to the solution described in detail above, but may be practiced in many ways within the scope of the claims. For example, a metal pool can be used instead of reinforced concrete. Vented water drainage eg. it can also happen through a funnel. The atomising organs are made not only of plastic fibers but also of e.g. they may also be made of metal fibers. Not only fiber beams but also other solid bodies can be used as nebulizers. The pool is replaced with reinforced concrete eg. it can be made of metal or plastic. Although the invention is primarily applicable to the biological treatment of wastewater containing organic contaminants, it is not excluded that it may be used for introducing other types of gas into a liquid.

Claims (16)

Patent claims A method for introducing a gas into a liquid, in particular air into sewage, by mechanically increasing the surface of the liquid by introducing the liquid under pressure into a hollow body rotating in the wall containing the gas, with openings in the masonry and in the liquid jets passing through the openings. The liquid is decomposed (sprayed) into the gas-containing space by colliding with solid bodies. Apparatus for introducing gas into a liquid, in particular air, into waste water, characterized in that it has a nozzle (7) having a rotatable hollow body with openings in its masonry, into which a pipe for supplying liquid flows; atomising organs aligned with the openings in the wall of the hollow body at a distance from the openings behind the openings in the direction of rotation of the hollow body; and the rotatable hollow body is located in a space containing the gas to be introduced into the liquid, wherein the device (s) for collecting and discharging the atomized liquid (droplets) are located. Embodiment according to Claim 2, characterized in that the rotatable body is formed by a nozzle tube (8) (as a sputtering drum), the geometric axis of rotation (X) of which is vertical or substantially vertical. An embodiment of the device according to claim 3, characterized in that the height of the nozzle (8) exceeds its diameter (D,). 5. Device according to any one of claims 1 to 3, characterized in that the walls (16) of the hollow body - in particular the drum-like cylindrical nozzle (8) - are arranged in rows spaced apart (f). 6. In steps 2-5. Device according to any one of claims 1 to 3, characterized in that the holes in the wall of the hollow body are tapered, expanding from the outside to the inside. 7. An embodiment of the device according to any one of claims 1 to 3, characterized in that in each row of holes / 17) a laterally extending spraying member (9) is attached to the nozzle (8) between two through holes (17). 8. In steps 2-7. An embodiment of the device according to any one of claims 1 to 3, characterized in that the spraying means (9) consist of a bundle of fibers, preferably of plastic material (18). 9. An embodiment of the apparatus of claim 8, wherein each beam comprises 30 to 60 pieces of plastic fibers of about 1 mm diameter, 10 to 40 cm, preferably about 20 cm in length. Embodiment according to claim 8 or 9, characterized in that the beams are fixed by means of rubber rings (19) in the holes (17) formed in the masonry (16) of the rotating body, such as the spray cylinder (8). 1 ί. 2-10. An embodiment of the apparatus according to any one of claims 1 to 6, characterized in that all the effective cross-sections of the fluid outlet openings formed in the wall of the rotating hollow body are equal to or substantially equal to the useful flow cross-section of the rotating hollow body. 12. An apparatus according to any one of claims 1 to 4, characterized in that a drive motor is connected to a pivot shaft in the upper end region of the nozzle (8) and a bearing (25) sealed on its outer surface at the lower end region of the fluid delivery tube (10). An embodiment of the device according to any one of claims 2 to 12, characterized in that said drive motor comprises an explosion-proof electric motor (20) fixed on a support structure above the nozzle (8). An embodiment of the apparatus according to any one of claims 2 to 13, characterized in that the space containing the gas to be introduced into the liquid is formed by an interior space of a pool (!) Made of reinforced concrete with a bottom plate and a sidewall. 15. An apparatus according to claim 14, characterized in that the pelvis is in a circular plan view, is formed in a circular plan, with a slope (C) inwards towards the bottom geometric axis (O) of the bottom plate (2) and for collecting liquid from the rotating hollow body. The structure is formed by an annular channel (5) at the bottom of the deepest part of the basin (J), from which a fluid outlet pipe (6) protrudes. An embodiment of the device according to claim 14 or 15, characterized in that the pool (1) is at least partially open at the top. 17. Device according to Claim 1, characterized in that the basin (1) is made of reinforced concrete and has a bracket (II) for suspending the drive motor, which is fixed to or supported on the sidewall (3).