EA039537B1 - Sparger apparatus and method for extracting particles - Google Patents

Abstract

Described is a sparger apparatus (1) for feeding a first fluid into a second flowing fluid. The sparger apparatus comprises a hollow tube member (2) defining a straight duct flow space (3) having an upstream inlet end (4) and a downstream outlet end (5), and nozzles (6) in the straight duct flow space (3). The nozzles (6) are configured to feed first fluid into second flowing fluid configured to flow in a direction of flow X in the straight duct flow space from the upstream inlet end (4) to the downstream outlet end (5). The openings (10) of the nozzles (6) are distributed at several positions along the direction of flow X so that the openings (10) forms upstream openings and downstream openings and so that each upstream opening is unfollowed by a downstream opening in the direction of flow X.

Description

Claim 1 of the claims.

A bubbler is used to supply a first fluid, such as a gas, to a second sheath, such as sheath fluids. It is known in the art to use prototype devices and spargers incorporating porous material such as ceramics, sintered systems, or laser cut devices.

A known problem with spargers is controlling the bubble size of the first fluid that is introduced into the second, flowing fluid, as well as controlling the distribution of the bubbles of the first fluid in the second, flowing fluid. Lack of control results in very small bubbles of the first fluid merging with each other to form larger bubbles of the first fluid, or to larger bubbles of the first fluid separating to form smaller bubbles of the first fluid, which can again merge.

Purpose of the invention

It is an object of this invention to provide a sparging device that provides a controlled supply of a first fluid, such as a gas, to a second, flowing liquid, such as flowing fluids.

Brief description of the invention

The sparging device differs in that it is defined in independent claim 1 of the claims.

Preferred embodiments of the bubbling device are defined in dependent claims 2 to 31 of the claims.

The present invention also relates to a method for recovering particles from a second fluid as defined in claim 32 of the claims.

Preferred embodiments of this method are defined in dependent claims 33-36 of the claims.

List of drawings

Hereinafter, the present invention is described in more detail below with reference to the drawings, in which FIG. 1 shows a first embodiment of a sparging device, FIG. 2 shows the one shown in FIG. 1 sparging device in partial section, FIG. 3 shows the one shown in FIG. 1 sparging device in partial section, FIG. 4 shows the one shown in FIG. 1, a bubbling device in a section along the plane B-B of FIG. 1, fig. 5 shows the one shown in FIG. 1 sparging device in one side view, FIG. 6 shows the one shown in FIG. 1 sparging device as seen from the other side, FIG. 7 shows the one shown in FIG. 1 sparging device in a section along the plane A-A of FIG. 5, fig. 8 shows the one shown in FIG. 1 sparging device as viewed from the downstream side, FIG. 9 shows the one shown in FIG. 1 the sparging device, seen from another side, FIG. 10 shows the one shown in FIG. 1 sparging device in a section along the C-C plane of FIG. 9, fig. 11 shows the one shown in FIG. 1 sparging device in a section along the plane D-D of FIG. 9, fig. 12 shows detail E in FIG. 11, fig. 13 shows a diagram in which the nozzle openings can be arranged, FIG. 14 is a sectional view of a second embodiment of the sparging device, FIG. 15 is a sectional view of a third embodiment of the sparging device, FIG. 16 is a one side view of a fourth embodiment of the sparging device, FIG. 17 shows the one shown in FIG. 16 the bubbling device in a section along the plane R-R of FIG. 16, fig. 18 shows the one shown in FIG. 16, sectional view of the bubbling device along line S-S of FIG. 16, fig. 19 is a view of the one shown in FIG. 16 of the bubbling device from the downstream end, FIG. 20 shows the one shown in FIG. 16 the bubbling device in a section along the T-T plane of FIG. 19, fig. 21 shows detail X in FIG. 18 and FIG. 22 is a view of the one shown in FIG. 16 of the bubbling device from the upstream end.

- 1 039537

Detailed description of the invention

The drawings show examples of a bubbling device 1 for supplying a first fluid medium (not shown in the drawings) to a second, flowing fluid medium (not shown in the drawings).

The first fluid may be a gas, such as air, oxygen, nitrogen, ozone, or carbon dioxide.

The second flowing fluid may be flowing liquids, for example, waste water, industrial process fluid, drinking water, raw water, mine water, industrial water, water containing substances that require biological oxygen consumption, water containing substances that require chemical oxygen demand, or water, which contains substances often referred to as total organic carbon.

The bubbling device comprises a hollow tubular element 2 defining a straight flow channel 3 having an upstream inlet end 4 and an outlet end 5 located downstream.

The bubbling device has nozzles 6 in the direct flow channel 3.

The nozzles 6 are designed to supply the first fluid to the second, flowing fluid, which flows in the straight flow channel 3 in the direction X of the flow, from the upstream inlet end 4 to the downstream outlet end 5.

The nozzles 6 are located in the bubbler 7 placed in the straight flow channel 3.

The bubbler 7 includes paddle elements 8; nine.

The nozzles 6 are provided on the vane elements 8; nine.

Blade elements 8; 9 can be configured to temporarily break up the flow of the second flow fluid in the straight flow channel 3, for example into a laminar flow or into a flow in a transient flow regime.

The holes 10 of the nozzles 6 are spaced apart in the X flow direction so that the holes 10 form upstream holes and downstream holes, with each upstream hole not followed by a downstream hole in the X flow direction.

The advantage of this sparging device is that the paddle elements 8; 9 protect the bubbles of the first fluid coming from the holes 10 of the nozzle 6 into the second, flowing fluid.

Due to the arrangement of the openings 10 of the nozzles 6, bubbles of the first fluid entering the second flow fluid from the upstream openings 10 in the nozzles 6 do not merge with the bubbles of the downstream openings in the nozzles.

The straight flow channel 3 need not be as long as the bubbler 7 as shown in the drawings. It is sufficient that a straight flow channel is provided at the nozzles and in a small area downstream of the nozzles.

Preferably, but not necessarily, the relative number of openings 10 increases in the flow direction X, towards the middle of the straight flow channel 3, for example towards the longitudinal central axis Y of the straight flow channel 3. due to friction between the second flow fluid and the walls of the straight flow channel than the walls of the straight flow channel. Thus, in order to achieve a uniform distribution of the first fluid in the second, flowing fluid, a greater amount of the first fluid should preferably be fed into the middle of the straight flow channel than at the walls of the straight flow channel.

The straight flow channel 3 preferably, but not necessarily, has a longitudinal central axis Y; and the straight flow channel 3 is preferably but not necessarily symmetrical about the longitudinal central axis Y of the straight flow channel 3.

If the straight flow channel 3 has a longitudinal central axis Y, and if the straight flow channel 3 is symmetrical about the longitudinal central axis Y of the straight flow channel 3, the orifices 10 of the nozzles 6 are preferably, but not necessarily, symmetrical about the longitudinal central axis Y of the straight flow channel 3. This has the advantage of a more uniform concentration of the first fluid in the second flow fluid.

If the straight flow channel 3 has a longitudinal central axis Y and if the straight flow channel 3 is symmetrical with respect to the longitudinal central axis Y of the straight flow channel 3, the blade elements 8; 9 is preferably, but not necessarily, symmetrical about the longitudinal central axis Y of the straight flow channel 3. The advantage is less turbulence in the second flow fluid, since the vane elements result in a smaller flow difference in the second flow fluid.

If the straight flow channel 3 has a longitudinal center axis Y, and if the straight flow channel 3 is symmetrical about the longitudinal center axis Y of the straight flow channel 3, the orifices 10 of the nozzles 6 are preferably, but not necessarily, positioned as shown in FIG. 13, according to scheme 14, which is defined by several rings 15 centered on the longitudinal central axis A

- 2 039537 direct flow channel 3; each ring 15 is located along the longitudinal central axis Y of the straight flow channel 3 in a position that differs from the position of the other rings 15; and each ring 15 has a diameter that is different from that of the other rings 15. This provides an easy and straightforward way of forming the upstream and downstream holes so that in the X flow direction, each upstream hole 10 is not followed by a downstream hole 10 .

Preferably, but not necessarily, the sparging device includes a fluid distribution ring 11 surrounding a straight flow channel 3, and the vane elements of the bubbler 7 preferably, but not necessarily, include first vane elements 8 and second vane elements 9 such that the first vane elements 8 are in in fluid communication with the fluid distribution ring 11, and the second vane elements 9 are in fluid communication with the first vane elements 8, and the nozzles 6 are provided on the second vane elements 9.

If, as shown, the sparging device includes a fluid distribution ring 11, then the sparging device preferably includes, but not necessarily, a fluid inlet 12 in fluid communication with the fluid distribution ring 11.

If, as shown, the sparger 7 of the sparging device comprises first vane elements 8, then each first vane element 8 preferably, but not necessarily, extends from the fluid distribution ring 11 to the middle of the straight flow channel 3 at an angle relative to the direction X of the flow in the direction located below downstream of the outlet end 5 of the hollow tubular element 2. The first vane elements 8 are preferably, but not necessarily, in fluid communication with each other in the middle of the straight flow channel 3, for example on the longitudinal central axis Y of the straight flow channel 3. The advantage of this is equalization of possible pressure differences between the first vane elements 8. Each first vane element 8 preferably, but not necessarily, extends at an angle of 15 to 75, preferably 30 to 60°, for example about 45°, with respect to the direction X of the flow, or with respect to to the longitudinal central axis Y straight flow channel 3.

If the sparger 7 of the sparging device includes first vane elements 8 and second vane elements 9 as shown, then the second vane elements 9 preferably, but not necessarily, extend between adjacent first vane elements 8. The second vane elements 9 preferably, but not necessarily, extend between adjacent first vane elements 8 in an oblique and/or curved configuration in the direction of the downstream outlet end 5 of a straight flow channel 3, between adjacent first vane elements 8. It is possible, for example, for the second vane elements 9 to have an arch-shaped or in the form of a lancet Gothic arch. In the direction perpendicular to the flow direction X, the second blade elements 9 can form at least two, preferably three or four annular concentric structures in the straight flow channel 3, so that intermediate zones 13 are formed between the first blade elements 8 and the second blade elements 9 of the bubbler 7 duct in the form of an arch or intermediate zones of the duct, shaped as part of a sector.

If the sparger 7 of the sparging device includes first vane elements 8 and second vane elements 9 as shown, then the cross-section of the first vane elements 8 is preferably, but not necessarily elliptical, teardrop or almond shaped. This has the advantage of less turbulence caused by the first vane elements in the flow of the second flow fluid.

If the sparger 7 of the sparging device includes first vane elements 8 and second vane elements 9 as shown, then the cross section of the second vane elements 9 is preferably, but not necessarily, elliptical, teardrop, almond, parallelogram, deltoid, isosceles trapezoid, and the like. which are incorrect. This has the advantage of less turbulence that the second vane element causes in the flow of the second flow fluid.

The openings 10 of the nozzles 6 are preferably, but not necessarily, in the form of a convex polygon, such as a rectangle, rhombus or square. The advantage of this shape is that the sharp edges of the holes 10 reduce the bubbles of the first fluid and facilitate the separation of the bubble of the first fluid from the hole 10.

The openings 10 of the nozzles 6 preferably, but not necessarily, have an area of 3 to 750 µm ² in order to create small sized bubbles of the first fluid.

The nozzles 6 preferably, but not necessarily, extend from the vane elements 8; 9, at least partially, in a direction perpendicular to the flow direction X. This has the advantage that the nozzles create local turbulence and/or a vacuum in the second, flowing fluid at the nozzle, which facilitates suction of the first fluid from the opening 10 in the nozzle 6 into the second flowing fluid flowing in the X direction of flow in the straight flow channel 3. Nozzles 6 extend preferably, but not necessarily, from the second vane elements 9, provided that the vane elements include such second vane elements 9 at least partially in a direction perpendicular to the flow direction X. The height of the nozzles 6 may be, for example, from 100 to 500 µm.

Alternatively, as in the case of the fourth embodiment depicted in FIG. 16-22, the holes 10 of the nozzles 6 may be on the surface of the blade elements 8; nine.

In some embodiments of the sparging device 1, such as the fourth embodiment shown in FIG. 16-22, each second bladed element 9 has an elongated upstream edge 18 and an elongated downstream edge 19, on one side of the second bladed element 9 a first surface 20 between the elongated upstream edge 18 and the elongated downstream edge 19, and on the other side of the second bladed element 9, the second surface 21 between the elongated upstream edge 18 and the elongated downstream edge 19. In such embodiments, the cross section of the second bladed elements 9 is shaped and sized such that the distance between the elongated upstream edge 18 and elongated downstream edge 19, when measured along the first surface 20, is longer than the distance between the elongated upstream edge 18 and the elongated downstream edge 19, when measured along the second surface 21. In such embodiments, the openings 10 of the nozzles 6 are provided on the first surface 20 second paddle elements 9. The advantage of this is that, once Since the second fluid flows faster on the first surface 20 than on the second surface 21, since the first surface 20 is longer than the second surface 21, a suction effect occurs on the first surface 20, facilitating the suction of the first fluid from the holes 10 of the nozzles 6 on the first surfaces of 20 second bladed elements 9.

The cross section of the second blade elements 9 may be shaped and sized such that the cross section of the first surface 20 is curved. In this case, the cross section of the second bladed elements 9 has such a shape and dimensions that the cross section of the second surface 21 has the shape of a straight line. The first surface 20 preferably, but not necessarily, has a rib 22 so that a first surface portion 23 is formed between the elongated upstream edge 18 of the second blade element 9 and the rib 22 of the first surface 20 of the second blade element 9, and so that a second surface portion 24 is formed between the elongated downstream edge 19 of the second bladed element 9 and the rib 22 of the first surface 20 of the second bladed element 9, while in the first section 23 of the surface of the hole 10 of the nozzles 6 are preferably absent, so that the holes 10 of the nozzles 6 are formed on the second section 24 of the surface.

In FIG. 1-12 shows a sparging device with a hollow tubular element 2 having a straight flow channel 3 with the same cross-sectional shape and dimensions between the upstream inlet end 4 and the downstream outlet end 5 of the straight flow channel 3. However, it is possible as shown in FIG. 14, the hollow tubular 2 includes a constricted portion 16 between the upstream inlet end 4 and the downstream outlet end 5 of the straight flow passage 3, and the bubbler 7 was located on the constricted portion 16. In such a case, the diameter of the constricted portion 16 preferably, but not necessarily 99 to 80% of the diameter of the straight flow channel 3 between the upstream inlet end 4 of the straight flow channel 3 and the constricted portion 16 and between the downstream outlet end 5 of the straight flow channel 3 and the constricted section 16.

Fig. 1-12 depict a sparging device with a hollow tubular element 2 having a straight flow channel 3 with the same cross-sectional shape and dimensions between the upstream inlet end 4 and the downstream outlet end 5 of the straight flow channel 3. However, it is possible, as shown in FIG. 15, the hollow tubular 2 includes a flared portion 17 between the upstream inlet end 4 and the downstream outlet end 5 of the straight flow channel 3, and the bubbler 7 is located on the flared portion 17. In such a case, the diameter of the flared portion 17 is preferably , but not necessarily, is from 101 to 120% of the diameter of the straight flow channel 3 between the upstream inlet end 4 of the straight flow channel 3 and the expanded section 17 and between the downstream outlet end 5 of the straight flow channel 3 and the expanded section 17.

In a sparging device, nozzle openings 10 6 are preferably, but not necessarily, provided in bubbler 7 such that there are no nozzle openings 10 6 in bubbler 7 as viewed from the upstream inlet end 4 of hollow tubular 2 in the direction parallel to the flow direction X, as illustrated in FIG. 22. It is advantageous that the nozzle openings 10 are located on the downstream side of the vane elements 8, 9 of the bubbler 7, because on the downstream side of the bubbler 7 where the openings 10 are located, the bubbler 7 creates a suction effect in the second fluid. This suction effect contributes to the suction of the first fluid from the holes 10 of the nozzles 6 into the second fluid.

In a sparging device, the sparger 7 preferably, but not necessarily, has an upstream surface (not indicated by a numerical footnote) that faces the upstream

- 4 039537 downstream of the inlet end 4 of the hollow tubular element 2, and has a downstream surface (not indicated by a numerical footnote), which faces the downstream outlet end 5 of the hollow tubular element 2, so that the holes 10 of the nozzles 6 are located on the downstream surface of the bubbler 7, as illustrated in FIG. 19 and the upstream surface of the bubbler 7 does not contain nozzle openings 10 6 as illustrated in FIG. 22.

In the sparging device, the openings 10 of the nozzles 6 are preferably, but not necessarily, spaced apart in the X direction of flow, such that the openings 10 form upstream openings and downstream openings, and each upstream opening is not followed by any part of the bubbler 7 in the X direction. flow, as illustrated in FIG. 8 and 19. This has the advantage that the first fluid that is supplied from the nozzle holes 10 to the second fluid does not collide with the bubbler 7 as the second fluid flows in the direction X of the flow; which means, for example, that the bubbler 7 does not destroy the first fluid droplets. This facilitates the creation of a laminar flow of the first fluid in the second fluid.

In a sparging device, sparger 7 is preferably, but not necessarily, in fluid communication with a gas source configured to supply a first fluid in the form of a gas to sparger 7.

In the bubbling device, the upstream inlet end 4 of the hollow tubular element 2 is preferably, but not necessarily, in fluid communication with a fluid source configured to supply a second, flowing fluid containing particles to be removed and which have a particle size in the range of 0.2 to 0.3 mm, for example 0.25 mm, into the straight flow channel 3 of the hollow tubular element 2. The particles may, for example, be macromolecules, complex ions, colloidal particles, or small particles having size less than 10 microns and density of solid particles from 0.8 to 1.25 kg/l; and if the particle size is small, for example 0.1 to 2 µm, the solid particle density may be 0.9 to 6 kg/L. The content of such particles can be, for example, 0.001 to 10 g/l, preferably 0.001 to 1 g/l. The gas, for example, can be supplied in such a way that a layer of gas from 3 to 8 μm is formed on the surface of the particle.

The flow direction X is preferred, but is not necessarily a linear flow direction.

The straight flow channel 3 of the hollow tubular element 2 is preferably, but not necessarily, vertical, so that the upstream inlet end 4 is either located above the downstream outlet end 5 in the vertical direction, or the upstream inlet end 4 placed under the downstream outlet end 5 in the vertical direction, whereby the flow direction X is the vertical flow direction. This has the advantage that providing such a vertical straight flow channel 3 effectively prevents the bubbles of the first fluid supplied upstream from the holes 10 in the nozzles 6 from merging into the second, flowing fluid, with the bubbles of the first fluid supplied downstream. from the holes in the nozzles into the second, flowing fluid.

The invention also relates to a method for extracting particles from a second fluid.

The method includes providing a sparging device 1 according to any of the embodiments described above, supplying a second fluid through a direct flow channel 2 of the sparging device 1, supplying a first fluid in the form of gas bubbles to the bubbler 7 of the sparging device 1, forcing the first fluid in the form of gas to exit from orifices 10 of the nozzles 6 in the bubbler 7 into the second fluid to cause the particles contained in the second fluid to adhere to the gas bubbles of the first fluid, and to extract from the second fluid the gas bubbles of the first fluid with the particles adhering thereto.

The person skilled in the art will appreciate that as technology develops, the basic idea of the present invention may be implemented in a variety of ways. Thus, the present invention and its embodiments are not limited to the above examples, and may vary within the scope of the claims.

CLAIM

Claims (36)

CLAIM 1. Bubbling device (1) for supplying the first fluid into the second flow fluid, including a hollow tubular element (2) defining a straight flow channel (3), having an inlet end (4) located upstream and located downstream outlet end (5), and nozzles (6) in the straight flow channel (3), wherein the nozzles (6) are designed to supply the first fluid to the second flow fluid flowing in the straight flow channel in the X direction of the flow, from the located upstream of the inlet end (4) to the downstream outlet end (5), characterized in that the nozzles (6) are provided in the bubbler (7) located in the straight flow channel (3), - 5 039537 the straight flow channel (3) has a longitudinal central axis Y, the straight flow channel (3) is symmetrical with respect to the longitudinal central axis Y of the straight flow channel (3), the bubbler (7) includes paddle elements (8; 9), nozzles (6 ) are provided on the vane elements (8; 9), the holes (10) of the nozzles (6) are distributed in the direction X of the flow separately, so that the holes (10) form upstream holes and downstream holes, while in the direction X of the flow behind each upstream hole does not follow a downstream hole, the holes (10) of the nozzles (6) are located symmetrically relative to the longitudinal central axis Y of the straight flow channel (3), the holes (10) of the nozzles (6) are located according to the scheme (14), which rings (15) are defined having a center on the longitudinal central axis Y of the straight flow channel (3), with each ring (15) occupying a position along the longitudinal central axis Y of the straight flow channel (3), which differs from the position of the other rings ( 15) and each ring (15) has a different diameter than the other rings (15) and the nozzles (6) extend from the vane elements (8; 9), at least partially, in a direction perpendicular to the direction X of the flow. 2. Bubbling device according to claim 1, characterized in that the relative number of holes (10) in the X direction of the flow increases towards the middle of the straight flow channel (3). 3. Bubbling device according to claim 1 or 2, characterized in that the straight flow channel (3) is surrounded by a distribution ring (11) for fluid, the vane elements of the bubbler (7) include first vane elements (8) and second vane elements (9 ), the first vane elements (8) are in flow connection with the fluid distribution ring (11), the second vane elements (9) are in flow connection with the first vane elements (8) and on the second vane elements (9) are provided nozzles (6). 4. A sparging device according to claim 3, characterized in that a fluid inlet (12) is provided in the downstream connection with the fluid distribution ring (11). 5. Bubbling device according to claim 3 or 4, characterized in that each first paddle element (8) extends from the fluid distribution ring (11) to the middle of the straight flow channel (3) at an angle to the direction X of the flow in the direction of the underlying along the flow of the outlet end (5) of the hollow tubular element (2). 6. Bubbling device according to claim 5, characterized in that the first vane elements (8) are in flow connection with each other in the middle of the straight flow channel (3). 7. Bubbling device according to claim 5 or 6, characterized in that each first vane element (8) extends at an angle of 15 to 75, preferably 30 to 60°, for example about 45°, with respect to the direction X of the flow. 8. Bubbling device according to any one of claims 3 to 7, characterized in that the second vane elements (9) extend between adjacent first vane elements (8). 9. Bubbling device according to claim 8, characterized in that the second vane elements (9) pass between adjacent first vane elements (8) in an inclined and/or curved configuration in the direction of the downstream outlet end (5) of the straight flow channel (3), between adjacent first bladed elements (8). 10. Bubbling device according to claim 9, characterized in that the second vane elements (9) have the shape of an arch or lancet Gothic arch in lateral projection. 11. Bubbling device according to any one of claims 8 to 10, characterized in that the second blade elements (9) form in a straight flow channel (3), in a direction perpendicular to the flow direction X, at least two, preferably three or four ring-shaped concentric structures. 12. Bubbling device according to any one of claims 3 to 11, characterized in that the cross section of the first vane elements (8) has the shape of an ellipse, a drop or an almond shape. 13. Bubbling device according to any one of claims 3 to 12, characterized in that the cross section of the second bladed elements (9) has the shape of an ellipse, a drop or an almond shape. 14. Bubbling device according to any one of claims 1 to 13, characterized in that the openings (10) of the nozzles (6) have the shape of a convex polygon, such as a rectangle, rhombus or square. 15. Bubbling device according to any one of claims 1 to 14, characterized in that the holes (10) of the nozzles (6) have an area of 3 to 750 µm ² . 16. Bubbling device according to any one of claims 1 to 15, characterized in that the height of the nozzles (6) is from 100 to 500 µm. 17. Bubbling device according to any one of claims 1-16, characterized in that every second blade - 6 039537 bladed element (9) has an elongated upstream edge (18) and an elongated downstream edge (19), while on one side of the second bladed element (9) there is a first surface (20) between the elongated upstream edge (18) and an elongated downstream edge (19), and on the other side of the second blade element (9) there is a second surface (21) between the elongated upstream edge (18) and the elongated downstream edge (19); the section of the second vane elements (9) has such a shape and dimensions that the distance between the elongated upstream edge (18) and the elongated downstream edge (19), measured along the first surface (20), is longer than the distance between the elongated upstream edge (20). edge (18) and elongated downstream edge (19) measured along the second surface (21), and holes (10) of the nozzles (6) are provided on the first surface (20) of the second vane elements (9). 18. Bubbling device according to claim 17, characterized in that the cross section of the second bladed elements (9) has such a shape and dimensions that the cross section of the first surface (20) has the shape of a curve. 19. Bubbling device according to claim 17 or 18, characterized in that the cross section of the second bladed elements (9) has such a shape and dimensions that the cross section of the second surface (21) has the shape of a straight line. 20. Bubbling device according to any one of claims 17-19, characterized in that the first surface (20) has a rib (22), so that between the elongated upstream edge (18) of the second vane element (9) and the rib (22) of the first surface (20) of the second bladed element (9) the first section (23) of the surface is formed and between the elongated downstream edge (19) of the second bladed element (9) and the rib (22) of the first surface (20) of the second bladed element (9) a second surface section (24) is formed, and the first surface section (23) does not contain holes (10) of nozzles (6) and holes (10) of nozzles (6) are formed on the second surface section (24). 21. Bubbling device according to any one of claims 1 to 20, characterized in that the hollow tubular element (2) includes a narrowed section (16) between the upstream inlet end (4) and the downstream outlet end (5 ) straight flow channel (3), and the bubbler (7) is located on the narrowed section (16). 22. Bubbling device according to claim 21, characterized in that the diameter of the narrowed section (16) is from 99 to 80% of the diameter of the straight flow channel (3) between the upstream inlet end (4) of the straight flow channel (3) and the narrowed section (16) and between the downstream outlet end (5) of the straight flow channel (3) and the narrowed section (16). 23. Bubbling device according to any one of claims 1 to 20, characterized in that the hollow tubular element (2) includes an expanded section (17) between the upstream inlet end (4) and the downstream outlet end (5 ) direct flow channel (3) and bubbler (7) is located on the extended section (17). 24. Bubbling device according to claim 23, characterized in that the diameter of the expanded section (17) is from 101 to 120% of the diameter of the straight flow channel (3) between the upstream inlet end (4) of the straight flow channel (3) and the expanded section (17) and between the downstream outlet end (5) of the direct flow channel (3) and the expanded section (17). 25. Sparging device according to any one of claims 1 to 24, characterized in that the holes (10) of the nozzles (6) are provided in the bubbler (7) so that the bubbler (7) does not contain holes (10) of the nozzles (6), if look at the bubbler (7) from the upstream side of the inlet end (4) of the hollow tubular element (2) in a direction parallel to the flow direction X. 26. Bubbling device according to any one of claims 1 to 25, characterized in that the bubbler (7) has an upstream surface facing the upstream inlet end (4) of the hollow tubular element (2), the bubbler (7) has a downstream surface facing the downstream outlet end (5) of the hollow tubular element (2), and holes (10) of the nozzles (6) are provided on the downstream surface of the bubbler (7), and the upstream surface bubbler (7) has no holes (10) nozzles (6). 27. Bubbling device according to any one of claims 1 to 26, characterized in that the holes (10) of the nozzles (6) are distributed sparsely in the direction X of the flow so that the holes (10) form upstream holes and downstream holes, and so that each upstream orifice in the X flow direction is not followed by any part of the bubbler (7). 28. A sparging device according to any one of claims 1 to 27, characterized in that the sparger (7) is in fluid communication with a gas source configured to supply a first fluid in the form of a gas to the sparger (7). 29. Bubbling device according to any one of claims 1 to 28, characterized in that located above - 7 039537 downstream inlet end (4) is in connection downstream with a source of fluid, made to supply a second flow fluid containing particles ranging in size from 0.2 to 0.3 mm, for example 0.25 mm, into the straight flow channel (3) of the hollow tubular element (2). 30. Bubbling device according to any one of claims 1 to 29, characterized in that the flow direction X is a linear flow direction. 31. Bubbling device according to any one of claims 1 to 30, characterized in that the straight flow channel (3) of the hollow tubular element (2) is vertical, so that the upstream inlet end (4) is located vertically above the one located below downstream outlet end (5), or such that the upstream inlet end (4) is vertically below the downstream outlet end (5) and the flow direction X is the vertical flow direction. 32. A method for extracting particles from a second fluid, characterized in that the second fluid is supplied through a straight flow channel (2) of the bubbling device (1) according to any one of claims 1 to 31, the first fluid in the form of gas bubbles is supplied to the bubbler ( 7) bubbling device (1) for supplying the first fluid in the form of gas from the holes (10) of the nozzles (6) in the bubbler (7) into the second fluid and ensuring that the particles in the second fluid adhere to the gas bubbles of the first fluid and extracting gas bubbles of the first fluid with particles adhering to them from the second fluid. 33. The method according to claim 32, characterized in that the second fluid, which is supplied through the direct flow channel (2) of the bubbling device (1), contains particles of at least one kind of macromolecules, complex ions, colloidal particles or fine particles. 34. The method according to claim 32 or 33, characterized in that the second fluid, which is fed through the direct flow channel (2) of the bubbling device (1), contains particles having a size of less than 10 μm and having a solid particle density of 0.8 up to 1.25 kg/l. 35. The method according to claim 32 or 33, characterized in that the second fluid, which is fed through the direct flow channel (2) of the bubbling device (1), contains particles having a size of 0.1 to 2 μm, and the solid particle density can range from 0.9 to 6 kg/l. 36. The method according to any one of claims 32 to 35, characterized in that the second fluid, which is fed through the direct flow channel (2) of the bubbling device (1), contains from 0.001 to 10 g of particles per liter of the second fluid, preferably from 0.001 to 1 g of particles per liter of the second fluid.