UA65541C2 - Method and device for formation of hydrodynamic lift or propulsive force - Google Patents

Abstract

In a method of formation in the fluid medium of hydrodynamic lift or propulsive force by interaction of fluid medium with rotary rotor, according to invention, the rotor is formed from fluid medium in the form of closed vortex tube due to the influence on the medium of centrifugal field with the help of, at least, one source, ensuring, besides rotary displacement, progressive displacement of medium in the direction of its rotational axis, moreover the rotary motion of medium is formed between the source and the closing element. In a device for formation in fluid medium of rotary type hydrodynamic lift or propulsive force, containing framework, according to invention, on the framework is fixed the source of centrifugal field, and in the area of forming the centrifugal field is fixed a closing element relative to the framework.

Description

The method of formation of a hydrodynamic lifting or driving force in a fluid medium and a device for its implementation.

The claimed inventions relate to hydrodynamics, namely, to methods of generating hydrodynamic lifting or driving force in a fluid medium using rotor-type devices performing the functions of a wing, blade or vane and can be used in aviation, shipbuilding, energy, turbo-, compressor- and pump construction.

There is a known method of formation of a hydrodynamic lifting or driving force in a fluid medium through interaction with the medium of bodies of a special shape during their flow (see the book by K.K. Fedyaevsky,

Ya.I. Voitkunskogo and Yu.I. Faddeev, Hydromechanics, L.: "Shipbuilding", 1968, 6.37 5).

Compared to the proposed method, the known one provides a much smaller value of the coefficient of lifting force "Su", and therefore, other things being equal, a much smaller lifting or driving force.

A known device that implements the above-described method is made in the form of a flat wing with a slat (see German application Mo3837812, U 64C 3/10, journal "Izobreteniya strán mira Me4-6, 1991), and the slat is made in the form of a cylindrical rotor, installed parallel to the flat wing with the possibility of rotation.

Compared to the proposed device, the known one has the following main disadvantages: 1) a more complex design; 2) much larger mass and weight; 3) significantly larger dimensions with equal lifting force; 4) restrictions on the speed of rotation of the rotor and the temperature of the medium washing it, which narrows the field of application of the known device.

There is also a known method of formation of a hydrodynamic lifting or driving force in a fluid medium through the interaction of a rotating rotor with the medium flowing around it (see the article by M. Kochunov, Zffekt

Magnus - in the air and under the water, magazine "Inventor and rationalizer" Mob, 1985. p.22) is chosen as a prototype for most essential features.

According to this method, using the Magnus effect, the hydrodynamic lifting force is obtained on the rotating rotor during its interaction with the medium moving relative to the rotor. When the rotating rotor is moved relative to the environment, a driving force is created that affects the environment.

In comparison with the proposed method, the prototype has the following main disadvantages: 1) it presents increased requirements to ensure safety of work, because in the event of destruction, the rotating rotor made of structural materials presents a great danger to service personnel; 2) has a narrower field of application, for example, due to weight restrictions, it is practically not used in aviation, and due to environmental temperature restrictions - in gas turbine construction; 3) it also has a limitation on the speed of rotation of the rotor, due to the strength limit of the structural materials used, and, therefore, the speed of the medium washing the rotor, which additionally narrows the field of use of the method; 4) requires higher energy consumption to create a lifting force due to higher flow resistance of the elements of the device that implements the method; 5) does not provide control of the position of the resulting lifting force along the length of the rotor, which narrows the functionality of the method.

In addition, a device that implements the above-described method and was chosen as a prototype for most essential features is known (see the article by M. Kochunov, The effect of Magnus - in the air and under the water, magazine "Izobretatel i rationalizator", Mob, 1985, p. 23) . This device consists of a cylindrical rotor with a drive fixed on a support structure with the possibility of rotation.

In comparison with the declared device, the prototype has the following main disadvantages: 1) much larger mass and weight, because the rotor in the prototype is made of structural materials, which limits the field of application of the device, for example, in aviation; 2) lower indicators of labor safety, since the rotating rotor, made of structural materials, represents a great danger for service personnel in the event of its destruction; 3) creates greater resistance during the flow of the fluid medium due to the additional resistance to the flow of fastening parts and drive elements, as well as the influence of end and other effects; 4) the design of the prototype does not allow changing the size and shape of the rotor during operation, as well as changing the speed of rotation of its individual sections, which narrows its functionality; 5) there is a limitation both on the maximum speed of rotation of the rotor, due to the strength limit of the structural materials used, and on the temperature of the fluid flowing around the rotor, since at a temperature greater than 2007С, coking of the lubricant occurs in the moving nodes of the device, which narrows the field of its application.

The basis of the invention - the method is the task of its improvement by changing the physical nature of one of the objects interacting in the method, which ensures a reduction in the mass (weight) of the device that implements the claimed method, and simplifying its design, reducing energy consumption and increasing safety indicators during its implementation, as well as expansion of the functionality of the method and the field of its application.

The task is solved by the fact that in the method of creating a hydrodynamic lifting or driving force in a fluid medium, through the interaction of a fluid medium with a rotating rotor, according to the invention, the rotor is formed from a fluid medium in the form of a closed vortex tube due to the influence of a centrifugal field on the medium with the help of, at least , one of its sources that provides, in addition to rotational, translational movement of the medium in the direction of its axis of rotation, and the rotational movement of the medium is formed between the source and the closing element.

In addition, the external field is created with the help of two sources installed opposite and rotating the fluid medium in the same direction, and the second source is used as a closing element of the first and vice versa.

After the formation of the vortex tube | are bent by, for example, turning the axes of rotation of the sources of the external field.

Moreover, the vortex tube is bent in the shape of a semi-ring.

And during the formation of the vortex tube or before it, the source of the centrifugal field and the closing element are brought together, and after the formation of the tube, they are moved to the working position.

Moreover, convergence is carried out up to the distance at which a rarefaction of the medium (vacuum) occurs on the surface of the closing element in the area of its intersection with the axis of rotation of the source.

And the speed of rotation of the vortex tube is supported by the higher speed of its flow around the fluid medium.

The invention is based on the task of improving the device by changing the design of both the device itself and the design of its parts, which ensures a reduction in the mass (weight) of the device and simplification of its design, a reduction in energy consumption and an increase in safety indicators during its operation, as well as expansion functional capabilities of the device and its field of application.

The task is solved by the fact that in the device for creating a hydrodynamic lifting or driving force in a fluid medium, of the rotor type, according to the invention, a centrifugal field source is fixed on the supporting structure, and in the area of creation of the centrifugal field (the location of its working organs) is fixed, relative to the supporting structure , closing element.

In addition, the closing element is made with a fluid-impermeable surface on the side facing the source.

The closing element can be made in the form of a plate, the dimensions of which are equal to or exceed the dimensions of the projection of the centrifugal field source onto it in the direction of the axis of rotation of the source.

For example, the plate is made flat and installed perpendicular to the axis of rotation of the source.

Or, the closing element is made in the form of another centrifugal field source installed opposite the first one.

Moreover, the sources of the centrifugal field are installed coaxially (with the alignment of the axes of rotation of the centrifugal fields created by them by the alignment of the axes of rotation of their working bodies).

In addition, the source of the centrifugal field and/or the closing element are installed relative to the supporting structure with the possibility of their fixed movement and equipped with movement mechanisms.

In addition, centrifugal field sources are installed with the possibility of turning their rotation axes and are equipped with turning mechanisms.

At least one source of the centrifugal field can be made in the form of a blade impeller mounted on a supporting structure with the possibility of rotation and connected to the drive.

This vane impeller is made with a coaxially located disk impermeable to the fluid medium, and the disk can be made with a diameter equal to the diameter of the wheel, and the blades are radial.

Moreover, as an option, a fluid-impermeable rim can be attached to the edge of the disk with the formation of a cavity open to the place of formation of the vortex tube, and the blades are placed inside this cavity, and the rim is made of a cylindrical shape or a shape that expands from the disk, for example, in the form side surface of the truncated cone.

This working vane wheel with coaxially located disc, impermeable to the fluid medium can be made with a disc diameter smaller than the diameter of the wheel with the installation of blades on the periphery of the disc with axial feed.

Moreover, centrifugal blades can be made on both sides of the disk.

To increase the axial feed, the working vane wheel is placed in a body impermeable to the fluid medium, open in the direction of the place of formation of the vortex tube, or in a similar recess in the supporting structure.

The axial supply of the equipment of the housing (recess) of the centrifugal field source is further strengthened by the inlet or outlet nozzle of the fluid medium.

Moreover, the nozzle is placed in the opposite, relative to the place of formation of the vortex tube, part of the body (recess), coaxially with the drive shaft of the impeller.

At least one source of the centrifugal field can be made in the form of a swirling flow of the nozzle connected to the supercharger of the fluid medium (pump or compressor) or a source of vacuum.

Moreover, the nozzle can be made in an open form, in the direction of the place of formation of the vortex tube, vessel, and the supply or removal of the fluid to or from it is carried out tangentially.

Or, the nozzle can be made in the supporting structure or its movable fragment in the form of an annular gap, equipped with a nozzle of the same shape, in the formed annular channel, elements are installed that twist the flow, for example, vanes, and the inner part, limited by the gap, is made impermeable to fluid medium.

Moreover, the nozzles for supplying the fluid are made in the form of nozzles.

And the side wall of the body (recess) and the nozzle in the corresponding versions of the centrifugal field source are made of a cylindrical shape or a shape that expands symmetrically from the bottom, for example, conical.

In all versions of the device, the space adjacent to the surface of the source and/or closing element is connected, at the point of vortex tube formation, with the environment and/or the vacuum source by means of a pipeline passing through the source or element and equipped with a shut-off and flow control device.

In addition, the surface of the supporting structure in the region of the location of the centrifugal field sources is made impermeable to the fluid medium.

Moreover, the surface of the supporting structure is made impermeable to the fluid in all directions from the axis of rotation of the centrifugal field source at a distance not less than 1.414 of the maximum value of the radius of the vortex tube.

The creation of a closed vortex tube in a fluid environment, by the action of a centrifugal field between its source and the closing element on it, allows you to obtain in the environment necessary for the implementation of the method, a rotating rotor fixed relative to the source of the centrifugal field, due to the fact that in the area of the location of its working organs under the action of centrifugal forces, a stable area of reduced pressure is "tied" to the source. Moreover, since rarefaction will be established inside the pipe due to the action of centrifugal forces on particles of the medium, the specific weight of the formed rotor will be less than the specific weight of the medium and, therefore, such a rotor will not burden the device in which it is used, but on the contrary, lighten it. In addition, an increase in the speed of rotation, unlike the prototype, will not lead to the destruction of the rotor, but to an increase in its stability and dimensions, which allows the use of the proposed method and device not only in subsonic flow regimes, like prototypes, but also in supersonic and hypersonic ones , that is, to expand the field of their application.

In addition, it is obvious that the consequences of the accidental destruction of such a rotor are not comparable to the consequences of the destruction of a rotor of similar size, but made of structural materials.

Creating a vortex tube with the help of two sources of a centrifugal field ensures a more complete closure of the vortex tube, increases the force that holds the rotor in a given place and allows you to change the direction of the lifting or driving force by changing the speed of rotation of one of the sources relative to the other, that is, to perform, in addition, control functions , which expands the functionality of the claimed method and device.

Installation of centrifugal field sources with the possibility of their movement and/or rotation of their axes of rotation allows to simplify the conditions for the formation of a vortex tube in a fluid medium and to carry out the necessary changes in its shape and size depending on the operating conditions, and therefore to expand the possibilities of controlling the rotor during operation and to reduce the force of resistance to the fluid medium when it flows around it.

The bending of the vortex tube in the form of a semi-ring by, for example, turning the axes of rotation of the sources of the centrifugal field parallel to each other allows you to obtain, in addition to the lifting and driving force in the stationary state of the rough, as well as to reduce the resistance of the rotor to the oncoming flow by ensuring the continuity of the velocity field of the fluid during its flowing (see the book Lavrentyeva M.A., Shabbat

B.V. Problem! hydromechanics and their mathematical models. - M: Nauka, 1975, p. 328).

Maintaining the speed of rotation of the vortex tube greater than the speed of its flow ensures the fulfillment of the condition of its stability.

Connecting the cavity of the vortex tube through one or both of its ends with the environment and/or a source of vacuum with the help of a pipeline passing through the source of the centrifugal field adjacent to its end, equipped with a closing and regulating flow device(s) provides additional opportunities for controlling the shape and diameter of the vortex pipes

The equipment of the body of the source of the centrifugal field made on the basis of a bladed impeller, with a nozzle for the supply of the fluid in the opposite, relative to the vortex tube, part of the body (recess) or the execution of the source of the centrifugal field in the form of a swirling flow nozzle connected to the supercharger of the fluid (pump or compressor), allows you to form a vortex tube in a fluid medium by supplying it with another fluid or the same medium, but which has a lower temperature and ensures, due to this, the removal of the movable connections of the parts of the centrifugal field sources from direct contact with the flow of the medium washing the rotor, that require lubrication. Since the vortex tube itself has no restrictions on the temperature of the environment, it becomes possible to use the claimed device as guide and/or working blades of gas turbines operating in conditions of high and ultra-high temperatures, which further expands the field of application of both the method and the device.

Making the supporting structures 5 and 6 impenetrable in the area of the centrifugal field sources allows to increase the force that keeps the vortex tube in a given place.

The invention is explained with illustrations and some variants of the device that implements the claimed method. Fig. 1 shows a version of the device with one source of the centrifugal field, Fig. 2 and Fig. 3 - versions of the device with two sources of different construction, Fig. 4 - a version with two sources of the centrifugal field, equipped with a system for their rotation (a - output state, c - the final state), in Fig. 5 - the source of the ventral field of the slit type.

The proposed device consists of a centrifugal field source 1 made in the form of a bladed centrifugal wheel connected by a shaft 2 to a drive 3. The centrifugal field source 1 is placed in a cylindrical recess 4 made in a supporting structure 5. Opposite the centrifugal field source 1 is a structure 6 with a surface impervious to the fluid medium, the dimensions of which exceed the dimensions of the projection onto it of the source 1. Along the axis of the blade centrifugal wheel of the source of the centrifugal field 1 and the shaft 2, an opening 7 is made, which is part of the pipeline 8 connected through adjustable valves 9 and 10 with the environment and the source vacuum 11 (option Me1, see Fig. 1).

The source of the centrifugal field 1 can be made to provide an additional axial supply of the fluid by installing in the groove 4 a nozzle for the supply of the fluid 12 coaxial with the shaft 2 and making it a vane impeller with a bilateral, relative to the disc 13, arrangement of the radial vanes. And in structure 6, opposite the source of the centrifugal field 1, in a similar recess 14, a similar source of the centrifugal field 15 with its pipeline 16, which connects the source 15 with the environment and the vacuum source 11, with the help of adjustable valves 17 and 18, is placed in a mirror image (option Me2, see Fig. 2).

Or, the source of the centrifugal field 1 can be made with a vane wheel that provides axial supply or removal of the fluid, and it is advisable to make the nozzle 12 in the recess 4, in this case, annular. Located opposite, in recess 14, the source of the centrifugal field 15 is similar, although it may have a different design, as, for example, in option 2 (option 3, see Fig. 3).

Centrifugal field sources 1 and 15 can be made in the form of nozzles - vessels 19 and 20, which have the shape of a truncated cone with an open large base on the side of which, near the bottom, tangentially installed nozzles 21 and 22 are connected by pipelines 23 and 24 to a fluid pump 25, for example, a compressor. Nozzles 21 and 22 are made in the form of subsonic nozzles. And the centrifugal field sources 1 and 15 are made with the possibility of their movement and rotation of the axes of rotation of the fields created by them with the help of mechanisms 26 and 27, for example, of the hydraulic type. To fix the vessels 19 and 20 in working condition, clips are provided (not shown in the drawing). Pipelines 8, 16 and 23, 24 are made flexible, for example, from reinforced rubber (option 4, see Fig. 4).

In the same version of the device, the sources of the centrifugal field 1 and 15 can be made of the slot type (see Fig. 5), where a slot channel 28 having the shape ring subsonic nozzle. Inside the channel 28, vanes 29 are installed at equal intervals, inclined relative to the cross section of the channel 28. Moreover, the vanes 29 are installed overlapping each other, and the channel 28 is connected to the fluid pump 25.

In all variants of the proposed device, the surface of the structure 5 and 6, in the area where the sources 1 are located, is made impermeable to the fluid medium at a distance from the axis of rotation of the sources 1 and 15 not less than 1.5 of the radius of the recesses 4, 14 or the maximum values of the radius of the nozzles.

The device works in a fluid environment as follows. When the centrifugal field sources 71 and 15 are unidirectionally launched, the part of the fluid interacting with them is drawn into rotation, forming a vortex tube closed between the centrifugal field source 1 and the impermeable surface of the structure b (option Me1) or between the centrifugal field sources 1 and 15 (options MeMe2, With and 4). Since a stable zone of reduced pressure is created in the zone adjacent to the axis of rotation of sources 1 and 15 due to the action of outward forces, and the formed vortex tube is closed on at least one of them and the pressure inside it is also reduced, then under the action of a higher external , in relation to the vortex tube, the fluid pressure will be maintained by source 1 (option Me1) or sources 1 and 15 (options MoMe2, C and 4) when the fluid flows around it. Because the vortex tube behaves like a rotating elastic body (see the book by V.I. Merkulov.

Familiar and unfamiliar hydrodynamics. - M.: Nauka, 1989, p. 65), then when it flows around the fluid medium, due to the Magnus effect, a lifting force is generated, which is transmitted to the sources 1 and 15 holding the rough or to the source | (variant Me1), and, therefore, the supporting structure 5. When moving the supporting structure 5 with sources 1 and 15 attached to it relative to the fluid medium, the vortex tube held by them will also move, creating, due to the Magnus effect, a driving force in the fluid medium .

In option 4, it is possible to change the configuration of the vortex tube during operation by turning sources 1 and 15 using mechanisms 26, 27, while optimizing its shape. For example, when sources 1 and 15 are unidirectionally rotated to the position when their axes of rotation become parallel to each other, the vortex tube will bend in the shape of a semi-ring, taking the optimal shape for its retention by sources 1 and 15. Moreover, this shape of the vortex tube allows creating, due to the interaction of its surface with the environment, a driving force that acts on both the environment and the vortex tube and without moving the vortex tube relative to the environment (see the journal "Inventor and Rationalizer" Me12, 1985, p. .22).

Sources 1 and 15 in variant C can work with the joint injection of the medium into the zone of vortex formation, with the joint suction of the medium from this zone, or one with injection and the other with suction.

In all versions of the device, it is possible to change the transverse dimensions of the vortex tube without changing its rotation speed by connecting its cavity with the environment (increase) or a vacuum source (decrease), using pipelines 8, 16 and adjusting its dimensions by changing the medium flow through these pipelines valves 9, 17 and 10, 18.

In addition, the claimed device provides for the ability to adjust the length of the vortex tube by moving sources 1 and 15 closer or farther apart using a suitable mechanism (not shown in the figures) to adjust the ratio of lifting and holding forces.

An example of the implementation of the method.

The method is carried out using, for example, the device shown in Fig. 4 in order to obtain a lifting force sufficient for the take-off of the device in the atmosphere.

Initial data: fluid medium - air, P-0.101MlLa, 1-20; speed of transverse flow around the F-9O0m/s pipe; the maximum diameter of nozzles 19 and 20 is 1.00m, the minimum is 0.9m; the distance between nozzles 19 and 20 is 0.5 m; fluid pump 25 - a compressor with a pumping pressure equal to 0.1 MPa; the mass of the installation that performs the declared method together with the payload is 7 tons.

Before the formation of a vortex tube in the atmospheric air, nozzles 19 and 20 are rotated coaxially to each other using mechanisms 26 and 27. Then inside the nozzles 19 and 20 through the nozzles 21, 22 and pipelines 23, 24, compressed air is supplied from the compressor 25 at a pressure lower than the accepted one, for example, 0.25 of the nominal. Since the supply nozzles 21 and 22 are installed tangentially, the air dispersed in them swirls in the conical nozzles 19, 20 and, going beyond their limits, will form, due to the addition of rotational and translational air movements, cone-shaped flows. Because the nozzles 19 and 20 are installed coaxially, these flows, rotating in one direction, collapse, creating a single cavity, which under the influence of external pressure will take the form of a vortex tube closed to the sources of the centrifugal field 1 and 15.

After the formation of the vortex tube, nozzles 19 and 20 are returned, with the help of mechanisms 26 and 27, to the working state and fixed with clips. At the same time, the vortex tube is bent in the form of a semi-ring.

Then the compressed air pressure in the compressor 25 is increased to the nominal value. Since nozzles 21 and 22 are made in the form of subsonic nozzles, with the assumed pressure difference, the air velocity at the exit from them, and, therefore, the speed of rotation of the vortex tube, will reach the speed of sound ((34O0m/s).

Similarly, the claimed method can be implemented in any other fluid medium, for example, in water with a corresponding change in the values of the used parameters and replacing the compressor with a pump.

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Claims (31)

1. The method of formation of a hydrodynamic lifting or driving force in a fluid medium by the interaction of the fluid medium with a rotating rotor, characterized by the fact that the rotor is formed from the fluid medium in the form of a closed vortex tube due to the influence of the centrifugal field on the medium with the help of at least one of its sources, which provides, in addition to rotary, translational movement of the medium in the direction of its axis of rotation, and the rotary movement of the medium is created between the source and the closing element. 2. The method according to claim 1, which differs in that the centrifugal field is created with the help of two sources installed opposite and rotating the fluid medium in the same direction, and the second source is used as a closing element of the first and vice versa. 3. The method according to claim 2, which differs in that after the vortex tube is formed, it is bent by, for example, turning the axes of rotation of the centrifugal field sources. 4. The method according to point C, which differs in that the vortex tube is bent in the shape of a semi-ring. 5. The method according to any of claims 1-4, which differs in that during the formation of the vortex tube or before that, the source of the centrifugal field and the closing element are brought together, and after the formation of the tube, they are moved to the working position. 6. The method according to claim 5, which is distinguished by the fact that the convergence is performed to the distance at which the rarefaction of the medium occurs on the surface of the closing element in the area of its intersection with the axis of rotation of the source. 7. The method according to any of claims 1-6, which is characterized by the fact that the speed of rotation of the vortex tube is maintained higher than the speed of its flow around the fluid medium. 8. A device for generating in a fluid medium a hydrodynamic lifting or driving force of the rotor type, containing a supporting structure, which is characterized by the fact that a centrifugal field source is fixed on the supporting structure, and a closing element is fixed relative to the supporting structure in the area of creation of the centrifugal field. 9. The device according to claim 8, which is characterized by the fact that the closing element is made with a fluid-impermeable surface on the side facing the source. 10. The device according to claim 9, which is characterized by the fact that the closing element is made in the form of a plate, the dimensions of which are equal to or exceed the dimensions of the projection of the centrifugal field source onto it in the direction of the axis of rotation of the source. 11. The device according to claim 10, which is characterized by the fact that the plate is made flat and is installed perpendicular to the axis of rotation of the source. 12. The device according to claim 8, which is characterized by the fact that the closing element is made in the form of another centrifugal field source installed opposite the first one. 13. The device according to claim 12, which differs in that the sources of the centrifugal field are installed coaxially. 14. The device according to any of claims 8-13, which is characterized by the fact that the source of the centrifugal field and/or the closing element are installed relative to the supporting structure with the possibility of their fixed movement and are equipped with movement mechanisms. 15. The device according to any of claims 8-14, which is characterized by the fact that the sources of the centrifugal field are installed with the possibility of turning their axes of rotation and are equipped with turning mechanisms. 16. The device according to any of claims 8-15, which is characterized by the fact that at least one source of the centrifugal field is made in the form of a vane impeller mounted on a support structure with the possibility of rotation and connected to the drive. 17. The device according to claim 16, which is characterized by the fact that the vane impeller is made with a coaxially located disk impermeable to the fluid medium, and the disk is made with a diameter equal to the diameter of the wheel, and the blades are radial. 18. The device according to claim 17, which is characterized by the fact that a fluid-impermeable rim is attached to the edge of the disk with the formation of a cavity open to the place of formation of the vortex tube, and the blades are placed inside this cavity, and the rim is made of a cylindrical shape or a shape that expands from disk, for example, in the form of a side surface of a truncated cone. 19. The device according to claim 16, which is characterized by the fact that the vane impeller is made with a coaxially located disc impermeable to the fluid medium, and the disc is made with a diameter smaller than the diameter of the wheel, and the blades are installed on the periphery of the disc to ensure axial feed. 20. The device according to any of claims 17-19, which is characterized by the fact that the disk has centrifugal blades on both sides. 21. The device according to any one of claims 16, 17, 19 and 20, which is characterized in that the working blade wheel is placed in a fluid-impermeable recess in the supporting structure. 22. The device according to claim 21, which is characterized by the fact that the recess of the source of the external field is equipped with a nozzle for supplying or removing the fluid. 23. The device according to claim 22, which differs in that the nozzle is placed in the opposite, in relation to the place of formation of the vortex tube, part of the notch, coaxially with the drive shaft of the impeller. 24. The device according to any one of claims 8-15, which is characterized by the fact that at least one source of the centrifugal field is made in the form of a nozzle that swirls the flow and is connected to a fluid pump or a vacuum source. 25. The device according to claim 24, which differs in that the nozzle is made in an open form, in the direction of the place of formation of the vortex tube, vessel, and the supply or removal of the fluid to or from it is carried out tangentially. 26. The device according to claim 24, which is characterized by the fact that the nozzle is made in the supporting structure or its movable fragment in the form of an annular gap, equipped with a nozzle of the same shape, in the formed annular channel, elements are installed that twist the flow, for example, blades, and the inner, limited by a gap, part of the nozzle is made impermeable to the fluid medium. 27. The device according to claim 25 or 26, which differs in that the nozzles for supplying the fluid are made in the form of nozzles. 28. The device according to any of claims 21-23, 25, which is characterized by the fact that the side wall of the recess and the nozzle is cylindrical or in a shape that expands symmetrically from the bottom, for example, conical. 29. The device according to any one of claims 8-28, which is characterized by the fact that the space adjacent to the surface of the centrifugal field source and/or the closing element is connected, at the point of formation of the vortex tube, to the environment and/or the vacuum source using pipeline equipped with a shut-off and flow control device. 30. The device according to any of claims 8-29, which is characterized by the fact that the surface of the supporting structure in the region of the location of the centrifugal field sources is made impermeable to the fluid medium. 31. The device according to claim 30, which is characterized by the fact that the surface of the supporting structure is made impermeable to the fluid in all directions from the axis of rotation of the centrifugal field source at a distance not less than 1.414 of the maximum value of the radius of the vortex tube.