RU2356637C2 - Shesterenko's head piece (versions) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: disclosed invention refers to gas distilling and gas transporting installations; also it can be implemented as installation for transporting fluids (gas fluids) in many other branches of engineering, where distillation of gas is required. Further the installation can be used for breaking particles of aerosol in paint and varnish equipment, for applying particles of aerosol on items and for heating either aerosol or gas fluid mixture and transforming it into fume. It is an object of the invention to expand the range of implementation of the system of Shesterenko's head pieces and to upgrade its efficiency. According to the invention not less than one pressure tight cluster of nozzles in the head piece consisting of pressure tight connected between them nozzles has not less, than one resonance chamber between nozzles; not less, than one nozzle is introduced into the chamber; gas dynamic flows escaping the chamber are directed into one zone of the resonance chamber. In addition the head piece also consisting from pressure tight connected between them nozzles is equipped with an arm, which is connected with rotation axis and with at least one cluster of pressure tight connected between them nozzles, which is mounted on the arm; the arm is designed to rotate. Not less, than one pressure tight cluster of nozzles mounted on the arm can have or have not one resonance chamber between the nozzles; not less, than one nozzle is introduced into the chamber escaping wherefrom gas dynamic flows are directed into one zone of this resonance chamber. Also in the cluster consisting of pressure tight connected between them nozzles not less, than once behind the last nozzle not less, that at some pressure tight connected between them nozzles either rigidly, or movable there is installed with a gap a nozzle ejecting not less, than once; the ejecting nozzle has critical cross section bigger in comparison with the critical cross section of a flow nozzle.

EFFECT: aerosols colliding in resonance chamber are destroyed to superfine particles, which is very significant at paints fabrication; molecules of oil products colliding in resonance chamber are destroyed to super-light fractions which is important in chemical technology; in addition efficiency of head piece sharply grows with enhancement of resonance vibrations.

8 cl, 8 dwg

Description

The present invention relates to the field of gas-dispersing and gas-transporting devices, and can also be used as devices for transporting liquids (gas-liquid) in many other industries where it is necessary to disperse gas. Also, this device can be used for crushing aerosol particles in paint and varnish equipment and for applying aerosol particles to products and for heating either an aerosol or gas-liquid mixture and converting it into steam.

PROTOTYPE.

Shesterenko nozzles, consisting of nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle, while at least once the last nozzle of the nozzles hermetically connected to each other with a gap is ejected to the first nozzle of the following nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle of these nozzles, and each subsequent critical section is flow-determining The nozzle is larger than each previous critical section of the nozzle. (Page 58, figure 3. N. A. Shesterenko. Application of the laws of supersonic gas dynamics in solving applied problems. The eternal engine of the second kind. The Great Potter. Poems. - M.: CPU "Vasizdast", 2006.-268 p.)

The disadvantage of the prototype is the non-use of the forces of the colliding flows, as well as the fact that the resonantly pulsating active jet exiting the nozzle is not used to suppress ripples, which are destructive for the structures following the nozzle.

ANALOGUE 1.

Shesterenko nozzles, consisting of nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle, while at least once the last nozzle of the nozzles hermetically connected to each other with a gap is ejected to the first nozzle of the following nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle of these nozzles, and each subsequent critical section is flow-determining th nozzle is larger than each previous critical section of the flow-determining nozzle (Figures 4 and 5. Shesterenko nozzles. Patent RU 2277441 C2).

The disadvantage of analogue 1 is the non-use of the forces of the colliding flows, as well as the fact that the resonantly pulsating active jet exiting the nozzle is not used to suppress ripples, which are destructive for the structures following the nozzle.

ANALOGUE 2.

The Shesterenko nozzles are known, consisting of supersonic Laval nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the first Laval supersonic nozzle in the direction of travel, characterized in that the first nozzle is coaxially inserted into the next one with the formation of an ejected cavity between them and tapering . (N.A. Shesterenko. Nozzle Shesterenko. Patent RU 2206409 C2).

The disadvantage of analogue 2 is the non-use of the forces of the colliding flows, as well as the fact that the resonantly pulsating active jet exiting the nozzle is not used to suppress ripples, which are destructive for the structures following the nozzle.

The objective of the invention is to expand the scope of the Shesterenko nozzle system and increase efficiency.

To solve this problem, the nozzles according to the first embodiment consist of nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle, while at least once the last nozzle of the nozzles hermetically connected to each other with a gap is ejected to the first nozzle of the following hermetically interconnected nozzles, critical sections of which are not less than the critical section of the flow-determining nozzle of these nozzles.

Each subsequent critical section of the flow nozzle is larger than each previous critical section of the flow nozzle.

According to the invention according to the first embodiment, at least one sealed bundle of nozzles between the nozzles has at least one resonance chamber into which at least one nozzle is introduced with the directivity of the gas-dynamic flows emerging from it into one region of this resonance chamber.

The nozzles in the second embodiment consist of nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle.

Not less than once, the last nozzle of the nozzles hermetically connected to each other with a gap is ejected to the first nozzle of the next nozzle hermetically connected to each other, the critical sections of which are not less than the critical section of the nozzle of the nozzles of these nozzles.

Each subsequent critical section of the flow nozzle is larger than each previous critical section of the flow nozzle.

According to the invention, according to the second embodiment, the nozzles are equipped with a shoulder, which is connected to the axis of rotation, and at least one bunch of nozzles hermetically connected to each other, which is mounted on the shoulder with the possibility of rotation of the shoulder.

At least one sealed nozzle bundle mounted on the shoulder between the nozzles may or may not have at least one resonance chamber, into which at least one nozzle with the directivity of the gas-dynamic flows emerging from it into one region of this resonance chamber is inserted.

Also, in the nozzle, the shoulder can be made in the form of at least one body of revolution.

In addition, the nozzles in the third embodiment consist of nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle.

Not less than once, the last nozzle of the nozzles hermetically connected to each other with a gap is ejected to the first nozzle of the next nozzle hermetically connected to each other, the critical sections of which are not less than the critical section of the nozzle of the nozzles of these nozzles.

Each subsequent critical section of the flow nozzle is larger than each previous critical section of the flow nozzle.

According to the invention, according to the third embodiment, at least once behind the last nozzle, at least one nozzle is hermetically connected to each other, or, rigidly, or with the possibility of movement, an ejector nozzle with a critical cross section that is larger than the critical cross section of the flow-determining nozzle is ejector with a gap of at least once .

The nozzle in three versions can be equipped with a combustion chamber.

The invention is shown in figures 1-8.

In Fig. 1, nozzles 1, 2 and 3 are hermetically connected to each other. Critical sections 4 and 5 are not less than the critical section 6 of the flow-measuring nozzle 1. On the nozzle 3, using the brackets 7, 8 and the adjusting screw 9, an ejector nozzle 11 is installed with a gap 10, on which, using the brackets 12, 13 and the adjusting screw 14, an ejector nozzle 16 is installed with a gap 15. The ejector nozzles 15 and 16 have critical sections 17 and 18, which are larger than critical sections 4, 5 and 6.

On the ejector nozzle 16, using the brackets 19, 20 and the adjusting screw 21, a nozzle 23 is installed with a gap 22, which is hermetically connected to the nozzle 24, and in turn is hermetically connected to the nozzle 25. The nozzles 24 and 25 have critical sections 26 and 27, which are not less than the critical section 28 of the flow-determining nozzle 23, which is larger than the critical sections 17 and 18.

On the nozzle 25 using the brackets 29, 30 and the adjusting screw 31 is installed with a gap 32 ejector nozzle 33 with a critical section 34. The nozzle 1 has an input section 35.

The nozzle 3 has an output section 36. The ejection nozzles 11, 16 and 33 have output sections 37, 38 and 39. A high-pressure line 40 is connected to the input section 35.

In figure 2, the nozzle 41, made in the form of a body of revolution, is introduced into the resonance cavity 42 so that the gas-dynamic flow exiting the nozzle 41 collides with the gas-dynamic flow exiting the nozzle 41 in the central region of the resonance cavity 42, which is equipped with an exit nozzle 43 , to which the nozzle 44 is hermetically connected. The nozzles 41 and 44 have critical sections 45 and 46, which are no less than (and preferably larger) than the critical section 47 of the flow-determining nozzle 43. On the nozzle 44, with brackets 48, 49 and an adjusting screw 50, it is installed with a gap 51 ezhe Thorn nozzle 52, which by means of brackets 53, 54 and the adjusting screw 55 with a gap 56 is set nozzle 57.

A nozzle 58 is sealed to the nozzle 57, onto which, in turn, a nozzle 59 is sealed.

An ejector nozzle 64 is installed with a gap 63 on the nozzle 59 using the brackets 60, 61 and the adjusting screw 62. The ejector nozzles 52 and 64 have critical sections (they are simultaneously output) 65 and 66.

The nozzles 44 and 59 have exit sections 67 and 68. The annular nozzle 41 has an annular inlet section 69. The nozzles 58 and 59 have critical sections 70 and 71, which are not less than the critical section 72 of the flow nozzle 57. The critical section 65 is larger than the critical sections 45, 46 and 47. Critical sections 70 and 72 are not less (or better, more) than the critical section 72 of the flow nozzle 57. Critical sections 72 are not less (or better than) the critical section 65. Critical section 66 is greater than the critical sections 70, 71, and 72. To the ring input section connected to llektor 73 with high pressure.

1 and 2 in the nozzles 11, 23 and 52 there are screw-shaped guides 74, 75 and 76. Between the nozzles 1 and 2, 23 and 24, 43 and 44, 57 and 58, respectively, there are evacuated cavities 77, 78, 79 and 80 .

Figure 3 shows a variant when the nozzles 1, 2 and 3, hermetically connected together and the subsequent ejecting nozzles 11 and 16 are mounted on the shoulder 81, which is connected with the common axis of rotation 82. The nozzle 3 has a visor 83. On the axis 82 are installed vanes 84. Axis 82 is located in bearings 85 and 86 associated with the core (not shown in FIG.). Axis 82 is equipped with gear 87 with motor 88.

In figure 4, the nozzles 1 and 2 are made in the form of bodies of revolution. An annular manifold 89 with a high pressure is connected to the nozzle 1. Bearings 91 are mounted on the shoulder 90, in which an axis 92 is mounted, to which a rotation shoulder 93 is attached, to which an ejector nozzle 16 is in turn attached. Blades 94 are mounted on the axis 92. In FIG. 4, the nozzle 16 has an output in relation to the axis 92 a section that allows the jet to move tangentially (in Fig. 4 there is no special section explaining this, therefore, see Fig. 3).

5, the high-pressure annular manifold 89 is provided with an annular nozzle 95 on which an annular nozzle 96 is sealed with an outlet section 97 inserted into a sealed resonance chamber 98, which is provided with an outlet nozzle 99 with an outlet section 100. At the nozzle 100 with a gap 51 installed nozzle 52 with a critical section of 65.

6, the nozzles consist of nozzles 101,10 2 and 103 hermetically connected to each other, critical sections 104 and 105 of which are less than the critical section 106 of the flow-determining nozzle 101. At least once, the tight connection between the nozzles 101,102 and 103 forms cavities 107 and 108. The nozzle 101 with the inlet section is located closer to the remaining nozzles 102 and 103 of the nozzle to the axis of rotation 110.

Figure 6 shows the axis of symmetry O ₁ and O ₂ .

It should be noted that the generatrices of the nozzles 101, 102 and 103 are welded to the cylinders 111 and 112, which are welded to the shoulders 113 and 114. The nozzles 101, 102 and 103 can also be in the form of disks (rotors).

6, the nozzle 1 is subsonic, and the nozzles 102 and 103 are supersonic (Laval nozzles). From the inlet section 109 to the critical section 105, the generatrices of the nozzles 101, 102 and 103 are symmetrical to the O ₃ symmetry axis. Behind the critical section 105, the nozzle 103 (Laval nozzle 103) has a supersonic part 115, which rotates and at which the output section 116 faces the axis of symmetry O ₂ , with respect to which the nozzles are almost symmetrical to the critical section 117 of the common nozzle 118. Behind the critical section 117, the common nozzle 118 has a rotatable part 119, which has an output section 120. The generatrix 121, which forms 122 nozzles 103, the output section 15 and the common nozzle 18 define a resonance cavity 123 to a critical section 17. The dotted line 124 indicates a region along which flows from the exit sections 115 go before a collision in the region of the O ₂ symmetry axis.

6, only on one side of the shoulder 113 has an inlet 125 and on the same side on the axis of rotation 110 can be blades 126, or mixers, or compressors, or fans, or both at the same time. The axis of rotation has a drive for rotation (not shown in Fig.6). The inlet pipe 127 has a nozzle or a labyrinth seal 128, or an oil seal (not shown in Fig. 6). The shoulder 114 has an opening 129. The arrows in FIG. 6 show the paths of gas-dynamic flow. The output section 120 is aligned with the input section of the nozzle 131 of the nozzle 132 mounted on a common nozzle 118 using the shoulder 133. The nozzle 132 has an axis of symmetry O ₄ .

7, the shoulder 113 has an inlet 125 from two sides. Instead of shoulders 114 there is a shoulder 134, which has no holes. The arm 134 is welded to the installation cylinder 135. The arm 113 is welded to the installation cylinder 136. Intermediate cylinders 137 are mounted between the installation cylinder 135 and the arms 113. The axis of rotation 110 has a thread 138, with which cylinders 135, 136 and are tightened with nuts 139 to the axis of rotation 110 137. The inlet pipe 127 to the nozzle is suitable from two sides. The cylinder stops on axis 110 of FIG. not shown.

7, the nozzle 101 is made in the form of a Laval nozzle. It should be noted that the nozzle can be any nozzle from the nozzles 101, 102 and 103. However, for simplicity of the description of the work, we accept the nozzle 1 as a flow meter.

Fig. 8 shows how, at least once, the paths of motion of at least two first and subsequent nozzles follow in a resonant cavity equipped with at least one output nozzle.

In Fig. 8, at least two nozzles are installed on the axis 110, which are shown in Figs. 6 and 7, the axis of symmetry O _{4 of the} two nozzles 132 intersecting in the region of the axis of symmetry O _{5 of the} resonance cavity 140, which is formed either by a sphere (or a torus) 141 and a common nozzle 142. The gas-dynamic flow introduced into the supply pipe 127 is distributed between the first nozzles by means of a hollow cylinder 143. The rotation axis 110 in all cases has a rotation drive (not shown in the figures). On the nozzle 142 using the bracket 144 installed with a gap ejector nozzle 145.

Figure 2 shows a variant when the ejector evacuated chamber 80 can be communicated through a pipe 146 and an overlapping device 147 with some capacity.

All nozzles or part of nozzles in all figures can be made in the form of bodies of revolution. The resonance parameters depend on the geometry of the resonance chambers 42, 98, 123 and 140 and the geometry of the evacuated cavities. In all figures, the supply of additional masses of various gas-dynamic flows can be carried out autonomously (in Fig. Not shown). The tangential orientation of the nozzles with respect to the planes of rotation in figure 3, 4, 6, 7 and 9 is not shown, but it can take place.

The combustion chambers of FIG. not shown, but they may also occur.

In all the figures, the arrows show the directions of motion of the gas-dynamic masses or the rotation of the axes.

The present invention works as follows.

In Fig. 1, a gas-dynamic flow (either gas, or aerosol, or gas-liquid mixture, or liquid, which in nozzles at high speeds turns into a gas-liquid mixture) is supplied to the inlet section 35 through the high-pressure line 40. Through the supersonic nozzle 1, the flow enters the supersonic nozzle 2, and then into the supersonic nozzle 3. Either in the ejected vacuum cavity 77, or in the cavity between the critical sections 4 and 5 due to the separation of the flow from the nozzle 2 and due to the ejection of the vacuum of this space, or here and there conditions are created for the occurrence and retention of the resonant-pulsating flow of the gas-dynamic flow from the inlet section 35 to the outlet section 36 in the operating mode. Consequently, an act arrives from the outlet section 36 to the ejector supersonic nozzle 11 An obvious resonant-pulsating gas-dynamic flow, which, as it were, with vibrating waves, captures additional portions of another gas-dynamic flow, which can be brought to the gap 10 via an additional line or from the environment. In the future, for simplicity, the gas-dynamic flow will be referred to as the gas flow. In the nozzle 11, the frequency and magnitude of the amplitude of the active gas stream are partially quenched and changed. If for technological reasons it is necessary to increase the damping of pulsations, then an additional ejector nozzle 16 is already in the path of the total flow. A partially calmed total gas flow through the outlet section or 37 or 38 enters the nozzle 23. In the same way, an additional ejection forces portion of gas. All gas passes through critical sections 28, 26 and 27, and then enters the ejector nozzle 33. In this case, everything repeats.

In figure 2, the gas stream is fed through the high pressure manifold 73 to the annular nozzle 41, where it accelerates, and then exits through the critical annular section 45 into the resonance cavity 42, where the gas flow collides in the central part of the resonance cavity 42, reaching maximum pressure therein and braking temperatures. Then, the gas flow is thrown onto the walls of the resonance cavity 42 and then leaves through the supersonic nozzle 43 output to the supersonic nozzle 44. Or in the resonance cavity 42, due to the abrupt change in high pressure and low or due to the ejector-evacuated cavity 79, conditions are created for occurrence and retention at the working the mode of the resonant-pulsating gas flow from the annular critical section 45 to the output section 67, from which the active resonant-pulsating stream enters the ejector nozzle 52, and from there the total a tive jet ejector is a nozzle 57. Further, all repeats, as in Figure 1.

In Fig. 3, axis 82 is rotated by gear 87 and motor 88. At a given speed due to centrifugal forces, air at supersonic speed passes through hermetically connected nozzles 1, 2, and 3, either in an ejected vacuum cavity 77 or in cavity between critical sections 4 and 5 due to separation of the flow from the nozzle 2 and due to the ejection of the vacuum of this space, or there conditions are created for the occurrence and maintenance of the resonant-pulsating flow of the gas-dynamic flow from the input section 35 to the output section 36. The nozzle 3 has a visor 83, by which the gas flow is rotated. Next, the same thing happens as in figure 1.

In Fig. 4, through a ring collector 89 with high pressure, a gas flow is supplied to an annular supersonic nozzle 1, through which it then enters an annular supersonic nozzle 2. In the ejected evacuated cavity 77, conditions are created for the resonant-pulsating gas-dynamic flow to arise and to remain in operation from the inlet annular section 35 to the outlet annular section 36. The active gas jet in the pulsating mode enters the ejector nozzles 16, which are installed along the ring and directed by the outlet section Figure 3 is similar to axle 92 (i.e. generated torque). As a result, the blades 94 of the reactor mixer rotate.

In Fig. 5, through a ring collector 89 with high pressure, a gas flow is supplied to a supersonic nozzle 95, through which it then enters a nozzle 96 with a critical (and output simultaneously) section 97. No less than 95 nozzles 95 and 96 are tightly connected to the collector, than two pairs. The axes of these nozzles converge at the point “C” (convergence of flows) in the central region of the resonance cavity 98. Similarly to FIG. 2, an active gas stream exits from the section 100 in a resonantly pulsating mode. Then everything repeats.

In the embodiment of FIG. 6, the axis of rotation 110 is driven by a drive. A gas-dynamic flow (either gas, or an aerosol, or a gas-liquid mixture, or a liquid, which, when cavitation partially or completely passes into a gaseous state), either through suction or under pressure of an additional pressure source (through FIG. not shown). There is a “critical number” of revolutions, after which a critical flow is established in critical sections 106.

In this case, the hole 125 has a cross section greater than the sum of the areas of the critical sections 106. With an increase in the number of revolutions above the “critical number”, a stream arises behind the critical section 106 and travels at a supersonic speed, which slows down on the walls of the Laval nozzle 102 without switching to a subsonic speed, and beyond the critical section 4 it accelerates again. The same thing happens in the Laval nozzle 103, only the flow during acceleration still rotates towards the axis of symmetry O ₂ . In the resonance cavity 123, the flow collides in the region of the axis of symmetry O ₂ . In such a collision, large particles and molecules break up into smaller particles and molecules. Due to the centrifugal forces in the resonance cavity 123, a rarefaction occurs near the generatrix 121, and the resulting stream is transferred by centrifugal forces through the common nozzle 118 and the outlet section 120 into the nozzle 131 or simply into another gas path for further processing (not shown). Blades 126 facilitate the flow of the gas dynamic flow into the nozzles. The vacuum resulting from the ejection in the cavities 107 and 108 contributes to the cracking processes in the stream, which contribute to the acceleration of the cracking products and the entire stream. The rarefaction in the resonance cavity 123 near the generatrix 121 enhances the cracking effect and creates resonant wave vibrations, which also contribute to an increase in the flow velocity in the output section 120. If this flow goes to the section 130, then an additional nozzle 131 receives additional ejection (or additional pressure from the outside) gas-dynamic flow.

Figure 7 shows a variant when gas-dynamic flows through the inlet nozzles 127 enter the nozzles with different components. And the connection of these different components occurs in the resonance cavity 123. This can be both hydrogen and oxygen. Then the resonance chamber is a combustion chamber. However, the greatest application of this nozzle relates to grinding aerosols and obtaining the highest effect of vacuum cracking of petroleum products.

On Fig shows the option when the additional gas-dynamic flow with the main stream of the cracking product, included in section 130, in the resonance cavity 140 collide and are carried out by centrifugal forces through a common nozzle 142. This can be applied to obtain complex polymers. In the resonant cavities 123 and 140, due to the inertial forces of rotation and the velocity of the colliding gas flows, resonant wave pulsations are inevitably created, which will be observed in the output sections of the nozzles 118 and 142.

The pulsating active jet coming from the outlet section 120 moves like a wave-like comb, pulling an additional mass of gas into the next section of Shesterenko nozzles 123 into section 130.

Therefore, the proposed nozzle is the most highly effective device for using pressure energy arising from the forces of rotation or other forces.

The technical effect is that:

1) in a collision in an aerosol resonance chamber, the latter are destroyed to the smallest particles, which is very important in the manufacture of paints, cement and other powder compositions;

2) in the event of a collision of oil product molecules in the resonance chamber, the latter will collapse to the lightest fractions due to the high braking temperature;

3) with a pulsating flow of gas-dynamic components into the nozzle 1 (Fig. 1) or 101 (Figs. 7 and 8) or when creating rarefaction waves due to ejection in evacuated cavities (in all the drawings), the entire nozzle becomes a device for accelerating the gas-dynamic flow with "abnormally high thrust growth ”according to the USSR Discovery No. 413“ Phenomena of an abnormally high thrust growth in a gas ejector process with a pulsating active jet ”of 1951 and the book“ Oscillating jet nozzle with additional mass attachment ”by O.Kudrin (proceedings of the Moscow Aviation Institute, 1958 );

4) upon repeated repetition (Fig. 8), the phenomenon of an abnormally high increase in thrust in a gas ejector process with a pulsating active jet gradually increases the total increase in thrust, i.e. increases the selection of atmospheric pressure energy, converting it into kinetic energy of the gas stream, which in turn can be used in devices for transporting gas and oil through the pipeline and for the creation of new technological industries of chemical technology and for other purposes and technologies where it is necessary to transport and accelerate large gas-dynamic mass, and can also be converted into energy of temperature and pressure, or in a gas-turbine device can be transformed into rotational motion of any drive or and rotor of an electric generator.

Claims (8)

1. The nozzle, consisting of nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle, while at least once the last nozzle of the nozzles hermetically connected to each other with a gap is ejected to the first nozzle of the next nozzle hermetically connected to each other , the critical sections of which are not less than the critical section of the flow-determining nozzle of these nozzles, and each subsequent critical section of the flow-determining nozzle is larger than each th preceding the critical section raskhodoopredelyayuschego nozzle, characterized in that the at least one sealed bundle of the nozzles between the nozzle has at least one resonance chamber which is entered by at least one nozzle oriented onto therefrom gasdynamic flows in one region of the resonant chamber. 2. Nozzles, consisting of nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle, while at least once the last nozzle of the nozzles hermetically connected to each other with a gap is ejected to the first nozzle of the following nozzles hermetically connected to each other , the critical sections of which are not less than the critical section of the flow-determining nozzle of these nozzles, and each subsequent critical section of the flow-determining nozzle is larger than each of the previous critical section of the flow-determining nozzle, characterized in that it is provided with a shoulder that is connected to the axis of rotation, and at least one bunch of nozzles hermetically connected to each other, which is mounted on the shoulder with the possibility of rotation of the shoulder, with at least one tight joint nozzles mounted on the shoulder, between the nozzles may or may not have at least one resonance chamber, into which at least one nozzle is introduced with the directivity of the gas-dynamic flows emerging from it in one region This resonance chamber. 3. Nozzles, consisting of nozzles hermetically connected to each other, the critical section of each of which is not less than the critical section of the flow-determining nozzle, and at least once the last nozzle of the nozzles hermetically connected to each other with a gap is ejected to the first nozzle of the following nozzles hermetically connected to each other , the critical sections of which are not less than the critical section of the flow-determining nozzle of these nozzles, and each subsequent critical section of the flow-determining nozzle is larger than each of the previous critical section of the flow-determining nozzle, characterized in that at least once behind the last nozzle, at least at one of the nozzles hermetically connected to each other, either an ejection nozzle with a critical section, large in comparison with the critical section of the flow-determining nozzle. 4. Nozzles according to claim 1, characterized in that it is equipped with a combustion chamber. 5. Nozzles according to claim 2, characterized in that the shoulder is made in the form of at least one body of revolution. 6. Nozzles according to claim 2, characterized in that it is equipped with a combustion chamber. 7. Nozzles according to claim 5, characterized in that it is equipped with a combustion chamber. 8. Nozzles according to claim 3, characterized in that it is equipped with a combustion chamber.

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