WO2008033047A1

WO2008033047A1 - Method and plant for producing power

Info

Publication number: WO2008033047A1
Application number: PCT/RU2006/000483
Authority: WO
Inventors: Yury Semionovitch Potapov
Original assignee: Yury Semionovitch Potapov
Priority date: 2006-09-14
Filing date: 2006-09-14
Publication date: 2008-03-20

Abstract

The invention relates to power engineering and is used for producing electrical, mechanical and heat energy with increasing a performance ratio. The inventive power producing method consists in supplying a pressurised gas-liquid mixture to a swirl-generating device via a mixture injecting unit, in directing the flow of mixture along a curvilinear trajectory about an axis of rotation with acceleration produced by centrifugal forces and in sending the swirling mixture flow to the hole of a rotor, which is mounted in said swirl-generating device, at an angle to the internal surface thereof, thereby rotating said flow in such a way that power is generated. The inventive plant for producing power comprises an swirl-generating device (3), a rotor (2) which is provided with holes embodied along the circumference thereof and is arranged in the swirl-generating device in such a way that it is rotatable by the action of a pre-swirling flow of a gas-liquid mixture, a unit for injecting the mixture into the swirl-generating device (3) in such a way that it is directed towards the rotor (2) and a unit which is used for supplying the pressurised mixture and which is connected to the mixture injecting unit and to an energy recovering unit.

Description

METHOD AND INSTALLATION FOR PRODUCING ENERGY

Technical field

The invention relates to the field of energy, in particular, mechanical and / or electrical, and / or thermal energy, and can be used in energy, transport and other industries, and in everyday life. The inventive method and device operate without burning traditional fuels, and the production of electrical and mechanical energy is carried out without harmful exhaust gases or harmful radioactive emissions. State of the art

Various methods for producing electrical or mechanical energy using conventional fuels and internal combustion engines are well known. Gasoline, gas, oil, diesel fuel, kerosene, firewood, coal, gas condensate are burned in the atmosphere. The main disadvantage of these methods and devices for generating electrical (mechanical) energy is that they burn fuel and have a low coefficient of performance (COP), and known magnetic motors, as a rule, are low-power (up to 7 kW), too heavy and constantly lose their power over time. Also known are methods of generating thermal energy using vortex heat generators with electric motors or internal combustion engines.

At present, environmentally friendly engines that operate on water as a "fuel" have been created. This, in particular, the hydraulic quantum engine disclosed in the patent of the Russian Federation N ² 2160840, and the electric motor disclosed in the USSR copyright certificate N ² 1796776. The essence of these inventions is that in the first case, water is injected into the quantum engine, and then explodes, and in the second, an electric discharge is produced in water. In both methods, overpressure is created in the chamber, which is transmitted to the turbine rotating the power take-off shaft. The most blocks to the claimed invention are indicated by the electric motor according to the USSR copyright certificate N ² 1796776. In this invention, the stator has tangential discharge chambers with cylindrical bores, and the rotor is made with ledges made on the peripheral surface. At least one pair of electrodes is placed in each chamber. The cavity of the chambers and bores are filled with liquid. One of the electrodes is fixed and installed with the possibility of rotation and periodic changes in the interelectrode distance. The movable electrode is made in the form of rods of electrically conductive material, mounted on an axis mounted rotatably in the stator. One of the electrodes is forked. The auxiliary motor shaft is kinematically connected with the axis of the movable electrode. According to the author, the implementation of one of the electrodes forked allows you to increase the power of the shock wave. Shock waves during engine operation directed by discharge chambers into a cylindrical bore between the rotor and stator rotate the rotor and the motion is transmitted to the power take-off shaft. The disadvantage of this device and method of generating energy is the presence of fluid between the stator and the rotor, which prevents the free rotation of the rotor. The resulting frictional forces between the rotor and the fluid reduce the efficiency of such an engine. In addition, in the chambers where the electric current is discharged, the stator walls and the grooves near the rotor begin to collapse. There is an electroerosive destruction of the engine.

Rank vortex tubes are also known for producing streams of cold and hot air. In similar, usually open on both sides of the pipe, air is supplied from the side along the spiral of Archimedes under considerable pressure and is twisted in the pipe. In this case, the molecules move under the pressure of the gas and a stable vortex is formed in the swirling flow and two regions are formed - the peripheral one with an elevated temperature and the inner one with a lower temperature. Hot air flows from one end of the pipe, and cold from the other. However, such installations are difficult to use to produce mechanical or electrical energy. Moreover, although Joseph Rank patented the corresponding method and device back in 1932 (in particular, US patent 1, 952,281) and they are implemented in practice, however, there is still no exact theoretical justification for the processes that occur.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method and installations for producing three types of energy (Potapov installations), providing high efficiency and having a simple design.

This problem is achieved in a method of producing energy, in which a mixture of liquid and gas under high pressure is supplied to the vortex generator through the mixture input means, the mixture flow is directed along a curved path around the axis of rotation with acceleration by centrifugal forces with the concentration of mixture molecules in the peripheral region of the stream, they direct the untwisted flow of the mixture into the holes of the rotor installed in the vortex formation device at an angle to their inner surface, whereby it is rotated produce energy. In this case, the liquid can be collected in the lower part of the vortex-forming device while maintaining its level below the rotor and recirculating the mixture and recovering energy.

In a preferred embodiment of the method, said mixture is fed to the rotor under a pressure of up to 2500 bar. It is most preferable to direct the mixture into the rotor holes at an angle of not more than 89 ° to their inner surface.

In a specific embodiment, the mixture is supplied under pressure to the vortex forming device by means of a pump through a fixed tangentially located nozzle.

A vortex heat generator can be installed in the vortex generating device, and the rotor holes are located in its peripheral part adjacent to the heat generator. In this case, the heat generator can serve as a means of additional heating of the mixture directed to the rotor, as well as a means of generating thermal energy.

In another specific embodiment, the recovery is carried out by draining the hot mixture to the pump.

Using this method, it is possible to obtain various types of energy (electrical, mechanical or thermal), depending on which means of consumption to put at the output of the device. Mechanical energy is obtained by connecting the rotor shaft with a means of consuming mechanical energy, for example, wheels, thermal energy with a means of consuming thermal energy, in a particular case it can be a heat convector. Electric energy can be obtained by connecting the rotor shaft to a means of consuming electric energy, in particular with electric motors or electrical devices.

An apparatus for producing energy is also proposed, comprising a vortex-forming device, a rotor with holes made around its circumference, mounted in a vortex-forming device with the possibility of rotation under the action of a previously swirling vortex flow of a mixture of liquid and gas, means for introducing the mixture into the vortex-forming device with the mixture directed to the rotor, means supplying the mixture under pressure associated with the means of introducing the mixture, means of energy recovery.

In a specific embodiment, the vortex generating device is a closed vortex chamber having an annular side wall, the means for supplying the mixture under pressure is a pump. Means for introducing the mixture are made in the form of nozzles located at least on two sides of the annular wall of the vortex chamber along a tangent line to it and connected at one end by pipelines, and at the other end having nozzles entering the vortex chamber and directed to the peripheral part of the rotor. Molecular energy recovery means include a conduit connecting the bottom of the chamber to the pump inlet. In a preferred embodiment, the rotor is made disk-shaped, and the holes (acting as blades) in the rotor are made in its peripheral part at an angle to the surface of the rotor disk, and the holes have a concave inner working part.

The rotor holes can be made cylindrical and at an angle to the surface of the rotor disk, so that the input and output parts of the hole have an elliptical shape, or have a variable cross-sectional size (for example, in the form of a nozzle). The elliptical shape of the inlet of the holes facilitates the capture and heating of the mixture molecules. Moreover, it is preferable if the holes in the rotor are located with the possibility of directing the mixture at an almost right angle to the holes of the rotor, which increases the torque by 2 times compared to feeding the mixture on a flat surface.

The installation may further comprise a vortex heat generator, including a housing, inside which is located the rotor, and having openings through which these nozzles pass, and an exhaust pipe for supplying heated water to the respective consumers or into the heat exchanger, and special recesses are made on the outer surface of the rotor and on the inner surface of the heat generator housing, which are located opposite each other with the possibility of sequential compression-expansion of the mixture passing through them .

In addition, the installation may further comprise a circulation pump, the inlet of which is connected to the lower part of the vortex chamber, and the outlet with a pipe, the end of which passes through the heat generator body into the zone of these recesses.

To obtain electrical and / or mechanical energy, the rotor shaft can be connected to an electric generator and / or means for consuming mechanical energy.

Due to the recovery of part of the energy of the mixture molecules, as well as giving additional acceleration to the mixture molecules due to heating and pulse injection, a significant increase in efficiency is possible.

Thus, the described vortex formation device, in particular in the form of a chamber with tangential flow inlet, is used in the present invention to increase and concentrate the kinetic energy of the molecules of a liquid and gas mixture by twisting them along a curved path with imparting directed motion and acceleration under the action of centrifugal forces and temperature, which allows to obtain mechanical and / or electrical and / or thermal energy from a molecular vortex flow. In this case, it is possible to increase the directional velocity of molecules more than 500 m / s due to heating, and the entire flow of the mixture can be the working fluid of the installation for the production of mechanical and / or electrical energy, and / or thermal energy, which is pre-twisted before converting the energy of the molecules into another type of energy, in particular mechanical, electrical or thermal energy. The possibility of obtaining energy from water and gas (air) molecules swirling with acceleration into a vortex stream was discovered by the author when he tried to understand the nature and cause of the enormous energy of such natural vortices as tornadoes and tornadoes. When conducting relevant experiments on various experimental installations it was unexpectedly found that when compressed water and air are supplied to the annular vortex chamber under high pressure by means of tangential entries for swirling the flow in the space of the vortex chamber, vortex movement along the ring inside the chamber is achieved with significant acceleration of molecules in the peripheral region of the flow and and the concentration of their kinetic energy, which can, for example, be converted into mechanical energy by sending accelerated molecules to the rotor turbine. In this case, it is possible to achieve unusually high efficiency of the device using the moment of inertia of the flywheel to generate energy. The data of the corresponding experiments are given below.

The process described above is given only in general terms for understanding the essence of the invention, and despite the apparent simplicity, in fact, it is very complex and currently not fully understood vortex process. Presumably, when the molecules twist along a curved path, their movement becomes less chaotic, and under the action of centrifugal forces and spontaneous heating, the molecules begin to accelerate in the direction of the vortex twist, which leads to an increase in centrifugal forces and further acceleration of the movement of the molecules (a kind of chain reaction: acceleration - increase in centrifugal force - increase in acceleration - even greater increase in centrifugal force, etc.). At present, it has become known and experimentally confirmed that the work of compressed air by 2-4 times can be more than the work spent on its compression (publications by Yu.I. Volodko, in particular, patent 2025572). In the experimental setup described below, an additional direction from the introduced flow, a side wall, and one of the end walls of the vortex chamber contribute to the additional direction of the resulting vector of molecular displacement and concentration of the kinetic energy of the molecules at one point. In this case, the acceleration of the molecules occurs in the direction left free for expansion (in the particular case, in the direction of exit from the holes in the rotor). It is possible that the additional acceleration of the molecules is also due to the action of electric repulsive forces arising from the approach (increase in concentration) molecules under the action of centrifugal force in the peripheral region of the flow, and is comparable in magnitude with the acceleration reported by centrifugal force. Moreover, since the centrifugal force is greater than the forces acting between the molecules, ordering of the movement of molecules with their direction along a certain vector and acceleration due to the kinetic and potential energy of the molecules is achieved, which allows you to convert the energy of the molecules into translational motion of the flow. Moreover, if in ordinary gas turbines gas molecules under high pressure hit the turbine blade at an angle of about 30 °, then in this invention it is possible to direct the mixture molecules to the holes acting as blades, at angles of about 89 ° to the corresponding inner surface (wall) of the holes . A vortex accelerates molecules by tens of times, accelerating them to huge speeds (possibly more than 200,000 rpm), which is not achieved in conventional gas turbines with vanes due to strength constraints. Moreover, in contrast to conventional turbines, where the pressure and density of the gas are mainly uniformly distributed in the turbine body, most of the mixture molecules in the vortex chamber are pressed against its walls, where their concentration may increase with a corresponding increase and concentration of their kinetic energy. When implementing the method, the environment inside the chamber is not uniform, both in temperature, pressure and density (grow with increasing distance from the axis of rotation), and in the direction of movement. An accelerating flow with the indicated concentrated kinetic energy of the molecules is discarded to the annular wall of the chamber and moves in a circle along the wall in the form of an annular flow with increased pressure and temperature (which additionally increases the kinetic energy of the molecules and their speed), with a decrease in pressure in the center down to vacuum as well as lowering the temperature. These processes make it possible to efficiently convert the energy of the molecules of the annular flow at the chamber wall into mechanical energy. A similar effect is not achieved in any of the known energy production or conversion plants that use swirling flow. In particular, in well-known centrifugal fans and compressors there is no free dispersal of air molecules under the action of centrifugal force, but only due to the movement of the blades.

Water and air are preferably used as the liquid and gas, but other liquids and gases or mixtures thereof supplied, in particular from the corresponding compressed gas reservoir or turbocharger, can also be used.

An important factor is the state of the mixture of water and air. preferably, if it is fed into the device under pressure up to 2500 bar.

The most preferred gas content in water is 5-10%. The vapor-air mixture is heavier than air and its use in the proposed engine is more efficient.

Inlet nozzles can be made in the form of means of preliminary (initial) acceleration of molecules, for example, in the form of Laval nozzles.

Obviously, the initial swirling of the flow can be carried out not only by tangential inputs, but also by other means of the initial swirling of the flow.

An annular (spherical) type of a vortex chamber with the same diameter along the axis of rotation seems to be the most preferable for this type of engine, but other options are also possible for it, for example, in the form of a cone tapering to the rotor, which will provide additional acceleration of the mixture molecules (however, in in case of using the engine in this design, the shoulder of the influence of the force of the mixture molecules on the rotor is reduced, which reduces the efficiency) The size (diameter) of the chamber can vary in a very wide range, the main thing here is to ensure the formation of a stable vortex.

As mentioned above, the holes in the rotor in the upper part can have special roundings in the form of recesses to hold the vortex flow, but it is also possible to use ordinary cylindrical holes made at an angle to the end surface. The mixture of water and air after performing work in this engine does not change its physico-chemical state and they remain environmentally friendly. Accordingly, the proposed method is clean and significantly different from burning fuel and other methods of obtaining energy. In addition, along with an increase in efficiency and simplification of the design, it is possible to note such additional positive effects of the invention as the possibility of reducing the mass and dimensions of the device, obtaining a different output power range, up to very high. Brief Description of the Drawings

In FIG. 1 shows a diagram of an installation for the production of electrical energy.

Figure 2 presents the diagram of the installation for the production of electrical and mechanical energy. In Fig. 3, an apparatus for producing electrical, mechanical and thermal energy is shown.

Figure 4 shows an embodiment of the rotor for the production of three types of energy.

Figure 5 presents a view A-A of figure 4. Figure 6 presents a view of B-B of figure 5.

7 shows a part of the rotor assembly with a heat generator.

Embodiments of the invention

In FIG. 1, an example is given of a preferred embodiment of a method and apparatus for generating electrical energy by rotating a rotor under vortex flow pressure. In this embodiment, the device includes an electric generator 1, a rotor 2 having cylindrical perimeter holes, an upper part 3 of the housing defining the interior of the vortex chamber at least from three sides, a lower part 4 of the housing in which the liquid 5 is placed, pump 6, support 7 for the casing and the pump, the outlet 8 of the outlet of the liquid-gas mixture connected to the inlet of the pump 6, pressure pipelines 9, extending from the outlet of the pump 6 and brought to the upper part 3 of the casing from its opposite sides, la (tips)

10 at the ends of pipelines 9, tangentially inserted into the housing, and bearings 1 1, in which the rotor shaft 2 is installed.

In FIG. 2 shows an example of obtaining, along with electric energy and mechanical energy, by adding a power take-off shaft 12, which can, in particular, be made as an extension of the rotor shaft 2. On Fig.3 shows a diagram of the simultaneous production of electrical, mechanical and thermal energy. To accomplish this, an additional circulation pump 13, an exhaust pipe 14, pipelines 15 of the circulation pump and a swirl heat generator 16 are installed. The inlet of the circulation pump 13 is connected to the hole in the lower part 4 of the housing, and the outlet with pipelines 15 passing through the lower and upper parts 3 of the vortex cameras and further through the body of the heat generator.

Figure 4-6 in an enlarged view shows part of the rotor 2, intended for the production of three types of energy. In the rotor 2 there are recesses 17 for interacting with the vortex heat generator, as well as cylindrical holes 18 with rounded recesses 19. The rotor 2 is mounted on the shaft of the electric generator 1 through the hole 20 and bolted through the holes 21. The rotor for installations without the heat generator (shown on figure 1 and 2) with the exception of the notches 17.

Fig. 7 shows a diagram of the rotor 2 assembled with a vortex heat generator 16, which has a housing (stator) 23 with fixing holes located along its perimeter 24. On the upper part (in Fig. 7 on the left) of the housing 23 of the vortex heat generator 16 there are recesses 22, the hole through which the pipe 15 (from the circulation pump 13) passes, and also the nozzle 10 is fixed for supplying a mixture of liquid and gas under pressure. On the lower part of the housing 23 of the vortex heat generator 16, likewise, there are recesses 25 and an opening through which the pipe 15 passes. A power take-off shaft 12 (and an electric generator 1 drive) is fixed to the rotor 2. Cylindrical holes 18 with recesses 19 are made on the rotor around its axis of rotation. The recesses 22 and 25 in the inner surface of the vortex heat generator 16 (stator) are made in two (as shown in the figures) or more rows in the same quantity as the recesses 17 of the rotor and are located opposite them. Nozzles 10 are installed tangentially (tangentially to the circumference of the vortex chamber) and at an angle from 10 ° to 89 ° to the inner surface of the holes in the rotor 2.

The presented installations work as follows.

To obtain electric energy, the pump 6 is turned on from the network and pressure is created in the pipelines 9. Through lugs 10, a jet of a mixture of liquid and gas is directly tangentially fed into the openings 18 of the rotor into the installation casing. A liquid with gas in a vortex flow untwists the rotor 2. When the required speed is reached, the electric generator begins to generate an electric current. Liquid 5 is collected in the lower part 4 of the installation housing and recycled. From the circulation pump 13, which reduces the current consumption due to heating of the liquid and lowering its viscosity, the liquid is supplied through pipelines 15 to the working area of the vortex heat generator 16 to the recesses 17. In the recesses, the mixture is sequentially compressed and expanded, which causes it to heat due to known phenomena (friction, cavitation and compound (synthesis) of water molecules into clusters). The liquid level 5 in the lower part of the housing of the vortex chamber is maintained below the rotor and is fed from the outside as necessary.

Further, part of the obtained electric energy is recovered, feeding it from the generator 1 to the electric motor (not shown) of the pump 6, and the rest is sent to the consumer.

The receipt of mechanical energy is possible from the power take-off shaft 12 by connecting it to the corresponding known means consuming mechanical energy. Moreover, given that the rotor 2 is simultaneously a flywheel, then to ensure the operation of the installation, pulse switching of the pump 6 is possible.

Installation of the vortex heat generator 16, the circulation pump 13 with pipelines 15 for supplying the mixture to the working area of the vortex heat generator 16 provides additional thermal energy. In this case, the start-up of the installation is similar to the method for producing electric energy described above.

Thus, the inventive method and device allows to produce three types of energy (electrical, mechanical and thermal) in an environmentally friendly way without burning traditional fuel and without violating the law of conservation of energy, since the kinetic and potential energy of the molecules and the moment of inertia of the flywheel-rotor 2 are used. The method of maintaining the installation in continuous operation with the recovery of water, air and electrical energy allows up to 30% of the received electrical use energy for own needs, and give up to 70% to the consumer. At the same time, cascade use of the same devices is possible, which will further increase their efficiency and power. Given that the device consists of a small number of parts, the reliability of such a machine increases dramatically. The estimated service life can reach 65,000 hours or more, and the service life of up to 30 years when replacing the bearings of an electric generator.

Example 1

A device was made, including an electric generator 1, a rotor 2 having a diameter of 300 mm, with sixteen cylindrical holes 18, a housing with an upper part 3 and a lower part 4, forming a container for a mixture of 5 water with air (water contained about 8% air), pump 6 with a power of 2.7 kW, support 7, an outlet 8 in the lower part 4 of the housing for supplying the mixture to the pump inlet 6, pipelines 9 extending from the pump outlet 6, nozzle 10, bearings 1 1 for supporting the shaft leading to the generator one.

At the beginning, they started pump 6 by applying electric current to it from an external network with a voltage of 220 V and a frequency of 50 Hz. The pump used created a pressure of 170 bar. The resulting stream of water with air was directed through the nozzles 10 at an angle to the cylindrical holes 18. At high pressure, the mixture heats up, and when passing through the nozzles 10 they exit with the formation of a gas-water mixture in the form of fog, in which rotor 2 rotates, acting as a turbine. When observing through the viewing window inside the camera, it was possible to observe that the rotor 2 rotates in a vaporous atmosphere. Rotor 2 reached a speed of 5400 rpm in 27 seconds. After that, the electric generator was loaded. In this case, the revolutions were reduced to 3000 rpm and the power supply of the pump 6 was switched to power from the electric generator 1. At a rotor speed of 3000 rpm, the recoil force at the nozzle 10 was 27 H. Thus, the device power was obtained, which can be calculated by the formula : N _e = (M _cr -n) / 9554 = (27-3000) / 95554 = 8.48 kW

Of these 8.48 kW, 2.7 kW was spent on own needs, and 5.78 kW went to the consumer. Example 2

Operations were performed and an installation similar to those described in Example 1 was used, but a power take-off shaft 12 was installed behind the electric generator 1, through which another pump was rotated. 2.5 kW was spent on these needs and 3.28 kW of electric energy remained for consumers.

Example 3

Operations were performed and an installation similar to those described in Example 1 and 2 was used, but an additional circulation pump 16 with a power of 90 W was connected and a vortex heat generator 16 was used. The liquid passing through the recesses 17, 22 and 25 quickly heats up. 2.27 kW was spent on heating the liquid. The remaining electrical energy went to consumers.

The results obtained indicate that the vortex method of obtaining electrical mechanical and thermal energy allows more work than it is spent on compression, the possibility of which, as noted above, is known to specialists.

In addition, recovery of the working medium and electric energy is used, which also reduces the energy consumed for the device’s own needs.

In practice, the use of the proposed method and device will reduce the amount of fuel burned and will improve the current environmental situation.

Claims

Claim

1. A method of producing energy, in which a mixture of liquid and gas under high pressure is supplied to the vortex generator through the mixture input means, direct the mixture flow along a curved path around the axis of rotation with acceleration by centrifugal forces with the concentration of the mixture molecules in the peripheral region of the stream, direct the untwisted the flow of the mixture into the holes of the rotor installed in the vortex forming device at an angle to their inner surface, whereby it is rotated to produce energy.

2. The method according to claim 1, characterized in that the liquid is collected at the bottom of the vortex formation device while maintaining its level below the rotor, the mixture is recycled and energy is recovered.

3. The method according to claim 2, characterized in that the mixture is fed to the rotor under a pressure of up to 2500 bar.

4. The method according to p. 3, characterized in that the mixture is directed to the holes in the rotor at an angle of not more than 89 ° to their inner surface.

5. The method according to claim 4, characterized in that the supply of the mixture under pressure into the vortex formation device is carried out by means of a pump through stationary tangentially located nozzles.

6. The method according to claim 5, characterized in that the vortex heat generator is installed in the vortex generator, and the rotor holes are located in its peripheral part adjacent to the heat generator, with the possibility of additional heating of the mixture directed to the rotor.

7. The method according to claim 6, characterized in that the recovery is carried out by removing the hot mixture to the pump.

8. The method according to claim 1, characterized in that the rotor shaft is connected to a means of consuming mechanical energy and / or to a means of consuming thermal energy and / or to a means of consuming electric energy.

9. Installation for generating energy, containing a vortex formation device, a rotor with holes made around its circumference, mounted in a vortex formation device with the possibility of rotation under the action of a previously swirling vortex flow of a liquid mixture and gas, means for introducing the mixture into the vortex forming device with the mixture directed to the rotor, means for supplying the mixture under pressure, associated with means for introducing the mixture, means for energy recovery.

10. Installation according to claim 9, characterized in that the vortex forming device is a closed vortex chamber having an annular side wall, the means for supplying the mixture under pressure is a pump, the means for introducing the mixture are made in the form of nozzles located on at least two sides of the annular walls of the vortex chamber along a tangent line to it and connected at one end by pipelines, and at the other end having nozzles entering the vortex chamber and directed to the peripheral part of the rotor, means of recovery ergii molecules include a conduit connecting the lower portion of the chamber to the inlet of the pump.

1 1. The installation according to claim 10, characterized in that the rotor is made disk-shaped, and the holes in the rotor are made in its peripheral part at an angle to the surface of the rotor disk, and the holes have a concave inner part.

12. The installation according to claim 11, characterized in that it further comprises a vortex heat generator, including a housing, inside which the rotor is located, and having holes through which these nozzles pass, and an exhaust pipe, moreover, on the outer surface of the rotor and on the inner surface of the housing the heat generator made recesses located opposite each other with the possibility of sequential compression-expansion of the mixture passing through them.

13. Installation according to claim 12, characterized in that it further comprises a circulation pump, the inlet of which is connected to the lower part of the vortex chamber, and the outlet with a pipe, the end of which passes through the body of the heat generator into the zone of these recesses.

14. Installation according to item 13, wherein the rotor shaft is connected to an electric generator and / or means for consuming mechanical energy.