RU2240435C2 - Energy generating system (versions) - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: proposed energy generating system has heating furnace with ion burner arranged in vertical cylindrical channel including lower and upper holes, great number of movable blades and electric generator arranged out of the channel. Ion burner increases temperature and concentration of ions in heating furnace and, as a result, gas rises in form of vortex ascending flow and rotates great number of movable blades secured on corresponding rotation shaft connected with energy generator shaft.

EFFECT: provision of reliable generation of energy.

18 cl, 7 dwg

Description

Technical field

The invention relates to a system for generating energy, in which electricity is generated from the energy of an artificially created continuous vortex upward flow.

State of the art

Known systems for generating energy, such as a thermal energy generating system, a nuclear energy generating system, a hydropower generating system, and the like. Although these systems are similar in that electricity is generated by rotating the turbine of an energy generator, they use different energy sources to rotate the turbine. In thermal systems, steam is generated to generate energy by burning heavy diesel fuel or other fuel, and the turbine rotates due to steam energy. In nuclear systems to generate energy, although the turbine rotates due to the energy of steam, steam is generated due to the heat released during nuclear fission. In hydraulic systems, a turbine rotates due to the energy of water falling from an elevated place. In addition to the above systems, there is a wind system for generating energy that uses wind energy, or a system in which electricity is generated through a chemical reaction between hydrogen and oxygen, and the like.

As the closest technical solution should indicate the system for generating energy disclosed in patent JP 61-085588, containing a vertical cylindrical channel having a height of several hundred meters, containing an air inlet made in the lower part of the cylindrical channel, a gas outlet made in the upper part of the cylindrical channel, a turbine located in the channel and an energy generator having a plurality of blades (fan) attached to a corresponding rotating shaft are connected nom with the shaft of an energy generator located in a cylindrical channel.

Summary of the invention

The basis of the present invention is the task of creating a system in which energy is generated by means of energy different from that used in conventional systems to generate energy and, in particular, in which rotating blades are driven by an artificially created continuous vortex upward flow (artificial tornado) , and the energy generator is driven by the obtained rotation force to generate energy.

A natural tornado is generated as follows. When the (ionized) air, the specific gravity of which is reduced by heating by the sun's rays or otherwise heated, rises, creating an upward flow, then since the atmospheric pressure in it decreases, this creates low pressure, air flows into the upward flow, excluding the difference pressure. In this case, since cold air tends to flow into the warm air surrounding the air, which is colder than the ascending (rising) air heated by the heat of sunlight or other heat, flows into the upward flow, thereby forming a vortex flow. Immediately after the formation of the vortex flow, since the additional air flows into the vortex stream in a vortex manner, the rotation force gradually increases, eventually forming a tornado.

If the temperature difference between the upward flow and the ambient air flowing into the upward flow is small, then, since the vortex flow is formed at a relatively low height, this vortex flow increases, as a result of which low pressure is created in the center of the vortex flow, and thus a typhoon is formed.

In an energy generating system according to the invention, an artificial tornado is created by using the principle of forming a natural tornado or typhoon, and the energy is generated from the energy of an artificial tornado. More specifically, according to the present invention, the task is solved as follows.

According to one aspect of the present invention, there is provided a system for generating energy, comprising a cylindrical channel having a height of several hundred meters, comprising an air inlet made in the lower part of the cylindrical channel, a gas outlet made in the upper part of the cylindrical channel, a plurality of movable blades, attached to a corresponding rotating shaft connected to the shaft of an energy generator located in a cylindrical channel, according to the invention, a system of holds a heating furnace having a peripheral wall formed of refractory materials and placed in a cylindrical channel, a flap for opening and closing the inlet, an ion burner and a discharge electrode, designed to increase the temperature and concentration of ions inside the heating furnace to the levels required for the formation of a vortex ascending flow, while the ion burner contains a nozzle for spraying fuel, which is used as kerosene, a metal powder mixed with oil a product, and water, which are supplied from a fuel supply device that contains a metal fuel supply device provided with a positive electrode and a negative electrode, so that when generating an electric discharge between the indicated electrodes, the metal powder particles formed on the positive electrode enter kerosene, kerosene hydrocarbon carbon is precipitated, metal powder adheres to carbon to form an oil product, the temperature and ion concentration in the heating furnace increased they are heated to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the cylindrical channel in the form of a vortex upward flow, a plurality of movable blades located above the heating furnace attached to a corresponding rotating shaft connected to the shaft of the energy generator located outside a cylindrical channel is driven into rotation by this vortex upward flow. According to another aspect of the present invention, the proposed system for generating energy, containing a cylindrical channel having a height of several hundred meters, containing an air inlet made in the lower part of the cylindrical channel, a gas outlet made in the upper part of the cylindrical channel, many movable blades, attached to a corresponding rotating shaft connected to the shaft of an energy generator located in a cylindrical channel according to the invention, a system contains a heating furnace having a peripheral wall formed of refractory materials and placed in a cylindrical channel, a damper for opening and closing the inlet, an ion burner designed to increase the temperature and ion concentration inside the heating furnace, a particle accelerator for the heating furnace to maintain the ion concentration in heating furnace or increasing the concentration of ions, and the temperature and concentration of ions in the heating furnace is regulated to form a vortex upward flow, while the ion burner contains a nozzle for spraying fuel, which is used kerosene, metal powder mixed with oil, and water, which are supplied from a fuel supply device that contains a metal fuel supply device equipped with a positive electrode and a negative electrode, so that when generating an electric discharge between the indicated electrodes, the particles of metal powder formed on the positive electrode enter kerosene, ker aspen precipitates carbon hydrocarbon, metal powder adheres to carbon to form an oil product, the temperature and concentration of ions in the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the cylindrical channel in the form of a vortex upstream above the heating furnace, a plurality of movable blades attached to a corresponding rotating shaft connected to a shaft of an energy generator located outside the cylindrical channel, it is driven into rotation by this vortex upward flow.

According to a third aspect of the present invention, there is provided a system for generating energy, comprising a cylindrical channel having a height of several hundred meters, comprising an air inlet made in the lower part of the cylindrical channel, a gas outlet made in the upper part of the cylindrical channel, a plurality of movable blades, attached to a corresponding rotating shaft connected to the shaft of an energy generator located in a cylindrical channel, according to the invention, a system with will have a heating furnace having a peripheral wall formed of refractory materials and placed in a cylindrical channel, a flap for opening and closing the inlet, an ion burner and a discharge electrode, designed to increase the temperature and concentration of ions inside the heating furnace to the levels required for the formation of a vortex ascending flow or ion burner and discharge electrode are designed to maintain the concentration of ions in a heating furnace or increase the concentration of ions by increasing the number of ions, a particle accelerator for the heating furnace to maintain the concentration of ions in the heating furnace or increasing the concentration of ions, while the ion burner contains a nozzle for spraying fuel, which uses kerosene, metal powder mixed with oil, and water, which are supplied from a fuel supply device that comprises a metal fuel supply device provided with a positive electrode and a negative electrode, so that when generating discharge between the indicated electrodes, metal powder particles formed on the positive electrode enter kerosene, hydrocarbon carbon is deposited in kerosene, metal powder adheres to carbon to form an oil mixed with metal powder, the temperature and concentration of ions in the heating furnace increase to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the cylindrical channel in the form of a vortex ascending eye located above the heating furnace plurality of movable blades that are attached to the respective rotating shaft connected to the shaft of a power generator located outside of the cylindrical channel is driven to rotate by this vortex riser.

According to a fourth aspect of the present invention, there is provided a system for generating energy, comprising a cylindrical channel having a height of several hundred meters, comprising an air inlet made in the lower part of the cylindrical channel, a gas outlet made in the upper part of the cylindrical channel, a plurality of movable blades, attached to a corresponding rotating shaft connected to the shaft of an energy generator located in a cylindrical channel according to the invention of systems contains a heating furnace having a peripheral wall formed of refractory materials and placed in a cylindrical channel, a flap for opening and closing the inlet, an ion burner and a discharge electrode, designed to increase the temperature and concentration of ions inside the heating furnace to the levels required for the formation of a vortex ascending flow or ion burner and discharge electrode are designed to maintain the concentration of ions in a heating furnace or increase the concentration of ion in by increasing the number of ions, a particle accelerator for the heating furnace to maintain the concentration of ions in the heating furnace or increasing the concentration of ions, while the ion burner contains an ion generator that contains a nozzle for spraying fuel, which uses kerosene, a metal powder mixed with oil and water that is supplied from a fuel supply device that comprises a metal fuel supply device provided with a positive electrode and a negative electron Thus, when generating an electric discharge between the indicated electrodes, the metal powder particles formed on the positive electrode enter kerosene, hydrocarbon carbon is deposited in kerosene, the metal powder adheres to carbon to form an oil mixed with metal powder when the positive electrode becomes shorter when discharge and separation of metal particles, the positive electrode is automatically fed into the container with a kerosene device automatically th feed, during the reproduction of ions in the ion generator, the cations and anions are vibrated and accelerated to increase the number of cations and anions, the temperature and concentration of ions in the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises a cylindrical channel in the form of a vortex upward flow, a plurality of movable blades located above the heating furnace attached to a corresponding rotating shaft connected to The scar of the energy generator located outside the cylindrical channel is driven into rotation by this vortex upward flow.

It is advisable that the system for generating energy contained at least two axial fans located in the cylindrical channel, and at least two energy generators for working with axial fans located outside the cylindrical channel, while the rotor blades of the axial fans rotate between stationary blades, installed in a cylindrical channel.

It is useful that the system for generating energy additionally contains an additional ion burner located in the upper part of the cylindrical channel and designed to re-heat the gas flowing through the cylindrical channel to accelerate the release of the vortex upward flow through the gas outlet.

Preferably, in the system for generating energy, the temperature and concentration of ions inside the heating furnace is increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel through the inlet is understood in the channel as a vortex upward flow, and axial fans are driven into rotation by this whirlwind, and energy generators are driven by rotation of the axial fans, to generate electricity, and when the temperature and The concentration of ions inside the heating furnace reaches predetermined levels using an ion burner, the latter is temporarily turned off, and then only the discharge electrode is activated to maintain the temperature or concentration of ions inside the heating furnace and, if the temperature or concentration of ions decreases below a predetermined level, again an ion burner is activated to increase the temperature and concentration of ions inside the heating furnace to predefined levels and by repeating the temporary shutdown of the ion burner, activating only the discharge electrode and re-activating the ion burner, the temperature and concentration of ions inside the heating furnace are maintained at the level suitable for the formation of a vortex upward flow.

Brief Description of the Drawings

The invention is further explained in the description of the preferred options for its implementation with reference to the accompanying drawings.

Figure 1 depicts schematically a system for generating energy (first embodiment), according to the invention;

figure 2 - diagram of the ion-flame generator of the ion burner used in the system for generating energy according to the invention;

figure 3 - diagram of the ion breeder of the ion burner according to the invention;

4 is a diagram of the installation of a fuel nozzle in an ion-flame generator according to the invention;

5 is a fuel nozzle (longitudinal section), according to the invention;

6 is a diagram of a device for supplying fuel mixed with metal powder, according to the invention,

7 is an embodiment of the use of a system for generating energy according to the invention.

Description of Preferred Option

the implementation of the invention

The system for generating energy according to the invention comprises a heating furnace 5 (FIG. 1) having ion burners 2, discharge electrodes 3 and particle accelerators 4 mounted in the intermediate part of cylinder 1 having an internal diameter of about 3 m and a height of about 300 m. Cylinder 1 and the heating furnace 5 has a vertical support in the form of a frame 6. In this case, the upper part of the upper cylindrical part 7 of the cylinder 1 above the heating furnace 5 protrudes outward from the frame 6.

A gas inlet 9 is made at the lower end of the lower cylindrical part 8 of cylinder 1 below the heating furnace 5, and an axial fan 10 is located inside the lower cylindrical part 8. At the upper end of the upper cylindrical part 7 of cylinder 1 above the heating furnace 5, a gas outlet 11 is made . Two axial fans 12, 13 are located inside the upper cylindrical part 7, and ion burners 2 are installed on the upper part of the upper cylindrical part 7. Rotating shafts 20, 21, 22 are connected to the rotating shafts 14, 15, 16 of the three axial fans 10, 12, 13 generators 17, 18, 19, respectively.

The frame 6 is made in such a way that four racks 23, each of which is obtained by interconnecting the required number of prismatic metal pipes with a size of 300 mm × 300 mm and a thickness of 10 mm, are mounted vertically on a concrete base, forming a truncated pyramid. Four racks 23 are connected by metal connecting elements 24 at five points of each rack in the vertical direction, and metal reinforcing elements 25 are connected between the lower ends of the racks 23 and the lowermost metal connecting elements 24. Additional metal reinforcing elements 25 are connected at an angle between the heating furnace 5 and the third (bottom) metal connecting elements 24. The height of the frame 6 is chosen equal to approximately 320 m, taking into account the height of the cylinder 1. Cylinder 1 may have an inner an early diameter of 3 m or more and a height of 300 m or more, in which case the height of the carcass 6 increases accordingly.

In the system for generating energy according to the invention, an artificial whirlwind is generated in the inner space (channel) of the cylinder 1 by increasing the temperature and ion concentration inside the heating furnace 5 by intermittent or continuous operation of the ion burners 2, discharge electrodes 3 and particle accelerators 4. Vortex upward flow hits the axial fan 10, located below the heating furnace 5, and the axial fans 12, 13, located above the heating furnace 5, thereby turning the axial fans 10, 12, 13, and energy generators 17, 18, 19 connected to the corresponding axial fans 10, 12, 13, and due to rotation are driven to generate electricity.

Molded refractory materials (for example, a mixture of refractory filler and alumina cement or a substance that hardens in water, such as phosphoric acid) are used in the peripheral wall of the heating furnace 5. On the peripheral wall at equal distances from each other in the circumferential direction there are three ion burners 2 (only two of them are shown in FIG. 1) having a calorific value of about 100 × 10 ⁴ KS. The distal ends of the three ion burners 2 are directed towards the center of the heating furnace 5, so that loud combustion sounds caused by the explosive nature of combustion (burning occurs at a speed of 13-15 m / s) and emitted by the corresponding ion burners 2, “collide” with each other, reducing total noise due to the suppression of sound waves and the Doppler effect caused by the "collision" of sound waves.

Each ion burner is made by a combined ion breeder 31 (FIG. 2) (FIG. 3) with an ion-flame generator 30 consisting of a turbofan 26, an electric motor 27, an axial compressor (turbine) 28 driven by an electric motor 27, and a generating part 29 ion flame. The turbofan 26 is used for air intake and air supply to the turbine 28. The turbofan 26 is equipped with an air control valve 32, so that the volume of intake air is regulated by adjusting the degree of opening of the air control valve 32 to regulate the amount of air supplied to the turbine 28. In the turbine 28 to the shaft 33, driven by an electric motor 21, movable vanes 34, a compression blade 35 and a distribution blade 36 are attached. When the movable vanes 34, 35 rotate inside the fixed stationary vanes 37, the air supplied by the turbofan 26 is compressed and injected into the ion flame generating part 29. The injected air is moved by the distribution blade 26 to ensure uniform pressure, and then sent to the five fuel injectors 38 of the ion generating flame portion 29.

In the ion flame generating part 29, the cylindrical body 39 is made of ferromagnetic metal (such as iron, nickel or cobalt), and five fuel nozzles 38 are located inside the cylindrical body 39 (FIG. 4), and material 40 is placed in front of the fuel nozzles 38 having a substantially cylindrical shape, ionizing upon contact with the flame (figure 2). Around the cylindrical body 39 is fixed an electromagnetic coil 41 having an iron core. Fuel nozzles 38 are fixed inside the cylindrical body 39 by means of a metal plate 42 shown in FIG.

In the fuel nozzle 38 (FIG. 5), an air injection nozzle 46 made of non-magnetic metal, having a diameter of 1-2 mm, is under high pressure (about 15 kg / cm ² ) and a nozzle 47 for dropping fuel is made of non-magnetic metal ( kerosene, a petroleum product mixed with metal powder, or water) is inserted inside and fixed inside a cylindrical body 45 made of non-magnetic material (such as brass, stainless steel, etc.), in its rear end portion. The inner peripheral surface of the distal (front) end 48 of the cylindrical body 45 is beveled or bore outward, the angle (θ) of the body is 40-60 degrees, the length (d) of the cone is 10-15 mm. About fifteen to twenty slots 49 are formed in the outer peripheral surface of the rear end portion of the cylindrical body 45, each of which has a width of 1.5-2 mm, and the angle (φ) of the beveled end of each slit 49 is selected to be 45 degrees. The nozzle 47 for the fuel drip feed is inserted into the cylindrical body 45 through one of the slots 49. The inner diameter (s) of the cylindrical body 45 is 35-45 mm, and the total length (a + b + d) is 170-215 mm, while ( a) is 160-200 mm, and (b) is 50-60 mm. In addition, the drip feed nozzle 47 is provided with a stirrer 50 for mixing the fuel feed. The mixer 50 is used to mix fuel by rotating a spiral rotating blade 51 by means of an electric motor 52.

In the fuel injector 38, fuel supplied in droplets from a fuel drip nozzle 47 is atomized by air into small particles having a diameter of 0.01 μm or less. Moreover, the first air stream having a high speed is directed from the turbine 28 located at the rear, and the second air stream under high pressure is injected from the nozzle 46 for injecting air. Then, fuel is injected into the distal end portion 48. In the fuel nozzle 38, due to the presence of a cone on the distal end portion 48, the atomized fuel is immediately injected smoothly without again becoming liquid, thereby achieving high atomization efficiency.

Material 40, ionized in contact with the flame, is made by crystallizing a mixture of a photoactive substance and a magnetic substance in an oxidizing medium. The photoactive substance can be monomeric, such as selenium, cadmium, titanium, lithium, barium or thallium, or a compound, such as their oxide, sulfide or halide, and the magnetic substance can be a ferromagnetic substance, such as iron, nickel, cobalt or their compounds ), or a paramagnetic substance, such as manganese, aluminum, tin or their compounds, or a diamagnetic substance, such as bismuth, phosphorus, copper, calcium or their compounds.

An electromagnetic coil 41 (FIG. 2) is formed by fastening a coil 53 of copper wire with an iron core 54. When a pulsed current is supplied from the power supply to the electromagnetic coil 41, a strong high-frequency magnetic field is generated inside the coil, which strongly magnetizes the cylindrical body 39 of part 29, generating an ion flame. A high-frequency magnetic field has, for example, a magnetic flux density of 10,000 or more and a frequency of about 20-50 MHz. The cylindrical body 39, magnetized by the electromagnetic coil 41, generates a high-frequency magnetic field inside to activate the material 40, which is ionized in contact with the flame. In this case, the hydrocarbon flame in contact with the material 40, which is ionized in contact with the flame, changes and becomes an ion flame containing many cations (carbon ions, hydrogen ions, iron ions, etc.) and anions (oxygen ions). Upon activation of the material 40, ionized in contact with the flame, although the atomized fuel burns out only by contact with the material ionized in contact with the flame, the material 40 is provided with an ignition electrode 55 to increase the probability of ignition.

In the ion breeder 31 (FIG. 3), the cylindrical body 60 is made of alternating interconnected rings 61 of non-magnetic metal, such as brass, stainless steel, etc., and rings 62 of ferromagnetic metal, such as iron, nickel, cobalt etc. Three electromagnetic coils 63 are fastened around ferromagnetic metal rings 62. Each electromagnetic coil 63 is made by winding an insulated copper wire 65 around a corresponding ferromagnetic metal ring 62 and insulating paper 64 between them, and winding a cooling copper tube 66 around the wire 65 and insulating paper 64 between them, as well as winding metal coating 67 around the tube 66 and insulating paper 64 between them. Moreover, each electromagnetic coil 63 is rigidly attached to the outer flange 68 of the cylindrical body 60 so that there is no shift under the action of the generated magnetic force or oscillations of the ion burners 2.

The insulated copper wire 65 of each electromagnetic coil 63 is connected to a power source (not shown), W receives a large pulse current from the power source. When a large pulse current is applied, the electromagnetic coil 63 generates a strong high-frequency magnetic field inside itself, so that the ferromagnetic metal ring 62 is highly magnetized in this strong high-frequency magnetic field, as a result of which a strong high-frequency magnetic field is created inside the magnetized ring 62 of the ferromagnetic material. Strong high-frequency magnetic fields inside rings 62 of ferromagnetic material cause ion vibrations in the ion flame generated by the ion flame generating part 29 and accelerate cations towards the flame inlet and the anions toward the ion generating part 29. These fields increase the number of cations and anions, while simultaneously promoting the elastic collision of these cations and anions with other particles (ionized particles and non-ionized particles). In addition, due to the alternating arrangement of rings 62 of ferromagnetic material and rings 61 of non-magnetic material, stepwise restrictions are imposed on the ion flame (self-constriction effect), and the compressed cation flame is introduced into the heating furnace 5. In this case, the anion flame is introduced in the direction of the generating part 29 ion flame.

The cooling copper tube 66 of each electromagnetic coil 63 is connected to a cooling device (not shown) so that cooling water can flow through the cooling copper tube 66 to cool the electromagnetic coil 63. Although the electromagnetic coil 63 is heated to high temperature by heat from an insulated copper wire 65 ( which flows a large current) and heat from the internal ion flame, cooling water prevents the coil from overheating. The electromagnetic coil 63 can be cooled with water, other cooling agents, or using a forced cooling system.

Although an example has been explained that the high frequency magnetic fields generated by the multi-stage electromagnetic coils 63 are used in the ion breeder 31, a strong electric field can be generated in the aforementioned ion flame generator 30, making it possible for the ions to vibrate and accelerate inside the cylindrical body 60 of the ion breeder 31.

A nozzle 47 (FIG. 5) for a drip fuel supply of an ion-flame generator 30 can receive fuel through a pipe from a fuel supply device 70. The fuel supply device 70 includes a kerosene supply device 71, a water supply device 72 and a fuel (oil product) supply device 73 mixed with metal powder. The kerosene supply device 71 is a kerosene storage tank, and the water supply device 72 is a water storage tank.

In the device 73 (FIG. 6) for supplying fuel mixed with metal powder, a cylindrical negative electrode 75 made of conductive metal is attached vertically to the center of the bottom of the kerosene tank 74 made of insulating material, and the positive electrode rod 76 made of a cylindrical iron rod, and a positive electrode rod 76 made of a cylindrical aluminum rod, are located near the negative electrode 75. The electrodes 75, 76 are connected to a high voltage source 78, so a high voltage can be applied between the electrodes 75 and 76, for example 30000-100000 V. When a discharge is generated between the electrodes 75 and 76 in the fuel supply device 73 mixed with metal powder, a voltage is applied between the negative electrode 75 and the positive electrode 76 made of iron or aluminum, iron powder or aluminum powder in the form of small particles (less than 0.5 mm) is removed from the surface of the positive electrode 76 and discharged into kerosene. In this case, carbon hydrocarbon precipitates in kerosene, while the iron or aluminum powder adheres to the precipitated carbon, which leads to the mixing of the metal powder with kerosene and thereby an oil product is mixed with the metal powder. If necessary, a surfactant can be added to the oil mixed with metal powder. In this case, the oil mixed with the metal powder can be stored for a relatively long period. However, the surfactant used should not impede combustion.

Both positive electrode rods 76 are inserted horizontally into the tank 74 through insert holes formed on both sides of the tank 74. Packing elements 79 are provided in the insert holes for holding the inserted positive electrode rods 76 to remove them and also to prevent liquid leakage. The insertion length of each positive electrode rod 76 into the tank 74 can be adjusted using an automatic feeding mechanism 80 (electrodes moving device), so that the distance between the distal end of the positive electrode rod 76 and the distal end of the negative electrode 75 can be adjusted to facilitate discharge. When the distal end of the positive electrode rod 76 is shortened, the automatic feeding mechanism 80 automatically feeds the positive electrode rod 76 outward towards the negative electrode 75, thereby always maintaining a constant distance between the distal ends of the electrodes 75 and 76. The feed amount of the positive electrode rod is controlled by automatic feeding mechanism 80, can be implemented, for example, by measuring the distance between the electrodes 75 and 76 with Strongly optical sensor outside the tank 74, or by the operative control potential or electrical current between the electrodes for generating proper discharge or by the preliminary search speed of the electrode decreases due to discharge and defined as the decreasing quantity per unit time.

Since it is possible to achieve an effective discharge between the electrodes 75 and 76, the above example is not restrictive for the negative electrode 75 and the positive electrode rods 76. For example, one of the electrodes 75, 76 or both the electrode 75 and the electrodes 76 can be made in the form of a prismatic element. In addition, the voltage or electric current applied between the electrodes 75 and 76 can be set in accordance with the configuration of the negative and positive electrodes 75, 76 and / or the distance between these electrodes and / or the material of these electrodes.

Tank 74 is equipped with an on-line fuel volume control device (not shown) for measuring the volume of fuel inside the tank and preventing the negative electrode 75 and positive electrodes 76 from protruding upward from the liquid level. If the fuel is consumed so that its volume becomes less than a certain predetermined value, the device for operational control of the fuel volume replenishes the fuel or informs the operator of such a fact. Due to the presence of a device for operational control of the fuel volume, it is possible to prevent the occurrence of a discharge in a state where the electrodes protrude above the liquid level, thereby preventing the ignition of kerosene and, therefore, preventing fire and explosion in the tank 74.

A mixing device 81 is located on top of the tank 74. The mixing device 81 comprises an electric motor 82, an impeller 83 driven by the rotation of the electric motor 82, and serves to mix kerosene in the tank 74 by means of the impeller 83. The speed of the impeller 83 can be set appropriately.

The kerosene feed device 71 shown in FIG. 5 may be provided with a cracking device. The cracking device is used to decompose a heavy oil product having a high boiling point, to obtain a light oil product having a low boiling point (gasoline, etc.). For example, as a cracking device, a contact decomposition device using a catalyst in the form of silica and / or alumina, or a thermal decomposition device designed to decompose at a high temperature (800-850 ° C) without a catalyst, or a device can be used for decomposition by hydrogenation, intended for decomposition using a catalyst in which the carrier of nickel or tungsten is silica and / or alumina, and using hydrogen under high by pressure. A cracking device is effective, in particular when, instead of kerosene, a fuel having a high boiling point, such as heavy diesel fuel, is used.

One of the fuels or the desired combination of fuels can be fed from the feeders 71, 72, 73 to the nozzle 47 for the drip supply of fuel through the fuel switches. For example, it is possible to supply only kerosene until the temperature reaches 1800 ° C after starting the device 30 generating the ion flame, and then it is possible to supply the oil mixed with the metal powder until the temperature reaches 2500 ° C, and after this, it is possible to supply an oil product mixed with metal powder and water. Thus, it is possible to select a suitable fuel and supply it in accordance with the combustion temperature.

The discharge electrodes 3 (Fig. 1) are located above the ion burners 2 opposite each other on the peripheral wall of the heating furnace 5. The discharge electrodes 2 are connected to power sources (not shown), so that the temperature inside the heating furnace 5 heated by the ion burners 2 can be maintained due to the formation of a discharge between the electrodes by applying voltage to these electrodes.

In addition, four particle accelerators 4 are provided on the peripheral wall of the heating furnace 5. Particle accelerators 4 serve to maintain the concentration of ions inside the heating furnace 5 or to increase the number of ions and thereby increase the concentration of ions. As an accelerator of 4 particles, you can use a betatron, cyclotron or synchrotron. In a betatron, the electrodes in the toroidal vacuum chamber are accelerated by applying an alternating magnetic field, so that the concentration of ions inside the heating furnace 5 can be increased by releasing accelerated electrons into the heating furnace 5. In a cyclotron, charged particles are re-accelerated by a high-frequency electric field having an oscillation parameter in a cyclotron corresponding to circular motion having a predetermined period and occurring under the action of the Lorentz force in a magnetic field current, due to which particles with high energy are obtained, and the concentration of ions inside the heating furnace 5 is increased by releasing such particles with high energy into the heating furnace 5. The synchrotron is an accelerator in which the upper energy limit of the aforementioned cyclotron is exceeded and in which along a circular path having a predetermined radius, electromagnets are arranged to increase the magnetic flux density, as a result of which the particle velocity increases.

The gas inlet opening 9 of the cylinder 1 is provided with a shutter so that when the temperature and concentration of ions inside the heating furnace 5 exceed a predetermined limit (for example, the temperature should be from 1800 ° C to 3500 ° C, and the ion concentration should be in the range of 30% up to 80%), gas (atmospheric air) can be introduced into cylinder 1, opening the damper. In addition, the volume of gas introduced can be adjusted by changing the degree of opening of the valve. In addition, the lower end of the gas inlet 9 is extended downward from the valve, so that when the valve is opened, atmospheric air can smoothly enter the cylinder 1. A metal mesh is attached to the lower end of the air inlet 9 to prevent foreign objects from entering the cylinder 1.

Axial fans 12, 13 (FIG. 1) have a plurality of movable blades 90 attached to respective rotary shafts 14, 15, 16 in their longitudinal directions, so that when the swirling upward flow going up the cylinder 1 hits the movable blades 90 , the rotating shafts 14, 15, 16 rotate due to the energy of the air flow. The rotating shafts 14, 15, 16 of the axial fans 10, 12, 13 are connected to the rotating shafts 20, 21, 22 of the high voltage power generators (from 10,000 V to 20,000 V) by means of gears so that when the axial fans 10, 12, 13 rotate , power generators 17, 18, 19 are driven to generate electricity. Figure 1 shows that a total of six power generators can be driven, since each of the axial fans drives two power generators. Among the three axial fans 10, 12, 13, the axial fan 12 of the middle stage has fewer movable blades 90 than the other axial fans 10, 13. The reason is that it is possible to obtain an adequate rotation force even when the number of movable blades 90 is small, because Vortex upward flow is stabilized in the central part of cylinder 1. Axial fans are designed to withstand vortex upward flow at a speed of 150 m / s.

Fixed cylinders 91 are provided around the axial fans 10, 12, 13 inside the cylinder 1, so that the movable blades 90 of the axial fans 10, 12, 13 can rotate inside the fixed blades 91. With this arrangement, the vortex upward flow collides with the movable blades 90 evenly, thereby the most efficient rotation of the axial fans 10, 12, 13.

Above the axial fan 13 of the upper cascade, a vortex upstream is discharged from the cylinder 1 through the gas outlet 11. The upper end of the gas outlet 11 is pushed upward from the frame 6, so that the gas can be discharged smoothly. In addition, auxiliary ion burners 2 (having a calorific value of about 120 x 10 ⁴ KS) are provided near the gas outlet 11, so that the upward flow of gas through cylinder 1 can be reheated to facilitate the release of this gas. The design of the auxiliary ion burners 2 is the same as that of the ion burners 2 provided on the heating furnace 5.

Application example

For example, electricity is generated using the energy generating system of the present invention and shown in FIG. 1 in the following ways.

1. In a state where the shutter of the gas inlet 9 is closed, ion burners 2 are activated to heat and ionize the air inside the heating furnace 5. Since the air heated inside the heating furnace 5 and having an increased concentration of ions rises (rises) along the cylinder 1 and is discharged out through the gas outlet 11, a high temperature is set inside the cylinder 1, and therefore, the air pressure inside the cylinder becomes lower than atmospheric.

2. When the temperature and concentration of ions inside the heating furnace 5 reach predetermined levels (for example, the temperature reaches 1600 ° C and the ion concentration is -30%), open the shutter of the gas inlet 9. Since the pressure inside the cylinder 1 is lower than atmospheric pressure, when the damper is open, atmospheric air flows into the cylinder 1 through the opening 9, equalizing the pressure. In this case, since air having a lower temperature tends to flow into air having a higher temperature outside, atmospheric air having a lower temperature than the temperature of the air inside the cylinder 1 flows into the cylinder 1 through the opening 9, forming a vortex flow, and collides with an axial fan 10 of the lower stage and rotates this axial fan 10. When the axial fan 10 of the lower stage rotates, two power generators 17 connected therein are driven to generate electricity.

3. The gas passing through the axial fan 10 of the lower cascade flows into the heating furnace 5, while the vortex speed increases by rotating the axial fan 10. In the heating furnace 5, the gas instantly heats up, creating a vortex upward flow, which, in turn, rises along cylinder 1. The velocity of the vortex upward flow is proportional to the temperature and ion concentration in the heating furnace 5.

4. Then the vortex upward flow collides with the axial fan 12 of the middle stage and rotates this axial fan 12. After that, the flow collides with the axial fan 13 of the upper stage and rotates this axial fan 13. When two axial fans 12, 13 rotate, the energy generators connected to them 18, 19 are driven to generate electricity.

5. The vortex upward flow, passed through the axial fans 12, 13 of the middle stage and the upper stage, is reheated by auxiliary ion burners 2 in front of the gas outlet 11, and then is discharged from the cylinder through the hole 11. Since atmospheric air (neutral) flows into the air ( ionized) in the produced vortex upward flow, the air is neutralized.

6. Thus, the fans of the lower cascade, the middle cascade and the upper cascade rotate, driving the power generators connected to them and thereby generating electricity.

Ion burners 2 are temporarily shut off when the temperature and concentration of ions inside the heating furnace 5 reach predetermined limits. After that, the temperature inside the heating furnace 5 is maintained by a discharge carried out on the discharge electrodes 3, and the ion concentration in the heating furnace 5 is supported by particle accelerators 4. If the temperature and concentration of ions in the heating furnace 5 decrease below predetermined levels, then the ion burners 2 are turned on again. When the ion burners 2 operate in this interrupted operation mode, the fuel needed for the ion burners 2 can be saved and the amount of carbon dioxide generated can be reduced. .

Other embodiments of the invention

Although the aforementioned application example has explained the use of only one energy generating system according to the present invention, two or more energy generating systems according to the invention can be used together, as shown in FIG. 7. In addition, the number of ion burners provided on the heating furnace is not limited to three; fewer or more ion burners can be used. The number of axial fans located in the duct and the power generators is also not limited to the above, it is possible to use fewer or more axial fans and power generators. In addition, it is possible to use power generators that are not high voltage power generators. Numerical values relating to the height of the frame, the dimensions of the uprights and the length and diameter of the cylinder, as well as other values, are given only as an example.

Industrial applicability

Compared to thermal energy generation systems, the system of the present invention can achieve proper energy generation with extremely low fuel consumption. In addition, the volume of silica formed is small.

Unlike nuclear systems for energy generation, there is no danger of leakage of harmful substances, for example, those with radioactivity. In addition, it is easy to clean the fuel used.

Unlike hydropower generating systems, there is no need to build a dam.

The design is simple, the installation costs are small. In general, compared to various conventional systems, it is possible to achieve proper power generation with a simple design and at low cost, without adversely affecting the environment.

Claims (18)

1. System for generating energy, containing a cylindrical channel having a height of several hundred meters, containing an air inlet for the hole made in the lower part of the cylindrical channel, a gas outlet in the upper part of the cylindrical channel, many movable blades attached to the corresponding rotating a shaft connected to the shaft of an energy generator located in a cylindrical channel, characterized in that the system comprises a heating furnace having a peripheral wall, with formed from refractory materials and placed in a cylindrical channel, a shutter for opening and closing the inlet, an ion burner and a discharge electrode designed to increase the temperature and concentration of ions inside the heating furnace to the levels required for the formation of a vortex upward flow, while the ion burner contains a nozzle for spraying fuel, which uses kerosene, metal powder mixed with oil, and water, which are supplied from the fuel supply device willow, which contains a metal fuel supply device, equipped with a positive electrode and a negative electrode, so that when generating an electric discharge between the indicated electrodes, the metal powder particles formed on the positive electrode enter kerosene, carbon hydrocarbon is deposited in kerosene, the metal powder adheres to carbon with the formation of an oil product, the temperature and concentration of ions in a heating furnace are increased to a predetermined level by means of an ion burner, as a result, the gas supplied to the cylindrical channel rises in the cylindrical channel in the form of a vortex upward flow; a plurality of movable blades located above the heating furnace attached to a corresponding rotating shaft connected to the shaft of the energy generator located outside the cylindrical channel is rotated by this vortex upward flow. 2. The system for generating energy according to claim 1, characterized in that it contains at least two located in the channel set of movable blades attached to the corresponding rotating shafts connected to the shafts of energy generators located outside the cylindrical channel, while the rotor blades many movable blades attached to the corresponding rotating shafts connected to the shafts of the energy generators rotate between stationary blades mounted in a cylindrical channel. 3. The system for generating energy according to claim 1, characterized in that it further comprises an additional ion burner located in the upper part of the cylindrical channel and designed to reheat the gas flowing through the cylindrical channel to accelerate the release of the vortex upward flow through the gas outlet. 4. A system for generating energy, containing a cylindrical channel having a height of several hundred meters, containing an air inlet for the air in the lower part of the cylindrical channel, a gas outlet in the upper part of the cylindrical channel, a plurality of movable blades attached to the corresponding rotating a shaft connected to the shaft of an energy generator located in a cylindrical channel, characterized in that the system comprises a heating furnace having a peripheral wall, with formed from refractory materials and placed in a cylindrical channel, a shutter for opening and closing the inlet, an ion burner designed to increase the temperature and ion concentration inside the heating furnace, a particle accelerator for the heating furnace to maintain the concentration of ions in the heating furnace or increase the concentration of ions, the temperature and concentration of ions in the heating furnace are regulated to form a vortex upward flow, while the ion burner contains a nozzle y for spraying fuel, which uses kerosene, a metal powder mixed with oil, and water, which are supplied from a fuel supply device that contains a metal fuel supply device equipped with a positive electrode and a negative electrode, so that when generating an electric discharge between these electrodes, metal powder particles formed on the positive electrode enter kerosene, carbon hydrocarbon precipitates in kerosene, metal powder sticks to carbon with the formation of an oil product, the temperature and concentration of ions in the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the cylindrical channel in the form of a vortex upward flow, many movable blades located above the heating furnace, attached to the corresponding rotating shaft connected to the shaft of the energy generator located outside the cylindrical channel, this vortex is rotated eve upstream. 5. The system for generating energy according to claim 4, characterized in that it contains at least two located in the channel set of movable blades attached to the corresponding rotating shafts connected to the shafts of the energy generators located outside the cylindrical channel, while the rotor blades many movable blades attached to a corresponding rotating shaft connected to the shaft of the energy generator rotate between stationary blades mounted in a cylindrical channel. 6. The system for generating energy according to claim 4, characterized in that it further comprises an additional ion burner located in the upper part of the cylindrical channel and designed to reheat the gas flowing through the cylindrical channel to accelerate the release of the vortex upward flow through the gas outlet. 7. The system for generating energy according to claim 4, characterized in that the temperature and concentration of ions inside the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the channel in the form of a vortex upward flow, and multiple movable blades attached to respective rotating shafts connected to the shafts of the energy generators are driven by this whirling upward flow, and when the temperature and concentration of ions inside the heater The cooking furnace reaches predetermined levels using an ion burner, the latter is temporarily turned off, and then only the discharge electrode is activated to maintain the temperature or concentration of ions inside the heating furnace, and if the temperature or concentration of ions decreases below a predetermined level, it is again activated ion burner to increase the temperature and concentration of ions inside the heating furnace to predetermined levels and by repeating time By switching off the ion burner, activating only the discharge electrode and re-activating the ion burner, the temperature and concentration of ions inside the heating furnace are maintained at the level suitable for the formation of a vortex upward flow. 8. The system for generating energy according to claim 4, characterized in that the temperature and concentration of ions inside the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the channel in the form of a vortex upward flow, and multiple movable blades attached to respective rotating shafts connected to the shafts of the energy generators are driven by this whirling upward flow, and when the temperature and concentration of ions inside the heater The pre-furnace reaches the predetermined levels with an ion burner, the latter is temporarily turned off, and then only the particle accelerator is activated to maintain the temperature or concentration of ions inside the heating furnace, and if the temperature or concentration of ions decreases below a predetermined level, it is again activated ion burner to increase the temperature and concentration of ions inside the heating furnace to predetermined levels and by repeating the time By shutting down the ion burner, activating only the particle accelerator and re-activating the ion burner, the temperature and concentration of ions inside the heating furnace are maintained at the level suitable for the formation of a vortex upward flow, and when the temperature and concentration of ions inside the heating furnace reach predetermined levels using an ion burner, the latter is temporarily turned off, and after that only a particle accelerator is activated to maintain the sludge and increasing the temperature or concentration of ions inside the heating furnace and, if the temperature or concentration of ions decreases below a predetermined level, the ion burner is again driven to increase the temperature and concentration of ions inside the heating furnace to predetermined levels and by repeating the temporary shutdown of the ion burner, bringing only the particle accelerator and the re-activation of the ion burner, the temperature and concentration of ions inside the heater hydrochloric oven maintained at values suitable for generating the vortical ascending current. 9. A system for generating energy, containing a cylindrical channel having a height of several hundred meters, containing an air inlet for the air in the lower part of the cylindrical channel, a gas outlet in the upper part of the cylindrical channel, many movable blades attached to the corresponding rotating a shaft connected to the shaft of an energy generator located in a cylindrical channel, characterized in that the system comprises a heating furnace having a peripheral wall, with formed from refractory materials and placed in a cylindrical channel, a valve for opening and closing the inlet, an ion burner and a discharge electrode designed to increase the temperature and concentration of ions inside the heating furnace to the levels required for the formation of a vortex upward flow, or an ion burner and a discharge electrode designed to maintain the concentration of ions in a heating furnace or increase the concentration of ions by increasing the number of ions, a particle accelerator for a baking oven for maintaining the concentration of ions in the heating furnace or increasing the concentration of ions, wherein the ion burner contains a nozzle for spraying fuel, which uses kerosene, metal powder mixed with oil, and water that are supplied from a fuel supply device that contains a device metal fuel supply, equipped with a positive electrode and a negative electrode, so that when generating an electric discharge between these electrodes, the particles are meta The crystalline powder formed on the positive electrode enters kerosene, hydrocarbon carbon is deposited in kerosene, metal powder adheres to carbon to form an oil mixed with metal powder, the temperature and concentration of ions in the heating furnace are increased to a predetermined level by means of an ion burner, resulting in the gas supplied to the cylindrical channel rises in the cylindrical channel in the form of a vortex upward flow; The main blades attached to the corresponding rotating shaft connected to the shaft of the energy generator located outside the cylindrical channel are driven into rotation by this vortex upward flow. 10. The system for generating energy according to claim 9, characterized in that it contains at least two located in the channel set of movable blades attached to the corresponding rotating shafts connected to the shafts of energy generators located outside the cylindrical channel, while the rotor blades many movable blades attached to the corresponding rotating shafts connected to the shafts of the energy generators rotate between stationary blades mounted in a cylindrical channel. 11. The system for generating energy according to claim 9, characterized in that it further comprises an additional ion burner located in the upper part of the cylindrical channel and designed to reheat the gas flowing through the cylindrical channel to accelerate the release of the vortex upward flow through the gas outlet. 12. The system for generating energy according to claim 9, characterized in that the temperature and concentration of ions inside the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the channel in the form of a vortex upward flow, and a plurality of movable blades attached to respective rotating shafts connected to the shafts of the energy generators are driven into rotation by this vortex upward flow, and when the temperature and concentration of ions inside the heat The cooking furnace reaches predetermined levels using an ion burner, the latter is temporarily turned off, and then only the discharge electrode is activated to maintain the temperature or concentration of ions inside the heating furnace, and if the temperature or concentration of ions decreases below a predetermined level, it is again activated ion burner to increase the temperature and concentration of ions inside the heating furnace to predetermined levels and, by repeating time by shutting off the ion burner, activating only the discharge electrode and re-activating the ion burner, the temperature and concentration of ions inside the heating furnace are maintained at the level suitable for the formation of a vortex upward flow. 13. The system for generating energy according to claim 9, characterized in that the temperature and concentration of ions inside the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the channel in the form of a vortex upward flow, and a plurality of movable blades attached to respective rotating shafts connected to the shafts of the energy generators are driven into rotation by this vortex upward flow, and when the temperature and concentration of ions inside the heat The pre-furnace reaches the predetermined levels with an ion burner, the latter is temporarily turned off, and then only the particle accelerator is activated to maintain the temperature or concentration of ions inside the heating furnace, and if the temperature or concentration of ions decreases below a predetermined level, it is again activated ion burner to increase the temperature and concentration of ions inside the heating furnace to predetermined levels and by repeating time By shutting down the ion burner, activating only the particle accelerator and re-activating the ion burner, the temperature and concentration of ions inside the heating furnace are maintained at the level suitable for the formation of a vortex upward flow, and when the temperature and concentration of ions inside the heating furnace reach predetermined levels using an ion burner, the latter is temporarily shut off, and after that only a particle accelerator is activated to maintain whether the temperature or ion concentration inside the heating furnace increases and if the temperature or ion concentration decreases below a predetermined level, the ion burner is activated again to increase the temperature and ion concentration inside the heating furnace to predetermined levels and by repeating the temporary shutdown of the ion burner only the particle accelerator and the re-activation of the ion burner, the temperature and concentration of ions inside the heater the flax furnace is maintained at a level suitable for the formation of a vortex upward flow. 14. A system for generating energy, containing a cylindrical channel having a height of several hundred meters, containing an air inlet for the air in the lower part of the cylindrical channel, a gas outlet in the upper part of the cylindrical channel, many movable blades attached to the corresponding rotating a shaft connected to the shaft of an energy generator located in a cylindrical channel, characterized in that the system comprises a heating furnace having a peripheral wall, formed from refractory materials and placed in a cylindrical channel, a valve for opening and closing the inlet, an ion burner and a discharge electrode designed to increase the temperature and concentration of ions inside the heating furnace to the levels required for the formation of a vortex upward flow, or an ion burner and a discharge electrode designed to maintain the concentration of ions in a heating furnace or increase the concentration of ions by increasing the number of ions, a particle accelerator for heating furnace to maintain the concentration of ions in the heating furnace or increase the concentration of ions, while the ion burner contains an ion generator that contains a nozzle for spraying fuel, which is used kerosene, metal powder mixed with oil, and water, which are supplied from the feed device fuel, which contains a metal fuel supply device provided with a positive electrode and a negative electrode, so that when generating an electric discharge between as indicated by the electrodes, metal powder particles formed on the positive electrode enter kerosene, hydrocarbon carbon is deposited in kerosene, metal powder adheres to carbon to form an oil mixed with metal powder, when the positive electrode becomes shorter when the metal particles are discharged and separated, automatic the positive electrode is fed into the container with kerosene by an automatic feeding device; during the reproduction of ions in an ion generator, vibration and acceleration of cations and anions are created to increase the number of cations and anions, the temperature and concentration of ions in the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the cylindrical channel in the form of a vortex upstream above the heating furnace, a plurality of movable blades attached to a corresponding rotating shaft connected to a shaft of an energy generator located outside the cylindrical anal, is driven into rotation by this vortex upward flow. 15. The system for generating energy according to 14, characterized in that it contains at least two located in the channel set of movable blades attached to the corresponding rotating shafts connected to the shafts of energy generators located outside the cylindrical channel, while the rotor blades many movable blades attached to the corresponding rotating shafts connected to the shafts of the energy generators rotate between stationary blades mounted in a cylindrical channel. 16. The system for generating energy according to 14, characterized in that it further comprises an additional ion burner located in the upper part of the cylindrical channel and designed to reheat the gas flowing through the cylindrical channel to accelerate the release of the vortex upward flow through the gas outlet. 17. The system for generating energy according to 14, characterized in that the temperature and concentration of ions inside the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the channel in the form of a vortex upward flow, and a plurality of movable blades attached to respective rotating shafts connected to the shafts of the energy generators are driven into rotation by this vortex upward flow, and when the temperature and concentration of ions inside the heat The preheater reaches the predefined levels with an ion burner, the latter is temporarily turned off, and then only the discharge electrode is activated to maintain the temperature or ion concentration inside the heating furnace and, if the temperature or ion concentration decreases below a predefined level, it is again activated ion burner to increase the temperature and concentration of ions inside the heating furnace to predetermined levels and by repeating By shutting down the ion burner, activating only the discharge electrode and re-activating the ion burner, the temperature and concentration of ions inside the heating furnace are maintained at the level suitable for the formation of a vortex upward flow. 18. The system for generating energy according to 14, characterized in that the temperature and concentration of ions inside the heating furnace are increased to a predetermined level by means of an ion burner, as a result of which the gas supplied to the cylindrical channel rises in the channel in the form of a vortex upward flow, and a plurality of movable blades attached to respective rotating shafts connected to the shafts of the energy generators are driven into rotation by this vortex upward flow, and when the temperature and concentration of ions inside the heat The preheater reaches the predefined levels with an ion burner, the latter is temporarily turned off, and then only the particle accelerator is activated to maintain the temperature or concentration of ions inside the heating furnace and, if the temperature or concentration of ions decreases below a predefined level, it is reactivated ion burner to increase the temperature and concentration of ions inside the heating furnace to predetermined levels and by repeating time by switching off the ion burner, activating only the particle accelerator and re-activating the ion burner, the temperature and concentration of ions inside the heating furnace are maintained at the level suitable for the formation of a vortex upward flow, and when the temperature and concentration of ions inside the heating furnace reach predetermined levels using an ion burner, the latter is temporarily turned off, and after that only a particle accelerator is activated to maintain and whether the temperature or ion concentration inside the heating furnace increases and if the temperature or ion concentration decreases below a predetermined level, the ion burner is activated again to increase the temperature and ion concentration inside the heating furnace to predetermined levels and by repeating the temporary shutdown of the ion burner only the particle accelerator and the re-activation of the ion burner, the temperature and concentration of ions inside the heater noy oven maintained at values suitable for generating the vortical ascending current.

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