RU2230197C2 - Electric generator - Google Patents

Abstract

FIELD: electric engineering; heat power stations, steam generators, ships. SUBSTANCE: according to invention, generator is furnished with water electrolyzer containing brush-like electrodes with tungsten needles pointed to each other and installed with required clearance. Electrodes are installed in rectangular or cylindrical container coaxially relative to each other. Perforated aerator-catalyst tube is installed on container bottom, said tube being connected with compressor. Electrolyzer container is connected by inlet pipe with section of condensate accumulating tank through condensate line, electric pump and with liquid alkali container through meter furnished with solenoid and time relay. Electrolyzer container is connected with plasma generator located in ionization chamber by means of pipe. Ionization chamber is furnished with plasma generator plasma jet and water steam deflector and collector and steam pipes arranged with different angles of inclination and pointed to plasma jet. Electrodes of electrolyzer are connected with ac source through amplidyne, electric pulse transmitter and switches. Invention makes is possible to provide non-expensive ecologically clean high-calorific fuel directly from water. EFFECT: increased capacity and efficiency in production of electric and thermal energy. 13 dwg

Description

The invention relates to the electrical industry and can be used for thermal power plants of steam generators and ships for generating electrical and thermal energy directly from water.

Known electrical generators containing a rotor, a stator, windings and windings, which induces an EMF, a steam turbine, a steam generator, a steam condenser, a compressor [1].

Known steam generator, consisting of a once-through boiler, combustion chamber, nozzle, pipe coil, through which water circulates using an electric pump [1].

Known plasmatron, consisting of a discharge chamber located between two electrodes of a tungsten cathode, and a copper anode in the form of a narrow hollow ring / nozzle / equipped with a solenoid [2].

A disadvantage of the known electric generator is the high cost of fuel, environmental pollution.

The aim of the invention is to obtain cheap environmentally friendly high-calorie fuel directly from water, increasing fuel efficiency for generating electric and thermal energy and increasing productivity.

This goal is achieved by the fact that the device is equipped with a water electrolyzer containing brush-shaped electrodes with tungsten needles, the electrodes are arranged in a vertical plane parallel to each other, the needles pointing at each other, a proper gap is established between them, the electrodes are installed in rectangular or cylindrical containers in parallel or coaxially to each other, a perforated aerator-catalyst tube is installed at the bottom of the electrolytic tank, the pipe is connected to a condensate storage tank with the help of a compressor and a tube, it is possible to move compressed air to the electrolytic tank to improve the mixing of liquid alkali with water and to detach hydrogen and oxygen atoms from water and to move oxygen to the nozzle of the steam generator, hydrogen to the plasma torch of the ionization chamber, the electrolytic tank is connected by an inlet pipe to the container section condensate accumulation, through a condensate line, an electric pump and with a liquid alkali capacity through a dispenser, the dispenser is equipped with a solenoid and a time relay, the electrolyzer capacity is connected It is provided with a plasmatron located in the chamber for ionizing water vapor using a tube configured to supply hydrogen to the plasmatron.

The capacity of the electrolyzer is connected to the nozzle of the steam generator, configured to supply oxygen to the nozzle. The ionization chamber is equipped with a plasma torch, a reflector, a collector, steam tubes equipped with nozzles located at different angles of inclination, directed to the plasma jet, made with the possibility of partial destruction and relaxation of molecular and ionic bonds and electrostatic attraction of ions in water. In this case, one or several electrons detach from the water molecule, create free charge carriers, partially release deuterium and burn it in the plasma to create high energy to power the steam turbine of the electric generator.

The alternating current source is connected to the electrodes through an electric machine converter, the electrical impulse sensor and switches are configured to operate the electrodes in different modes: direct current at rated voltage, pulsating direct current at rated voltage; at constant electric current at high voltage; with a pulsating constant electric current at a high voltage voltage and a change in the direction of the electric current at the cathode and anode.

The novelty of the claimed technical solution is due to the fact that due to the electrolyzer we obtain cheap, environmentally friendly, high-calorific fuel oxygen and hydrogen directly from water during electrolysis. Oxygen is used as a fuel for a steam generator, hydrogen is used to ionize water vapor by a plasma torch. Due to the plasma torch, ionization of water vapor occurs for partial destruction of molecular and ionic bonds and partial destruction of the electrostatic attraction of ionic bonds in water vapor, detachment of one or more electrons from water vapor molecules and the creation of free charge carriers, partial release of deuterium and its combustion to create high energy to power a steam turbine of an electric generator.

By connecting the AC source with the electrodes of the electrolyzer through an electric machine converter, an electric pulse sensor and switches, the electrodes, cathode and anode operate in different modes: at a constant electric current at rated voltage; on pulsating direct electric current - at rated voltage; on direct electric current at high voltage; with pulsating direct current at high voltage, a change in the direction of the electric current on the electrodes.

In the study of the claimed technical solution for patent, scientific and scientific-technical materials, such a combination of features was not found that allows us to judge the materiality of the claimed features.

The invention is illustrated by drawings, where:

figure 1 shows a General diagram of an electric generator;

figure 2 - jet steam turbine;

figure 3 - the movement of ions in the electrolysis process;

figure 4 and 5 are variants of the chambers of ionization of water vapor and the location of the steam tubes with nozzles;

figure 6 - the device of the electrolyzer according to the first embodiment;

in Fig.7 and 8 - options for partitions and the device of the electrolysis tank;

figure 9 is a diagram of the device of the electrolyzer according to the second embodiment;

figure 10 is a diagram of the manufacture of the electrode according to the first embodiment;

figure 11 is an electrical diagram of the operation of the electrolyzer in different modes;

on Fig - electrolyzer according to the third embodiment, a top view;

Fig.13 - electrolyzer according to 4 embodiment.

The device consists of an electric generator 1, consisting of a stator 2, a rotating part of the rotor 3, an AC winding 4 is located on the inner surface of the stator 2. The generator 1 is equipped with a steam generator 5, a steam condenser 6, an electrolyzer 7. The capacity of the electrolyzer 7 is made of dielectric material. The coils 8 of the steam generator 5 are connected to the steam turbine 9 through the steam line 10, the chamber 11 (figure 4 and 5) of the ionization of water vapor, located underground at the required depth, equipped with refractory material, hydro and thermal insulation. At the end of the steam pipe 10 is a nozzle 12.

The chamber 11 for ionizing water vapor can be made in the following variants: spherical shape, in the form of a cylinder, or a rectangle, or a polygon, or an oval shape, or in the form of a truncated cone. In all cases, the outlet pipe of the steam pipe has a conical shape, providing the opportunity to improve the removal of ionized water vapor. The plasma torch 13 can be installed in three versions: above the chamber 11, under the chamber or on the side of the chamber 11. The plasma torch 13 contains a frame 14, a cathode 15, an anode 16, a solenoid 17, a discharge chamber 18, a cyclone 19 for supplying hydrogen fuel, compressed air and argon. The tube 20 is designed to supply water for cooling the cathode 15, the tube 21 to supply water for cooling the anode 16.

The frame 14 is made of durable refractory dielectric material. The cathode 15 is made of a refractory material of tungsten in the form of a tube with a welded bottom, where there is an extension. Tubes 20 and 21 are connected to a water supply system (not shown in the drawing) and a tank 72, made with the possibility of cooling the electrodes 15 and 16 and removing water into the section 86 of the tank 72. The anode 16 is made in the form of a narrow hollow ring of copper, performs the function of a nozzle. The ring of the anode 16 is equipped with a solenoid 17.

The solenoid 17 is connected to an alternating current source 22 by an electric circuit. The AC source is connected to the ignition coil 23. Nozzles 12 and steam line 10 can be installed in the chamber 11 in the following variants.

First option.

The nozzle 12 of the steam line is directed to the plasma jet in the center of the flame. The steam line is located in a horizontal plane perpendicular to the axis of the plasma jet. The compressor 24 is connected to the cyclone 19 of the plasma torch 13 using a tube 25. A cylinder 26 containing liquid argon is connected to the tube of the cyclone 19 of the plasma torch 13 using a tube 27, which is configured to blow a plasma jet of inert gas of argon and compressed air to increase the temperature of the plasma up to 20,000 K, creating a neutral atmosphere, eliminating the contact of the plasma jet with the surface of the electrodes and improving the ionization of water vapor.

The steam line 10 with the nozzle 12 can be performed in the second embodiment.

The second option differs from the first in that the steam line is equipped with a manifold 28 having branched tubes 10 of steam lines that are installed in the chamber 11 from different sides, their nozzles 12 are directed to the center of the flame, the tubes 10 are installed in a horizontal plane and directed perpendicular to the axis of the plasma jet.

The steam line 10 with the nozzle 12 can be made in the third embodiment. The third option is the same as the second option, differs from it in that the steam pipe 10 is directed from all sides to the plasma jet at an acute angle.

The steam line 10 with the nozzle 12 can be made in the fourth embodiment. The fourth option is the same as the third option, differs from it in that all the tubes of the steam lines 10 are bent to one side and configured to supply a steam jet to accelerate the swirl of the plasma jet to give it a rotational movement.

The steam line can be made in the fifth embodiment. The fifth option is the same as the third and fourth options, differs from them in that the tubes 10 of the steam lines are directed parallel to the walls of the chamber 11.

The steam line 10 can be made in the sixth embodiment. The sixth option is the same as the second and third options, differs from them in that the camera 11 is equipped with a reflector 29 of the plasma jet and water vapor. The reflector 29 is located between the walls of the chamber 11 and the plasma jet, made of double-walled copper plates in the form of a cylinder, or oval, or cone. The reflector 29 is equipped with an inductor 30, is rigidly fixed to the walls of the reflector 29, the interwall space of the reflector 29 is connected to the steam pipe 10. Near the plasma torch 13 on the reflector 29 there are tubes 31 located on all sides at an acute angle to the plasma jet, having a bend of one side, which makes it possible to supply steam through the interwall space, additional heating of the steam and its supply to the center of the plasma jet to blow the plasma jet with a vortex stream to impart acceleration to the plasma jet Nogo rotational motion and improving the ionization of the water vapor plasma jet exception of contact with the reflector surface 29, compression ionized water vapor, plasma, mixing with steam and the formation of a homogeneous mass, and feeding it to the steam turbine.

The device steam lines can be performed in the seventh embodiment. The seventh option differs from the first in that the cathode 15 is made in the form of a tungsten tube connected to a steam line, configured to move water vapor to the center of the plasma jet.

The steam line can be made in the eighth embodiment. The eighth option is the same as the seventh option, differs from it in that part of the vapor moves through the tubular tungsten cathode 15, and part of the steam is supplied through the collector 28 to the steam tubes 10 and nozzles 12, configured to move the steam combined in the center and on the side surfaces of a plasma jet.

The capacity of the cell 7 is provided with a cathode 32 and the anode 33. The capacity of the cell 7 is connected to the tank 34 by means of a liquid alkali batcher 35 (sodium hydroxide or potassium hydroxide) and a tube 36. The batcher 36 comprises a cylinder 37, a piston 38, a microswitch 39. The batcher 35 is connected to the stem 40 of the solenoid 41. The solenoid 41 contains a ferromagnetic core 42 and a spring 43. The solenoid 41 is equipped with a time switch 44. The capacity of the electrolyzer can be made of ceramic, plastic and other materials resistant to electrolyte, made of dielectric material in direct angular shape.

The capacity of the electrolyzer 7 contains a cover 4-5, a gasket 46, in the upper base of the container there are ears 47 with holes (not shown) for the valve 48. The valve 48 has a hole with screw threads, into which screws 49 are screwed, which allow sealing and sealing the cover 45. In the electrolytic tank 7, grooves 50 are made, in which electrodes 32 and 33 are mounted, rigidly fixed to the tank 7.

The electrodes 32 and 33 are made in the form of a metal brush containing stainless steel plates 51, on the surface of which tungsten needles 52 are fixed rigidly perpendicular to the plane of the plate 51. The plates 51 are arranged in a vertical plane perpendicular to each other. The needles 52 are arranged horizontally, the ends of the needles 52 of one electrode are directed to the ends of the needles of the other electrode. The needles 52 of the electrodes 32 and 33 are installed with the proper clearance. A baffle 53 is installed between the electrodes 32 and 33, containing a window 54 or holes 55 below the electrolyte layer at a depth of 3-4 cm from the surface of the liquid. To facilitate installation and rigid attachment of the needles 52 to the plate 51, the ends of the needles 52 of one plate coincide with the ends of the needles 52 of the other plate 51. For this plate 51 (figure 10) are made standard, of the same length, width, thickness. Vertical and horizontal lines with the necessary equal intervals are applied to the plate with the coloring matter. At the intersection of horizontal and vertical lines, nests for holes 56 corresponding to the diameter of the needles 52 are made. The needles 52 are installed and rigidly fixed to the holes 52, observing the height level of all the needles 52. The section of the electrolytic cell 7 filled with oxygen is connected to the nozzle 57 by means of a gas pipeline 58 and valve 59.

The nozzle is configured to move air-oxygen fuel from the tank 7 to the nozzle 57 of the steam generator 5 and regulate the fuel supply by means of the valve 59. A section of the capacity of the electrolyzer 7 filled with hydrogen is connected to the plasma torch 13 located in the chamber 11 by means of a gas pipeline 60 and a valve 61, providing the ability to move hydrogen from the tank 7 of the cell to the chamber 11 and the plasma torch 13.

In the capacity of the electrolyzer 7 is an electrolyte - alkaline distilled water containing sodium hydroxide or potassium hydroxide. In the capacity of the electrolytic cell 7, a level regulator 62 is mounted, connected to the electric pump 63 by means of an electric circuit. In the lower base of the tank 7 is located aerator-catalyst 64, made in the form of a tube with perforated holes. The aerator tube 64 is located between the electrodes 32 and 33, which can operate in several modes, for example, an alternating current source 22 is connected to the electrodes 32 and 33 through an electric machine converter 65 and electric switches 66 and 67, configured to convert an alternating electric current to direct current at rated voltage of electric current.

The electrodes 32 and 33 can be performed in the second embodiment. The second option is the same as the first, differs from it in that the electrodes 32 and 33 are connected to an alternating current source 22 through an electric machine current converter 65 and an electric pulse sensor 69 and electric switches 66 and 68, configured to convert alternating current to direct current and creating electrical pulses at a rated voltage of electric current.

The electrodes 32 and 33 can be made in the third embodiment. The third option is the same as the first option, differs from it in that the electrodes 32 and 33 are connected to an alternating current source 22 through an electric machine current transformer 65 and electric switches 56 and 70 configured to convert electric alternating current to direct current, low conversion voltage - into a high voltage current.

The electrodes 32 and 33 can be made in the fourth embodiment. The fourth option is the same as the third option, differs from it in that the electrodes 32 and 33 are connected to an AC source 22 through an electric machine current converter 65, an electric pulse sensor 69, and switches 66 and 71 configured to convert the electric current to direct current , low voltage current to high voltage current and the creation of high voltage electrical pulses.

The electrodes 32 and 33 can be made in the fifth embodiment, the fifth variant is the same as the 1-4 variants, differs from them in that, using the switches 67, 68, 70 and 71 in the electrodes, it is possible to change the direction of the electric current on the electrodes, while the cathode becomes an anode, anode - a cathode, this allows you to automate the cleaning of alkali deposits.

A vacuum pump 73 is located in the condensate storage tank 72. The aerator 64 of the electrolysis tank 7 is connected to a compressor 74 configured to supply compressed air to the electrolysis tank 7 for aeration of the electrolyte, separation of hydrogen and oxygen bubbles from water and oxygen supply to the steam generator nozzle 57 5, and hydrogen into the plasma torch 13 of the chamber 11. The capacitance of the steam condenser 6 contains a coil 75 connected by a tube 76 to a steam turbine 9 and to a capacity 72 of the condensate storage tank. In containers 6 and 72, a fluid level controller 77 is located at an appropriate level and is connected to an electric magnet 78 by an electric circuit. An electric magnet 78 is located in the valve 79. The valve 79 consists of a spherical concave chamber 80 made of bronze, an electric magnet 78 is located in the upper base of the chamber 80, a hole 81 is located in the lower base of the chamber 80. A ball 82 made of stainless steel is located in the chamber 80 steel. The valve 79 is installed in the water supply network 83. The tank 72 contains a partition 84 separating the tank into sections 85 and 86. In section 85 there is condensate without impurities of fresh water, the condensate is intended for electrolysis of water for hydrogen and oxygen. Section 86 contains condensation mixed with fresh water. Section 85 is connected to the capacitance of the electrolyzer 7 using the condensate line 87 and the electric pump 63. Section 86 of the tank 72 is connected to the coil 8 of the steam generator 5 using the electric pump 88 and the condensate line 89.

The capacitor 6 is connected in a closed cycle with heating radiator batteries 90 and a shower unit, a faucet through a heat exchanger 91 and an electric pump 92 located in residential, public and industrial buildings or greenhouses, or greenhouses, using water pipes 93 and electric pumps 94. On water pipes pipes 94 are fitted with valves 95. In the summer, when heating of apartments and public buildings will not be needed, the water will be cooled in the cooling tower 96 using water pipes 97 and an electric pump 98.

The steam generator 5 comprises a pipe 99 for removing smoke and gas. The steam turbine 9 comprises a housing 100, a fresh steam chamber 101, an unloading piston 102, a connecting steam line 103, a rotor drum 104, rotor blades 105, guide vanes 106. The electrode, cathode 32 and anode 33 are equipped with electric switches 67, 68, 70.71, made with the possibility of switching electrical circuits to change the direction of electric charges on the electrodes 32 and 33. The cell 7 can be performed in the second embodiment. The second option is characterized in that the electrodes 32 and 33 are made in the form of stainless steel plates.

The cell 7 can be performed in the third embodiment. The third option is the same as the first option, differs from it in that the cell is made in the form of a rectangular battery 107 containing brush-shaped electrodes 32 and 33, where tungsten needles 52 are mounted on the extreme plates 51 only on one side. The central electrode contains needles 52 on both sides. This plate 51 serves simultaneously as a partition, made with the possibility of free movement of ions, but prevents the mixing of hydrogen and oxygen. Battery 107 may contain several sections. All sections of hydrogen are interconnected and the plasma torch 13 using the gas pipeline 60. All sections of oxygen are interconnected and the nozzle of the steam generator 5 using the gas pipeline 58.

The cell 7 can be performed in the fourth embodiment. The fourth option is the same as the first option, differs from it in that the capacitance of the electrolyzer 7 and the electrodes 32 and 33 are cylindrical, mounted and rigidly fixed coaxially to each other.

The cell 7 can be performed in the fifth embodiment. The fifth option is the same as the fourth option, differs from it in that the electrolyzer 7 is made in the form of a cylindrical battery 108. All sections of oxygen are connected to each other and the nozzle using a gas pipeline 58, and all sections of hydrogen are connected to each other and the plasma torch 13 using a gas pipeline 60.

In the tank 72 in the upper base is a vacuum regulator 109. The electric generator can be made in the sixth embodiment. The sixth option is the same as options 1-5, differs from them in that the pipeline 10 is connected to the steam turbine 9 using a tee coupling, the second sleeve of the pipeline 10 is connected to the ionization chamber 11, is configured for combined use of steam, part of the steam moves to steam turbine 9 without ionization, the other part of the steam is ionized in the chamber 11 using a plasma torch 13.

An electric generator can be made in the seventh embodiment. The seventh option is the same as options 1-6, differs from them in that the pipe for removing gases from the steam generator 5 is connected to the cyclone 19 of the plasma torch 13 in the ionization chamber 11.

The device operates as follows. We open the valves 59 and 61 in the gas pipelines 58 and 60. We close the electric circuit supplying the electric pumps 88 63, 92, 94 or 98, the compressor 74, the plasma torch 13, solenoids 17, the time switch 44, the vacuum pump 73, the ignition coil 23, the electrodes 32 and 33. Compressor 74 moves the compressed air through the tube into the electrolytic tank 7, into the aerator tube 64, the compressed air exits through the openings of the tube between the electrodes 32 and 33. During the electrolysis, water decomposes into hydrogen and oxygen, which are released in the form of bubbles in the water. . Compressed air moves upward through the electrolyte layer, absorbs hydrogen and oxygen bubbles, detaches them from the water and moves them to the nozzle 57 of the steam generator 5 under the pressure of the compressor 74. The ignition coil 23 ignites the fuel gas mixture with an electric spark. During combustion, the air-oxygen mixture creates a torch of fire in the nozzle 57. In addition to the oxygen that comes from the electrolysis of water, in addition to this volume 21% of the oxygen comes from the air stream through the compressor 74. The torch heats the coil of pipes 8 through which water and water circulate heats up and turns into steam. The vapor moves into the ionization chamber 11.

Working gas-hydrogen and compressed air are supplied by the compressor 24 to the cyclone 19 of the plasma torch 13 through the spiral channels of the cyclone 10. As a result, a gas vortex occurs. A gas vortex, passing between two electrodes under the action of a magnetic field of solenoids perpendicular to the plane of the nozzle, causes the arc current channel to rotate continuously, flowing around the anode ring, a gas vortex is formed under the influence of compressed air and argon, blowing around the arc column, the colder gas is forced out by centrifugal forces to the walls of the chamber, isolating them from contact with the arc, while the arc is stabilized by a gas “swirl.” Passing through the nozzle, hydrogen, compressed air containing nitrogen 78.1%, argon 0.9%, mol The gas cells are ionized by a rotating arc section, hydrogen, nitrogen, argon, helium are converted into plasma in an arc discharge between a refractory cathode made of tungsten and a water-cooled copper anode made in the form of a narrow nozzle ring using a solenoid. 21% of oxygen burns out in the plasma the arc.

Steam tubes 10 containing nozzles 12 can operate in the following variants: steam moves through the steam line 10 through nozzle 12, which are directed to the plasma jet at the center of the flame perpendicular to the axis of the plasma jet. In the collision of water vapor with plasma under the influence of a high temperature of the plasma and the electromagnetic field, the water vapor is ionized, as a result of which one or several electrons are detached from the water vapor molecules, free charge carriers appear in the gas, molecular and ionic bonds and the electrostatic attraction of ions are partially destroyed in water, water vapor possess new properties, electrical conductivity, more susceptible to the splitting of water vapor into hydrogen and oxygen during electrolysis.

Steam tubes 10 with nozzles 12 can operate in the second embodiment. The second option is the same as the first, differs from it in that the steam line 10 is equipped with a collector 28. From the collector 28, a network of steam tubes 10 with nozzles 12, which are installed in the chamber 11, branches out, directed to the center perpendicular to the axis of the plasma jet from different sides. In this case, water vapor collides with plasma on all sides and the ionization of the vapor.

Steam tubes 10 with nozzles 12 can operate in the third embodiment. The third option is the same as the second option, differs from it in that the tubes of the steam lines 10 are directed from all sides towards the plasma jet at an acute angle of inclination to its axis. In this case, the plasma jet is blown with water vapor, ionization of the vapor occurs.

Steam tubes 10 with nozzles 12 can operate in the fourth embodiment. The fourth option is the same as the third option, differs from it in that all the tubes of the steam lines 10 are bent in one direction. In this case, the effect of the vapor force on the plasma jet occurs, leading to an increase in the turbulence of the plasma jet. Steam ionizes.

Steam tubes 10 with nozzles can work in the fifth embodiment. The fifth option is the same as 3-4 options, differs from them in that the tubes of the steam lines 10 with nozzles 12 are directed along the walls of the chamber 11.

Steam tubes 10 with nozzles 12 can operate in the sixth embodiment. The sixth option is the same as 2-3 options, differs from them in that the camera 11 is equipped with a reflector 29 of the plasma jet and steam. A reflector 29 is located between the walls of the chamber 11 and the plasma jet.

The reflector 29 is made of double-walled copper plates in the form of cylinders, or an oval, or a cone. The reflector 29 is equipped with an inductor 26, rigidly mounted on its wall. Water vapor is introduced into the interstitial space of the reflector 29, which, moving through the interstitial space, is additionally heated and enters the plasma jet at an acute angle of inclination. In this case, an additional twist of the plasma jet and vapor occurs. The inductor 30 generates a magnetic field, rotating the plasma jet additionally, in addition, the steam jets are directed at a certain angle, affect the plasma jet, accelerating its rotation. Under the action of centrifugal force, water vapor during ionization is forced out and forced out to the walls of the reflector 29, which prevents contact with the plasma jet.

Steam tubes 10 with nozzles 12 can operate in the seventh embodiment. The seventh option is the same as the first option, differs from it in that water vapor is supplied through the cathode tube 15. Nozzle 12 is located at the end of the cathode tube 15. Water vapor is supplied through the tungsten cathode 15 to the center of the plasma jet. At a high temperature of the plasma and the action of a magnetic field under the action of centrifugal forces, water vapor mixes with the plasma and is displaced by it outside the jet. In this case, active ionization of water vapor occurs. Water vapor does not allow the cathode 15 to melt.

A steam tube with a nozzle 12 can work in the eighth embodiment. The eighth option is the same as the seventh option, differs from it in that part of the steam is supplied through the tubular cathode 15, and part of the steam through the collector 28 to the steam tubes 10. In this case, the active ionization of water vapor occurs.

Ionized steam moves into a steam turbine, having a very high temperature and high pressure obtained from the compressor 24, the plasma torch 13 from the plasma jet and the steam ionization process. The steam moves into the steam turbine 9 with a pressure of P ₁ and a speed of _About . Steam enters the aperture 101 of the fresh steam chamber. The vapor pressure falls to the movable and stationary crowns of rotor blades 105 and the vanes 106, and the speed is increased by the fixed and movable crowns triggered at a pressure P ₂ and the speed _S. The steam leaves the turbine 9 through the exhaust pipe and moves into the coil 75 of the condenser 6. So the steam pressure before and after the crowns is not equal. Drum 104 with great force tends to move along the axis to balance this force in the turbine 9, in which the unloading piston 102 is installed. The difference in pressure from the vapor pressure on the piston on both sides balances the drum 104 and drives the electric generator 1, which converts mechanical energy into the electric.

Electric energy is transported by wire to consumers in cities and villages. Water vapor pressure and temperature are the main parameters of a steam turbine. The higher the parameters at the entrance to the turbine and the lower they are at the exit of the turbine 9, the more energy is used by the turbine 9. To lower them at the exit of the turbine 9, the steam is not released into the air, but sent to the coil 75 of the condenser 6, the cooled steam it turns into condensate, moves to storage tank 72. The tank 72 is equipped with a vacuum pump 73 and a vacuum regulator 108. A reduced air pressure is formed in the tank 72, all air bubbles are removed, and the outlet pressure decreases. To increase the inlet pressure, the compressor supplies compressed air to the cyclone of the plasma torch 13, to the ionization chamber 11, and also hydrogen is supplied to the cyclone of the plasma torch 13.

The pipes of the coil 75 are washed with cold water in the condenser 6. In the condenser 6, water circulates through the pipes 93 of the heating radiator battery 90 using an electric pump 94. Radiator batteries 90 are located in residential, public and industrial buildings, greenhouses, greenhouses. In the condenser, 6 steam and condensate circulate in a small closed circle, water - in a large closed circle. The steam from the steam generator 5 is mixed through the steam line 10 into the chamber 11, the water vapor is ionized by the plasma jet using a plasma torch 13. In this case, the molecular and ionic bonds are partially destroyed and relaxed, the electrostatic attraction of the ions in the water vapor is partially destroyed and relaxed, one or several electrons, the creation of free charge carriers, the partial release and burning of deuterium. In addition, the compressor 24 delivers compressed air and an inert gas to blow the plasma jet, as a result of which the working gas-hydrogen, nitrogen, argon, helium are converted into plasma. This creates high energy that is used by the steam turbine, the exhaust steam from the steam turbine 9 is transferred to the coil 75 of the condenser 6. In the condenser 6, the water vapor is cooled and transferred to the storage tank 72 using the electric pump 88 of the condensate line 89. The condensate is moved to its original position in steam generator 5. So the circulation is carried out in a small closed circle of steam and condensate.

In a large vicious circle, water circulates from the capacitor 6, moves through the water supply 93 through heat exchangers 91 and electric pumps 92, heating radiator batteries 90, or panels, or convectors, and pumps 94 located in residential, public or industrial buildings, in greenhouses, greenhouses.

The heat in the heated rooms is transferred by hot water through heat exchangers 91 and heating radiator batteries 90, where the water is cooled and moved to its original position in the capacitor 6 using an electric pump 94, 92 and water pipes 97 or water is circulated through the water supply 93 through a shower unit, cooling tower 96 by means of an electric pump 98 and pipes 97 and moves to its initial position in the condenser tank 6. As soon as the water level in the tanks 6 and 72 decreases below the prescribed limits, the controller 109 of operation turns on and closes the electric circuit supplying the electric magnet 79. Under the influence of an electromagnetic field, the ball 82 moves to the upper base, the valve opening 81 opens, water moves through the opening 81 to the capacitor tank 6 or to the section 86 of the tank 72. After filling the tank 6 or 72 to the proper level, the controller 77 operates and opens the electric circuit supplying the electric magnet 78. The magnetic field disappears, the ball 82 from its own weight moves to its original position in the lower base and closes the hole 81. Di Stilled water (condensate) moves to section 85 of tank 72, after filling it is poured through wall 84 into section 86. In section 86, level controls 77 are installed at different levels, which automatically maintain the liquid level. In section 85 of the tank contains condensate without impurities of fresh water, designed to be supplied to the tank electrolyzer 7 for electrolysis of water. In section 86 of tank 72, water is mixed with condensate and transferred to the coil 8 of the steam generator 5. The vacuum pump 73 and the vacuum regulator 109 automatically maintain the proper vacuum level to improve the performance of the steam turbine 9. The electrodes 32 and 33 can operate in different modes, in several options.

First option. We close the electric circuit supplying the electrodes 32 and 33 with the alternating current source 22 through the electric machine current converter 65 (Fig. 11) by electric switches 66 and 67. In this case, the alternating current is converted into direct current at rated voltage.

The electrodes 32 and 33 can operate in the second embodiment. The second option is the same as the first option, differs from it in that the electric circuit of the electrodes 32 and 33 is closed with the alternating current source 22 through the machine converter 65 and the electric pulse sensor 69 using electric switches 66, 68. In this case, the variable is converted current to direct current and the creation of electrical pulses on the electrodes 32 and 33 with an electro-hydraulic effect at a rated voltage of electric current.

The electrodes 32 and 33 can operate in the third embodiment. The third option is the same as the first option, differs from it in that when the electric circuit is closed using switches 66 and 70 of the electrodes 32 and 33 with the AC source 22, the AC current is converted to direct current through the electric machine converter 65 and the electric pulse sensor 69 current, low voltage current - into a high voltage current and the creation of high voltage electrical pulses. With the passage of a constant electric current in electrodes 32 and 33, electrochemical processes occur in the electrolyte: positively charged cation ions move toward the cathode, and negatively charged anion ions move toward the anode. Ionized distilled water, which has undergone a multiple process of vaporization, ionization and condensation, has new properties: electrical conductivity and electrostatic attraction of ions in water. In this case, water decomposes into hydrogen and oxygen in the form of bubbles. Compressed air from the compressor 74 moves through the aerator-catalyst 64, through the perforated holes of the tubes, in the lower base of the container 7 above the electrodes 32 and 33 it moves through the liquid layer from bottom to top, absorbs hydrogen and oxygen bubbles with its bubbles, detaches them from water and moves oxygen to the nozzle 57 of the steam generator 5, and hydrogen to the plasma torch 13 of the ionization chamber 11. The fuel supply is adjusted using valves 59 and 61.

Periodically, after a certain period of time 44, the electric circuit supplying the solenoid 41 is activated and opened. Under the action of the force of the spring 43, the rod 40 moves in the cylinder 37, moving the piston 38. In this case, a dosed portion of liquid alkali (sodium hydroxide or potassium hydroxide) moves from the dispenser cylinder 40 35 through the tube 36 from the tank 34 to the cell of the electrolyzer 7. During the electrolysis, the ions move freely through the window 54 of the partition 53, it is difficult to mix hydrogen and oxygen above the surface of the liquid. Using electric switches 67, 68, 70, 71, after a certain period of time, the electrical circuits are switched to change the direction of the electric current in the electrodes 32 and 33. Before the electric current is switched, the operation of the electrolyzer is stopped, the valves change the direction of movement of hydrogen and oxygen through the pipes 58 and 60, then make a short circuit - switching electrical circuits using electrical switches 67, or 68, or 70, or 71.

The acceleration of the electrolysis process occurs using a catalyst 64, made in the form of a perforated tube made of nickel, palladium. The electrolyte contacts the catalyst 64, and the rate of the chemical reaction changes. The catalyst enters into an intermediate interaction with the electrolyte. Catalyst 64 restores its composition at the end and allows chemical reactions to be carried out at high rates at low temperatures. Compressed air supplied by compressor 74 transfers oxygen to the nozzle using gas pipeline 58. The air composition contains oxygen by volume 21%, by weight 23.1% of the total composition. All oxygen burns in the nozzle 57 of the steam generator 5, heating the water in the coil 8 of the steam generator. Further, all operations are repeated. As soon as the water level in the tank 7 decreases below the prescribed level, the controller 52 activates and closes the electric circuit supplying the electric pump 63. The electric pump 63 moves the ionized distilled water from the tank 72 to the tank 7. As soon as the water level in the tank 7 rises to a predetermined level , the level control 52 activates and opens the electric circuit supplying the electric pump 63. The water supply is interrupted.

The cell 7 can work in the second embodiment. The second option is the same as the first, differs from it in that the electrodes 32 and 33 are made in the form of plates.

The cell can be made in the third embodiment. The third option is the same as the first option, differs from it in that the electrolyzer is made in the form of rectangular batteries 107 containing brush-shaped electrodes 32 and 33, where tungsten needles 52 are mounted on the extreme plates 51 only on one side, the neutral electrode contains needles with two parties. The central plate is also a partition, made with the possibility of free movement of ions, but prevents the mixing of hydrogen and oxygen. Battery 107 may contain two or more sections. The hydrogen sections are connected between themselves and the plasmatron 13 by means of a gas pipeline 56. The oxygen sections are connected between themselves and the nozzle 57 of the steam generator 5 by means of a gas pipeline 58.

The electrolyzer can work in the fourth embodiment. The fourth option is the same as the first option, differs from it in that the capacitance of the electrolyzer 7, the electrodes 32 and 33 and the partitions 53 are made of cylindrical shape, mounted coaxially to each other.

The cell 7 can work in the fifth embodiment. The fifth option is the same as the fourth option, differs from it in that the electrolyzer 7 is made in the form of a cylindrical battery 108 containing several sections. The oxygen sections are interconnected and the nozzle 57 using the gas pipeline 58, the hydrogen sections are interconnected and the plasma torch 13 using the gas pipeline 60.

The electric generator can operate in the sixth embodiment. The sixth option is the same as options 1-5, differs from them in that the pipe 10 is divided into two sleeves (not shown in the drawing) using a tee coupling, one sleeve of the pipe 10 is connected to a steam turbine 9, and the other to an ionization chamber 11 and made with the possibility of combined use of steam, part of the steam is transferred to the steam turbine 9 without ionization, the other part is ionized in the chamber 11 using a plasma torch 13. The amount of supplied steam is controlled by valves.

The electric generator can work in the seventh version. The seventh option is the same as options 1-6, differs from them in that in the combustion chamber of the steam generator 5, all of the oxygen coming from the electrolytic cell 7 and oxygen 21% of the air volume are burned. Nitrogen (78% of the volume) of the air does not support combustion, remains inert (Polytechnical Dictionary. - M., 1976, p. 19). Gases from the steam generator 5 using a pump and pipes (not shown) are transferred to the cyclone 19 of the plasmatron 13. Hydrogen is supplied to the cyclone 13 from the capacity of the electrolyzer 7 and gases from the steam generator 5, 78% nitrogen from the volume, 0.9% argon and others inert gases. Gases nitrogen, argon and other inert gases blow a stream of plasma and turn into plasma (Polytechnical Dictionary. - M., 1976, p. 361). This increases the fuel efficiency.

Sources of information

1. Polytechnical dictionary. - M., 1976, p. 579, 346, 36.

2. The Great Soviet Encyclopedia. 5th ed., Vol. 19, p. 606.

Claims (1)

An electric generator containing a rotor, a stator, windings, windings in which an EMF is induced, a steam turbine, a steam generator, a steam condenser, a compressor, characterized in that the device is equipped with a water electrolyzer containing brush-shaped electrodes located in a vertical plane parallel to each other, needles, directed at each other, containing the proper gap, the electrodes are mounted in a rectangular or cylindrical container coaxially to each other, a perforated tube is installed at the bottom of the cell and the aerator-catalyst, the tube is connected to the compressor and is configured to move compressed air to the electrolytic tank to detach hydrogen and oxygen atoms from water, move oxygen to the steam generator nozzle, hydrogen to the plasma torch of the water vapor ionization chamber, the electrolyzer capacity is connected to the section by the inlet pipe condensate storage tanks, via a condensate line, an electric pump and with a liquid alkali tank through a metering device equipped with a solenoid and a time switch, the electrolyzer capacitance is connected to a plasma It is located in the ionization chamber by means of a tube and is capable of supplying hydrogen to the plasmatron, the plasma torch is connected to the compressor, the capacity of the electrolyzer is connected to the nozzle of the steam generator, and is capable of supplying oxygen to the nozzle, the ionization chamber is equipped with a plasmatron, reflector, collector, and steam tubes located at different angles of inclination, aimed at the plasma jet, made with the possibility of partial destruction and relaxation of molecular and ionic bonds and electrostatic the attraction of ions in water, detachment of one or more electrons from water vapor molecules, creation of free charge carriers, partial release of deuterium and its burning to create high energy to power a steam turbine of an electric generator, electrolysis electrodes are connected to an alternating current source through an electric machine converter, a sensor electrical pulses and switches are made with the possibility of the electrodes operating in different modes: at constant electric current at rated voltage AI; on pulsating direct current at rated voltage; on direct electric current at high voltage; with pulsating direct current at high voltage and a change in the direction of the electric current on the electrodes.

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