RU2260077C1 - Device for splitting water on hydrogen and oxygen - Google Patents

Abstract

FIELD: electrochemical industry.

SUBSTANCE: device is made in form of vacuum tank, provided with float chamber, vacuum adjuster, vacuum pumps and output gas lines. Upper portion of electrolyzer tank is connected via input pipe to middle portion of vacuum tank and via output pipe through electric pump - to lower base of vacuum tank. Float chamber with hermetically sealed parts, float and plates of permanent magnet is made with possible automatic removal of condensate from vacuum tank to electrolyzer tank. Output gas lines of vacuum tank are connected to burner through vacuum pumps and valves, and vacuum adjuster is provided with arrow of permanent magnet, along perimeter of movement of which hermetically sealed portions are placed, connected to vacuum pumps via electric circuit and made with possible interaction of magnetic field of arrow with hermetically sealed parts for creating and preserving given vacuum parameters and parameters for controlling operation of pumps. Portion of electrodes is made of nickel with possible combination of functions of electrode and catalyst, and pallet of electrolyzer tank is provided with ultrasound or infrasound generator.

EFFECT: simplified construction, higher productiveness, broader functional capabilities, higher quality, higher efficiency, higher reliability, higher durability.

5 cl, 30 dwg

Description

The invention relates to the electrical industry and can be used to obtain cheap high-calorific fuel, water and oxygen directly from water to power steam boilers, cars, internal combustion engines and other equipment.

A device is known for splitting water into hydrogen and oxygen, containing a hermetically sealed electrolyte capacitance of a cell in which a battery of stainless steel electrodes is mounted, interconnected through washers of dielectric material using bolts and nuts. The anodes and cathodes are respectively connected in series with each other and with an alternating current source through an electrical machine converter, an electrical pulse generator, and electrical switches. The first inlet tube of the electrolytic tank is connected to the tank with distilled water through a level regulator. The second inlet tube is connected to the tank with liquid alkali through a dispenser equipped with a solenoid and a timer, and the capacity of the electrolyzer is connected to a device for separating hydrogen from oxygen. / Patent of RUSSIA 2227177 C2, IPC С 25 В 1/04, January 27, 2004 /.

A disadvantage of the known technical solution is the complexity of the design of the device for separating hydrogen from oxygen, insufficient productivity, insufficient quality of separation of hydrogen from oxygen.

The aim of the invention is to simplify the design, increase productivity, expand technological capabilities, improve the quality of separation of hydrogen from oxygen, automatically remove condensate from the vacuum cylinder into the electrolytic tank, improve the reliability and durability of the vacuum regulator.

This goal is achieved by the fact that the device for separating hydrogen from oxygen is made in the form of a vacuum cylinder equipped with a float chamber, a vacuum regulator, vacuum and pumps, outlet gas pipelines, the upper part of the electrolytic cell is connected via an inlet tube to the middle part of the vacuum cylinder using an exhaust pipe through an electric pump with a lower base for a vacuum cylinder. The float chamber with reed switches, float and plates made of a permanent magnet is made with the possibility of automatic removal of condensate from the vacuum cylinder into the capacity of the cell. The outlet gas pipelines of the vacuum cylinder are connected to the burner through vacuum pumps and valves, the vacuum regulator is equipped with a permanent magnet arrow, along the perimeter of the movement of which there are reed switches connected to vacuum pumps by an electric circuit and made with the possibility of interaction of the magnetic field of the arrow with reed switches to create and maintain the specified vacuum parameters and control the operation of the pumps. Moreover, part of the electrodes is made of nickel with the possibility of combining the functions of the electrode and the catalyst, and the tray of the electrolytic cell is equipped with an ultrasonic or infrasound generator. The electrodes can be made of plate, perforated, corrugated, brush-shaped mesh, cell, cell honeycomb, cell scallop tubular from the outer and inner tubes having a cross section in the form of a square, circle, oval, rhombus, polygon, made in the form of multi-storey shelves mounted in rows on different levels so that the electrodes of one row enter the grooves of another row, between the shelves and rows there is a gap and a different polarity. The capacity of the electrolyzer can be equipped with a compressor and a vacuum valve.

The novelty of the claimed technical solution in comparison with patent 2227177 is due to the fact that due to the use of different electrodes, the expansion of technological capabilities is provided.

By using a vacuum cylinder without diaphragms, without bypass pipes and valves and connecting it to the upper part of the cell using two tubes, where one tube is connected to the middle of the vacuum cylinder, the other to the lower base of the vacuum cylinder, the outlet tubes of the vacuum cylinder connected to the burner through vacuum pumps, it improves the quality of separation of hydrogen from oxygen, simplifies the design and automatically removes condensate from the cylinder into the cell.

Through the use of an ultrasonic or infrasonic generator during electrolysis, an increase in productivity is provided.

Through the use of a compressor and a vacuum valve, technological capabilities are expanding.

Due to the implementation of the part of the nickel electrodes, the combination of the functions of the electrode and the catalyst is ensured, which helps to increase productivity.

Due to the use of the magnetic needle of the vacuum regulator and the reed switches, the magnetic field of the arrow with the reed switches is provided to create and maintain the specified vacuum parameters and control the operation of the vacuum pumps.

Due to the vacuum in the electrolysis tank, hydrogen and oxygen are extracted during the electrolysis using vacuum pumps.

Due to the vacuum in the capacity of the vacuum cylinder, the separation of hydrogen from oxygen is improved by the difference in the specific gravity of the gases.

Under the influence of excess pressure in the electrolysis tank, a compressor provides the extraction of hydrogen and oxygen in the electrolysis process.

Due to the vacuum valve simplifies the design of the fluid level controller, increasing reliability and durability.

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

The invention is illustrated by drawings, where

figure 1 shows a diagram of a device for a water electrolyzer;

figure 2 shows a diagram of a water electrolyzer equipped with a compressor and a vacuum valve;

figure 3 shows a diagram of the connection of the electrodes in the battery;

Figures 4 and 5 show batteries with plate electrodes;

in Fig.6 and 7 - the same with corrugated electrodes;

Fig.8 is the same with perforated electrodes;

figure 9 is the same with the cell electrodes;

figure 10 shows a longitudinal view of a plate electrode;

11 and 12 show brush-shaped electrodes;

13 and 14 and 15 depict cell electrodes;

in Fig.16 shows the connection of the cell electrodes with shield-shaped electrodes;

on Fig depicted cell cellular electrodes;

on Fig and 19 depict shelf electrodes;

in Fig.20 shows tubular electrodes of a cylindrical capacity of the electrolyzer;

21 and 22 depict cylindrical needle electrodes;

23 depicts square needle electrodes;

on Fig depicted multifaceted needle electrodes;

on Fig depicts a burner device for explosive gas;

on Fig shows a diagram of the device dispenser and solenoid;

on Fig depicts a comb electrode;

on Fig depicts a battery device with tubular electrodes;

on Fig shows a longitudinal section of a tubular electrode;

on Fig depicts a device for a vacuum regulator.

The water electrolyzer consists of a sealed container 1 made of stainless steel. The container 1 is provided with a cover 2. Inside the container 1, a battery 3 is installed, made of either plate 4, or corrugated plate 5, or plate perforated 6, or mesh 7 stainless steel electrodes. These electrodes at the corners have openings 8, through them they are rigidly connected to each other through washers 9 of dielectric material with bolts 10 and nuts 11. The battery 3 is equipped with legs 12 and side stops 13 of dielectric material. Between the nuts 11 and the washer 9 are installed spring-loaded split washers 14. Between the electrodes 4 or 5, 6, 7 there is a proper gap and different polarity. Holes 15 for moving the electrolyte can be located on the electrodes. The electrodes 4, 5, 6, 7 can be made of stainless steel by deformation by pressure using a stamp for sheet hot stamping or cast on foundry machines under pressure in vacuum. At the bottom of the tank 1 of the electrolyzer there is a drain pipe 16 with a valve 17 made with the possibility of draining the electrolyte in the winter period of time in frost to avoid defrosting the system.

The electrodes in the battery 3 can be made in the second embodiment. The second option is the same as the first, differs from them in that the electrodes 18 are made brush-shaped, the needles 19 of which are directed to the base 20 of the oppositely arranged plates. Between the base 20 of the plates and the ends of the needles 19 there is a proper gap and different polarity. Brush-shaped electrodes 18 are made by casting on lettering machines under pressure in vacuum.

The electrodes 18 can be made in the third embodiment. The third option is the same as the second option, differs from it in that the brush-shaped electrodes 18 are directed at each other with their ends of the needles 19. Between the ends of the needles 19 there is a proper gap and different polarity.

The electrodes 21 in the battery 3 can be performed in the fourth embodiment. The fourth option is the same as the third option, differs from it in that the electrodes 21 are made cell. Cells 22 may have a cross-section in the form of a circle, oval, square, rhombus, polyhedron, made on casting machines under pressure in a vacuum. Between the cell electrodes 21, brush-shaped electrodes 18 are installed, on both sides of their needles 19 are installed in the center of each cell 22. Between the needles 19 and the walls of the cells 22 there is a proper gap and different polarity.

The electrodes 23 in the battery 3 can be performed in the fifth embodiment. The fifth option is the same as the fourth option, differs from it in that the electrodes are made in the form of honeycomb cells 23 containing inside the diaphragm 24 similar to a honeycomb. Brush-shaped electrodes 18 are installed between the cell electrodes 23 of the electrodes 18. The cell cell electrodes 23 have a cross section in the form of a circle or an oval, or a square, or a rhombus, or a polygon. Between the walls of the cells 22 of the electrodes 23, brush-shaped electrodes 18 are installed on both sides, the needles 19 of the brush-shaped electrodes 18 are installed in the center of each cell 22. Between the needles 19 and the walls of the cells 22 and the diaphragm 24 there is a proper gap and different polarity. The electrodes 23 and 18 are made by casting on foundry machines under pressure in a vacuum.

The electrodes 25 in the battery 3 can be performed in the sixth embodiment. The sixth option is the same as the fourth option, differs from it in that the electrodes 25 are made in the form of scallop cell electrodes containing longitudinal plates with one row of rigidly fixed needles 26. The brush-shaped electrodes 25 have only one row of needles, and the brush-shaped electrodes have many rows of needles 19. The needles of the scallop cell electrodes 25 are mounted in such a way as to give the cells 22 a proper shape, for example, the shape of a square, circle, oval, rhombus, polyhedron. Between the comb scallop electrodes 25, brush-shaped electrodes 18 are installed on both sides, their needles 19 are installed in the center of each cell 22 of the electrodes 25. There is a proper gap and different polarity between the needles 19 and the walls of the cells 22 of the electrodes 25. The electrodes 18 and 25 are made on stainless steel casting machines under pressure in a vacuum.

The electrodes 27 in the battery 3 can be made in the seventh option / 5 /. The seventh option is the same as options 2-6, differs from them in that the electrodes 27 are made tubular of the outer 28 and inner tubes 29. The outer tubes 28 are interconnected into a battery 3, have a cross-section of holes in the form of a circle, oval, square , rhombus, polyhedron, inside them are located inner tubes 29 having a cross section similar to outer tubes 28. The inner tubes 29 are rigidly fixed to the frame 30. Between the outer 28 and inner 29 tubes there is a proper gap and different polarity. The batteries 3 are provided with legs 12 and side stops 13 of dielectric material.

The electrodes 32 in the battery 3 can be made in the eighth embodiment. The eighth option is the same as the 1-7 options, differs from them in that the electrodes 32 are made in the form of cylinders mounted in a cylindrical container coaxially to each other. Between it there is a proper gap and different polarity.

The electrodes 33 may be made in the ninth embodiment. The ninth option is the same as the eighth option, differs from it in that the electrodes 33 are made in the form of a polyhedron, mounted parallel to each other in a multifaceted capacitance. Between them there is a proper gap and different polarity.

The electrodes 34 in the battery 3 can be performed in the tenth embodiment. The tenth option is the same as the 1-9 options, differs from them in that some of the electrodes are made of nickel. These electrodes are located among electrodes made of stainless steel. Nickel electrodes serve simultaneously as catalysts, are configured to enter into an intermediate interaction with electrolyte substances, they restore their properties by the end of the transformation.

The electrodes in the battery 3 can be made in the eleventh embodiment. The eleventh option is the same as options 1-10, differs from them in that on the pallet 35, with the hole of the proper diameter, an ultrasonic or infrasound generator 36 is mounted and rigidly fixed, configured to generate and generate elastic waves with an oscillation frequency of 20 kHz up to 1 GHz or less than 16 Hz during electrolysis to increase productivity.

The electrolyzer 37 in the battery 3 can be made in the 12th version. The twelfth variant is the same as the first variant, differs from it in that the electrodes 37 are made in the form of multi-storey shelves 38. The shelf electrodes 37 are mounted in rows at different levels so that the electrodes 37 of one row enter the gap of the other row, and between the shelves and in rows there is a proper gap and different polarity.

The anodes of the electrodes are connected in series with each other, the cathodes of the electrodes are connected in series with each other and the AC source 39 by means of an electric circuit through an electric machine converter 40, an electric pulse generator 41 and electric switches 42, 43, 44, 45, 46, configured to convert AC into direct current, low voltage current - into high voltage current, creating electrical pulses of the proper frequency and duration and ability to work in different modes: Example, at rated voltage or at rated voltage in pulsed mode, or at high voltage. The capacitance 1 of the cell is connected to the tank 47 with distilled water using a tube 48. At the end of the tube 48, a liquid level regulator is arranged in the form of a check valve 49. A valve 50 is installed on the tube 48 and is configured to maintain a given level of liquid in the tank 1 of the cell at the help of a level regulator - a non-return valve 49. The upper part of the electrolytic tank 1 is connected to the lower base of the tank 51, filled with liquid alkali / sodium hydroxide or potassium hydroxide / through the dispenser 52. The dispenser 52 is equipped with salt oidom 53 and 54. The time switch is configured to move liquid through the alkali doses of time. The dispenser 52 consists of a cylinder 55, a piston 56, a rod 57, a microswitch 58. The solenoid 53 consists of an inductor 59, a core 60, a spring 61.

The device for separating hydrogen from oxygen is made in the form of a vacuum cylinder 62 containing inlet tubes — a gas line 63 and an outlet tube 64. The upper part of the electrolytic tank 1 is connected to the middle of the vacuum cylinder 62 by means of a gas line 63, and the upper part of the electrolyzer is connected to the lower the base of the vacuum cylinder 62 using the tube 64 through the electric pump 65. In the vacuum cylinder or next to the cylinder 62, a float chamber 66 is installed, in which reed switches 67 and 68 are installed in the upper and lower bases, and p a float 69, on its upper and lower bases, permanent magnet plates 70 are mounted, arranged to move hydrogen and oxygen from the electrolytic tank 1 to the vacuum cylinder 62 and to automatically remove condensate from the vacuum cylinder 62 to the electrolyzer tank 1 in the initial position. The vacuum cylinder 62 is equipped with vacuum pumps 71 and 72, a vacuum regulator 73 and gas pipelines 74 and 75, configured to accelerate the extraction of hydrogen and oxygen from water during electrolysis and to improve the quality of separation of hydrogen from oxygen and move them to the burner 76 through gas pipelines 74 and 75 and simplification of design. The gas lines 74 and 75 are provided with valves 77. They are configured to control the supply of gaseous fuels of hydrogen and oxygen to the burner 76. The vacuum regulator 73 and the vacuum gauge are combined and made of a hollow brass tube 78, the cavity of which communicates with the reduced pressure of the vacuum cylinder 62. The brass tube 78 is located in a cylindrical box 79 made of polymer materials, equipped with a scale 80, graduated (in mm) of the mercury column. The loose end of tube 78 is connected to arrow 81 by a gear 82 made of bronze. The arrow 81 of the vacuum gauge is made of a permanent magnet. Arrows 81 are located at appropriate points in the box 79 along the perimeter of the motion path and the reed switches 83 and 84 are rigidly fixed. The magnetic field of the arrow 81 is connected with the reed switches 81 to automatically control and maintain a given limit of low pressure parameters and control the operation of vacuum pumps 71 and 72. Reed switches 83 are configured to open the electric circuit supplying the vacuum pumps 71 and 72, and the reed switch 84 operates to close the electric circuit supplying the vacuum pumps 71 and 72. The burner 76 consists of ear tubes 85 and 86. Tube 85 is connected to the gas conduit 74, which is moved by hydrogen, and the tube 86 is connected to the gas conduit 75 by which oxygen is moved.

A device for splitting water into hydrogen and oxygen can be performed in the second embodiment. The second option is the same as the first option, differs from it in that the tank 1 is equipped with a compressor 87 and a tube 88. The tank 47 is filled with distilled water, connected to the tank 1 of the electrolyzer using a tube 48. The tank 47 is corked by a plug 89. Made with the possibility of movement distilled water from tank 47 to tank 1 by gravity and maintaining a predetermined liquid level in tank 1 using a vacuum valve.

The device operates as follows.

We open valves 50, 70 on the tube 48 and gas pipelines 74 and 75. We close the electric circuit supplying the time switch 54 and the flat plate 4, or plate corrugated 5, or plate perforated 6, or mesh 7, or brush-like 18, or cell 21, or cell honeycomb 23, or cell scallop 25, or tubular 27 / outer 28 and inner 29 / electrodes, or cylindrical 32, or multifaceted 33, or shelf 37, ultrasonic generator 36 or infrasound generator, through electrical switches 42 and 43, through electric machines converter 40. In this case, the machine-converter 40 converts alternating current to direct current at rated voltage and feeds electrodes 4 or 5, 6, 7, 18, 21, 23, 25, 27, 32, 33, 34, 37. Distilled water from capacity 47 moves from top to bottom along the tube 48, into the tank 1 of the electrolyzer 1 by gravity. At the same time, the air moves with bubbles from bottom to top along the tube 48, filling the proper volume of vacuum in the tank 47. As soon as distilled water fills the proper volume in the tank 1 of the electrolyzer to the level of the tube 48, the lower end of the tube 48 is closed by liquid and prevents the air from moving from bottom to top in the tank 47 The vacuum in the tank 47 prevents the liquid from moving from top to bottom. The movement of fluid from the tank 47 is stopped. After a period of time, the time relay 54 opens the electric circuit supplying the solenoid 53. In the solenoid 53, the magnetic field disappears, under the action of the spring 61, the core 60 moves the piston 56 with the rod 57 along the cylinder 55. The dosed portion of liquid alkali / potassium hydroxide or sodium hydroxide / moves into the tank 1 of the cell through the tube. As soon as the piston 56 moves to the microswitch 58, the microswitch 58 closes the electrical circuit supplying the solenoid 53 and the time relay 54. A magnetic field is generated in the solenoid 53. The solenoid 53 is activated and moves the piston 56 to its original position. When an electric current passes through the electrodes of the electrolyzer 1, electrochemical processes of the movement of ions to the electrodes occur. Positively charged ions move toward the cathode, and anode oxygen ions move toward the cathode. The electric current along the external circuit is the process of movement of ions from the anode to the cathode. At the anode and cathode, a neutralization reaction of ions occurs, which leads to the formation of atoms and molecules and the release of substances at the oxygen anode, and hydrogen at the cathode. In distilled water there are no salts and other impurities, therefore, precipitation and deposits of salts do not remain on the electrodes. In distilled water, molecular and ionic bonds are not stable enough. During the electrolysis of alkaline distilled water, the destruction of molecular and ionic bonds and the splitting of water into hydrogen and oxygen are faster than when using tap water. The vacuum regulator 73 regulates and maintains the specified vacuum parameters in the vacuum cylinder 62 and controls the operation of the vacuum pumps 71 and 72 in automatic mode. Vacuum pumps 71 and 72, working, create a reduced pressure / vacuum / in the vacuum cylinder 62 and in the tank 1 of the cell. Due to the vacuum in the tank 1 of the electrolyzer 1, hydrogen and oxygen are extracted from the electrolyte during the electrolysis, the splitting of water into hydrogen and oxygen and acceleration to the vacuum cylinder 63 are accelerated. In the vacuum cylinder 63, hydrogen is separated from oxygen by the difference in the specific gravity of the gases and moves using vacuum pumps 71 and 72 to the burner 76 through gas pipelines 74 and 75.

The electrodes in the battery 3 can work in the second embodiment. The second option is the same as the first, differs from it in that the electrodes 18 are made brush-shaped, the needles 19 of which are directed to the base 20 of the plates located on the opposite side. Between the base of the plates 20 and the ends of the needles 19 there is a proper gap and different polarity.

The electrodes 18 in the battery 3 can work in the third embodiment. The third option is the same as the second option, differs from it in that the ends of the needles 19 of the brush electrodes 18 are directed at each other. Between the ends of the needles 19 there is a proper gap and different polarity.

The electrodes 21 in the battery 3 can work in the fourth embodiment. The fourth option is the same as the third option, differs from it in that the electrodes 21 are made cell. The cell electrodes 21 in cross section may be in the form of cells 22 in the form of a circle, oval, square, rhombus, polyhedron. Between the cell electrodes 21, brush-shaped electrodes 18 are installed on two sides, their needles 19 are installed in the center of each cell 22. Between the needles 19 and the walls of the cells 22 of the electrodes 21 there is a proper gap and different polarity.

The electrodes 23 in the battery 3 can work in the fifth embodiment. The fifth option is the same as the fourth option, differs from it in that the electrodes 23 are made in the form of cell honeycomb electrodes, inside the cells there is a diaphragm 24 similarly to bee cells. Cells 22 in the electrodes 23 may have a cross section in the form of a circle, oval, square, rhombus, polygon. Between the electrodes 23, brush-shaped electrodes 18 are installed, needles of the brush-shaped electrodes 18 are installed in the center of each cell 22. Between the needles 19 and the walls of the cells 22 and the diaphragm 24 there is a proper gap and different polarity.

The electrodes 25 in the battery 3 can work in the sixth embodiment. The sixth option is the same as the fourth option, differs from it in that the electrodes 25 are made in the form of scallop cell electrodes 25 containing a plate with one row of needles 26, mounted in such a way as to give the cells 22 a circle, oval, square, diamond shape, polygon. Brush-shaped electrodes 18 are installed between the cell comb electrodes 25, their needles 19 are installed in the center of each cell 22 of the electrodes 25. There is a proper gap and different polarity between the electrode needles 19 and the walls of the cells 22.

The electrodes 27 in the battery 3 can work in the seventh embodiment. The seventh option is the same as 2-6 options, differs from them in that the electrodes 27 are made tubular. The outer tubes 28 are interconnected into a single frame in the battery 3. Inside the outer tubes 28 are inner tubes 29 located coaxially to each other. The cross section of the pipes may take the form of a circle, oval, square, polygon, rhombus. The inner tubes 29 are rigidly fixed to the frame 30. Between the outer 28 and the inner tubes 29 there is a proper clearance and different polarity. The battery 3 is equipped with legs 12 and side stops 13 of dielectric material.

The electrodes 32 in the battery 3 can work in the eighth embodiment. The eighth option is the same as the 1-7 options, differs from them in that the electrodes 32 are made in the form of cylinders mounted in a cylindrical container coaxially to each other. Between them there is a proper gap and different polarity. The electrodes 33 in the battery 3 can work in the ninth embodiment. The ninth option is the same as the eighth option, differs from it in that the electrodes 33 are made in the form of polyhedrons installed in a polyhedral container parallel to each other. Between them there is a proper gap and different polarity.

The electrodes 34 in the battery 3 can operate in the ninth embodiment. The tenth option is the same as options 1-9, differs from them in that part of the electrodes are made of nickel, and part is made of stainless steel, these electrodes are interconnected. Nickel electrodes act as catalysts. Made with the possibility of entering into intermediate interactions with electrolyte substances, at the end of electrolysis they restore their properties.

The electrodes in the battery 3 can be made in the eleventh embodiment. The eleventh option is the same as the 1-10 options, differs from them in that an ultrasonic or infrasound generator 36 is mounted and rigidly fixed to the pallet 35, configured to generate and generate elastic waves. In the process of electrolysis, the generator 36 creates elastic waves interacting with the electrochemical processes of ion movement, leads to an acceleration of the destruction of molecular and ionic bonds, accelerates the splitting of water into hydrogen and oxygen, increases productivity and reduces the energy cost of splitting water.

The electrodes 37 in the battery 3 can be made in the twelfth embodiment. The twelfth option is the same as the 1st option, differs from it in that the electrodes 37 are made in the form of multi-storey shelves. The shelves of the electrodes are installed at different levels so that the shelves 37 of one row fit into the grooves of the shelves of the other row. Between the rows of shelves there is a proper gap and different polarity. The electrodes 37 can be located both in the vertical and in the horizontal plane.

Electrodes 4, 5, 6, 7, 18, 21, 23, 25, 27, 33, 37 can work in the second mode. The second mode is the same as the first mode, differs from it in that the electrodes are connected to an alternating current source 39 through an electric machine converter 40, an electric pulse generator 41 and electric switches 42 and 44. In this case, the alternating current is converted to direct current. An electric pulse generator 41 generates electric pulses on the electrodes at a nominal voltage of an electric current.

Electrodes 4, 5, 6, 7, 18, 21, 23, 25, 27, 33, 34, 37 can work in the third mode. The third mode is the same as the first mode, differs from it in that the electrodes are connected to an alternating current source 39 through an electric machine converter 40 and electric switches 42 and 45. In this case, the alternating current is converted to direct current, the low voltage current is converted to high voltage current tens of thousands of volts.

The vacuum regulator 73 operates as follows. When the vacuum pumps 71 and 72 are operating, a low pressure vacuum is created in the vacuum cylinder 62 and the capacity 1 of the electrolyzer. The tubes of the vacuum regulator 73 communicate with the brass hollow tube 78, when the pressure changes, the hollow tube 78 of the vacuum regulator 73 is twisted somewhat, its movement is transmitted using the transmission mechanism 82 to change the position of the arrow 81. The arrow 81 rotates and interacts with its magnetic field of a permanent magnet with reed switch 83. Under the influence of the magnetic field of the arrow 81, the reed switch 83 opens the electric circuit supplying the vacuum pumps 71 and 72. The vacuum pumps 71 and 72 stop working. By electrolysis of water, water is decomposed into hydrogen and oxygen. Hydrogen and oxygen are transferred from the tank 1 of the electrolyzer to the vacuum cylinder 62 and fills it. In the vacuum cylinder 62, hydrogen is separated from oxygen in a vacuum. Hydrogen moves up, and oxygen goes down from the difference in the specific gravity of the gases. From the vacuum cylinder 62 it moves to the burner 76, hydrogen moves through the gas line 74, oxygen - through the gas line 75. In this case, oxygen moves to the central tube 86, and hydrogen - to the inter-space between the tubes 86 and 85 in the burner 76. As soon as the increase pressure above the specified parameters in the vacuum cylinder 62, the pressure through the tube is transmitted to the vacuum regulator 73. The brass tube 78, with increasing pressure, is straightened and moved to its original position. As soon as the pressure reaches the proper parameter, the arrow 81 moves to the reed switch 84 and acts on the reed switch 84 with its magnetic field. The reed switch 84 closes the electric circuit supplying the vacuum pumps 71 and 72. The vacuum pumps begin to work and move hydrogen and oxygen. A vacuum pump transfers hydrogen from a vacuum cylinder 62 to a burner 76, and a vacuum pump 72 transfers oxygen from a vacuum cylinder 62 to a burner 76. Explosive gas can be used as fuel in steam boilers for heating residential and industrial premises, in steam steam locomotive boilers, steam boilers in power plants, in internal combustion engines and other machines. In the process of electrolysis and the movement of hydrogen and oxygen on the capacitance 1 of the electrolyzer, part of the water vapor enters the vacuum cylinder 62. Vapors are cooled and converted to condensate / distilled water. As soon as the condensate level rises to the level of the upper reed switch 67, the float floats up, moves from bottom to top in the float chamber 66, the float 69 interacts with the reed switch 67 by the magnetic field of the permanent magnet. Reed switch 67 closes the electric circuit supplying the electric pump 65. The electric pump 65 moves the condensate from vacuum cylinder 62 into the tank 1 of the cell through the tube 64 to its original position. As soon as all the condensate has been removed, the float 69 moves from top to bottom and interacts with the reed switch 68 in the float chamber 66 and the magnetic field of the permanent magnet located on the float 69. Reed switch 68 opens the electric circuit supplying the electric pump 65. The pump 65 stops working.

A device for splitting water into hydrogen and oxygen can work in the second embodiment. The second option is the same as the first option, differs from it in that the electrolyzer of the Veda is equipped with a compressor 87 / Fig. 28/. We close the electric circuit supplying compressor 87. Compressor 87 creates excess pressure, compressed air with a pressure of at least 0.2 MPa / 2 kgf / cm ² / and feeds into the tank 1 electrolyzer under the pan 35. The compressed air under the pan is evenly distributed and moves through the holes of the pan 35 from the bottom up with the help of air bubbles. Air bubbles absorb the hydrogen and oxygen bubbles released during the electrolysis and tear them away from the electrolyte or water. Hydrogen and oxygen move into the vacuum cylinder 62 under the influence of the difference in the specific gravity of the gases. There, hydrogen is separated from oxygen by the difference in the specific gravity of the gases. Hydrogen moves through gas line 74, and oxygen moves through gas line 75 to burner 76.

Claims (5)

1. A device for splitting water into hydrogen and oxygen, containing a sealed electrolytic tank filled with electrolyte, in which a battery of stainless steel electrodes is installed, interconnected through washers of dielectric material with bolts and nuts, the anodes and cathodes of which, respectively, in series interconnected and with an alternating current source through an electric machine converter, an electric pulse generator and electrical switches, the first input tube of the electrolyte the isera is connected to the tank with distilled water through a level regulator, the second inlet pipe is connected to the tank with liquid alkali through a dispenser equipped with a solenoid and a timer, and the capacity of the cell is connected to a device for separating hydrogen from oxygen, characterized in that the device for separating hydrogen from oxygen is made in the form of a vacuum cylinder, equipped with a float chamber, a vacuum regulator, vacuum pumps and outlet gas pipelines, the upper part of the electrolysis tank is connected using an inlet pipe plugs with the middle part of the vacuum cylinder and with the help of the outlet tube through the electric pump - with the lower base of the vacuum cylinder, the float chamber with reed switches, the float and plates from the permanent magnet is made with the possibility of automatic removal of condensate from the vacuum cylinder into the capacity of the electrolyzer, outlet gas pipelines the vacuum cylinder is connected to the burner through vacuum pumps and valves, and the vacuum regulator is equipped with a permanent magnet arrow, along the perimeter of the movement of which there are reed switches connected to the vacuum pump using an electric circuit and made with the possibility of interaction of the magnetic field with the reed switches to create and maintain the specified vacuum parameters and control the operation of the pumps, some of the electrodes are made of nickel with the possibility of combining the functions of the electrode and the catalyst, and the electrolyzer capacitance pan is equipped with ultrasonic or infrasonic generator. 2. The device according to claim 1, characterized in that the electrodes are made of plate, perforated, corrugated, brush-like mesh, cell, cell honeycomb, cell scallop. 3. The device according to claim 1, characterized in that the electrodes are made in the form of external and internal pipes of different polarity, the cross section of which may be in the form of a circle, oval, square, rhombus, polygon, while the inner pipes are rigidly fixed to the frame, and between there is a gap between the inner and outer pipes. 4. The device according to claim 1, characterized in that the electrodes are made in the form of multi-storey shelves installed in rows at different levels so that the electrodes of one row enter the grooves of another row, and there is a gap and a different polarity between the shelves and the rows. 5. The device according to claim 1, characterized in that the capacity of the cell is equipped with a compressor and a vacuum valve.

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