RU2675862C2 - Method for decomposition of water into oxygen and hydrogen and devices for its implementation - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to a method for the decomposition of water into oxygen and hydrogen and a device for its implementation. Method is carried out by affecting the water flowing through the interelectrode cavities, electric and magnetic fields. In this case, a constant pulsed electric field is supplied to coaxially arranged tubular insulated hydrogen electrodes of negative potential and to insulated oxygen electrodes of positive potential, separated by interelectrode cavities having inlet and outlet water holes, the volumes of which are connected to the volumes of hydrogen and oxygen electrodes through gas holes. In this connection, the water flowing between the electrodes under the action of electric and magnetic fields is decomposed into hydrogen and oxygen ions, hydrogen ions through the holes of the hydrogen electrode are attracted by a negative static field formed by a negative conductive hydrogen insulated surface, inside the hydrogen electrode, similarly, oxygen ions through the holes of the oxygen electrode are attracted by a positive static field formed by a positive insulated conductive surface, into the oxygen electrode, in which hydrogen and oxygen ions are neutralized, respectively, by negative and positive neutralization surfaces and in the form of atoms go out through each of their openings to further use.EFFECT: technical result is to increase the performance of the decomposition of water by increasing the energy of the electric and magnetic fields.4 cl, 4 dwg, 1 ex

Description

The invention relates to techniques for the decomposition of water into oxygen and hydrogen (hydrogen energy) and can be used as a unit for converting thermal energy when burning hydrogen into mechanical energy, in particular in vehicles where water is used instead of gasoline.

A known method of producing hydrogen from water (see patent No. 2456377), in which the decomposition of water occurs under the influence of a resonant electromagnetic field, the frequency of the nth harmonic which approaches the natural frequency of water. The disadvantage of this method is that when it is implemented, there is a change in the capacitive component of the LC circuit (s) due to the presence of its decomposition products in the water, leading to a change in the dielectric constant of the dielectric of the water capacitor, at a constant value of the inductive component. This phenomenon leads to a decrease in performance due to deviations from resonance in circuits with serial or parallel circuits. Also in the device implementing the method, there is a small contact area of the isolated capacitor plates with water, referred to a unit volume of the working chamber, which also leads to a decrease in the performance of water decomposition. Also known patent No. 2496917 a method of producing hydrogen from water, comprising the decomposition of water by an electric field using a water capacitor with insulated plates to which a high-voltage rectified voltage of a pulse form is applied, and the decomposition of water occurs under the influence of electric and magnetic fields, and the vector of the magnetic field is directed perpendicular to the electric field vector, while the vector acts on water simultaneously and with a frequency equal to the frequency of hydrodynamic natural oscillations of water. To implement the method, a device is used in which the decomposition of water by electric and magnetic fields occurs using at least two oscillatory circuits, while the capacitance of the first and the associated inductance of the second circuit and, accordingly, the capacitance of the second and the associated inductance of the first are charged and discharged with a given frequency, while the phase of the input voltage is shifted 90 degrees. The disadvantage of this method is that the electric field acts on water unidirectionally and periodically, and its duration is equal to the time of the downward curve of the input voltage, which halves the performance of the decomposition of water.

The technical result of the invention is to increase the productivity of water decomposition by increasing the energy of electric and magnetic fields.

The physics of the proposed device is as follows. The following sites contain information on known methods of decomposing water into oxygen and hydrogen https://yandex.ru/images/search?p=6&text= ways%20 decomposition%20water%20on%20 oxygen oxygen20 and%20 water we select the reaction of water decomposition by electric current electrolysis https://im0-tub-ru.yandex.net/i?id=09c0c7751466c174d9cc9dc81648bc91-sr&n=13 where the decomposition of water under the influence of electric current occurs according to equation 1., i.e. 2H ₂ O = 2H ₂ + O ₂ . But this equation does not show how much energy is spent on the decomposition of water. When heating water or when steam is decomposed (see patent No. 2142905), the thermal energy of Brownian motion cannot decompose water without the action of fields. Only when the field acts, the water dipoles are oriented along its intensity vector, reducing the Brownian motion, whose energy relaxes the atomic dipole bonds, and therefore, their ultimate destruction requires a reduced value of electromagnetic energy. (see also the video on the site https://www.youtube.com/watch?v=-ROZ0KU5ncM Given that water H ₂ O is an ideal dielectric (electrolyte) that contacts two electrodes, which in the complex is a water condenser bias currents, which form the energy of the electric field, and inductance currents form the energy of the magnetic field.The two energies generated by the currents differ from each other in the vector directions of their vector energies, which, acting on the dipole water molecules, destroy them, as a result of which the water molecules decay hydrogen and oxygen ions. Of course, the energy power of the fields should ensure the destruction of water molecules. The question is, where are the electrodes, if the energy of electric and magnetic fields freely passes through the non-conductive walls of the water vessel. The novelty of the invention is that the electrodes of the electrolyzer are insulated by a dielectric the permeability of which exceeds the dielectric constant of water of 80 units. Since the energy of the electric field is proportional to the capacitance of the water capacitor and the square of the voltage supplied to the electrodes of the water capacitor, and the energy of the magnetic field is proportional to the inductance and the square of the current passing through the inductance, by increasing these values, we can control the production rate of oxygen and hydrogen ions.

It should be noted that during electrolysis and the present invention, it is common that an electric field is involved in the decomposition of water into ions, which means, as indicated above, that the insulation of the electrodes does not matter. It only prevents the participation of electrode metals in the reaction and excludes the passage of current through water containing impurities dissolved in it. When the electrodes are insulated, water heating is excluded, which allows the use of unused thermal energy to reuse hydrogen to produce hydrogen and oxygen, thereby closing the energy cycle, which significantly increases the efficiency of the device.

In Fig 1, 2, 3, 4 shows the decomposition of water into oxygen and hydrogen. They comprise a dielectric housing 7 having openings 3 for entering water (steam) and openings 4 for exiting non-decomposing water. The housing contains tubular hollow (volume) cavities representing negative hydrogen electrodes 23 and coaxially hydrogen electrodes alternately through the interelectrode space 22 are located tubular hollow (volume) cavities representing positive oxygen electrodes 24. Dielectric baffles containing gas holes 6 separating interelectrode cavities from hydrogen electrodes 23 contain conductive negative surfaces 25 a dielectric partitions containing holes 6 dividing the intere The electrode cavities from the oxygen electrodes 24 contain positive conductive surfaces 26. In addition, the volumes of the hydrogen electrodes 23 before the hydrogen exit through the openings 19 contain neutralizing negative surfaces 14 and the volumes of the oxygen electrodes 24 before leaving the oxygen outlet 18 contain neutralizing positive surfaces 15. Negative and positive the potential on the conductive surfaces 25, 26 is supplied simultaneously and is a pulse rectified voltage with m. Fig. 2. The positive potential on the oxygen neutralization surface 15 and the negative potential on the hydrogen neutralization surface 14 whose potentials represent a pulsed rectified voltage, the pulses of which are supplied between the pulses supplied to the conductive surfaces 25 and 26. The holes 6 located on the electrodes are used to move gas ions in the electrode cavity and also not decomposed water to the outlet 4. Feeding on the conductive surfaces 25 and 26 of the pulse voltage and p consequently between these pulses for supplying the pulse voltage 14 and neutralization grid 15 obtain the neutralization of hydrogen ions and oxygen are pressurized through the openings 19 and 18 act to further use. The electrodes 23 and 24 represent the hollow plates of a water capacitor. These are water capacitors, which are connected in order to increase the energy of the electric field, while simultaneously receiving one total capacitor, the dielectric constant of the insulation of which must exceed the dielectric constant of water. The formed capacitor having a significant electrode surface, dielectric constant, the minimum distance between the electrodes significantly increases the electric field energy produced by it, which leads to a significant increase in the performance of the device for decomposing water (steam) into oxygen and hydrogen. When applying a regulated constant pulse voltage, it is possible to regulate the performance of water decomposition and, as a result, to exclude the output

not decomposed water. To minimize the voltage supplied to the DC capacitor in order to increase the range of regulation of the energy of the electric field, we use the energy of the magnetic field, the intensity vector of which is directed perpendicular to the vector of the electric field. To do this, we use a transformer emitter, the magnetic circuit of which is a closed loop made of electrical steel with sequentially mechanically connected spiral-shaped (similar to an inductor) parts 8 and a linear part 13, representing a rectangular or round shape in cross section. The efficiency of the emitting transformer lies in the fact that at a wavelength of three thousand kilometers, the magnetic flux through the transformer turns passes as many times as the length of the magnetic circuit fits in the wavelength. The magnetic flux of the radiating transformer represents the flux passing through steel and water, for this it is necessary that the spiral turns of the transformer on the left and right sides have an opposite winding. When 50 Hz voltage is applied to the primary coil 11 of the transformer, a 100 Hz change in direction of the magnetic field vectors directed perpendicular to the electric field vectors occurs, which leads to an intensification of water decomposition. The secondary coil 12 of the transformer through the diodes produces a sequential supply of pulses of the required polarity to the conductive surfaces 24, 25 and the neutralization grids 14, 15 cm. FIG. 2. Magnetic energy can be adjusted by the feedback coil 5 in FIG. 1 not conditionally shown. This coil is the load of the secondary coil of the transformer and plays the role of the primary. With the coincidence of the vectors of the magnetic strengths of the primary and feedback coils, we obtain positive feedback, and vice versa, with the vectors not coinciding, we obtain negative feedback.

The operation of the device is that decomposition occurs when water flows through the interelectrode cavities of an electric and magnetic field, while a constant pulsed electric field is formed by applying a negative potential to bulk isolated hydrogen electrodes and applying a positive potential to bulk isolated oxygen electrodes, and the vector electric field intensity directed perpendicular to the magnetic field vector which is formed by a closed magnetic circuit with holding two spiral-shaped swirls with water flowing between the swirls and opposite poles with respect to water, thus, the water flowing between the electrodes under the action of electric and magnetic fields decomposes into hydrogen and oxygen ions, while hydrogen ions are attracted through the holes 6 of the hydrogen electrode by negative static field formed by a negative conductive hydrogen insulated surface inside the hydrogen electrode is similar to oxygen ions through about 6 Verstov oxygen electrode attract positive static field formed by the positive isolated conductive surface in which hydrogen and oxygen ions are neutralized by the negative and positive respectively neutralizing surfaces and in the form of atoms located at every opening to its further practical use. The electric field formed by the conductive surfaces has a rectified pulsed character, between the pulses of which are simultaneously fed to a neutralizing non-isolated hydrogen surface, a negative potential in the hydrogen cavity and a positive potential in the neutralizing non-isolated oxygen surface, in the oxygen cavity. In the absence of neutralizing surfaces in the electrode volumes, the conductive surfaces between the inlet and outlet gas openings have an uninsulated inner surface.

According to FIG. 4, volumetric hydrogen and oxygen electrodes with interelectode cavities can have a rectangular shape in horizontal and vertical sections.

Claims (4)

1. The method of decomposition of water into oxygen and hydrogen, carried out by exposure to water flowing through interelectrode cavities, electric and magnetic fields, characterized in that a constant pulsed electric field is applied to coaxially arranged tubular insulated hydrogen electrodes of negative potential and to isolated oxygen electrodes of positive potential separated by interelectrode cavities having inlet and outlet water openings, the volumes of which are connected through gas openings They are connected with the volumes of hydrogen and oxygen electrodes, while the water flowing between the electrodes under the influence of electric and magnetic fields decomposes into hydrogen and oxygen ions, and hydrogen ions are attracted through the holes of the hydrogen electrode by a negative static field formed by a negative conductive hydrogen insulated surface inside the hydrogen electrode, similarly, oxygen ions through the openings of the oxygen electrode are attracted by a positive static field formed by positively insulated conductive surface inside the oxygen electrode in which hydrogen and oxygen ions are neutralized by the negative and positive respectively neutralizing surfaces and in the form of atoms located every their holes for further use. 2. The method according to claim 1, characterized in that the electric field formed by the conductive surfaces has a rectified pulse character, between the pulses of which are simultaneously fed to the neutralizing non-insulated hydrogen surface located in the hydrogen cavity, the negative potential and to the neutralizing non-insulated oxygen surface located in the oxygen cavity, a positive potential. 3. A device for implementing the method according to any one of claims 1, 2, characterized in that it contains tubular coaxially arranged bulk hydrogen and oxygen isolated electrodes separated by interelectrode cavities having inlet and outlet water openings, the volumes of which are connected through the gas openings to the volumes of hydrogen and oxygen electrodes having respectively neutralizing surfaces and outlet hydrogen and oxygen gas openings. 4. The device according to claim 3, characterized in that the volumetric hydrogen and oxygen electrodes with interelectrode cavities have a rectangular shape in horizontal and vertical sections.

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