RU2836668C1 - Device of multi-electrode type for generation of thermal energy of hydrogen and oxygen - Google Patents

Abstract

FIELD: physical and chemical processes.

SUBSTANCE: invention relates to physical and chemical processes for obtaining thermal energy, hydrogen and oxygen during electrolysis of water. Multielectrode type device for obtaining thermal energy of hydrogen and oxygen comprises a housing made of dielectric material, an interelectrode chamber, inlet and outlet nozzles for flow of alkaline solution, anode connected to positive pole of power supply, and a cathode equipped with a dielectric cathode holder, connected to the negative pole of the power supply, the cylindrical housing is equipped with removable cathode and anode side covers, in each of which there are 8 hollow cylindrical electrodes equipped with cylindrical dielectric holders, with possibility of interelectrode distance adjustment from 20 to 40 mm and change of number of electrode pairs from 2 to 8, anodes and cathodes are arranged symmetrically relative to each other; at that, cathodes are made of bronze, anodes are made of stainless steel.

EFFECT: increased stability of the technological process and energy parameters of the device, as well as the possibility of adjusting the device to control power by changing the interelectrode space and the number of electrodes.

1 cl, 2 dwg

Description

The invention relates to physical and chemical processes for obtaining thermal energy, hydrogen and oxygen during the electrolysis of water.

A technical solution is known, described in the patent of the Russian Federation No. 103807U, which describes a system for obtaining thermal energy, containing an electrochemical activator, made in the form of a container filled with water and equipped with a level regulator, an electrokinetic evaporator, a parametric molecular resonator, connected to each other by means of connecting elements (pipe system). The system also contains a storage tank and a boiler (heat exchanger) with a thermocat, control units, a hydraulic valve, a high-voltage unit made according to the voltage multiplier circuit. Parameters of the electrochemical activator: power 220 W and current 0.99 A, electrode area S = 18 × 10 ^-3 m ² . The technical result is the production of fuel gas from aqueous solutions with its subsequent flameless combustion to obtain hot water for the hot water supply system (DHW).

The disadvantage of this invention is that this physical and chemical process does not provide for regulation of the thermal power of the installation.

A technical solution is known, described in Russian patent No. 2816078, a device for producing hydrogen, comprising a housing made of a dielectric material, an anode connected to the positive pole of a pulse power supply, and a cathode connected to the negative pole of a pulse power supply, pipes for the input and output of an alkaline solution, a channel for the removal of hydrogen and a channel for the removal of oxygen, characterized in that it contains an annular flat anode without holes with an area of s = 2.0 × 10 ^-3 m ² and a cathode s = 16.8 × 10 ^-4 m ² , consisting of a metal rod with a replaceable metal tip, on which metal rings are located at an angle of 45° relative to the axis of the cathode, and a vertically adjustable dielectric holder, while it is designed with the possibility of supplying a pulsed supply voltage of 220 V, an electric current of 0.98 A and a frequency of 500 Hz to the anode and cathode.

The disadvantages of the invention described above are that the performance of the known device does not allow obtaining thermal power higher than 1 kW, which is due to the impossibility of regulating the distance between the anode and cathode and the presence of one pair of electrodes.

A technical solution is known, described in Russian patent No. 2157862 (prototype), for obtaining thermal energy of hydrogen and oxygen, comprising a housing made of a dielectric material, a cover, also made of a dielectric material, which has a cylindrical-conical lug with a through hole, forming together with the housing an anode and a cathode cavity, the anode is made flat, annular with holes, located in the anode cavity and connected to the positive pole of the power source, the cathode is in the form of a rod made of refractory material, inserted into the dielectric rod with an external thread, by means of which it is introduced into the interelectrode chamber through a threaded hole in the housing and centered in the through hole of the cover and connected to the negative pole of the power source, a branch pipe for introducing the working solution is located in the middle part of the anode cavity.

The disadvantages of the invention described above are: 1. The impossibility of regulating the distance between the anode and cathode, which complicates the use of an electrolyte solution with different densities. 2. The ratio of the areas of the cathode and anode is not taken into account, which significantly affects the costs of electrical energy.

The technical result is an increase in the stability of the technological process and energy indicators of the device, as well as the ability to adjust the device to regulate power, change the interelectrode space and the number of electrodes. The technical result is achieved due to the fact that a multi-electrode type device for obtaining thermal energy of hydrogen and oxygen, containing a housing made of a dielectric material, an interelectrode chamber, inlet and outlet pipes for flowing an alkaline solution, an anode connected to the positive pole of a power source, and a cathode equipped with a dielectric cathode holder, connected to the negative pole of the power source, is characterized in that the cylindrical housing is equipped with removable cathode and anode side covers, in each of which 8 hollow cylindrical electrodes are mounted, equipped with cylindrical dielectric holders, with the possibility of adjusting the interelectrode distance from 20 to 40 mm and changing the number of pairs of electrodes from 2 to 8, the anodes and cathodes are located symmetrically relative to each other, wherein the cathodes are made of bronze, the anodes are made of stainless steel.

The novelty of the technical solution is that due to the special design of the cathode and anode electrodes and the change in their number in the installation, during the interaction of the electrodes with the passing electrolyte solution, its uniform heating occurs throughout the entire volume of the device. The ability to regulate the interelectrode space and the density of the electrolyte solution ensures a change in the intensity of the plasma electrolytic process and the rate of formation of hydrogen and oxygen, and thereby regulates the thermal power of the installation. This can be used for local heating of premises, obtaining hydrogen and oxygen for technological needs with lower energy costs.

The essence of the invention is explained by the drawing, where Fig. 1 shows a multi-electrode type device for obtaining thermal energy of hydrogen and oxygen.

The device consists of a cylindrical dielectric housing 1 having removable cathode 8 and anode 9 covers. Electrodes are mounted in the side covers, eight cathodes 2 on one side, eight anodes 3 on the other. The cathodes 2 are hollow cylindrical, equipped with cylindrical dielectric holders 4, adjustable horizontally, allowing to change the distance between the electrodes. The anodes 3 are hollow cylindrical and equipped with anode cylindrical dielectric holders 5, the device has an interelectrode space 12 for the flow of an alkaline solution, an input cathode 6 and an output anode branch pipes 7 are provided, cathode 11 and anode 10 contacts are used to connect the pulse power source. To change the electrodes, the device has cathode 8 and anode 9 covers, having a circle shape, are provided. The view of the anode and cathode covers, having axial electrode holes 13-14, into which cathode and anode cylindrical dielectric holders are mounted by means of threads, as well as inlet and outlet pipes 6-7 for the flow of alkaline solution, is shown in Fig. 2.

The multi-electrode device for obtaining thermal energy of hydrogen and oxygen operates as follows. Prepared water (after the distiller) is mixed with alkali Ca (OH) in a ratio of 11: 1, the resulting solution with a density of 1010-1050 kg / m ³ is fed into the body of the device 1, at the same time, pulse voltage is applied to the cathodes and anodes and the plasma electrolytic process begins with the formation of plasma, which is as follows. Hydrogen begins to be released on the cathodes, oxygen on the anodes, during this process heat is released due to partial combustion of hydrogen in the cathode area as a result of interaction with oxygen, which is formed on the anodes, while in order to ensure uniform flow of the plasma electrolytic process, the electrodes (cathodes and anodes) are located symmetrically in a cylindrical structure in the installation, which allows achieving the same current and voltage density and balancing the process of stable hydrogen combustion. Using dielectric holders 4 and 5, the electrodes are replaced and the distance between the electrodes is adjusted from 20-40 mm, which changes the productivity of the unit. It is possible to adjust the power of the unit by changing the density of the electrolyte solution.

It was established experimentally that the most optimal and energy-saving mode of the plasma electrolytic process is the use of an electrolyte solution with a density of 1030 kg/ ^m3 , at an interelectrode space distance of 40 mm, a pulsed supply voltage of 220 V and an electric current of 4.58 A and a frequency of 500 Hz. With a decrease in the interelectrode distance to 20, 30 mm, the number of gas bubbles in the cathode and anode regions increases, which leads to an increase in the specific resistance of the installation and a decrease in energy efficiency, i.e. a decrease in thermal power. With a decrease in the density of the electrolyte solution to 1010 kg/ ^m3 , 1020 kg/ ^m3, the plasma electrolytic process occurs with a lower intensity of thermal energy release, if the density is increased to 1040 kg/ ^m3 , 1050 kg/ ^m3 , then there is an increase in the concentration of the released gases, which in intensity form a gas space. which leads to an increase in the specific resistance of the solution and, accordingly, the installation itself, which reduces the thermal power output.

As for the pulse voltage of 220 V and frequency of 500 Hz, these parameters allow to implement the resonance mode and to save energy, in which the maximum release of hydrogen occurs on bronze cathodes, since bronze has an increased electrochemical equivalent for the release of hydrogen, with an area of s = 34.8 × 10 ^-4 m ² and oxygen on stainless steel anodes with an area of s = 16.4 × 10 ^-4 m ² . If we consider the nearest frequencies of 400 and 600 Hz, resonance is not observed at such frequencies, and accordingly, the maximum release of hydrogen and oxygen with subsequent heat synthesis does not occur. To calculate the thermal power, a standard calculation formula is used.

where c is the heat capacity of the solution, 4.19 kJ/kg; Δt is the temperature difference between the outlet and inlet of the device, °C; m is the mass of the passing solution. An example of a specific implementation of the claimed device/

A solution with a density of ρ=1030 kg/ ^m3 is fed into the device shown in Fig. 1. Water decomposes into oxygen and hydrogen with the release of heat of 3340.69 kJ. The duration of the experiment is 5 min.

To prove the efficiency of the device, production tests were conducted. The distance between the electrodes was 40 mm and the pulse current frequency was 500 Hz (Table 1).

The conducted studies showed that the most effective density of the solution is ρ=1030 kg/ ^m3 , the thermal energy was 490.23 kJ, which confirms the efficiency of the installation at a distance between the cathode and anode of 40 mm.

To prove the efficiency of the device, production tests were conducted with an interelectrode distance of 30 mm and a pulse current frequency of 500 Hz (Table 2)

The conducted studies showed that the most effective density of the solution is ρ=1030 kg/ ^m3 , the thermal energy was 2991.66 kJ, which confirms the efficiency of the installation at a distance between the cathode and the anode of 30 mm.

To prove the effectiveness of the device, production experiments were conducted with an interelectrode distance of 20 mm and a pulse current frequency of 500 Hz (Table 3).

The conducted studies showed that the most effective density of the solution is ρ=1030 kg/ ^m3 , while the thermal energy was 3141.24 kJ, which confirms the efficiency of the installation at a distance of 20 mm between the cathode and the anode. The energy efficiency of the device is 3.31. This is explained by the symmetrical arrangement of the electrodes in the installation space, and the ability to regulate the number of pairs of electrodes.

Claims (1)

A multi-electrode device for obtaining thermal energy of hydrogen and oxygen, comprising a housing made of a dielectric material, an interelectrode chamber, inlet and outlet pipes for flowing an alkaline solution, an anode connected to the positive pole of a power source, and a cathode equipped with a dielectric cathode holder, connected to the negative pole of the power source, characterized in that the cylindrical housing is equipped with removable cathode and anode side covers, each of which has 8 hollow cylindrical electrodes mounted therein, equipped with cylindrical dielectric holders, with the possibility of adjusting the interelectrode distance from 20 to 40 mm and changing the number of pairs of electrodes from 2 to 8, the anodes and cathodes are located symmetrically relative to each other, wherein the cathodes are made of bronze, the anodes are made of stainless steel.

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