RU2821975C1 - Method of producing thermal energy, 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. In the method, the interelectrode space is filled with a weak aqueous solution of an alkali and voltage is supplied until a stable plasma electrolytic process appears, followed by removal of a heated gaseous phase – hydrogen from the cathode region and oxygen from the anode region. Alkali used is potassium hydroxide, which is added to purified water at ratio of 1:10 to obtain an aqueous solution of alkali with density of 1,030 kg/m³. Brass cathode and the stainless steel anode with the same diameters are installed coaxially to each other with the possibility of changing the distance between them from 10 to 30 mm. Areas of contact of the anode and cathode with the aqueous alkali solution have ratio of 1:2, respectively. Voltage of 220 V and pulse current of 1.68 A are supplied to electrodes.

EFFECT: higher thermal power output of hydrogen generator.

1 cl, 1 dwg, 3 tbl

Description

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

A known technical solution is described in RF patent No. 103807 U1, where thermal energy is obtained using an electrochemical activator in the form of a container filled with water. 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 followed by flameless combustion to produce hot water for a hot water supply system (DHW).

The disadvantage of the known invention is the lack of regulation of the thermal power of the installation.

There is a known method of converting the energy of hydrogen combustion into the thermal energy of water in a water boiler, which consists in the fact that the pressure of hydrogen and oxygen at the inlet of the device is set by simultaneous regulation according to the required proportions and pressure, after which the gases enter two sealed, variable-volume, unconnected chambers, where mix, alternately compress and ignite, and the thermal energy obtained as a result of combustion in the form of steam continuously enters the boiler water (RF patent No. 2511795, class F24H 1/00, 2014).

An invention is known in which hydrogen is obtained from water by decomposing water under the influence of an electric field using a water coaxial capacitor with insulated plates, to which a high-voltage rectified pulse voltage is applied, while the decomposition of water into oxygen and hydrogen occurs under the influence of a resonant electromagnetic field, frequency The nth harmonic of which approaches the natural frequency of water, and the energy of water decomposition consists of the thermal and minimally consumed electrical energy of water decomposition (RF patent No. 2456377, class C25B 1/04, 2012).

There is a known method for obtaining thermal energy (RF patent No. 2261942), including the conversion of electrical energy in a plasma-electrolytic process carried out between the anode and cathode in water, with the removal of hydrogen gas from the cathode region and oxygen from the anode region, the water is subjected to hydrodynamic cavitation in a vortex flow , in which massive oxygen ions are moved by centrifugal force to the periphery of the flow, hydrogen ions with low mass are concentrated in its center, and electrical voltage is applied in the center of the flow to the cathode and at the periphery of the flow - to the anode, and the plasma-electrolytic process is carried out in an ionized environment.

It is also known to obtain thermal energy of hydrogen and oxygen using a weak aqueous solution of alkali, which is used to fill the interelectrode space and apply a gradually increasing rectified current voltage until a stable plasma appears in the electrode zone (RF patent No. 2157862, class C02F 1/04, 2000, prototype.).

The disadvantages of the prototype and known technical solutions are:

1. Lack of ability to regulate the distance between the anode and cathode to ensure the use of liquids with different densities.

2. There is no regulation of the range of heat production from hydrogen and oxygen and regulation of the reduction of energy costs depending on technological needs.

The technical result is to increase the thermal power performance of the hydrogen generator.

The technical result is achieved by the fact that in the method of producing thermal energy of hydrogen and oxygen, including the use of a weak aqueous solution of alkali, which fills the interelectrode space, the supply of a gradually increasing rectified current voltage until a stable plasma-electrolytic process appears between the anode and the cathode in an aqueous solution of alkali, followed by removal of the heated gaseous phase - hydrogen from the cathode region and oxygen from the anode region, according to the invention, potassium hydroxide is used as an alkali, which is added to purified water in a ratio of 1:10, while the cathode is made of stainless steel and the anode is made of brass, they are installed coaxially to each other with the possibility of changing the distance between them from 10 to 30 mm, and the surface areas of the cathode and anode in contact with an aqueous alkali solution have a ratio of 2:1, respectively.

The novelty of the proposed technical solution lies in the fact that due to the design features of the cathode and anode, the aqueous solution of alkali passing through them, which is used as potassium hydroxide, KOH is heated over the entire area of interaction between this solution and the electrodes, that is, the solution is effectively heated throughout the entire volume devices, in addition, by regulating the interelectrode space between the anode and the cathode, it is possible to regulate the intensity of the plasma-electrolytic process, accompanied by the intensity of the production of hydrogen and oxygen, followed by regulation of the thermal power of the installation and the ability to select the power depending on the density of the solution.

According to scientific, technical and patent literature, the authors do not know the claimed set of features aimed at achieving the stated task, and this solution does not follow clearly from the known level of technology, which allows us to conclude that the solution corresponds to the level of the invention.

The proposed technical solution is industrially applicable, since it is possible to use the proposed method for local heating of premises and obtain hydrogen and oxygen for technological needs with lower energy costs.

The essence of the invention is illustrated by the drawing, where in FIG. 1 shows a device with the help of which the inventive method of obtaining thermal energy of hydrogen and oxygen is implemented.

The device with which the inventive method is implemented consists of a cylindrical dielectric housing 1, a dielectric holder 2 for the cathode 3, an anode 4, which also has a dielectric holder 5 and an interelectrode chamber 6 for the flow of an aqueous alkali solution; potassium hydroxide KOH is used as a crust. Electrodes: anode 4 and cathode 3 serve as inlet and outlet pipes. The anode 4 is made hollow, with a diameter equal to the diameter of the cathode 3 and is installed coaxially with it with the possibility of axial movement. The contact areas of anode 4 and cathode 3 with an aqueous alkali solution with a density of 1030 kg/m ³ are made in a ratio of 1:2, respectively. The anode 4 is made of stainless steel, and the cathode 3 is made of brass. To regulate the distance between the electrodes, dielectric holders 5 and 2 are used. To connect a pulsed power source (not shown in the figure), cathode 7 and anode contacts 8 are used. Housing 1 has output pipes for hydrogen 9 and oxygen 10. Branch pipes 9 and 10 are installed in the top and the lower part of the body, in places where hydrogen and oxygen accumulate.

The method for producing thermal energy of hydrogen and oxygen is implemented as follows

Prepared water (after the distiller) with the addition of alkali potassium hydroxide (KOH) in a ratio of 10:1 with a density of 1030 kg/m ³ is supplied to the body of the device 1 in the interelectrode chamber 6 through the hollow cathode 3 and the required solution flow rate is set. The use of KOH makes it possible to increase the ionization of water and contributes to a more efficient release of hydrogen and oxygen and heat in the installation due to the more active chemical component of potassium itself and its activity in the ionization process in the plasma-electrolytic process; if you use alkali CaOH, the process will be less intense in ionization, so as calcium is less active in the ionization process and plasma-electrolytic process than potassium. The device is then connected to a switching power source and the voltage is gradually increased until a stable plasma appears. In the interelectrode chamber 6, the solution is heated to boiling temperature with the partial decomposition of water into hydrogen and oxygen. Oxygen released at the anode 4 is removed from the anode cavity through the outlet pipe 10.

Gaseous molecular hydrogen, formed at the plasma-liquid interface, is collected in the upper part of the cathode cavity and exits along with water vapor through the outlet pipe 9.

Under the influence of an electric field, between the area of the cathode 3, which is doubled in relation to the area of the anode 4, a flow of alkali metal ions is formed, focused on the cathode. Having a reserve of kinetic energy when moving towards the cathode, alkali metal ions separate protons of hydrogen atoms and hydrogen atoms from water molecules. As a result, a plasma of atomic hydrogen is formed in the cathode cavity. The source of energy is the synthesis of hydrogen atoms and molecules.

Thus, the hydrogen plasma at the cathode is a source of thermal energy transferred to the aqueous solution, and a source of atomic and molecular hydrogen and oxygen at the same time.

In order to balance the process of stable combustion of hydrogen, the interelectrode distance is adjusted from 10-30 mm using dielectric holders 2 and 5; using these holders, the cathode and anode can be replaced, and the power of the installation can also be adjusted depending on the density of the solution.

To prove the effectiveness of the proposed technical solution, experimental studies of the proposed method were carried out under different modes of the following parameters: density of the aqueous solution of alkali KOH 1010-1050 kg/m ³ ; interelectrode distance 10-30 mm and frequency 400-600 Hz.

Based on the results of experimental experiments, it was revealed that the most optimal and energy-saving plasma-electrolytic process occurs in an aqueous solution of alkali KOH with a density of 1030 kg/m ³ , with a pulsed supply voltage of 220 V, an electric current of 1.68 A, a frequency of 500 Hz and with an interelectrode space distance of 30 mm .

At interelectrode distances of 10 or 20 mm, the concentration of gas bubbles on the surfaces of the cathode and anode increases, which leads to an increase in the resistivity of the installation and a decrease in energy efficiency, that is, a decrease in thermal power.

When the density of the solution decreases from 1010 kg/m ³ or to 1020 kg/m ^3, the plasma-electrolytic process proceeds with a lower intensity of thermal energy release; if the density is increased from 1040 kg/m ³ or to 1050 kg/m ³ , the concentration of released gases increases, which intensity form a gas space, leading to an increase in the resistivity of the solution and, accordingly, the installation itself, as a result of which the output of thermal power decreases.

As for the pulse voltage of 220 V and frequency of 500 Hz, then with such parameters a resonant mode is achieved, in which maximum hydrogen evolution occurs at the brass cathode. Since brass has an increased electrochemical equivalent in terms of hydrogen yield compared to the stainless steel from which the anode is made, the contact area of the cathode with the aqueous solution should be greater than that of the anode, namely in a ratio of 2:1 or cathode area s = 4.35⋅ 10 ^-4 m ² and anode area s = 2.05⋅10 ^-4 m ² in order to ensure optimal oxygen yield for a stable physical and chemical process of synthesis of hydrogen, oxygen and subsequent heat release followed by combustion and heat synthesis.

As for the frequency, at 400 and 600 Hz resonance is not observed and, accordingly, the maximum release of hydrogen and oxygen with subsequent heat synthesis does not occur. To calculate thermal power, the standard calculation formula is used: Q _n =c ⋅ Δt ⋅ m,

where c is the heat capacity of the solution, 4.19 kJ/kg; Δt - temperature difference at the outlet and inlet of the device, °C; m is the mass of the passing solution, kg.

An example of a specific application of the proposed device

An aqueous solution of alkali is fed into the device (Fig. 1). Water decomposes into oxygen and hydrogen with the release of heat 233.80 kJ, the duration of the experiment is 5 minutes, the pulse current frequency is 500 Hz.

Experiments were carried out with aqueous solutions of alkali with different densities from 1010-1050 kg/m ³ and with different interelectrode distances. The results are presented in tables 1, 2 and 3.

The studies showed that the most effective density of the aqueous solution of KOH alkali is ρ=1030 kg/m ³ , the thermal energy was 490.23 kJ, which confirms the efficiency of the installation at a distance between the cathode and anode of 30 mm (Table 1).

The studies showed that the most effective density of the solution is ρ=1030 kg7 m ³ , the thermal energy was 452.52 kJ, which confirms the efficiency of the installation at a distance between the cathode and anode of 20 mm (Table 2).

The studies showed that the most effective density of the solution is ρ=1030 kg/m ³ , the thermal energy was 505.31 kJ, which confirms the efficiency of the installation at a distance between the cathode and anode of 10 mm (Table 3) in comparison with the prototype.

Claims (1)

A method for producing thermal energy, hydrogen and oxygen, including the use of a weak aqueous alkali solution, which fills the interelectrode space, the supply of a gradually increasing rectified current voltage until a stable plasma-electrolytic process appears between the anode and the cathode in an aqueous alkali solution, followed by the removal of the heated gaseous phase - hydrogen from the cathode region and oxygen from the anode region, characterized in that potassium hydroxide is used as an alkali, which is added to purified water in a ratio of 1:10, while the cathode is made of brass and the anode is made of stainless steel and with the same diameters, they are installed coaxially to each other each other with the possibility of changing the distance between them from 10 to 30 mm, and the surface areas of the cathode and anode in contact with an aqueous alkali solution have a ratio of 2:1, respectively, and a voltage of 220 V and a pulse current of 1.68 A are supplied to the electrodes at a density of aqueous alkali solution 1030 kg/ ^m3 .

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