RU2227817C1 - Electrolytic cell of low-ampere electrolyzer for production of hydrogen and oxygen from water - Google Patents

Abstract

FIELD: physico-chemical technologies for production of hydrogen and oxygen from water. SUBSTANCE: proposed electrolytic cell has taper housing made from current-conducting material and used as cathode, additional taper electrodes and taper cover made from current-conducting material and used as anode. Cylindrical bases of housing, additional electrodes and cover have circular recesses for dielectric rings. Housing, additional electrodes and cover are connected by means of bolts inserted into holes in cylindrical bases. Insulation between anode, additional electrodes and cathode is insured by dielectric rings, dielectric washers and dielectric bushes. Solution is fed from reservoir to inter-electrode space through passage. Gases escape through branch pipe. Proposed cell may be used for polarization of ions of solution and water molecules in horizontal and vertical planes, thus forming positive potential on anode and negative potential on cathode before connecting the cell to electric circuit; process of separation of gases continues after disconnection of cell from circuit. EFFECT: considerable reduction of power requirements for decomposition of water. 1 dwg, 1 tbl

Description

The invention relates to physicochemical technologies and techniques for producing hydrogen and oxygen.

Known technical devices (Holstein AB, Serebryansky FZ Operation of electrolysis plants for the production of hydrogen and oxygen. - M .: Energy, 1969) for the production of hydrogen and oxygen.

A technical solution is known (US Patent No. 969214, C 25 V 1/02, 1976), comprising a housing, a nozzle for introducing a working solution, an interelectrode chamber, an anode connected to the positive pole of a power source, and a cathode connected to a negative power source.

Also known is a technical solution (British Patent No. 1139614, class C 01 B 13/06, 01/08/1969), comprising a housing made of dielectric material with a through hole, an interelectrode chamber, nozzles for input and output of a working solution, an anode connected with a positive pole of the power source, and a cathode connected to the negative pole of the power source.

The disadvantage of these and other similar inventions is that the uneconomical high-ampere process of electrolytic dissociation of water molecules is used to produce hydrogen and oxygen.

A device for producing thermal energy, hydrogen and oxygen (see Russian Patent No. 2175027, C 02 F 1/46, 2001 - prototype), comprising a housing with a lower cylindrical tide and a lower cover made of dielectric material; a chamber for condensation of steam; an anode connected to a positive power source, and a cathode connected to a negative power source, as well as a nozzle for introducing a solution.

The disadvantage of this invention is that for the production of hydrogen and oxygen, hard-to-control plasma is used as a source of thermal dissociation of water molecules.

The technical solution to the problem is the production of hydrogen and oxygen by economical low-ampere electrolytic decomposition of water.

This goal is achieved by the fact that the electrolytic cell for producing hydrogen and oxygen from water contains a housing, a cathode connected to the negative pole of the power source, an anode connected to the positive pole of the power source, a channel for supplying a solution to the interelectrode chamber, a pipe for the exit of gases, as a cathode, a conical housing with a flat cylindrical base on the outer surface was used, and as an anode, a conical cover with a flat cylindrical base on the outside was used on the surface, between the anode and cathode, additional conical electrodes with flat cylindrical bases and axial holes at the tops of the cones are installed; the base of the housing has a channel for supplying the solution to the interelectrode chambers, a pipe for the exit of gases is located in the upper part of the cone of the lid; the housing, additional electrodes and the cover are connected by bolts having dielectric washers and dielectric bushings, and the cylindrical bases of the housing, additional electrodes and covers have annular recesses in which the dielectric rings are located.

The novelty of the claimed device is due to the fact that the conical surfaces of the anode, cathode and additional electrodes create conditions for the polarization of solution ions and water molecules in two planes: horizontal and vertical. As a result, a positive potential appears on the anode before the cell is included in the electric network, and negative at the cathode. After the cell is connected to the electric network, the pre-polarized solution ions and water molecules dissociate into hydrogen and oxygen at a lower consumption of electrons from the electric network. The proof of this is a small current strength, therefore this process is called low-ampere. The potential at the electrodes is maintained after disconnecting the cell from the network. Due to this, the energy consumption for the decomposition of water into hydrogen and oxygen is significantly reduced.

According to the patent literature, a similar set of features has not been found in which the energy costs for producing hydrogen and oxygen are significantly reduced, which allows us to judge the inventive step of the proposal. The invention is illustrated in the drawing, which shows a General view of the device.

The electrolytic cell for producing hydrogen and oxygen contains a conical housing 1 with a flat cylindrical base 2 made of a conductive material and acting as a cathode, additional conical electrodes 3 made of conductive material with axial holes in the tops of the cones (Fig. 1 shows one electrode ) and cylindrical bases 4, a conical cover 5 with a flat cylindrical base 6, made of conductive material and acting as an anode. The cylindrical base of the housing, the additional electrodes and the cover have annular recesses for accommodating the dielectric rings 7. The housing 1, the electrodes 3 and the cover 5 are connected by bolts 8 inserted into the holes of the cylindrical base of the housing, additional electrodes and the cover. The insulation between the anode, the internal electrodes and the cathode is provided by dielectric rings 7, dielectric washers 9 and dielectric bushings 10. The solution is fed into the interelectrode space through the channel 11 from the tank 12. Gases exit through the pipe 13.

The electrolytic cell operates as follows. The electrolytic solution is poured into the tank 12 to a predetermined level. The cell is connected to a DC network. The voltage corresponding to 1.6-2.2 V per pair of electrodes is set. The current strength depends little on the surface areas of the anode, cathode and additional electrodes and is close to 0.02 A.

A few minutes after connecting the cell to the electric network, active gas evolution begins; it continues after disconnecting the cell from the electrical network. The process of gas evolution with a disconnected network fades out gradually over several hours. The average results of multiple measurements are shown in the table.

The most reliable way to determine the amount of gas released during electrolysis of water is a method that takes into account the mass of dissociated water. The results of experiments in which this method was applied are given below (see table).

It is known that a gram atom is numerically equal to the atomic mass of a substance, and a gram molecule is equal to the molecular mass of a substance. For example, the gram-molecule of hydrogen in a water molecule is 2 g, and the gram-atom of an oxygen atom is 16 g. The gram-molecule of water is 18 grams. Since the mass of hydrogen in the water molecule is 2 × 100/18 = 11.11%, and the mass of oxygen is 16 × 100/18 = 88.89%, the same ratio of hydrogen and oxygen is contained in one liter of water. This means that in 1000 g of water contains 111.11 g of hydrogen and 888.89 g of oxygen.

One liter of hydrogen weighs 0.09 g, and one liter of oxygen -1.47 g. This means that from one liter of water you can get 111.11 / 0.09 = 1234.44 l of hydrogen and 888.89 / 1.47 = 604.69 L of oxygen. It follows that 1 g of water contains 1.23 liters of hydrogen.

The cost of electricity to produce 1000 liters of hydrogen is now 4 kWh, and per liter - 4 Wh. Since 1.234 liters of hydrogen can be obtained from one gram of water, 1.234 × 4 = 4.94 Wh is now consumed to produce hydrogen from one gram of water.

Instruments and equipment used in the experiment

Experimental cell of a low-ampere electrolyzer; M2004 voltmeter (accuracy class 0.2 GOST 8711-78); ammeter M2015 (accuracy class 0.2 GOST 8711-60); electronic scales with a division value of 0.1 and 0.01 g; stopwatch with a division value of 0.1s.

Claims (1)

An electrolytic cell for producing hydrogen and oxygen from water, comprising a housing, a cathode connected to the negative pole of the power source, an anode connected to the positive pole of the power source, a channel for supplying a solution to the interelectrode chamber, a pipe for the exit of gases, characterized in that as a conical housing with a flat cylindrical base on the outer surface was used in the cathode, and a conical cover with a flat cylindrical base on the outer surface, m I wait for the anode and cathode to install additional conical electrodes with flat cylindrical bases and axial holes at the tops of the cones, while the base of the housing has a channel for supplying the solution to the interelectrode chambers, a pipe for the exit of gases is located in the upper part of the cover cone, the housing, additional electrodes and the cover are connected bolts having dielectric washers and dielectric bushings, and the cylindrical bases of the housing, additional electrodes and covers have annular recesses in which are located dielectric rings.