RU113074U1 - ELECTROCHEMICAL GENERATOR - Google Patents

Abstract

1. An electrochemical generator, including a fuel cell, the palladium anode and cathode of which are separated from each other by a polymer electrolyte, an electrolyzer and a power source with current leads, characterized in that the electrolyzer is made in the form of a plasmatron, consisting of a vertical-cylindrical body with nozzles for introducing a plasma-forming medium and the outlet of gaseous products located in the body of a sealed interelectrode chamber with cylindrical electrodes, and the fuel cell is installed in the interelectrode chamber of the plasmatron and fixed on the end surfaces of the body, and the anode of the plasmatron and the anode of the fuel cell are made in the form of a single element (anode), and between the anode and the cathode of the fuel cell is an electrolyte made of solid polymeric material, and the space between the cathode of the plasmatron and the anode is filled with water, while the second electrode, the cathode, of the plasmatron is fixed on the cylindrical part of the transparent body, and the cathode and anode of the plasmatron are made of material that does not interact with hydrogen and oxygen, while the part of the cathode of the fuel cell located above the plasma formation medium has a through porosity designed to pass oxygen or ozone into the internal volume of the fuel cell, and the polymer electrolyte is made of sulfated polytetrafluoroethylene, and the nozzles for introducing the plasma medium are made on the upper end surface of the body. ! 2. An electrochemical generator according to claim 1, characterized in that either nanofibrous nickel or neither is used as a material that does not interact with hydrogen and oxygen.

Description

The utility model relates to an electrochemical generator in which the conversion of chemical energy into electrical energy occurs. The generator can be used as a stationary source of electric energy (mainly of high power) in any industry: energy, engineering, etc.

Generators based on the electrochemical method of energy conversion are known.

These include, along with galvanic cells and batteries, fuel cells.

Fuel cells comprise mainly a pair of electrodes — an anode and a cathode, as well as an ionic conductor — an electrolyte, for example, an alkali or acid solution, or a molten carbonate located between them.

Depending on the physical state of the electrolyte, fuel cells are divided into cells with liquid electrolyte and solid electrolyte.

Gaseous reagents are passed through the electrodes during operation of the fuel cell: through the anode is a reagent called fuel, and through the cathode is a reagent called oxidizer.

Hydrogen (H ₂ ), less often carbon monoxide (CO) and methane (CH ₄ ), are used as fuel in fuel cells, and oxygen (O ₂ ), including air oxygen, is used as an oxidizing agent.

The closest in technical essence to the proposed utility model is an electrochemical generator comprising at least one fuel cell, consisting of a porous matrix impregnated with the required amount of liquid electrolyte, a pair of electrodes: a fuel electrode (providing the element with hydrogen) and an air electrode (providing the element oxygen), which are located on both sides of the porous matrix and the electrolyzer (US Patent No. 5677073, CL. H01M 27/00).

The known design combines two processes: the operation of a fuel cell and an electrolyzer that produces hydrogen and oxygen components for it.

The disadvantage of this generator is that the fuel cell is difficult to manufacture and has a high cost, because required:

- special materials for the matrix;

- a special tool for continuous monitoring of the amount of electrolyte, which decreases during operation of the generator;

- supply of electrolyte matrix;

- special tools for combining cells into batteries.

The known design practically combined the disadvantages of modern fuel cells and electrolyzers, which lie in the low-temperature ability of polymer electrolytes based on sulfated polytetrafluoroethylene, which also have insufficiently high ionic conductivity and, as a consequence, the need for compression cleaning of the anode surface of the fuel cell.

Another disadvantage of the electrochemical generator is the delivery of hydrogen and oxygen electrolysis products to the cathode and anode of the fuel cell in a stoichiometric ratio.

Since the volume ratio of the products released in the electrolyzer is very different, even not counting the “leakage” of hydrogen along the way to the fuel cell, there is a need to create buffer tanks for hydrogen and oxygen.

The introduction of an unreliable and complex element for heating and cooling a hydrogen tank for:

a) preventing cooling down to freezing inside during endothermic generation;

b) gas overheating during exothermic compression during the regeneration of a fuel cell.

Such a measure was taken on the basis of the need to reduce the weight of the system and increase the resource of work at capacities up to 30 Quatt.

Due to the presence of different pressures in the tanks for hydrogen and oxygen, the known design has a complex design of the alignment valves.

The use of expensive carbon fiber composites with a protective layer on the internal surfaces in contact with hydrogen and oxygen, due to their discontinuity, leads to the release of exothermic energy in a pulsed mode.

The use of both a monolithic and a porous cathode and anode in a fuel cell separated by a proton membrane of the NAFION.T.M class class significantly reduces the reliability of the electric energy generator, since it is rather difficult to control the dispersion of micropores, their morphology and its reproducibility in the manufacture of cathodes and anodes, given that the through porosity is measured by angstroms.

Also a disadvantage of the known electrolyzer is its poor operation in the mode of a short current pulse and in the conditions of an electrolyte flow.

The technical result solved by the proposed utility model is the creation of an electrochemical generator design, which eliminates the need to provide a fuel cell with fuel (hydrogen from cylinders) and an oxidizing agent (oxygen from air) by obtaining them from water due to its dissociation in plasma-initiated bubbles and separated by due to the use of palladium anodes for hydrogen and oxygen.

The technical result in the proposed utility model is achieved by creating an electrochemical generator including a fuel cell, the palladium anode and cathode of which are separated from each other by a polymer electrolyte, the electrolyzer and the power supply with current leads, according to the utility model, the electrolyzer is made in the form of a plasma torch, consisting of a vertical cylindrical body with nozzles for entering the plasma formation medium and output of gaseous products located in the housing of the sealed interelectrode chamber with a cylinder electrodes, moreover, the fuel cell is installed in the interelectrode chamber of the plasma torch and mounted on the end surfaces of the housing, the anode of the plasma torch and the anode of the fuel cell are made as a single element (anode), and an electrolyte made of a solid polymer material is located between the anode and cathode of the fuel cell, and the space between the cathode of the plasma torch and the anode is filled with water, while the second electrode-cathode, plasma torch is mounted on the cylindrical part of the transparent body, and the cathode and anode of the plasma torch They are made of a material that does not interact with hydrogen and oxygen, while the part of the cathode of the fuel cell located above the plasma formation medium has a through porosity designed to pass oxygen or ozone into the internal volume of the fuel cell, and the polymer electrolyte is made of sulfated polytetrafluoroethylene, and nozzles for introducing the medium plasma formation is performed on the upper end surface of the housing.

The execution of the anode of the plasma torch and the anode of the fuel element in the form of a single element (anode) allows us to simplify the design of the generator, because on the one hand, it acts as an electrode for the dissociation of water, and on the other hand, it is an electrode of a fuel cell in the circuit of which they generate an electric current.

The use of nickel foil, or nanofibrous nickel, or cobalt or stainless steel as a material that does not interact with hydrogen and oxygen makes it possible to collect impurities accumulating during plasma “burning” in the form of compounds of especially heavy metals (salts, alkaline hydrides, mechanical impurities).

The presence at the plasma torch cathode of a viewing window along the generatrix of the cylinder, designed to control combustion, makes it possible to observe the process of plasma dissociation of water.

The presence at the cathode of a fuel cell outlet intended for the output of hot water from it, and its connection with the inlet of the plasma formation medium of the plasma torch allows you to create a closed cycle of the electrochemical generator, by using hot water as a plasma formation medium.

The proposed electrochemical generator is equipped with a screen placed in the plasma torch housing above the plasma formation medium and ensuring the return of its vapor to the medium.

The proposed electrochemical generator has an additional number of advantages, namely: it is easy to manufacture and reliable, because it does not carry exploitative elements that may fail due to the “human factor”.

- has no restrictions on the purity of water (plasma formation medium);

- has a compact power source plasmatron;

- has a low weight in relation to the generated current.

The conducted patent studies showed that technical solutions with the indicated set of essential features are not known in similar designs of electrochemical generators, i.e. the proposed solution meets the criterion of "novelty."

We believe that the information presented in the application materials is sufficient for the practical implementation of the utility model.

The proposed electrochemical generator is illustrated by the following description and drawing, which shows the construction of the electrochemical generator in section.

The electrochemical generator includes a fuel cell, anode 1 and cathode 2, separated from each other by a polymer electrolyte 3, an electrolyzer and a power source 4 with current leads 5.

The electrolyzer is made in the form of a plasma torch, consisting of a vertically cylindrical body 6 with nozzles for input 7 of the plasma formation medium and output of 8 gaseous products located in the housing of the sealed interelectrode chamber 9 with cylindrical electrodes made of a material that does not interact with hydrogen and oxygen.

Depending on technological capabilities, this material can be either nickel foil, or nickel, or cobalt or stainless steel.

The fuel cell is installed in the interelectrode chamber 9 of the plasma torch, and is mounted on the end surfaces of the housing 6.

The plasma torch anode and the fuel cell anode are made as a single element 1 (anode).

Between the anode 1 and the cathode 2 of the fuel cell is an electrolyte 3 made of a solid polymer material, for example, sulfated polytetrafluoroethylene.

The space between the cathode 10 of the plasma torch and the anode 1 is filled with a plasma formation medium, for example, water. fifteen

The plasma torch cathode 10 is mounted on the cylindrical part of the transparent body 6.

The plasma torch cathode 10 has a viewing window 11 along the generatrix of the cylinder, designed to control plasma combustion.

Part 12 of the cathode of the fuel cell located above the plasma formation medium has a through porosity designed to pass oxygen or ozone into the internal volume of the fuel cell.

The nozzles 7 for entering the plasma formation medium are made on the upper end surface of the housing 6.

The cathode 10 of the fuel cell has an output 13, intended for the withdrawal of hot water from it, and connected with the nozzle 7 of the plasma formation medium of the plasma torch.

The proposed utility model is equipped with a screen 14 located in the housing 6 of the plasma torch above the plasma formation medium to return its vapor back to the housing, which allows more economical use of the amount of plasma formation medium, i.e. water used.

The proposed device operates as follows:

Inside the body 6 of the plasmacheotron, water is poured through the pipe 7 to enter the plasma formation medium and maintained at the indicated maximum level of water dissociation.

They create a potential difference between the electrodes of the plasmachetron by applying current and voltage between the cathode - nickel foil and the anode of the nickel winding.

As a result, in the interelectrode space filled with water they “ignite” the plasma of a capacitive discharge and form hydrogen, oxygen, and ozone.

The voltage between the electrodes is supplied under visual control of the plasma, preventing sudden boiling of water.

At the time of the start of the plasmacheotron, replenishment of the water level is not allowed, as this makes the plasma unstable.

As water dissociates and evaporates, its level is continuously maintained constant, depending on the required volumes of hydrogen and oxygen.

Hydrogen, penetrating through the palladium anode in ionized form, enters the solid electrolyte from polytetrafluoroethylene.

And then, in the form of a hydrogen ion, it enters the cathode of the fuel cell, giving it conduction electrons.

Oxygen and ozone obtained during the dissociation of water as a result of plasma treatment enters the inner part of the cathode 2 of the fuel cell interacts with hydrogen and forms hot water, which can be used for space heating or simply as hot water

Since the output 13 of the cathode of the fuel cell is designed to withdraw hot water from it, and is connected to the input 7 of the plasma formation medium of the plasma torch, a continuous generator operation process can be organized.

An electric current, proportional to the number of hydrogen and oxygen ions, ozone, flows in the anode-cathode circuit of the fuel cell.

The proposed utility model was tested and the following results were obtained: the power source of the plasma torch consumed 1 kW, which led to the formation of a current in the fuel cell circuit of 100 A.

Claims (5)

1. An electrochemical generator comprising a fuel cell, the palladium anode and cathode of which are separated from each other by a polymer electrolyte, an electrolyzer and a power supply with current leads, characterized in that the electrolyzer is made in the form of a plasma torch, consisting of a vertically cylindrical body with nozzles for introducing a plasma formation medium and output of gaseous products located in the housing of the sealed interelectrode chamber with cylindrical electrodes, the fuel cell being installed in the interelectrode chamber the plasma torch and is mounted on the end surfaces of the housing, the anode of the plasma torch and the anode of the fuel cell are made as a single element (anode), and an electrolyte of solid polymer material is located between the anode and the cathode of the fuel cell, and the space between the plasma torch cathode and the anode is filled with water, the second electrode, the cathode, the plasma torch is mounted on the cylindrical part of the transparent body, and the cathode and anode of the plasma torch is made of a material that does not interact with hydrogen and oxygen, while some ode of the fuel cell situated above the plasma production medium has a through porosity adapted for passing into the interior volume of the fuel cell oxygen or ozone, and a polymer electrolyte made of polytetrafluoroethylene sulfated and tubes for input of plasma medium formed on the upper end surface of the housing. 2. The electrochemical generator according to claim 1, characterized in that as the material not interacting with hydrogen and oxygen, either nanofiber nickel, or nickel foil, or nickel, or cobalt, or stainless steel is used. 3. The electrochemical generator according to claim 1, characterized in that the cathode of the plasma torch has a viewing window along the generatrix of the cylinder, designed to control plasma burning. 4. The electrochemical generator according to claim 1, characterized in that the cathode of the fuel cell has an outlet for outputting hot water from it, and associated with the input of the plasma formation medium of the plasma torch. 5. The electrochemical generator according to claim 1, characterized in that it is provided with a screen placed in the plasma torch housing above the plasma formation medium and designed to return its vapor to the medium.