RU2608749C1 - Electrochemical generator on solid oxide fuel cells - Google Patents

Abstract

FIELD: electrochemistry.

SUBSTANCE: invention relates to devices for direct conversion fuel chemical energy into electrical energy using solid oxide fuel cells (SOFC) and can be used for independent power supply of different domestic and process low-power devices. Proposed is an electrochemical generator on solid oxide fuel cells having a housing, a located inside it chamber for mixing the fuel and the oxidizer, a fuel oxidation chamber accommodating at least one fuel cell, an oxidation products afterburning chamber, an oxidizer heating and distribution chamber, herewith the outlet of the chamber for mixing the fuel and the oxidizer is connected to the fuel oxidation chamber, and the fuel oxidation chamber outlet is connected to the inlet into the oxidation products afterburning chamber. Distinctive feature of the proposed electrochemical generator is that the fuel oxidation chamber includes two zones: the zone of partial oxidation of the fuel and the zone of electrochemical oxidation of the fuel, for which the fuel oxidation chamber is separated from the chamber for mixing the fuel and the oxidizer with a wall permeable for the fuel and oxidizer mixture made from a refractory material.

EFFECT: higher fuel efficiency, increased reliability, simplified design, as well as faster bringing the SOFC to the operating mode, all are the technical result of the invention.

7 cl, 2 dwg

Description

The invention relates to a device for the direct conversion of chemical energy of fuel into electrical energy using solid oxide fuel cells (SOFC) and can be used for autonomous power supply of various household and technological devices of low power.

Currently, there is an urgent need for autonomous sources of dispersed energy supply of small capacity to meet the household and production needs of remote consumers with their own sources of gaseous and liquid fossil fuels: natural and associated gas, liquefied hydrocarbon gases, gas condensate, biogas and other types of hydrocarbon feedstocks. Solid oxide fuel cells (SOFCs) can be a convenient source to meet these needs. However, the well-known designs of SOFC-based energy sources are extremely difficult to operate, require a large number of auxiliary equipment and complex preparation of fuel gas, which makes them unacceptable for most practical purposes.

A device for the direct conversion of chemical energy of fuel into electrical / US 4374184, H01M 8/06, 1983 /, including a battery of tubular elements. The battery case of the known device includes a generating chamber, an afterburner, which is also a chamber for preheating air, a chamber for incoming air and a chamber for mixing reagents for fuel reforming and distribution of reforming products. The tubular elements of the known batteries are arranged horizontally, made in the form of test tubes made of zirconium dioxide, the closed ends of which are directed to the mixing chamber, and the open ones are directed to the afterburner and air heating chamber. The chambers of the known device are separated by partitions with passage openings to ensure the passage of the corresponding gas flows between the chambers. One of the partitions is a tube plate with tubes for supplying air into the elements to their closed ends. The combination of tubes for supplying air to the internal cavities of the elements, the large length of the channels for air flows predetermine significant hydraulic resistance for air flows, which suggests the presence of devices for forced air supply.

Known invention, which describes an electrochemical generator based on solid oxide fuel cells / RU 2027258, 1995, H01M8 / 12 /. The well-known electrochemical generator (ECG-SOFC) includes a housing separated by transverse partitions with through holes on the fuel and oxidizer mixing chamber, an electrochemical oxidation chamber with a battery of vertically arranged fuel cells in the form of test tubes, the closed ends of which are directed to the mixing chamber, and a fuel afterburner and heating air. A catalyst for converting a mixture of gases into synthesis gas is located in the chamber for mixing fuel and oxidizer. The fuel cells with open ends are buried in the partition between the electrochemical oxidation chamber and the chamber for burning fuel and heating the air. The mixing chamber is located in the lower part of the housing, and the fuel afterburning chamber is located in its upper part. The heating of the air entering the inner space of the elements is carried out by heat exchange with gases leaving the afterburner. The large path length of the supplied air, including a change in the direction of flow, predetermines significant hydraulic resistance to the flow, so air is supplied to the electrochemical oxidation chamber using an air flow inducer. The main disadvantage of such an ECG is the need to use air supply devices containing moving parts, which reduces the reliability of the ECG and complicates its design, lowering the overall efficiency (COP) of the device.

Closest to the proposed invention is a patent / RU 2474929, H01M8 / 12, 2013 / for an electrochemical generator based on solid oxide fuel cells, which comprises a housing, a chamber for mixing methane and air located thereon, a chamber for partial oxidation of methane, a chamber for electrochemical oxidation of fuel with a fuel cell battery and a fuel afterburner. This design is selected as a prototype. A distinctive feature of the prototype is that the generator contains a second chamber for mixing methane and air, located under the first chamber for mixing methane and air. The methane partial oxidation chamber contains a plurality of tubes fixed to the tube plate with a methane partial oxidation catalyst deposited on their outer surfaces. Fuel cells in the form of tubes with open ends are coaxially connected to the tubes of the partial oxidation chamber. The afterburner contains a set of perforated plates with a afterburning catalyst deposited on them, and a catalyst for oxidizing the fuel in excess air is deposited on the inner surface of the tubes of the partial oxidation chamber.

The disadvantages of the prototype include low fuel efficiency, low reliability, as well as the complexity of the design. These disadvantages are due to the presence of a separate burner for the initial heating of the chamber for oxidizing natural gas into synthesis gas, high requirements for the purity of the natural gas used and the inability to use other types of gas raw materials, which leads to a high likelihood of soot formation on the surface of the partial oxidation catalyst and its failure in carbonization or overheating.

The invention solves the problem of creating an electrochemical generator devoid of these disadvantages. The technical result consists in increasing the fuel efficiency, increasing the reliability of the device, simplifying the design, accelerating the SOFC output to the operating mode.

To solve the problem and achieve the claimed technical result, an electrochemical generator based on solid oxide fuel cells is proposed, comprising a housing, a chamber for mixing fuel and an oxidizing agent located in it, a fuel oxidation chamber with at least one fuel cell located therein, and an oxidation products afterburner chamber. In this case, the output of the fuel and oxidizer mixing chamber is connected to the fuel oxidation chamber. The output of the fuel oxidation chamber is connected to the entrance to the afterburner of oxidation products. A distinctive feature of the claimed ECG is that the fuel oxidation chamber includes two zones: a zone of partial oxidation of fuel and a zone of electrochemical oxidation of fuel. In this case, the fuel oxidation chamber is separated from the fuel and oxidizer mixing chamber by a wall made of heat-resistant material that is permeable to the mixture of fuel and oxidizer.

Additionally, it is proposed between the zones of partial oxidation of fuel and electrochemical oxidation of fuel to install a perforated screen with a gap with respect to the permeable wall.

The perforated screen can be separated from the permeable wall at a distance of 0.5-5 mm.

It is further proposed that the fuel cell be made in the form of a tube with open ends, the inside of the tube being a porous air electrode, the outside being a porous fuel electrode, and a gas-tight oxygen electrolyte located between the electrodes. In particular, the ECG may contain several tube fuel cells cantilevered at one end in the tube sheet, while the other ends are connected to the afterburner of oxidation products. In this case, the fuel oxidation chamber can be separated from the afterburner of the oxidation products by a partition with openings into which the ends of the fuel elements are placed with a gap.

The wall permeable to the mixture of fuel and oxidizing agent can be made of perforated ceramic, or of a metal mesh, or of pressed metal wire, or of metal fabric, or of foam metal.

In the particular case, in the zone of electrochemical oxidation it is possible to arrange the battery in the form of a set of vertically and parallel to each other tubular fuel cells with open ends.

The fuel element may be in the form of a tubular element, for example, having a circular cross section or a rectangular section with open ends, while the outer side of the element may be coated with a porous anode, such as, for example, Ni-YSZ stabilized with yttrium oxide zirconia (YSZ) . The anode may be coated on the inside with a dense electrolyte, such as, for example, Y ₂ O ₃ —ZrO ₂ . The dense electrolyte may be coated internally with a porous cathode, such as, for example, LaMnO ₃ . The compositions used for the manufacture of SOFC tubes are not critical to the present invention.

The combination of two zones in the fuel oxidation chamber: the partial oxidation zone of the fuel and the electrochemical oxidation zone of the fuel, separated by a perforated screen, the separation of the fuel oxidation chamber from the fuel and oxidizer mixing chamber, which is permeable to the mixture of fuel and oxidizer by a wall made of heat-resistant material, allows for a stable surface combustion (partial oxidation) of the fuel, heating the oxidizing agent due to the heat released from the partial oxidation reaction. It also makes it possible to increase the reliability of the device, accelerate the SOFC output to operating mode, increase fuel efficiency and use a wide range of various hydrocarbon gases of both natural and biological origin as fuel, as well as simplify the design by eliminating burners from the ECG design for preheating additional devices for forced pumping of gases.

The installation of a perforated screen with a gap with respect to the permeable wall allows for stable combustion of the fuel.

Thus, a technical result is achieved.

The invention is illustrated by drawings: in FIG. 1 shows an assembly of ECG in a perspective view; FIG. 2 - vertical section of the ECG, where 1 is the housing, 2 is the fuel and oxidizer mixing chamber, 3 is the fuel oxidation chamber, 4 is the fuel cell, 5 is the afterburner of oxidation products, 6 is the oxidizer heating and distribution chamber, 7 is the partial oxidation zone fuel, 8 - zone of electrochemical oxidation of fuel, 9 - wall permeable to the mixture of fuel and oxidizing agent, 10 - perforated screen, 11 - pipe grate, 12 - partition, 13 - insulation, 14 - casing, 15 - holes in the pipe grate 11, 16 - holes in the partition 12, 17 - heat exchanger.

The housing 1 may have a rectangular or circular shape. The housing 1 is surrounded by thermal insulation 13, closed by the casing 14. The chamber 2 for mixing fuel and oxidizer is adjacent to the housing 1, part of the walls of which are the walls of the chamber. The chamber 2 is closed by walls 9, which are permeable to the mixture of fuel and oxidizer, which form the oxidation chamber 3 of their external side, which can have a rectangular or circular shape, the fuel oxidation chamber 3 has two zones: a partial oxidation zone 7 and an electrochemical oxidation zone of fuel 8.

The battery of fuel cells 4 can be supported by various functional components, in particular a tube sheet 11 made of aluminum oxide or other high temperature resistant material.

In the tube sheet 11 a set of holes 15 is formed, which provide a passage to the interior of the tubes 4.

At the second end of the tube 4 are fixed by protrusions in the holes 16 in the partition 12.

In the chamber 6, the heat exchanger 17 is a set of metal tubes of heat-resistant metal. The upper ends of the tubes are inserted into the openings of the lid of the chamber 6, and the lower ends of the tubes are inserted into the openings of the housing 1. The chamber 6 is formed by a grid 10, which is hermetically connected to the cover of the heat exchanger 17.

The device operates as follows. The initial hydrocarbon gas (methane, propane, natural gas, biogas, etc.) is simultaneously supplied with the oxidizer (air or oxygen) to the fuel and oxidizer 2 mixing chamber, the mixture of fuel and oxidizer passes through the permeable wall 9, a gas-phase autothermal partial oxidation process occurs ( conversion) with the formation of synthesis gas with the release of heat. This process makes it possible to use almost any gaseous hydrocarbon fuel and does not require its deep cleaning from impurities. The ECG is started by igniting the gas-air mixture on the inner surface of the permeable wall 9. The perforated screen 10, on the one hand, passes the synthesis gas to the fuel cells, and on the other hand, reflects radiation on the permeable wall 9 and stabilizes surface combustion on the wall 9 of the fuel mixture and oxidizing agent. The supply of hot synthesis gas to the fuel cells 4 is carried out by natural convection, the synthesis gas washes the fuel cells evenly, then the spent synthesis gas flows through the openings 16 in the baffle 12 into the afterburner 5. The oxidizing agent (air) for electrochemical oxidation enters through the heat exchanger 17 Using heat from the partial oxidation process, it is distributed throughout the cell 6 and then heated over the SOFC elements 4, providing a continuous uniform flow of the oxidizer through the inner cavity of the element.

Under certain conditions, the oxidizing agent flows through natural convection.

After the fuel cells 4 reach a temperature of 750 ^° C, the electrochemical generator is connected to the load.

Claims (7)

1. An electrochemical generator based on solid oxide fuel cells, comprising a housing, a fuel / oxidizer mixing chamber located therein, a fuel oxidation chamber with at least one fuel cell disposed therein, an oxidation products afterburner, an oxidizer heating and distribution chamber, and the chamber exit the mixture of fuel and oxidizer is connected to the fuel oxidation chamber, the output of the fuel oxidation chamber is connected to the entrance to the afterburner of oxidation products, characterized in that the fuel oxidation chamber It consists of two zones: a zone of partial oxidation of fuel and a zone of electrochemical oxidation of fuel, while the chamber of fuel oxidation is separated from the chamber of mixing fuel and oxidizer, a wall made of heat-resistant material is permeable to the mixture of fuel and oxidizer. 2. The generator according to claim 1, characterized in that between the zones of partial oxidation of the fuel and electrochemical oxidation of the fuel there is a perforated screen with a gap with respect to the permeable wall. 3. The generator according to claim 2, characterized in that the perforated screen is spaced from the permeable wall at a distance of 0.5-5 mm. 4. The generator according to claim 1, characterized in that the fuel cell is made in the form of a tube with open ends, the inside of the tube is a porous air electrode, the outside is a porous fuel electrode, and a gas-tight oxygen electrolyte is located between the electrodes. 5. The generator according to claim 4, characterized in that it contains several tube fuel cells cantileverly fixed at one end in the tube sheet, and the other ends are connected to the afterburner of oxidation products. 6. The generator according to claim 5, characterized in that the oxidation chamber of the fuel separates the partition with holes in the ends of the fuel cells from the afterburner of the oxidation products. 7. The generator according to claim 1, characterized in that the wall permeable to the mixture of fuel and oxidizing agent is made of perforated ceramic, or of a metal mesh, or of pressed metal wire, or of metal fabric, or of foam metal.

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