KR20130075988A - Separator for stack of solid oxide fuel cell - Google Patents

Abstract

PURPOSE: A separator for a solid oxide fuel cell is provided to transfer direct current to a normal unit cell next to a bad cell through a current unit by attaching the current unit to the surface between separators. CONSTITUTION: A separator (100) for a solid oxide fuel cell is located between a cell frame (300) on which a unit cell (200) including an air electrode, an electrolyte, and a fuel electrode, and includes a real use region which accommodates a cell frame and a sealing part and a current unit-accommodating region which accommodates a current unit (101) extended from the real use region. A solid oxide fuel cell includes the unit cell including the air electrode, the electrolyte, and the fuel electrode; the cell frame where the unit cell is disposed; and the separator between the cell frames.

Description

Separator for solid oxide fuel cell {SEPARATOR FOR STACK OF SOLID OXIDE FUEL CELL}

The present invention relates to a separator used in a solid oxide fuel cell.

A fuel cell is a power generation system that produces direct current by converting chemical energy of fuel (hydrogen) directly into electrical energy, and supplies oxidant (eg oxygen) and gaseous fuel (eg hydrogen) through an oxide electrolyte. By chemically reacting, it is an energy conversion device that produces direct current electricity.

A fuel cell is classified into a phosphoric acid fuel cell, a molten carbonate fuel cell, a solid oxide fuel cell, a polymer electrolyte type or an alkaline fuel cell according to the type of electrolyte used. The phosphoric acid fuel cell operates at a relatively low temperature, and the molten carbonate fuel cell and the solid oxide fuel cell operate at a high temperature.

In particular, the solid oxide fuel cell (SOFC) of the fuel cells is a fuel cell using a solid oxide having oxygen or hydrogen ion conductivity as an electrolyte, the highest temperature (600 ~ 1000) of the existing fuel cells ° C), all components are solid and simple in structure compared to other fuel cells, there is no problem of electrolyte loss, replenishment and corrosion, no precious metal catalyst, and fuel supply through direct internal reforming It is easy. In addition, since the hot gas is discharged, thermal combined cycle power generation using waste heat is possible.

The solid oxide fuel cell has a structure in which a plurality of electricity generation units each including a unit cell and a separator plate are stacked. The unit cell includes an electrolyte membrane, an anode (air electrode) located on one surface of the electrolyte membrane, and a cathode (fuel electrode) located on the other surface of the electrolyte membrane.

When oxygen is supplied to the cathode and hydrogen is supplied to the cathode, oxygen ions generated by the reduction reaction of oxygen at the cathode move through the electrolyte membrane to the cathode, and then react with hydrogen supplied to the cathode to generate water. In this case, electrons flow in an external circuit in the process in which electrons generated at the cathode are delivered to the cathode and are consumed, and the unit cell uses the electron flow to produce electrical energy.

A fuel cell composed of an electrolyte, an air electrode and a fuel electrode is called a unit cell, and since the amount of electric energy produced by one unit cell is very limited, the unit cells are connected in series in order to use the fuel cell for power generation. The laminated structure (stack, stack) is produced. The separator is used to prevent the mixing of fuel and air while electrically connecting the cathode and the anode of each unit cell to form a stack.

In general, after placing the unit cell in a frame of the cell, the frame and the separator are repeatedly stacked to form a stack of a solid oxide fuel cell. In this case, a manifold hole is formed to pass through the stack to inject the fuel and air, and gas is introduced into the flow path of the separation plate through the hole. Air is introduced into the flow path of the separation plate in contact with the cathode.

However, in the fuel cell stack, a large number of separators and cell frames are sequentially stacked, and in some cases, the performance of some unit cells is degraded in the process of applying high pressure at high temperature during operation, resulting in defective cells. As described above, when a defective cell is partially generated in the fuel cell stack, the internal cell of the defective cell has a large internal resistance, so when the current is applied, the potential difference is lowered. This can seriously impede the performance of the stack and prevents the stack from operating normally.

In fact, in order to commercialize a large-capacity fuel cell stacking a large number of unit cells, when a problem occurs in some unit cells, the remaining unit cells except for the problematic unit cell should be able to operate normally.

At present, it attempts to operate or replace a module unit by combining 10 or more unit cells into a single module, but this is not only too large a range of loss compared to a problem range, but also a whole stack There is also the difficulty of dismantling the module and replacing the module.

One aspect of the present invention provides a separator for a fuel cell capable of continuing fuel cell operation even in the presence of defective cells.

One aspect of the present invention is a separator for a solid oxide fuel cell provided between a cell frame in which a unit cell including an air electrode, an electrolyte, and a fuel electrode is located.

A real use area accommodating a cell frame and a seal, and a current accommodating area accommodating an ammeter extending outwardly from the actual use area, the ammeter accommodating area being provided with an ammeter attachment means for attaching the ammeter; The present invention provides a separator for a solid oxide fuel cell.

Another aspect of the present invention is a unit cell including an air electrode, an electrolyte and a fuel electrode; A cell frame in which the unit cell is located; A solid oxide fuel cell comprising a separator plate provided between the cell frames, wherein the separator plate is a separator plate for the fuel cell provided by the present invention.

According to the present invention, when a separator including a region extending outward from an actual use region to be provided with an electric current is applied to a solid oxide fuel cell, between the separator plates when a bad cell is generated in the stack of the fuel cell. By attaching an armature to the current, the DC current cut off by the defective cell can be continuously transmitted to the next normal unit cell.

Therefore, it is possible to solve the problem that the current is blocked by the generation of defective cells, it is possible to efficiently operate the fuel cell without additional work, such as replacing the existing module.

1 is a view showing a structure before assembling a solid oxide fuel cell stack including a separator for a fuel cell according to the present invention.
FIG. 2 is a view illustrating a structure in which the solid oxide fuel cell stack of FIG. 1 is assembled.
3 is a view showing a structure before assembly of a solid oxide fuel cell stack including a separator for fuel cells according to the present invention.
FIG. 4 is a view illustrating a structure in which the solid oxide fuel cell stack of FIG. 3 is assembled.

Hereinafter, with reference to the drawings will be described in detail a specific embodiment of the present invention. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may be easily suggested, but this will also be included in the spirit of the present invention.

The fuel cell stack is a structure in which a large number of separators and cell frames in which unit cells are positioned are continuously stacked, and high pressure is applied at high temperatures during the operation of the stack. May occur.

At present, the unit cells are bundled into 10 or more units and configured as a module to operate as a module unit, and when a bad cell occurs during operation, the module is replaced, but this is more than a problem range. Not only is the range of losses to be too large, but also the difficulty of disassembling the entire stack and replacing modules.

Accordingly, an object of the present invention is to provide a fuel cell separation plate that enables efficient delivery of fuel even when defective cells are generated in the fuel cell stack. .

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 and 2 is a view showing a structure before and after assembling an example of a solid oxide fuel cell stack including a separator for a fuel cell according to the present invention.

As shown in Figures 1 and 2, the solid oxide fuel cell separator 100 of the present invention is a solid oxide fuel provided between the cell frame 300 in which the unit cell 200 including the air electrode, the electrolyte and the fuel electrode is located. A battery separator comprising: a real use area accommodating a cell frame and a seal, and an ammeter receiving area accommodating an ammeter 101 extending outwardly from the real use area, wherein the ammeter is attached to the ammeter receiving area. An armature attachment means 102 is provided.

Separation plate provided in the present invention is sufficient to serve to provide a flow path of fuel and air at the same time to distinguish each unit cell irrespective of the shape, for example, the separation plate may have a rectangular shape.

The armature receiving region included in the separator may be formed in at least one of front, rear, left and right directions of the rectangular separator. Referring to the drawings, the armature accommodating area is a region in which the armature 101 can be accommodated in FIGS. 1 and 3, and the armature attaching means for attaching the armature 101 to this region ( 102 is provided.

FIG. 1 is a structure of a fuel cell stack configured to include a separator plate 100 having regions extending in left and right directions facing each other from a practical use area as compared with a conventional rectangular separator.

In addition, as shown in FIG. 3, the other separator plate 100 ′ of the present invention may have an ampere receiving region extended in the front and rear directions facing each other from the actual use region.

As described above, the separator plate 100 and 100 ′ further include an armature accommodating region and an armature attaching means extending outward from the actual use region when the defective cell is generated in the fuel cell stack. This is to smoothly transfer the DC current blocked by the defective cell by attaching an armature to the means to the normal unit cell 200 positioned next to the defective cell through the armature 101. In this case, even if a defective cell occurs, the operation of the fuel cell can be continued.

Ampere 101 that can be provided in the amperage receiving region of the separator 100 can improve the electrical performance of the fuel cell stack, any material can be used as long as it can deliver the current, specifically metal Materials having conductive properties such as alloys or precious metals may be used, but are not limited thereto.

Representative metal currents can be used as Inconel, the main alloy metal of iron-nickel-chromium, which is excellent in heat resistance, acid resistance and high temperature resistance. Stainless steel with 18% or more of chromium content can be used as a low-cost material. have.

As described above, the separator plate 100 according to the present invention, in addition to the armature 101 and the armature attachment means 102 for attaching the armature, the fuel input manifold hole 103 to which fuel can be supplied. It is preferable that an air manifold hole 104 for supplying air and air can be formed.

When the fuel and air are introduced through the manifold hole, the inlet 103 and the outlet 103 ′ of the manifold hole into which the fuel is injected and the manifold hole into which the air is introduced to prevent the fuel and air from being mixed therein. Inlet 104 and outlet 104 'must be formed as separate holes.

The gas introduced through the fuel manifold hole 103 and the air manifold hole 104 moves along the flow path of the separator 100 to produce and consume electrons in the unit cell 200. By generating electrical energy.

More specifically, in the fuel introduced through the fuel injection manifold hole 103, hydrogen is decomposed into hydrogen ions and electrons at the anode, and the generated hydrogen ions move to the cathode via the electrolyte. Thereafter, electrons generate current through an external circuit, and some electrons are introduced into the cathode to combine with hydrogen ions and oxygen introduced through the air manifold hole 104 to generate water.

Another aspect of the present invention is a unit cell including an air electrode, an electrolyte and a fuel electrode; A cell frame in which the unit cell is located; Provided is a solid oxide fuel cell including a separator provided between the cell frames.

The separating plate provided between the cell frames includes a real use area accommodating the cell frame and the sealing part and an ammeter receiving area accommodating an ammeter extending outward from the real use area, as described above. It is preferable that the receiving region be a separating plate provided with an armature attachment means for attaching the armature.

In an example of the solid oxide fuel cell according to the present invention, as shown in FIGS. 1 and 2, the separators 100 provided in the fuel cell have the same armature accommodating area having the armature attachment means 102. It can be stacked to be located on the side.

3 and 4 show another example of a solid oxide fuel cell according to the present invention.

In the case where a defective cell is generated in the fuel cell stack and the armature is provided in the armature receiving region of the separator, when the unit cell 200 is too narrow in length, it is difficult to effectively attach the armature 101 to FIGS. 3 and 4. As shown in the figure, the separators 100 and 100 ′ having regions extending in different directions are provided at the intersections, whereby the currents 101 may be provided at intervals of two unit cells 200.

That is, as shown in FIGS. 3 and 4, the separator plates 100 and 100 ′ are located at different sides from the armature receiving region of the closest separator plate and closest to each other. It is preferable to be laminated so that it may be located on the same side as the armature receiving region of the next separation plate of the plate.

As described above, when an unexpected defective cell occurs in the fuel cell stack, an ammeter may be attached between the separator plates so that a direct current may be transferred to the normal unit cell located after the defective cell through the ammeter.

Accordingly, the current can be smoothly transmitted even in the presence of a defective cell, and the fuel cell can be continuously operated without additional work such as replacing an existing module.

1000: fuel cell
100: separator for fuel cell
100 ': separator plate for fuel cell
101: ammeter
102: armature attachment means
103: manifold hole for fuel injection
103 ': Fuel drain manifold hole
104: air manifold hole
104 ': Manifold hole for air exhaust
200: unit cell
300: cell frame

Claims (7)

A separator for a solid oxide fuel cell provided between a cell frame in which a unit cell including an air electrode, an electrolyte, and a fuel electrode is located,
A real use area accommodating a cell frame and a seal, and a current accommodating area accommodating an ammeter extending outwardly from the actual use area, the ammeter accommodating area being provided with an ammeter attachment means for attaching the ammeter; Separator for solid oxide fuel cells.
The solid oxide of claim 1, wherein the separator has a rectangular shape, and the armature receiving region is formed in at least one of front, rear, left, and right directions of the rectangular separator. Separator for fuel cell.
3. The separator plate for solid oxide fuel cells according to claim 2, wherein the armature receiving region is formed in two directions facing at least one of front, rear, left and right directions of the rectangular separator.
The separator of claim 1, wherein the current is made of Inconel, which is a main alloy metal of iron-nickel-chromium, or stainless steel having a chromium content of 18% or more.
A unit cell including an air electrode, an electrolyte, and a fuel electrode;
A cell frame in which the unit cell is located;
A solid oxide fuel cell comprising a separator plate provided between the cell frames, wherein the separator plate is a separator plate according to any one of claims 1 to 4.
6. The solid oxide fuel cell as set forth in claim 5, wherein the separators are stacked such that the armature receiving region provided with the armature attachment means is located on the same side.
The separator of claim 5, wherein the separators have a rectangular shape, and the armature receiving region is formed on the rectangular separators in front and rear directions and is formed in left and right directions. The separators are stacked such that the armature receiving area of one separator plate is located on a different side from the armature receiving area of the nearest separator plate and is located on the same side as the armature receiving area of the next separator plate of the closest separator plate. Solid oxide fuel cell, characterized in that.

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