JPWO2018154656A1 - Flat plate type electrochemical cell stack - Google Patents

Abstract

A flat electrochemical cell stack in which a plurality of unit units are stacked, wherein the unit units are a flat solid oxide cell and a sealing plate disposed to be in contact with the peripheral portion of the cell. And a conductive separator having a cell storage portion for storing the cells, and a recess provided around the cell storage portion for fitting the sealing plate, and at least an outer periphery of the recess of the separator. And a sealing member having a sealing surface which seals the side and the sealing plate in the same plane.

Description

  Embodiments of the present invention relate to planar electrochemical cell stacks.

  Fuel cells that convert chemical energy into electrical energy by electrochemically reacting hydrogen and oxygen attract attention. Fuel cells have high energy utilization efficiency, and are being developed as large-scale distributed power sources, household power sources, and mobile power sources.

  Fuel cells are classified into solid polymer type, phosphoric acid type, molten carbonate type, solid oxide type, and the like according to the temperature range, the materials used, and the type of fuel. Among them, solid oxide fuel cells (SOFCs) that obtain electric energy by an electrochemical reaction using an electrolyte composed of solid oxide are attracting attention from the viewpoint of efficiency and the like. In addition, high-temperature steam electrolysis, in which hydrogen is produced by a solid oxide electrolytic cell (SOEC) using the reverse reaction of SOFC, has also been developed in recent years.

  An electrochemical cell (hereinafter simply referred to as a cell), which is the smallest structural unit of SOFC and SOEC, is at least a laminate of an air electrode, an electrolyte and a fuel electrode, and each uses materials of different characteristics. The air electrode and the fuel electrode are porous, and different gases are supplied to the air electrode and the fuel electrode, respectively, with a dense electrolyte. The air electrode and the fuel electrode are electric conductors, and the electrolyte is an ion conductor that does not conduct electricity.

  The shape of the cell is, for example, a flat plate type, a cylindrical shape, or a cylindrical flat plate type. For example, a flat cell has a shape in which an air electrode, an electrolyte, a fuel electrode and the like are stacked in a flat plate shape.

  A plurality of integrated cells are generally called a stack. For example, in the case of flat cells, the stack is formed by stacking a plurality of flat cells, and supplies different gases to the air electrode and the fuel electrode of each cell, and the cells can be connected electrically in series. Has a simple structure.

  The cell and the cell are separated by a separator, which separates the gas per cell. In addition, since the separator is conductive, it also plays a role of electrical conduction between cells. A gas supply / discharge flow path to each cell is also generally formed in the separator.

  FIG. 4 shows an example of the structure of a stack 400 using flat cells. An example of the flat plate type cell is a fuel electrode supported type cell. The gas flowing to the air electrode side and the fuel electrode side of the cell is not particularly limited, but FIG. 4 shows an example where air is flowed to the air electrode side of the cell and hydrogen is flowed to the fuel electrode side on the assumption that power is generated. The

  The cell 414 is mainly composed of a porous fuel electrode 413, a porous air electrode 412, and a dense electrolyte 411. In the stack 400, the portion where the cell 414 is installed has a dense electrolyte 411, and this electrolyte 411 isolates the atmosphere of the fuel electrode 413 and the air electrode 412. On the other hand, in the portion where the cell 414 is not installed, it is necessary to isolate the atmosphere of the fuel electrode 413 and the air electrode 412 by some precise member.

  In the example shown in FIG. 4, the atmosphere of the cells 414 adjacent to each other is isolated by the dense separator 423. Further, for the atmosphere of the fuel electrode 413 and the air electrode 412 of the same cell 414, the sealing plate 424 is provided on the electrolyte 411 which is a dense layer to separate the fuel electrode 13 from the air electrode 412. The seal between the sealing plate 424 and the separator 423 is achieved by installing a compressive sealing material 421 which is deformed by pressure on the sealing plate 424. In the separator 423 and the sealing plate 424, gas channels 422 for supplying gas to the cells 414 are formed. Also, a current collector 426 is provided between the fuel electrode 413 and the separator 423. Similarly, between the air electrode 412 and the adjacent separator 423, a current collector (not shown) for electrically connecting these is provided.

  In the stack 400 using the flat cell 414, in particular, the outflow of the gas flowing in the stack 400 to the outside of the stack 400, and the supply gas to the fuel electrode 413 and the air electrode 412 mix in the stack 400. In other words, the gas sealability is a major issue. The structure that separates the fuel electrode 413 from the air electrode 412 greatly affects the gas sealability, and a structure capable of achieving high sealability is required. In the conventional flat stack, in order to isolate the atmosphere of the fuel electrode 413 and the air electrode 412, as shown in FIG. 4, the sealing plate 424 and the compressive sealing material 421 are often used in combination.

JP, 2016-126893, A

  In the case of SOFC, for example, the loss of fuel gas necessary for power generation is reduced by preventing the outflow of the gas flowing inside the stack to the outside of the stack and the mixing of the atmosphere gas of each of the fuel electrode and the air electrode inside the stack. Power generation performance can be improved.

  In the conventional flat stack, as described above, in order to separate the atmosphere of the fuel electrode and the air electrode, the sealing plate and the compressive seal material are often used in combination. However, in this structure, there are many gas leak paths between the separator and cell and the sealing plate, between the sealing plate and the sealing material, and between the sealing material and the separator, and there is a problem that it is difficult to improve sealing performance. .

  Moreover, although a compressible seal seals by applying a pressure, if a sealing board is thin, it will deform | transform and become a factor which reduces sealing performance. On the other hand, if the sealing plate is thickened to increase the strength, there is a problem that the size of the stack becomes large.

  The problem to be solved by the present invention is to provide a flat electrochemical cell stack having a small size and a high gas sealability.

  The flat plate electrochemical cell stack according to the embodiment is a flat plate electrochemical cell stack in which a plurality of unit units are stacked, and the unit unit is a flat solid oxide cell, and a peripheral portion of the cell. A conductive plate having a sealing plate disposed to abut on the cell, and a cell receiving portion for receiving the cell, and a recess provided around the cell receiving portion and into which the sealing plate is fitted; A sealing member having a sealing surface for sealing at least the outer peripheral side of the recess of the separator and the sealing plate in the same plane is provided.

The figure which shows typically the cross-sectional structure of a part of stack of 1st Embodiment. The figure which shows the whole structure of a stack typically. The figure which shows typically the cross-sectional structure of a part of stack of 2nd Embodiment. The figure which shows typically the cross-sectional structure of a part of example of a stack.

  Hereinafter, embodiments will be described with reference to the drawings. FIG. 1 is a view schematically showing a cross-sectional configuration of a part of a flat plate type electrochemical cell stack (hereinafter simply referred to as a stack) 100 of the embodiment.

  The stack 100 includes flat cells 104. The flat cell 104 has a structure in which a porous air electrode 102, a dense electrolyte 101, and a porous fuel electrode 103 are stacked. Gas can pass through the air electrode 102 and the inside of the fuel electrode 103, but gas does not pass through the inside of the electrolyte 101. The cell 104 is in the form of a rectangular plate.

  The electrolyte 101 is made of solid oxide and has oxygen ion conductivity. As the electrolyte 101 of the solid oxide, for example, a compact stabilized zirconia, a perovskite type oxide, a compact of a ceria-based solid solution, or the like is used.

  For the fuel electrode 103, generally, a mixed sintered body (cermet) of metal and solid oxide is used. For example, Ni-YSZ (yttria stabilized zirconia), Ni-ScSZ (scandia stabilized zirconia), etc. are used.

  On the other hand, for the air electrode 102, generally, a perovskite oxide or an oxide in which some of these sites are substituted is used. For example, LaSrMn oxide, LaSrCo oxide, LaSrCoFe oxide, LaSrFe oxide etc. may be mentioned. Moreover, the mixture with the solid oxide used for electrolyte etc., etc. are used, for example, LSM-YSZ, LSM-ScSZ, LSC-SDC, LSC-GDC etc. are mentioned.

  A separator 123 made of a conductive material is disposed so as to surround the cell 104. The entire shape of the separator 123 is, for example, a rectangular plate, and the central portion of the separator 123 has a cell accommodating portion 123a formed of a recess. The cell 104 is installed in the cell accommodating portion 123 a of the separator 123. The material of the separator 123 is a dense and conductive material such as a metal or a ceramic. Moreover, as this material, a material having a thermal expansion coefficient close to that of the cell 104 is desirable.

  In order to reduce the electrical resistance between the cell 104 and the separator 123, a current collector made of a conductive member is disposed. Between the fuel electrode 103 and the separator 123, a current collector 126 made of a cushioning conductive member is installed. The current collector 126 needs to be permeable to gas. For this reason, the current collector 126 is made of, for example, a mesh-like metal. Similarly, in FIG. 1, the air electrode 102 and the separator 123 located above the air electrode 102 are electrically connected by a current collector or the like (not shown).

  Recesses 123b are respectively formed along the two opposing sides (the side on the left side and the side on the trunk side in FIG. 1) of the separator 123 around the cell accommodation portion 123a. In the stack 100 shown in FIG. 1, the depth of the recess 123 b is smaller than the depth of the cell accommodation portion 123 a.

  Sealing plates 124 are respectively fitted in the recessed portions 123b formed along the two opposing sides of the cell accommodating portion 123a. The sealing plate 124 is configured in a plate shape, and the inner edge thereof is configured to abut on the periphery of the electrolyte 101 of the cell 104. The thickness of the sealing plate 124 is the same as the depth of the recess 123 b. Therefore, the surface 124s of the sealing plate 124 and the surface 123s of the separator 123 on the outer peripheral side of the sealing plate 124 are located in the same plane. That is, the surface 123s of the separator 123 and the surface 124s of the sealing plate 124 are flush with each other. The separator 123 and the sealing plate 124 are preferably joined by welding or the like. By this, the sealing performance of gas can be improved.

  Further, the surface 123s of the separator 123 and the surface 124s of the sealing plate 124 described above and the surface 101s of the electrolyte 101 of the cell 104 are located in the same plane. In other words, these are the same. The term "in the same plane" means that there is a level difference or the like due to a tolerance due to dimensional accuracy as well as the case where the plane is completely the same plane.

  Then, on these surfaces, a compressive sealing material 121 which is crushed by exerting pressure and exhibits sealing performance is installed. The sealing material 121 is in the form of a frame having a rectangular outer shape. The material of the sealing material 121 is not particularly limited, but desirably has high electrical insulation. Examples of the material of the sealing material 121 include alumina, zirconia, silica, and materials containing at least these. About density, precise thing is desirable.

  On the sealing material 121, the separator 123 which accommodates the adjacent cell 104 is laminated | stacked. Through holes are formed in the separator 123, the sealing plate 124, and the sealing material 121 in order to form a gas flow path 122 for supplying and discharging a gas. The gas flow path 122 circulates the gas along the stacking direction of the stack 100 (vertical direction in FIG. 1). A gap 125 is provided between the sealing plate 124 and the separator 123. The gap 125 constitutes a gas path for allowing the fuel gas to flow between the gas flow path 122 and the fuel electrode 103.

  As shown in FIG. 2, an arbitrary number of unit units having the above-described structure are stacked to form a stack 100. In addition, the end plate 120 etc. are arrange | positioned at the both-ends (The upper end and lower end in FIG. 2) of the lamination direction. Then, these are tightened and fixed by fastening means, for example, a plurality of bolts 111 and nuts 112 or the like. In addition, illustration of a part of part in which the separator 123 grade | etc., Of the same structure is arrange | positioned in FIG. 2 is abbreviate | omitted.

  The stack 100 is pressurized in the stacking direction by the bolts 111 and the nuts 112 and the like, whereby the pressure is applied to the compressive seal member 121 to exhibit a gas sealing function. In order to prevent deformation of the sealing plate 124 when such pressure is applied, as shown in FIG. 1, the sealing plate support 127 is between the sealing plate 124 and the bottom of the cell accommodating portion 123 a of the separator 123. Provided to intervene in the Although the sealing plate support 127 may have any shape, it is preferable that the sealing plate support 127 has a shape that does not impede the flow of gas on the fuel electrode 103 side.

  As described above, in a state in which pressure is applied in the stacking direction, as shown in FIG. 1, the total thickness of the cell 104 and the thickness of the current collector 126 is the depth of the cell accommodating portion 123 a of the separator 123. It is the same.

  On the other hand, for example, when assembling the stack 100, the total thickness may be larger than the depth of the cell accommodation portion 123a before the pressure is applied in the stacking direction. Then, when pressure is applied in the stacking direction, the cell 104 is pushed by the sealing material 121 and the current collecting material 126 is crushed, thereby reducing the thickness, and the total thickness is the same as the depth of the cell storage portion 123a. May be configured as follows. That is, before the pressure is applied in the stacking direction, the surface 123s of the separator 123 and the surface 101s of the electrolyte 101 are not flush with each other, but when pressure is applied in the stacking direction, they become flush. It is also good.

  In the stack 100 configured as described above, the surface 123s of the separator 123, the surface 124s of the sealing plate 124, and the surface 101s of the electrolyte 101 of the cell 104 are located in the same plane. Then, the sealing material 121 is sandwiched between these surfaces and the adjacent separator 123 for gas sealing. For this reason, there are only two places where the gas may leak to the outside, the two places of the both sides of the inserted sealing material 121.

  On the other hand, for example, in the stack 400 shown in FIG. 4, three between the separator 423 and the sealing plate 424, between the sealing plate 424 and the sealing material 421, and between the sealing material 421 and the separator 423. There is a possibility that gas may leak to the outside from the place. Therefore, in the stack 100 shown in FIG. 1, the possibility of gas leakage to the outside can be reduced as compared with the stack 400 shown in FIG. 4, and the sealing performance can be improved. Further, the stack 100 shown in FIG. 1 can be miniaturized because the number of apparent stacked layers is reduced as compared with the stack 400 shown in FIG. 4.

  Next, a second embodiment will be described. FIG. 3 is a view schematically showing a cross-sectional configuration of a part of the stack 200 according to the second embodiment. In FIG. 3, the same parts as in FIG. 1 will be assigned the same reference numerals and overlapping explanations will be omitted.

  As shown in FIG. 3, in the stack 200, concave portions 223b are respectively formed along the two opposing sides (the side on the left side and the side on the trunk side in FIG. 1) of the cell accommodating portion 223a of the separator 223. The depths of these concave portions 223b and the depth of the cell accommodation portion 223a are the same, and they are integrally formed. A sealing plate 224 having the same height as the depth of the recess 223b is provided in each recess 223b.

  Therefore, the surface 223s of the separator 223 on the outer peripheral side of the recess 223b and the surface 224s of the sealing plate 224 are located in the same plane. That is, the surface 223s of the separator 223 is flush with the surface 224s of the sealing plate 224. The separator 223 and the sealing plate 224 are preferably joined by welding or the like. By this, the sealing performance of gas can be improved.

  Further, the surface 223s of the separator 223 and the surface 224s of the sealing plate 224 described above and the surface 101s of the electrolyte 101 of the cell 104 are located in the same plane. In other words, these are the same. Then, on these surfaces, a compressive seal member 221 is installed via a plate member 228, and sealing is performed by a flat seal surface 221s. The plate member 228 is formed in a frame shape from a flat plate, and is for protecting the mechanically fragile sealing material 221.

  That is, although the surfaces 223s, 224s, and 101s are located in the same plane, there is a state in which there is a level difference or the like due to a tolerance due to dimensional accuracy, etc. other than the case where they are completely the same plane. included. In this case, when pressure is applied, the force applied to the seal surface of the seal material 221 becomes uneven, and the seal material 221 may be damaged. In order to prevent such a damage of the sealing material 221, a flat plate-like plate member 228 is disposed to make the force applied to the sealing surface uniform. In addition, since the plate member 228 may be thinner than a sealing plate or the like, an increase in the thickness of the stack 200 can be suppressed. Also, the plate member 228 is not necessarily required, and may be omitted.

  In the sealing plate 224, in addition to the through holes that constitute the gas flow path 122 provided along the stacking direction shown in FIG. 3, the gas is allowed to flow from the gas flow path 122 toward the fuel electrode 103 of the cell 104. A gas flow path 229 is formed.

  In the stack 200 configured as described above, the thickness of the sealing plate 224 is large, and there is no gap between the sealing plate 224 and the separator 223, so deformation when pressure in the stacking direction is applied is suppressed. Thereby, the sealability can be improved. In addition, the stack 200 does not increase in size due to the thickness of the sealing plate 224 being increased.

  While the embodiments of the present invention have been described above, the embodiments are presented as examples and are not intended to limit the scope of the invention. This novel embodiment can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and the gist of the invention, and are included in the invention described in the claims and the equivalent scope thereof.

  100 ... stack, 101 ... electrolyte, 102 ... air pole, 103 ... fuel pole, 104 ... cell, 111 ... bolt, 112 ... nut, 120 ... end plate, 121 ... sealing material, 122 ... gas flow path, 123 ... separator, 123a: cell housing portion, 123b: recess, 124: sealing plate, 125: gap, 126: current collector, 127: sealing plate support, 101s: surface of electrolyte, 121s: sealing surface, 123s: surface of separator, 124s ... surface of sealing plate, 200 ... stack, 221 ... sealing material, 223 ... separator, 223a ... cell accommodation portion, 223b ... recess, 224 ... sealing plate, 228 ... plate material, 229 ... gas flow path, 221s ... sealing surface , 223s ... surface of separator, 224s ... surface of sealing plate, 400 ... stack, 411 ... electrolyte, 412 ... air electrode, 413 ... burn Electrode, 414 ... cell, 421 ... sealing member, 422 ... gas flow channel, 423 ... separator, 424 ... sealing plate, 426 ... power collector.

Claims (4)

A flat electrochemical cell stack in which a plurality of unit units are stacked,
The unit is
A flat solid oxide cell;
A sealing plate disposed to abut the peripheral edge of the cell;
A conductive separator having a cell storage portion for storing the cells, and a recess provided around the cell storage portion and into which the sealing plate is fitted;
A flat electrochemical cell stack comprising: a sealing member having a sealing surface that seals at least the outer peripheral side of the recess of the separator and the sealing plate in the same plane.   The flat electrochemical cell stack according to claim 1, wherein a gas flow path for circulating a gas is formed between the sealing plate and the separator.   The flat electrochemical cell stack according to claim 1 or 2, wherein at least a part of the contact portion between the sealing plate and the separator is joined.   The flat electrochemical cell stack according to any one of claims 1 to 3, further comprising a sealing plate support interposed between the bottom portion of the cell storage portion of the separator and the sealing plate.

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