JP4872286B2 - Separator assembly and planar polymer electrolyte fuel cell for planar polymer electrolyte fuel cell - Google Patents

Description

  The present invention relates to a planar polymer electrolyte comprising a pair of a fuel supply separator and an oxygen supply separator used in a planar polymer electrolyte fuel cell in which unit cells are arranged in one direction in a plane. The present invention relates to a separator assembly for a type fuel cell and a surface-type polymer electrolyte fuel cell using the separator.

Recently, expectations for fuel cells have increased rapidly from the standpoint of protecting the global environment, using hydrogen as a direct fuel, and having high energy conversion efficiency.
Until now, it has been used for space development and marine development, but recently, it has been expanded to be used as a power generator for home use instead of an automobile engine, and it has become more likely to be widely used.
A fuel cell is simply a device that continuously supplies fuel (reducing agent) and oxygen or air (oxidant) from the outside, and reacts electrochemically to extract electrical energy. Recently, depending on the type of electrolyte used, it is largely divided into solid oxide fuel cell (SOFC), molten carbonate fuel cell (MCFC), phosphoric acid. Generally, the fuel cell is classified into five types: a fuel cell (PAFC), a polymer electrolyte fuel cell (PEFC), and an alkaline aqueous fuel cell (AFC).
These use hydrogen gas generated from methane or the like as a fuel. Recently, a direct methanol fuel cell (DMFC) that directly uses an aqueous methanol solution as a fuel is also known.

Under such circumstances, a solid polymer membrane is composed of two types of electrodes sandwiched between two types of electrodes, and these members are sandwiched between separators (this is a polymer electrolyte fuel cell). Hereinafter, PEFC (Polymer Electrolyte Fuel Cell) is also drawing attention.
In this PEFC, a unit cell is configured by arranging electrodes such as an air electrode (oxygen electrode) and a fuel electrode (hydrogen electrode) on both sides of a solid polymer membrane, and both sides of the unit cell are sandwiched between fuel cell separators. It has a configuration.
A fuel electrode and an air electrode comprising a catalyst layer having a thickness of 10 μm to 20 μm are formed and integrated on both sides of a polymer electrolyte having a thickness of 20 μm to 70 μm, and a porous support layer (carbon paper, pores) as a current collector on the outside of the catalyst layer. And a separator (partition plate) that also serves as a supply path for a reactive gas such as hydrogen or oxygen.
In order to prevent direct reaction between the fuel (hydrogen) and the oxidant (air), it is necessary to isolate them and to carry hydrogen ions (protons) generated at the fuel electrode to the air electrode side.
A fuel cell that operates at room temperature (100 ° C or less) and moves protons in a solid polymer membrane. The solid polymer membrane has a thin film (thickness) with a perfluorocarbon sulfonic acid structure that has sulfonic acid groups as ion exchange groups. Can be used, and a compact battery can be manufactured.
The output performance is 1 to 3 A / cm ² , 0.6 to 2.1 V / single cell, and a high output density of 2.1 W / cm ² can be obtained.
As a PEFC separator, a graphite plate is currently cut out and grooved, but it is expensive in terms of cost.
For this reason, development of a carbon compound moldable separator in which carbon is kneaded into a resin is in progress, but this is problematic in terms of strength.
In addition, metal separators are expected to solve these cost problems and strength problems, but there is a problem in corrosion resistance.
Each of these separators is formed with a groove for supplying fuel gas and / or a groove for supplying oxidant gas as required.
From the aspect of corrosion resistance, a form in which gold plating or the like is applied is also employed.

The PEFC generally has a stack structure in which a plurality of unit cells each having an electrode are stacked on both sides of a solid polymer film and electrically connected to each other.
In the case of this structure, a fuel gas groove for supplying fuel gas to one adjacent unit cell is generally formed on one side surface of the separator for a fuel cell, and the other unit cell adjacent to the other side cell is formed on the other side surface. An oxidant gas groove for supplying oxidant gas is formed.
In such a separator, fuel gas and oxidant gas are supplied along the separator surface.

In addition to this stack structure, the PEFC is a planar type constructed by arranging a plurality of unit cells each having electrodes arranged on both sides of a solid polymer film and electrically connecting them. In recent years, however, development and improvement have been actively made for use as a power source for a portable terminal, which requires a thin electromotive force without requiring an electromotive force so much.
However, in the case of a planar type in which a plurality of unit cells are arranged in a plane and are electrically connected, there is a problem that the supply of fuel and oxygen becomes uneven depending on the location.
Therefore, in order to improve the non-uniformity of the fuel supply, a large number of through holes are formed in the direction perpendicular to the surface of the separator in contact with the membrane electrode assembly (MEA). A separator having a structure for supplying oxygen is considered. (See Patent Document 1)
Here, a composite including an electrode portion positioned between the fuel supply side separator and the oxygen supply side separator of the fuel cell, for example, a current collector layer, a fuel electrode, a polymer electrolyte, an oxygen electrode, A composite such as a film formed by stacking current collector layers is referred to as a membrane electrode composite (MEA).
JP, 2003-203647, A The applicant of this application has proposed such a plane type PFEC and a plane type separator used for it in Japanese Patent Application No. 2004-292268 (patent documents 2). Japanese Patent Application No. 2004-292268

Such a planar PEFC will be briefly described with reference to a planar methanol fuel cell (DMFC) directly using a methanol aqueous solution as a fuel as shown in FIG. Keep it.
FIG. 5 is a block diagram showing an example of a planar PEFC (polymer electrolyte fuel cell) 10 incorporating a pair of fuel supply side separator 20 and oxygen supply side separator 30, and FIG. 6 is shown in FIG. It is the figure which showed the state which spaced apart each member of the planar type PEFC.
In FIG. 5, a PEFC (Polymer Electrolyte Fuel Cell) 10 includes a battery body 10A in which a membrane electrode assembly (MEA) 40 is sandwiched between a pair of a fuel supply side separator 20 and an oxygen supply side separator 30, and a case body. 60.

In the battery main body 10 </ b> A, the fuel supply side separator 20 and the oxygen supply side separator 30 are bent at connecting hinge portions (not shown), and the respective insulating frames of the fuel supply side separator 20 and the oxygen supply side separator 30 are. 23 and 33 are arranged to face the membrane electrode assembly (MEA) 40.
In addition, current collectors 21 </ b> A and 31 </ b> A of the fuel supply side separator 20 and the oxygen supply side separator 30 are in contact with the membrane electrode assembly (MEA) 40 through the carbon paper 51 and 52.
The membrane electrode assembly (MEA) 40 includes a fuel electrode side catalyst layer 43 on the fuel supply side separator 20 side, and an oxygen electrode side catalyst layer 44 on the oxygen supply side separator 30.
Here, as shown in FIG. 6, the fuel supply side separator 20 and the oxygen supply side separator 30 are sandwiched between a pair of frame bodies 22 and 23 and frame bodies 32 and 33, respectively. The frame bodies 23 and 33 on the side of the composite (MEA) 40 open the entire cell region, but the outer frame bodies 22 and 32 are arranged in order to improve the adhesion of the current collectors 21A and 31A. The through portions 22a and 32a are provided so that the electric portions 21A and 31A can be pressed.
The conductive substrate 21 (31) of the separator 20 on the fuel supply side shown in FIGS. 5 and 6 is laminated with the frame bodies 22 and 23 on both sides thereof as shown in the perspective view of FIG.
In this case, the frame body 23 that opens the entire cell region is the membrane electrode assembly (MEA) 40 side.
FIG. 8 is a perspective view showing the parts in FIG. 7 apart from each other.
The same applies to the separator 30 on the oxygen supply side, and the conductive substrate 31 is laminated with frame bodies 32 and 33 on both sides thereof as shown in the perspective view of FIG.
And the frame 33 which has opened the whole cell area | region is laminated | stacked as the membrane electrode assembly (MEA) 40 side.

Thus, the three unit cells 81, 82, 83 are arranged in a plane.
The current collector 31A (unit conductive substrates 31a, 31b, 31c) and the current collector 21A (unit conductive substrates 21a, 21b, 21c) between the three unit cells 81, 82, 83 are connected hinges. It is electrically connected via a part (not shown).
Here, the connecting hinge portion may be covered with an insulating resin to provide an insulating coating. Further, in the battery main body 10A described above, the peripheral end portion of the membrane electrode assembly (MEA) 40 is sandwiched between the outer peripheral frame portions of the separators 20 and 30 via the seal member 70.
The battery body 10 </ b> A is fixed to the case body 60 via the seal member 70 using fixing bolts 90.

Further, an electrode terminal 37 connected to the unit conductive substrate 31a of the oxygen supply side separator 30 constituting the unit cell 81 is provided.
Further, an electrode terminal 27 connected to the unit conductive substrate 23 a of the fuel supply side separator 20 constituting the unit cell 83 is provided.
As a result, the three unit cells 81, 82, and 83 are electrically connected in series including the connection by the connecting hinge portion as follows.

In such a PEFC (Polymer Electrolyte Fuel Cell) 10, three unit cells 81, 82, 83 are connected by a connecting hinge portion, and there is no need for a connecting step using a connecting member, and The contact resistance is extremely low and the power generation characteristics are high.
In order to arrange the hinges without taking time when manufacturing the PEFC, conventionally, the connection hinge portions are formed by connecting the unit conductive substrates 21 a to 21 c and 31 a to 31 c of the separators 20 and 30. When manufacturing by etching or the like, the connection hinge part forming part is integrally connected together with these.
However, the connecting hinge manufactured in this way has a problem that it cannot withstand repeated bending when manufacturing the PEFC.
For this reason, the predetermined part of the connecting hinge part forming part is further thinned by a die press to be easily bent, but in this case, the connecting hinge itself is manufactured by etching or the like. In addition to the outer shape processing, it is necessary to perform a thinning process by a die press, which is troublesome and problematic.

As described above, in recent years, the development and application of fuel cells have progressed more and more, and recently, the use as a power source for mobile terminals, which requires flat electromotive force and is as thin as possible without requiring much electromotive force. Since then, the development and improvement of planar PEFC has been actively conducted.
Under such circumstances, in the planar type PEFC, a connecting hinge for electrically connecting the fuel supply side separator and the oxygen supply side separator is used. However, each separator member is manufactured by conventional etching processing or the like. If the connecting hinge part forming part is formed, there is a problem that the hinge part forming part is less resistant to repeated bending, and the predetermined part of the hinge part forming part is further thinned by a die press. In this method, it is necessary to perform a thinning process in addition to the outer shape processing such as etching processing, and there is a problem that it takes time and effort, and these measures have been required.
The present invention corresponds to this, and specifically, a fuel supply separator, an oxygen supply separator used in a planar polymer electrolyte fuel cell in which unit cells are planarly arranged in one direction, Is a pair of separators, which is a connection part that can be easily connected to a fuel supply separator and an oxygen supply separator in place of a conventional connection hinge part, and does not require much labor. Furthermore, the present invention intends to provide a separator assembly having a connection portion that can be formed and that is resistant to repeated bending when a PEFC is manufactured.
Furthermore, the present invention intends to provide a separator assembly in which each separator member has compatibility.
Another object of the present invention is to provide a separator assembly in which the fuel supply separator and the oxygen supply separator are compatible.
Furthermore, an object of the present invention is to provide a planar polymer electrolyte fuel cell using such a separator assembly.

The separator assembly for a planar polymer electrolyte fuel cell according to the present invention includes a fuel supply separator and an oxygen supply used in a planar polymer electrolyte fuel cell in which unit cells are arranged in one direction in a plane. A separator assembly for a planar polymer electrolyte fuel cell having a pair of separators for fuel, wherein each of the fuel supply separator and the oxygen supply separator includes a plurality of fuel supply or oxygen supply separators. A separator member in which n unit conductive substrates having through holes are arranged in one direction in a plane through a gap portion (n is an integer of 2 or more) and a separator member are integrated so as to sandwich the separator member. A pair of insulating frames, each of the pair of insulating frames having predetermined openings corresponding to the arrangement positions of the unit conductive substrates of each separator member, and the fuel supply for One separator member of the separator and oxygen supply separator is the first to (n-1) th unit conductive substrate at one end in the arrangement direction among the n unit conductive substrates. The connecting protrusion protruding in the direction orthogonal to the arrangement direction, the connecting protrusion having a notch portion for hook connection, and the other separator The member for the second unit to the nth unit conductive substrate at the end corresponding to the one side of the arranged direction among the n unit conductive substrates is a direction side orthogonal to the arrangement direction. And the connection protrusion has a cut-out portion for hook connection, and further forms the one separator member. = 1 to (n-1)) for connecting unit conductive substrates The cut-out portion of the protruding portion and the cut-out portion of the connecting protrusion of the (k + 1) th unit conductive substrate forming the other separator member are provided for the planar polymer electrolyte fuel cell. In such a case, it is provided in a shape and a position that match each other's hooked state.
The separator assembly for the above-described planar polymer electrolyte fuel cell, wherein one separator member of the fuel supply separator and the oxygen supply separator is an array of n unit conductive substrates. The first to (n−1) th unit conductive substrates at the one end in the above-mentioned direction have protruding portions that protrude in the direction of adjacent unit conductive substrates in the ascending direction of n at the corners. The second to nth unit conductive substrates correspond to the projecting portions of adjacent unit conductive substrates, and are notched portions having a shape in which a gap is formed between the unit conductive substrates. At the corner, and the projecting portion for connection at the projecting portion, and the other separator member is the two of the n unit conductive substrates at the one end in the arranged direction. Nth to nth unit conductive substrates are adjacent to n in descending direction The unit conductive substrate from the first to the (n−1) th corresponds to the projecting portion of the adjacent unit conductive substrate. And a notch portion having a shape in which a gap is formed between the projecting portion and the projecting portion at the corner, and the projecting connecting portion projects from the projecting portion in a direction perpendicular to the arrangement direction. It is characterized by having.
Also, any one of the above-described separators for a planar polymer electrolyte fuel cell, wherein the separator assembly for the planar polymer electrolyte fuel cell is adapted to be caught in each other when used in a planar polymer electrolyte fuel cell. The connecting protrusion of the separator and the connecting protrusion of the oxygen supply separator are located on the boundary extension line of the adjacent unit conductive substrate and are symmetrical with respect to the boundary extension line. It is characterized by a shape.
Also, any one of the above-described separators for a planar polymer electrolyte fuel cell, characterized in that the fuel supply separator and the oxygen supply separator are similarly compatible. To do.

  The planar polymer electrolyte fuel cell according to the present invention is a planar polymer electrolyte fuel cell in which unit cells are planarly arranged. The planar polymer electrolyte according to claim 1, A separator assembly for an electrolyte type fuel cell, wherein the fuel supply separator and the oxygen supply separator have a notch portion of a connecting protrusion protruding from a unit conductive substrate of one separator member, and the other The n unit cells are electrically connected in series so that the notch portions of the connecting protrusions protruding from the unit conductive substrate of the separator member are connected to each other. To do.

The separator assembly for a planar polymer electrolyte fuel cell according to the present invention is used in a planar polymer electrolyte fuel cell in which unit cells are arranged in one direction in a plane by having such a configuration. The separator assembly is a pair of a fuel supply separator and an oxygen supply separator, and can be easily connected to the fuel supply separator and the oxygen supply separator in place of the conventional connecting hinge portion. It is possible to provide a separator assembly including a connecting portion that can be formed easily and without trouble, and that can withstand repeated bending when manufacturing a PEFC. .
This further makes it possible to provide a flat polymer electrolyte fuel cell using such a separator assembly.
Specifically, each of the fuel supply separator and the oxygen supply separator includes a unit conductive substrate having a plurality of through holes for fuel supply or oxygen supply in one direction in a plane through a gap. (N is an integer of 2 or more) arranged separator members, and a pair of insulating frames integrated so as to sandwich the separator members, the pair of insulating frames, Each separator member has a predetermined opening corresponding to the arrangement position of the unit conductive substrates, and one separator member of the fuel supply separator and the oxygen supply separator has n unit conductives. Among the conductive substrates, the first to (n-1) th unit conductive substrate at one end in the arranged direction has a connecting protruding portion protruding in the direction orthogonal to the arranging direction, In addition, the projecting portion for connection includes The separator member has a notch portion for hook connection, and the other separator member is an end of the n unit conductive substrates corresponding to the one side in the arranged direction. The second to nth unit conductive substrates have connection protrusions protruding in the direction orthogonal to the arrangement direction, and the connection protrusions have notch portions for hook connection. And a notch portion of the connecting protrusion of the kth (k = 1 to (n−1)) unit conductive substrate forming the one separator member, and the other separator. The notch portion of the connecting protrusion of the (k + 1) th unit conductive substrate that forms the member is a shape and a position that match each other when they are applied to the planar polymer electrolyte fuel cell. By providing this Forms.
Specifically, the notch portion of the connecting protrusion of the kth (k = 1 to (n−1)) unit conductive substrate forming the one separator member and the (k + 1) th forming the other separator member. When the separator is used in a flat polymer electrolyte fuel cell, the cutout portion of the unit conductive substrate connecting portion is provided in a shape and a position that match each other. Thus, when used in a planar polymer electrolyte fuel cell, adjacent cells can be connected in series in order.
Such a connecting protrusion having a notch portion can be processed together with high precision when producing a unit conductive substrate having a plurality of through holes for fuel supply or oxygen supply. It is advantageous in terms of efficiency and processing accuracy, and can be a connection portion that can be easily connected instead of the conventional hinge portion for connection.
More specifically, one separator member of the fuel supply separator and the oxygen supply separator is the first (n−1) of the one end of the n unit conductive substrates in the arranged direction. ) The unit conductive substrates up to the number n have overhanging portions protruding in the direction of adjacent unit conductive substrates in the ascending direction of n, and the second to nth unit conductive substrates are adjacent to each other. The unit conductive substrate has a cut-out portion corresponding to the projecting portion and formed with a gap formed between the projecting portion and the connecting portion at the projecting portion. The other separator member is the n unit conductive substrates, and the second to nth unit conductive substrates at the one end in the arrangement direction are arranged in descending order of n. Has a protruding part at the corner that protrudes in the direction of the adjacent unit conductive substrate in the direction The first to (n−1) th unit conductive substrates correspond to the projecting portions of adjacent unit conductive substrates and have a shape in which a gap is formed between the unit conductive substrates. The form of invention of Claim 2 which has a notch part in a corner | angular part and has the said protrusion part for a connection in the direction orthogonal to the said arrangement | sequence direction in the said overhang | projection part can be mentioned.
When provided in a planar type polymer electrolyte fuel cell, the connecting protrusion of the fuel supply separator and the connecting protrusion of the oxygen supply separator, which are fitted to each other, are positioned in the arrangement direction. And a separator member for a fuel supply separator according to the third aspect of the present invention, wherein the separator member is on a boundary extension line of adjacent unit conductive substrates and is symmetrical with respect to the boundary extension line. The separator for the oxygen supply separator is processed with the same design and can be used in different directions. Furthermore, the frame of the fuel supply separator and the oxygen supply separator is compatible. The fuel supply separator and the oxygen supply separator are eventually made to be compatible with each other by providing the fuel supply separator and the oxygen supply separator. By, the separator set, the manufacture of each of the separators can be unified into one design, which is advantageous in terms of production.

The planar polymer electrolyte fuel cell of the present invention is a planar polymer electrolyte fuel cell in which unit cells are arranged in one direction in a planar manner by such a configuration. It is possible to provide a flat polymer electrolyte fuel cell that can be connected easily and without taking time and effort in place of the connecting hinge portion.
In some cases, a conductive material such as solder may be further added to lower the contact resistance at the portion connected by the connecting portion.

As described above, the present invention provides a pair of a fuel supply separator and an oxygen supply separator used in a planar polymer electrolyte fuel cell in which unit cells are planarly arranged in one direction. It can be formed into a fuel supply separator and an oxygen supply separator with a connection part that can be easily connected instead of a conventional connection hinge part, and without any effort. In addition, it is possible to provide a separator assembly including a connection portion that can withstand repeated bending during PEFC fabrication.
In particular, it is possible to provide a separator assembly in which each separator member is compatible.
Furthermore, it has become possible to provide a separator assembly in which the fuel supply separator and the oxygen supply separator are compatible.
At the same time, it has become possible to provide a planar polymer electrolyte fuel cell using such a separator assembly.

Embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a first example of an embodiment of a separator assembly for a planar polymer electrolyte fuel cell according to the present invention.
2A is a plan view of the separation member of the oxygen supply separator in the first example shown in FIG. 1, and FIG. 2B is a separation view of the fuel supply separator in the first example shown in FIG. In the plan view of the member,
FIG. 3A is a plan view of a separator member for an oxygen supply separator in the second example of the embodiment of the separator assembly for a planar polymer electrolyte fuel cell according to the present invention, and FIG. FIG. 4A is a plan view of a separator member of a fuel supply separator in the second example, and FIGS. 4A to 4B are diagrams showing a manufacturing process of a planar polymer electrolyte fuel cell of the present invention. FIG. 4C is a diagram showing the state of the F0 portion in FIG.
1 to 3 indicate the direction of arrangement, and the first to third indicate the order of the arrangement direction.
2A and 2B indicate the connection areas of the corresponding connection protrusions 128 and 138. In FIG.
1-4, 110 is a separator assembly, 120 is a fuel supply separator, 121 is a separator member (of the fuel supply separator), 121A is a current collector, 121B is a through hole, and 121a to 121f are unit conductivity. Substrate 122, 123 is a frame (also called an insulating frame), 123a is an opening, 124 is a gap, 125 is an overhang, 126 is a notch, 127 is a terminal electrode, and 128 and 128a are projections for connection. 129, 129a are notched portions, 130 is an oxygen supply separator, 131 is a separator member (of the oxygen supply separator), 131A is a current collector, 131B is a through hole, 131a to 131f are unit conductive substrates, 132 and 133 are frames (also referred to as insulating frames), 132a is an opening, 134 is a gap, 135 is an overhang, 136 is a notch, and 137 is an end. Electrodes, 138,138A protruding portions for connection, 139,139A a portion cut away, the 140 is a membrane electrode assembly (MEA).

First, a first example of an embodiment of a separator assembly for a planar polymer electrolyte fuel cell according to the present invention will be described with reference to FIG.
The separator assembly 110 for a planar polymer electrolyte fuel cell of the first example is a fuel supply separator 120 used for a planar polymer electrolyte fuel cell in which unit cells are arranged in one direction in a plane. And an oxygen supply separator 130 as a pair.
The fuel supply separator 120 includes a separator member 121 (see FIG. 2) in which three unit conductive substrates having a plurality of through holes for fuel supply are arranged in one direction in a plane via a gap, and the separator And a pair of insulating frames 122 and 124 integrated so as to sandwich the member 121, and the pair of insulating frames correspond to the arrangement positions of the unit conductive substrates of the separator member 121, respectively. The predetermined opening is provided.
The oxygen supply separator 130 includes a separator member 131 (see FIG. 2) in which three unit conductive substrates having a plurality of through holes for supplying oxygen are arranged in one direction in a plane via a gap, and the separator A pair of insulating frames 132 and 134 that are integrated so as to sandwich the member 131, and the pair of insulating frames correspond to the arrangement positions of the unit conductive substrates of the separator member 131, respectively. The predetermined opening is provided.

In this example, as shown in FIG. 2B, the separator member 121 of the fuel supply separator 120 is a unit conductive substrate 121a to 121c having a plurality of through holes 121B for fuel supply. The three conductive substrates 121a to 121c are arranged in one plane in a plane through the gap portion 124, and the first of the one end in the arranged direction among the three unit conductive substrates 121a to 121c. The second unit conductive substrates 121a and 121b have connection protrusions 128 protruding in the direction orthogonal to the arrangement direction, and each connection protrusion 128 has a hook connection. It has a cutout portion 129.
On the other hand, as shown in FIG. 2 (a), the separator member 131 of the oxygen supply separator 130 includes a plurality of through holes 131B for supplying oxygen as unit conductive substrates 131a to 131c. Three conductive substrates 131a to 131c are arranged in one direction in a plane via a gap 134, and correspond to the one side in the arranged direction among the three unit conductive substrates 131a to 131c. The second and third unit conductive substrates 131b and 131c at the end of the connecting side have connection protrusions 138 protruding in the direction orthogonal to the arrangement direction, and each connection protrusion 138 includes Has a notch 139 for hook connection.
In this example, as shown in FIG. 2, joining regions including the cutout portions 129 and 139 of the connecting protrusions 128 and 138 connected to each other (dotted squares in FIGS. 2A and 2B). The region in the arrangement direction is on the boundary extension line with the adjacent unit conductive substrate and is symmetrical to the boundary extension line, and the separator member 121 of the fuel supply separator 120 And the separator member 131 of the oxygen supply separator 130 are processed with the same design as each other. Therefore, the separator member 121 and the separator member 131 are interchangeable when used in different directions.
In this example, since the frame body 122 and the frame body 132 and the frame body 123 and the frame body 133 are formed so as to have the same design when the directions are changed, the fuel supply separator 120 and the oxygen supply separator 130 are interchangeable by using different directions.

The insulating frame 123 in the fuel supply separator 120 is on the membrane electrode assembly (MEA) side when used in a polymer electrolyte fuel cell, and the entire unit cell region is opened. On the other hand, the insulating frame 122 in the fuel supply separator 120 is on the side opposite to the membrane electrode assembly (MEA) side when used in a polymer electrolyte fuel cell. A plurality of through holes (not shown) are provided so as to open through holes (121B in FIG. 2) for allowing the fuel of the unit conductive substrate to pass therethrough.
The oxygen supply separator 130 is also basically the same as the fuel supply separator 120, and is an insulating frame 133 that becomes the membrane electrode assembly (MEA) side when used in a polymer electrolyte fuel cell. In contrast to the fact that the entire unit cell region is open, the insulating frame 132 that is the side opposite to the membrane electrode assembly (MEA) side when used in a polymer electrolyte fuel cell has its unit In the cell region, a plurality of through-hole portions 132a are provided so as to open through-holes (131B in FIG. 2) through which oxygen of the unit conductive substrate passes.

Also, in this example, one of the separator member 121 of the fuel supply separator 120 and the separator member 131 of the oxygen supply separator is one of the first and second ends of one of the unit conductive substrates in the arrangement direction. Each of the second unit conductive substrates 121a and 121b has a protruding portion 125 at the corner extending in the direction of the adjacent unit conductive substrates 121b and 121c in the ascending order, and from the second to the nth. The unit conductive substrates 121b and 121c up to this point correspond to the projecting portion 125 of the adjacent unit conductive substrate, and the notch portion has a shape in which the gap portion 124 is formed between the unit conductive substrates 121b and 121c. 126 is provided at the corner, and the projecting portion 128 is provided on the overhanging portion 125 here.
The other of the separator member 121 of the fuel supply separator 120 and the separator member 131 of the oxygen supply separator 130 is the second and third units of the one end in the arrangement direction of the unit conductive substrates. Each of the conductive substrates 131b and 131c has a protruding portion 135 that protrudes in the direction of the adjacent unit conductive substrates 131a and 131b in the descending direction at the corner, and the first and second unit conductive properties. Each of the substrates 131a and 131b has a notch portion 139 having a shape corresponding to the protruding portion 138 of the adjacent unit conductive substrate and having a gap portion 134 formed between the protruding portions 135. It has in the corner part, and has the protrusion part 138 for a connection in the overhang | projection part 135 here.
In this way, the notch portions 129 of the connecting protrusions 128 of the first and second unit conductive substrates 121a and 121b forming the separator member 121 of the fuel supply separator 120, and the oxygen supply separator 130 When the notched portion 139 of the connecting protrusion 138 of the second and third unit conductive substrates 131b and 131c forming the separator member 131 is used in a flat polymer electrolyte fuel cell. , Provided in a shape and position that match the hooked state.
When the separator assembly of this example is used in a planar polymer electrolyte fuel cell, the notch portion 129 of the connecting protrusion 128 and the notch portion 139 of the connecting protrusion 138 are caught with each other. Used according to the state.

Next, each part of the separator member 121 of the fuel supply separator 120 and the separator member 131 of the oxygen supply separator 130 will be briefly described.
The unit conductive substrates 121a to 121c and 131a to 131c may include a protective layer made of a corrosion-resistant (acid-resistant) and electrically conductive resin layer at least on the surface portion on the electrolyte side of the fuel cell.
As a method for forming such a protective layer, a method of forming a film by electrodeposition using a material in which a conductive material such as carbon particles and corrosion-resistant metal is mixed in a resin and then heat-curing, or a conductive polymer is used. The method of forming the film | membrane of the state which contained the dopant which improves electroconductivity in the resin to be formed by electrolytic polymerization etc. is mentioned.
Further, the surface of the unit conductive substrates 121a to 121c and 131a to 131c may be subjected to a plating treatment such as gold plating to provide a corrosion-resistant metal layer without impairing the conductivity.
Furthermore, a protective layer having acid resistance and electrical conductivity may be disposed on such a corrosion-resistant metal layer.
Each of the unit conductive substrates 121a to 121c and 131a to 131c is processed into a predetermined shape by machining or etching using photolithography technology.
The overhang portions 125 and 135, the cutout portions 126 and 136, the connecting protrusions 128 and 138, the cutout portions 129 and 139, the fuel supply through-hole 121B, and the oxygen supply through-hole 131B are formed by these methods. It is a thing.

As the material of the insulating frames 122, 123, 132, and 133 constituting the fuel supply separator 120 and the oxygen supply separator 130, it is preferable to use an insulating material that has good workability, is light, and has high mechanical strength.
As such a material, a substrate material for a printed wiring board is used, and examples thereof include glass epoxy and polyimide.
The insulating frame having a desired shape can be formed by machining, laser processing, or the like.
The fuel supply side separator 120 and the oxygen supply side separator 130 may be manufactured by fixing the separator members 120a and 130a, which are individually manufactured, and the corresponding insulating frames while aligning them. .
The fixing of each member includes, for example, a method in which an adhesive such as an epoxy resin is applied and the adhesive is cured and fixed in a state where the members are overlapped.
The adhesive used in this case is not particularly limited as long as it does not affect other members in the manufacturing process and has excellent resistance to operating conditions when used in a fuel cell. .
Further, there is a method in which a part or all of the insulating frame is formed of a semi-cured prepreg, and is crimped to the separator members 121 and 131 to be fixed.

Next, a second example of an embodiment of a separator assembly for a planar polymer electrolyte fuel cell according to the present invention will be described.
The second example is the same as the first example, except that the separator member 131 shown in FIG. 2A and the separator member 121 shown in FIG. The separator is replaced with the separator member shown in FIG. 3B, and the rest is the same as the first example.
Also in the case of the second example, the separator member 121 of the fuel supply separator has unit conductive substrates 121d to 121f as the conductive substrates having a plurality of through holes 121B for fuel supply, which are unit conductive substrates 121d to 121f. Three 121f are arranged in one direction in a plane via the gap 124, and the first and second end of one side of the arranged direction among the three unit conductive substrates 121d to 121f. Each of the unit conductive substrates 121d and 121e has a connection protrusion 128a protruding in a direction orthogonal to the arrangement direction thereof, and each connection protrusion 128a has a notch portion 129a for hook connection. The separator member 131 of the oxygen supply separator is a conductive substrate having a plurality of through holes 131A for supplying oxygen, which is a unit conductive substrate 131d to 131. The three unit conductive substrates 131d to 131f are arranged in one plane in a plane via the gap 134, and the unit conductive substrates 131d to 131f are arranged in the arranged direction. The second and third unit conductive substrates 131e and 131f at the ends corresponding to one side have connection protrusions 138a protruding in the direction orthogonal to the arrangement direction, and each connection The protruding portion 138a has a notch portion 139a for hook connection.
The shapes of the unit conductive substrates 121d to 121f and 131d to 131f of the separator members 121 and 131 in the second example and the shapes of the connecting protrusions 128b and 138b are different from those in the first example.
In addition, the unit conductive substrates 121d to 121f and 131d to 131f in the second example have a shape that does not have the overhang portions 125 and 135 and the notch portions 126 and 136 in the first example.
The connection protrusions of the first and second unit conductive substrates 121d and 121e forming the fuel supply separator member 121 in a shape as shown in FIG. 2 by devising the shape of the connection protrusions 128a and 138a. The notch part 129a of the part and the notch part 139a of the projecting part for connection of the second and third unit conductive substrates 131e and 131f forming the oxygen supply separator member 131 are a planar polymer electrolyte. When it is used in a fuel cell, it is provided in a shape and a position that match each other.
For this reason, when it is used in a planar polymer electrolyte fuel cell, the shape is adapted to the state in which the notch portion 129a of the connecting protrusion 128a and the notch portion 139a of the connecting protrusion 138a are caught with each other. , The adjacent cells can be connected in series in order.
Also in the case of the second example, as shown in FIG. 3, the joining regions (not shown) including the notch portions 129a and 139a of the connecting protrusions 128a and 138a connected to each other are positioned in the arrangement direction. It is on the boundary extension line with the adjacent unit conductive substrate and is symmetric with respect to the boundary extension line. Similar to the first example, the separator member for the fuel supply separator and the oxygen supply member The separator member is compatible when used in a different direction, and the fuel supply separator and the oxygen supply separator are compatible when used in different directions.
The material of each part and the manufacturing method are the same as in the first example, and the description thereof is omitted here.

The fuel supply side separator 120 and the oxygen supply side separator 130 in the separator assembly 110 for the planar polymer electrolyte fuel cell of the first example are as shown in FIGS. 4 (a) to 4 (b). The flat polymer electrolyte fuel cell can be manufactured to provide a flat polymer electrolyte fuel cell as shown in FIG.
The fuel supply-side separator 120 and the oxygen supply-side separator 130 are arranged with a membrane electrode assembly (MEA) 140 between them, so that the notch portions of the corresponding connecting protrusions are fitted to each other. Thus, the gap is narrowed to form a stack.
As shown in FIG. 4C, the connecting protrusions 128 and 138 overlap and are electrically connected to each other at notch portions (129 and 139 in FIG. 2).
As described above, in some cases, a conductive material such as solder may be further added in order to lower the contact resistance at the portion connected by this connecting portion.
As described above, the membrane electrode assembly (MEA) 140 is a composite such as a current collector layer, a fuel electrode, a polymer electrolyte, an oxygen electrode, and a membrane in which a current collector layer is laminated. For example, as shown in FIG. 5, the fuel electrode side catalyst layer 43 and the oxygen electrode side catalyst layer 44 are arranged on the membrane of the polymer electrolyte 41.
From the notch part of the connecting protrusion protruding from one unit conductive substrate of the separator member 121 of the fuel supply separator 120 and the separator member 131 of the oxygen supply separator 130 and from the other unit conductive substrate The three unit cells are electrically connected in series so that the notch portions of the protruding connection protrusions are in a state of being caught with each other.

Each of the above forms is an example, and the present invention is not limited to these.
For example, the thickness of the connecting protrusions 125 and 136 may be made thinner than the other parts so as to be easily bent.
In the etching process, it is easy to make only the connection protrusions 125 and 136 thinner than others.
Further, the shape of the connecting protrusions 125 and 136 is not limited to the shape shown in FIG.
Of course, the form in the case where the arrangement of unit cells is four or more is also included.
Further, in the separator assembly for the planar polymer electrolyte fuel cell of the first example and the second example, the separator member for the fuel supply separator and the separator member for the oxygen supply separator face each other. The fuel supply separator and the oxygen supply separator are interchangeable and used interchangeably. However, these incompatible structures are also included.

1 shows a first example of an embodiment of a separator assembly for a planar polymer electrolyte fuel cell according to the present invention. 2A is a plan view of the separation member of the oxygen supply separator in the first example shown in FIG. 1, and FIG. 2B is a separation view of the fuel supply separator in the first example shown in FIG. It is a top view of a member. FIG. 3A is a plan view of a separator member for an oxygen supply separator in the second example of the embodiment of the separator assembly for a planar polymer electrolyte fuel cell according to the present invention, and FIG. These are the top views of the member for separators of the fuel supply separator in a 2nd example. 4 (a) to 4 (b) are diagrams showing the fabrication process of the planar polymer electrolyte fuel cell of the present invention, and FIG. 4 (c) is the state of the F0 part in FIG. 4 (b). FIG. 1 is a cross-sectional view of an example of a planar PEFC (Polymer Electrolyte Fuel Cell). It is the figure which showed the state which spaced apart each member of planar type PEFC shown by FIG. It is a perspective view of the separator by the side of a fuel supply. It is the perspective view which showed each part of FIG. 7 spaced apart.

Explanation of symbols

110 Separator assembly 120 Fuel supply separator 121 Separator member 121A (for fuel supply separator) Current collecting part 121B Through holes 121a to 121f Unit conductive substrates 122, 123 Frame (also referred to as insulating frame)
124 gap portion 125 overhang portion 126 notch portion 127 terminal electrode 128, 128a connecting projection portion 129, 129a notch portion 130 oxygen supply separator 131 (for oxygen supply separator) separator member 131A current collector portion 131B through hole 131a to 131f Unit conductive substrates 132, 133 Frame (also referred to as insulating frame)
132a Opening 134 Cavity part 135 Overhang part 136 Notch part 137 Terminal electrode 138, 138a Protruding part 139, 139a Notch part 140 Membrane electrode assembly (MEA)
10 PEFC (Polymer electrolyte fuel cell)
10A Battery body 10A
20 Fuel Supply Side Separator 21 Conductive Substrates 21a-21c Unit Conductive Substrate 21A Current Collector 22, 23 Frame (also referred to as insulating frame)
22a Through-hole 23a Opening 24 Cavity 27 Electrode terminal 30 Oxygen supply side separator 31 Conductive substrates 31a to 31c Unit conductive substrate 31A Current collectors 32 and 33 Frame (also referred to as insulating frame)
32a Through-hole 33a Opening 34 Gap 37 Electrode terminal 40 Membrane electrode assembly (MEA)
41 Solid polymer membrane (also called polymer electrolyte)
43 Fuel electrode side catalyst layer 44 Oxygen electrode side catalyst layer 51, 52 Carbon paper 60 Case body 61 Fuel tank 62 Fuel supply port 70 Seal members 81, 82, 83 Unit cell 90 Fixing bolt

Claims (5)

  For a planar polymer electrolyte fuel cell, which is a pair of a fuel supply separator and an oxygen supply separator used in a planar polymer electrolyte fuel cell in which unit cells are arranged in one direction in a plane. The separator for supplying fuel and the separator for supplying oxygen are each configured such that a unit conductive substrate having a plurality of through holes for supplying fuel or supplying oxygen is planarly arranged through a gap. N separators (n is an integer of 2 or more) arranged in the direction, and a pair of insulating frames integrated so as to sandwich the separator members, the pair of insulating frames , Each having a predetermined opening corresponding to the arrangement position of the unit conductive substrate of each separator member, one separator member of the fuel supply separator, oxygen supply separator, Among the n unit conductive substrates, the first to (n-1) th unit conductive substrates at one end in the arranged direction are connected to the direction protruding perpendicular to the arrangement direction. The connecting protrusion has a notch portion for hook connection, and the other separator member is one of the n unit conductive substrates. The second to nth unit conductive substrates at the ends corresponding to the one side in the arranged direction have a connecting protrusion protruding in the direction perpendicular to the arranging direction, and The projecting portion for connection has a notch portion for hook connection, and further, the kth (k = 1 to (n−1)) unit conductive substrate forming the one separator member. Forming a notch portion of the connecting protrusion and the other separator member. The notch portion of the connecting protrusion of the + 1st unit conductive substrate is provided in a shape and a position that match each other when they are used in the planar polymer electrolyte fuel cell. A separator assembly for a planar polymer electrolyte fuel cell characterized by   The separator assembly for a planar polymer electrolyte fuel cell according to claim 1, wherein one of the fuel supply separator and the oxygen supply separator is a member of n unit conductive substrates. The first to (n−1) th unit conductive substrates at the one end in the arranged direction have corners with protruding portions protruding in the direction of adjacent unit conductive substrates in the ascending order of n. The second to nth unit conductive substrates corresponding to the protruding portions of adjacent unit conductive substrates and having a shape in which a gap is formed between the protruding portions. It has a cut-out portion at a corner, the protruding portion for connection is provided at the projecting portion, and the other separator member is the one end of the n unit conductive substrates in the arranged direction. The second to nth unit conductive substrates are adjacent to n in the descending direction. The unit conductive substrate from the first to the (n-1) th unit corresponds to the projecting portion of the adjacent unit conductive substrate. And a notch portion having a shape in which a gap is formed between the projecting portion and the projecting portion at the corner, and the projecting connecting portion projects from the projecting portion in a direction perpendicular to the arrangement direction. A separator assembly for a planar polymer electrolyte fuel cell, characterized by comprising:   The separator assembly for a planar polymer electrolyte fuel cell according to any one of claims 1 to 2, wherein when the separator assembly is used in a planar polymer electrolyte fuel cell, the separator assembly is in a state of being caught with each other. The connecting protrusion of the fuel supply separator and the connecting protrusion of the oxygen supply separator are located on the boundary extension line of the adjacent unit conductive substrate at a position in the arrangement direction, and the boundary extension line A separator assembly for a planar polymer electrolyte fuel cell, characterized in that the shape is symmetrical with respect to the surface.   A separator assembly for a planar polymer electrolyte fuel cell according to any one of claims 1 to 3, wherein the fuel supply separator and the oxygen supply separator are made compatible with each other. A separator assembly for a planar polymer electrolyte fuel cell, characterized in that A planar polymer electrolyte fuel cell in which unit cells are planarly arranged, wherein the separator assembly for a planar polymer electrolyte fuel cell according to claim 1 is used, The notch part of the connection protrusion protruding from the unit conductive substrate of one separator member of the fuel supply separator and the oxygen supply separator and the connection protruding from the unit conductive substrate of the other separator member A planar type polymer electrolyte fuel cell characterized in that n unit cells are electrically connected in series so that the notch portions of the protrusions are hooked to each other.

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