KR20160082629A - Stack assembly for air-electrode battery - Google Patents

Abstract

The purpose of the present invention is to provide a stack assembly for a metal air battery, in which an anode current collection means is made of metal having a panel type, and thus, an assembly operation is simplified and manufacturing costs are reduced by omitting a configuration unit for supplying the metal. According to the present invention, the stack assembly for a metal air battery comprises: a unit cell structure which includes a cell block which has a block shape having a certain area and a certain width and having an opened central portion, a pair of cathode current collection panels which are respectively provided on the front portion and the rear portion of the cell block and cover and seal the opened central portion of the cell block, and an anode current collection panel is inserted into the opened central portion from a side surface of the cell block and is located to face the pair of the cathode current collection panels, and allows a current collection to be performed at a cathode and an anode from the cathode current collection panels and the anode current collection panel by causing a chemical reaction between metal, oxygen, and water at the time of introducing oxygen in the air and water from the outside of the cell block into spaces where the cathode current collection panels and the anode current collection panel face each other; and cover frames which form an appearance of the stack assembly while respectively covering the pair of the cathode current collection panels on a front portion and a rear portion of the cell block.

Description

[0001] Stack assembly for air-battery [0002]

[0001] The present invention relates to a stack assembly for a metal-air battery, and more particularly to a stack assembly for a metal-air battery, in which unit cells constituting a stack of a metal- A cathode current collecting panel and a pair of anode current collecting panels can be easily assembled to improve the assembling efficiency and facilitate the large-capacity and large-sizing work of a plurality of cell blocks through stacking in the stack .

In recent years, electric vehicles, motorbikes, electric buses, etc., which do not generate soot in accordance with environmental policy and green energy policy to preserve nature have become hot topic. Thus, hydrogen fuel cells that use high concentration of hydrogen as fuel, which does not emit pollutants at all, are most popular as next generation energy resources. However, due to the inflow of impurities such as carbon monoxide, it is difficult to use other fuel A metal air battery is being developed.

Such a metal-air battery eliminates the risk of poisoning carbon monoxide through the metal used as fuel and can replace hydrogen. The most common fuel is zinc or aluminum metal, and oxygen in the air is used as the positive electrode active material. And zinc or aluminum is used as the negative electrode active material.

That is, the stack assembly for a metal-air battery includes a plurality of cell blocks in which a metal is stored, as disclosed in Patent Documents 10-1007554, 2001-0101692, and 10-2012-0024094, And a frame block in which the cell block is supported.

Here, each of the cell blocks may be spaced apart from each other to allow air to flow between adjacent cell blocks, and air introduced between the cell blocks may react with the metal stored in the cell block, So that electricity is generated.

In other words, in the conventional stack for a metal air battery, a current collecting bag is formed inside the cell block, a ball type or pellet type metal is accommodated together with the electrolyte in the current collecting bag, So that electricity generated by the reaction of oxygen in the fuel cell stack is collected through the current collecting bag.

However, in the conventional metal-air battery stack, when the ball or pellet-type metal supplied to the current collecting bag of the cell block is oxidized during the reaction with air, Should be.

In order to solve the above problems, metal can be periodically supplied to the current collecting bag. However, since the sensing means for sensing the amount of metal and the supplying means are configured in the cell block, There is a problem that it is difficult to control the operation such that overcharging occurs when the metal is overcharged.

Also, in the case of the stack for a metal air battery, a negative electrode current collecting electrode and a positive electrode current collecting electrode are formed in a housing of a cell block having a current collecting bag, and the unit cell is manufactured.

In order for the unit cells to be large-sized, large-sized, and expanded, a plurality of cell blocks are successively arranged in a stack structure, and then a pipe for a flow path for circulating the electrolyte and air for each cell block and a pumping means connected thereto are connected There is a problem that the operation is very complicated and the manufacturing cost is increased.

Meanwhile, in the case of the stack for a metal air battery, it is very important that the air introduced into the cell block is sufficiently evenly contacted with the ball or pellet type metal. As described above, when the ball or pellet- There is a problem that the oxidation efficiency of the metal is lowered and the efficiency of the current collecting reaction is lowered.

Accordingly, it is an object of the present invention to provide a unit cell constituting a stack of a metal-air battery using a metal such as a water cell or the like, wherein the unit cell structure includes one negative electrode collecting panel and a pair of positive electrode collecting panels The present invention provides a stack assembly for a metal-air battery, which can be assembled easily, thereby improving assembling efficiency and facilitating a large-capacity and large-scale operation through stacking of a plurality of cell blocks in a stack.

Another object of the present invention is to provide a stack assembly for a metal-air battery in which cathode current collecting means is constituted by a panel-type metal, thereby omitting a constituent part for supplying the metal, thereby simplifying the assembling work and reducing the manufacturing cost will be.

It is another object of the present invention to provide a metal air battery which can improve the efficiency of the current collection reaction by allowing oxygen in the air to diffuse over the entire surface of the anode current collector metal, For example.

Meanwhile, the object of the present invention is not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to the present invention, there is provided a cell block comprising: a cell block having a block shape having a predetermined area and width and an open central portion; A pair of positive electrode current collecting panels each formed at a front portion and a back portion of the cell block to cover and seal the opening portion of the cell block; And a negative electrode current collecting panel inserted into the opening portion from the side surface of the cell block and positioned in a state facing the pair of positive electrode current collecting panels, and the negative current collecting panel facing the positive current collecting panel and the negative current collecting panel, A unit cell structure configured to collect electrons from the anode current collecting panel and the cathode current collecting panel by causing a chemical reaction between metal, oxygen and water when oxygen and water in the air flow into the space; There is provided a stack assembly for a metal-air battery including a cover frame that forms an outer appearance of a stack assembly while covering the pair of positive electrode current collecting panels at the front and rear portions of the cell block, respectively.

Here, it is preferable that a plurality of unit cell structures are stacked in series on the inner side of the cover frame.

Also, the cell block may be a block-shaped body having a predetermined area and width and opening at a central portion thereof; A positive electrode current collecting panel seating part formed on the front and back sides of the body so as to cover the opening part of the body so that a pair of positive current collecting panels are respectively seated thereon; A negative current collecting panel inserting part for inserting the negative current collecting panel from the side part of the body while covering the opening part so that each one face part faces the pair of positive current collecting panels; And a pair of anode current collecting panels facing each other. The anode current collecting panel and the pair of anode current collecting panels are disposed in the upper and lower ends of the body, respectively, A reactant inlet and outlet for causing water to flow in and out, allowing the water in the anode current collector panel to be oxidized by oxygen in the air filtered by the water and the cathode collector panel; And an enlarged fastening part which is positioned at an edge part of the body and penetrates from the front part toward the back part to fasten the plurality of cell blocks in a stacked structure through serial lamination.

In addition, the anode current collecting panel has an area corresponding to the opening of the cell block and has an edge bonded to the anode current collecting panel mounting groove, so that only oxygen in the air introduced from outside flows into the reaction space with the cathode current collecting panel, A catalytic part for providing a catalytic function for oxidizing the metal of the cathode current collector panel by the oxygen in the reaction space; A reinforcing panel portion for increasing the overall rigidity of the catalytic portion so that the catalyst portion is bolted to the anode current collecting panel mounting groove from the upper edge of the catalytic portion or bonded to the upper surface of the catalytic portion so that the catalyst portion is fixed to the anode current collecting panel mounting groove .

The cathode current collecting panel may have a surface area corresponding to the opening of the cell block and spaced apart from the catalyst part of the cathode current collecting panel so that a predetermined reaction space is formed, And a metal-fuel portion that provides a fuel function through the exhaust port.

Therefore, according to the present invention, a pair of anode current collecting panels having a panel shape are adhered to the front surface of a single cell block having a central opening and a panel shape for forming a predetermined reaction space facing each cathode current collecting panel therebetween So that the assembling efficiency of the unit cell structure can be improved.

In addition, after a positive electrode collector plate and a negative electrode collector plate are formed as a single unit cell structure in a single cell block, a plurality of unit cell structures having the above-described structure are stacked in series to form a stack structure, .

On the other hand, the effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view illustrating a unit cell structure of a stack for a metal-air battery according to a preferred embodiment of the present invention;
FIG. 2 is an exploded perspective view of the unit cell structure of FIG. 1; FIG.
FIGS. 3 and 4 are perspective views showing front and rear surfaces of the cell block in the unit cell structure of FIG. 1, respectively; FIG. And
FIG. 5 illustrates a stack assembly in which a plurality of unit cell structures of FIG. 1 are stacked in series. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating a unit cell structure of a stack for a metal air battery according to a preferred embodiment of the present invention, and FIG. 2 is an exploded perspective view illustrating the unit cell structure of FIG. 3 and 4 are perspective views showing the front and back surfaces of the cell block in the unit cell structure of FIG. 1, respectively, and FIG. 5 is a view illustrating a stack assembly in which a plurality of unit cell structures of FIG. 1 are stacked in series.

1 to 5, a stack assembly SS for a metal-air battery according to a preferred embodiment of the present invention includes a cell block 100 having a block shape having a predetermined area and width, A pair of anode current collecting panels 200 which are respectively formed on the front and back surfaces of the cell block 100 to cover and close the opening portions of the cell block 100 and a pair of anode current collecting panels 200, And a cathode current collecting panel 300 inserted into the anode current collecting panel 200 and positioned facing the pair of cathode current collecting panels 200. The anode current collecting panel 200 and the cathode current collecting panel 200 are disposed outside the cell block 100, Oxygen and water H are introduced into the confronting spaces between the anode current collecting panel 200 and the cathode current collecting panel 300 so that the chemical reaction between the oxygen, 300) for collecting the positive and negative electrodes Include (S) and the cover frame 400 while the front and rear portions of the cell block 100, each covering the positive electrode current collector panels 200 of the pair forming the exterior of the stack assembly.

That is, the stack assembly SS for a metal-air battery according to the present invention includes a cell block 100 having the positive electrode collector panel 200 and the negative collector collector 300 formed on the inside of the cover frame 400, Sized and enlarged through a stack structure in which a plurality of unit cell structures S having the above-described structure are stacked in series after the cell structure S is formed.

The cell block 100 is a housing unit of the unit cell structure S and includes a block body 110 having a central opening with a predetermined area and width, A positive electrode current collecting panel mounting part 120 which is formed with a groove and in which a pair of anode current collecting panels 200 described below are respectively seated to cover an opening of the body 110, A cathode current collecting panel inserting unit 130 for inserting the anode current collecting panel 300 into the anode current collecting panel 200 while covering the opening part so as to face the anode current collecting panel 200, The anode current collecting panel 300 and the pair of anode current collecting panels 200 facing each other are formed so as to penetrate toward the front portion and the rear portion in a state of being positioned at the upper end and the lower end or the left end and the right end, Water (H) flows into the space from the outside and And a reactant inlet and outlet 140 for allowing the metal of the anode current collector panel 300 to be oxidized by the oxygen in the air A filtered by the water H and the cathode current collector panel 200, A plurality of cell blocks 100 are connected to each other by bolting means, and the plurality of cell blocks 100 are stacked through a plurality of serial stacks, An enlarged fastening part 150 for allowing a large capacity, a large size, and an enlarged size.

Here, the cell block 100 is preferably formed of a synthetic resin material having excellent heat resistance, oil resistance, chemical resistance, and predetermined rigidity.

The body 110 has a block shape in which an opening 111 is formed at a central portion with a predetermined area and width and a durability of the body 110 is improved at a side portion of the body 110. In addition, A seating protrusion 112 may be further formed to allow the seat assembly 120 to be easily seated in the installation position when assembled into the seat assembly SS.

The ratio of the cross-sectional area of the opening 111 (as viewed from the front) relative to the entire cross-sectional area of the body 110 (as viewed from the front) is set at 1: 0.6 to 1: 0.7. If the cross-sectional area of the opening 111 is greater than 0.7, the contact area between the air A and the cathode collector panel 200 increases while the overall stiffness of the body 110 decreases. On the other hand, It is most preferable that the contact area of the anode current collector A and the anode current collecting panel 200 is reduced while the overall rigidity of the body 110 is improved.

The anode current collecting panel mounting portion 120 is formed in the front and back portions of the body 110 so that the pair of cathode current collecting panels 200 are respectively seated to form the opening 111, The panel holding groove 121 and the anode current collecting panel receiving groove 121 are formed at predetermined intervals so that the anode current collecting panel 200 is placed in the anode current collecting panel receiving groove 121, And a plurality of partition walls 122 and guide grooves 123 for preventing a reactant containing water (H) and oxygen from leaking.

Here, the partition 122 and the guide groove 123 may improve the durability by increasing the contact or bonding area through the concavo-convex structure in the structure of the cathode current collector panel 200, and more preferably, Even if leakage occurs due to poor contact between the upper surface of the partition wall 122, which is an adhesion portion of the catalyst portion 210 described later, of the nickel catalyst mesh 212 and the lower surface of the nickel catalyst mesh 212, And the guide groove 123 can be made high, thereby providing the function of the O-ring member.

The anode current collecting panel mounting portion 120 may be formed in the anode current collecting panel mounting groove 121 so that the catalyst portion 210 of the cathode current collecting panel 200, An electrode exposing groove 124 which is connected to the positive electrode collector 230 to allow the positive electrode collector 230 to be exposed to the outside of the cell block 100 without interfering with the recess structure, It is preferable to extend from a section of the anode current collector panel mounting groove 121.

The anode current collector panel insertion portion 130 includes an insertion port 131 formed in a side surface portion of the body 110 and a guide groove 132 formed in an inner circumferential surface of the opening portion of the body 110, The negative electrode current collecting panel 300 described later through the guide grooves 131 and the guide grooves 132 covers the opening of the body 110 and is inserted into a pair of the positive current collecting panels 200, A reaction space is formed.

The reactant inlet 140 may include a reactant inlet 141 formed at the upper end and the lower end or at the left end and the right end of the body 110 so as to be pierced toward the front portion and the rear portion, And a reactant outlet hole 142 and a reactant inlet hole 143 and a reactant outlet hole 144 formed in the guide groove 132 formed in the inner circumferential surface of the opening portion of the body 110, The water H is introduced into and discharged from the outside into the reaction space of each of the one surface portion of the anode current collecting panel 300 and the pair of anode current collecting panels 200 faced thereto, So that the metal of the cathode current collecting panel 300 is oxidized and reacted with oxygen in the air A to be introduced. The water H in the reaction space and oxygen in the air A flow out of the reaction space through the reactant outflow hole 144 and the reactant outflow port 142.

When the plurality of cell blocks 100 are stacked in a stacked structure, the reactant inlet 141 and the reactant outlet 142 of the adjacent cell block 100 and the reactant outlet 142, respectively, So that the air A is circulated in each of the plurality of cell blocks 100, as is the case with the prior art, through which the air is circulated So that the construction of the stack assembly SS can be simplified.

The expansion joint part 150 includes a plurality of fastening holes 151 that are positioned at edge portions of the body 110 and pass through from the front part toward the back part, So that a stack structure can be formed through a plurality of serial stacks, thereby enabling a large-capacity, large-sized, and expanded system.

Therefore, according to the cell block 100, the anode current collecting panel 200 having a single body 110 and the anode current collecting panel 300 having one surface facing each of the anode current collecting panel 200 have a simple structure The metal oxide can be oxidized in the reaction space where the cathode current collecting panel 200 and the cathode current collecting panel 300 face each other.

In addition, since the plurality of cell blocks 100 having the above-described structure are fastened and coupled by bolting means to each other, the unit cell structures S are easily stacked and large-capacity or large-sized And can be expanded.

The anode current collecting panel 200 is respectively formed in the anode current collecting panel mounting grooves 121 of the anode current collector panel mounting portion 120 of the cell block 100 to cover and seal the opening portions of the cell block 100 A positive electrode collector means for collecting the positive electrode during a catalytic reaction by allowing air (A) from the outside to flow into the reaction space, the positive collector collector having an area corresponding to the opening (111) of the cell block (100) 121 of the anode current collecting panel 300 so that only oxygen in the air A introduced from the outside flows into the reaction space with the cathode current collecting panel 300, A catalytic part 210 for providing a catalytic function to allow the metal of the catalytic part 210 to be oxidized and reacted with the catalytic part 210, It is bonded to the configuration And a reinforcement panel 220 for increasing the overall rigidity of the catalytic part 210 so that the catalyst part 210 is fixed to the anode current collector panel mounting groove 121.

Here, the catalytic unit 210 allows only the oxygen component in the external air A to flow into the reaction space with the anode current collecting panel 300, so that oxygen and water H in the reaction space, A carbon catalyst plate 211 made of a carbon material exposed to the outside and a nickel catalyst mesh 212 configured to face the reaction space are provided as means for providing a catalytic function so that the metal of the metal catalyst 300 is oxidized and reacted, , And have mutually attached states.

The carbon catalyst plate 211 preferably has a fluorine-coated state, and through which the contaminants in the air A are filtered, oxygen is supplied to the reaction space with the cathode current collector frame 300 Diffusion of the catalyst.

The nickel catalyst mesh 212 provides a catalytic function of generating oxygen upon contact with water (H) introduced into the reaction space, and at the same time, (230) are connected to provide a current collecting function.

The negative electrode current collecting panel 300 is formed by inserting a guide groove 132 from an insertion opening 131 of a negative electrode current collector panel inserting portion 130 of the cell block 100 to cover an opening portion of the cell block 100, A negative electrode collector means for collecting a negative electrode during a catalytic reaction caused by the inflow of air A and water H into a reaction space with the panel 200, And is spaced apart from the catalytic portion 210 of the anode current collecting panel 200 so that a predetermined reaction space is formed and the fuel H is injected into the reaction space through the metal oxidized by oxygen in the air H, And a metal-fuel portion 310 for providing a function.

The metal fuel part 310 may include water H flowing into and out of the reaction space along the reactant inlet and outlet part 140 of the cell block 100 and the catalyst part of the anode current collector panel 200 And at least one of aluminum, zinc, and magnesium is used as a means for providing a fuel function so that the metal is oxidized by the air (A) or oxygen that flows into the reaction space through the inlet A metal plate 311 which is connected to the metal plate 311 and which is inserted into the guide groove 132 along the insertion opening 131 to shield the opening 111, And a closing plate 312 that closes the insertion port 131 in the insertion configuration.

The metal plate 311 may be formed of the air A supplied to the reaction space by the anode current collecting panel 200 and the water H supplied from the reactant inlet and outlet 140 of the cell block 100 from the outside. And the negative electrode collector electrode 320, which is a conductive material such as copper, brass, bronze, or nickel, is connected to provide a current collecting function.

The cover frame 400 is a protection frame for protecting the constituent parts of the unit cell structure S. The cover frame 400 includes an opening 111 formed in the body 110 of the cell block 100, A reaction material inlet 141 formed at an upper end and a lower end or a left end and a reaction end of the reactant outlet 142 formed at the left end of the body 110 and a fastening hole 151 formed at an edge of the body 110, , It is preferable to have a material of aluminum or other metal or alloy so that the body can maintain rigidity.

Hereinafter, a manufacturing method and an operation of a stack assembly (SS) for a metal air battery according to a preferred embodiment of the present invention will be described.

First, a method of manufacturing a unit cell structure S of a stack for a metal air battery according to a preferred embodiment of the present invention includes the steps of: (a) forming a positive electrode current collector plate 120 on a front surface and a back surface of a cell block 100; And a cathode current collecting panel 300 is inserted through the cathode current collecting panel inserting portion 130 of the cell block 100 so that one surface of the cathode current collecting panel 300 And the anode current collecting panel 200 are faced with each other to form a predetermined reaction space.

The step of mounting the pair of anode current collecting panels 200 on the anode current collector panel seating part 120 may be carried out by forming the edges of the nickel catalyst mesh part 212 of the catalyst part 210 of the cathode current collector panel 200, The edge of the reinforcing panel 220 having a window shape is attached to the edge of the carbon catalyst plate 211 corresponding to the upper side thereof in a state where the edge of the reinforcing panel 220 is positioned And then adhered to the edge of the carbon catalyst plate 211 by bolting to the anode current collecting panel mounting groove 121.

The step of inserting the negative electrode current collecting panel 300 through the negative current collecting panel inserting portion 130 may include inserting the metallic plate 311 of the metallic fuel portion 310 into the negative current collecting panel inserting portion The insertion opening 131 is inserted by the closing plate 312 after the opening 111 is closed by inserting along the guide groove 132 formed on the inner circumferential surface of the opening 111 in a state where the insertion opening 131 is positioned at the insertion opening 131 of the opening 131, Is closed.

As described above, in the single cell block 100, a pair of anode current collecting panels 200 are adhered to each other, and a plurality of anode current collecting panels 200 are formed, The unit cell structure S can be easily assembled through the cathode current collecting panel 300 being inserted and the cover frame 400 is fastened to the front portion and the back portion of the cell block 100 The stack assembly SS can be assembled.

Thereafter, in a state as described above, the positive electrode current collecting panel 200 and the negative electrode current collecting panel 300 of the cell block 100 are exposed from the pump P through the reactant inlet port 141 and the reactant outlet port 143 And the oxygen in the air A is allowed to flow into the reaction space and then the reactant outflow hole 143 and the reactant outflow port 142 The anode current collecting panel 300 is oxidized and reacts with oxygen and water H in the air A so that current or electrons can be transferred to the anode current collecting panel 300, The positive current collecting electrode 230 of the current collecting panel 200 and the negative current collecting electrode 320 of the current collecting panel 300 can be collected.

Here, only oxygen in the air (A) passes through the reaction space and passes through the carbon catalyst plate 211 and the nickel catalyst mesh 212 of the cathode current collecting panel 200. At this time, Is in contact with one surface of the metal plate (311) and the other surface through the reactant inlet (141) of the reactor (100) and the reactant inlet hole (143).

Accordingly, since the negative electrode current collecting panel 300 is formed of the metallic plate 311, the conventional metallic parts can be omitted, thereby simplifying the assembling work and reducing the manufacturing cost. Further, the positive current collecting panel 200 The catalytic portion 210 of the panel type may be formed in the anode current collecting panel 300 so that the oxygen in the air A is diffused over the entire surface of the metal plate 311 of the cathode current collecting panel 300 to improve the current collecting reaction efficiency.

Meanwhile, the electrochemical reaction formula of the unit cell structure S can be defined as [4M + 3O 2 + 6H 2 O 4M (OH) 3 + 2.71v] S) can be operated at a voltage typically lower than 2.7 volts, typically from 0.7 volts to 1.5 volts, and the remainder of the energy is released as heat, which is a well-known technique and therefore a detailed description will be omitted.

Meanwhile, the stack assembly SS for a metal-air battery according to the present invention includes a plurality of unit cell structures S, that is, cell blocks 100 having the above-described structure, 150 are arranged in a stacked structure while being passed through by fastening means, and then the front and rear portions of the cell block 100 positioned at the left and right ends of the cell blocks 100 are respectively fastened to the cover frame The large-capacity, large-sized, and expanded apparatuses can be connected through the fastening member 400.

At this time, it is preferable that the reactant inlet 141 and the reactant outlet 142 of each of the reactant inlet / outlet portions 140 of the cell block 100 are in a state in which adjacent cell blocks 100 are communicated with each other.

The inlet pipe for allowing the water H to flow into the reactant inlet 141 has a larger diameter than the inlet pipe for allowing the water H to flow out from the reactant outlet 142, It is preferable that a sufficient amount of water H is always supplied to the inlet piping so that the water H in the reaction space is drained to the outside rather than a water storage space connected to the pump P externally. Are preferably connected.

The reactant inlet port 141 and the reactant outlet port 142 located at the front portion of the cell block 100 at the leftmost end among the plurality of unit cell structures S are connected to the pump P And the reactant inlet port 141 and the reactant outlet port 142, which are formed to pass through toward the back surface of the cell block 100 at the rightmost end, are closed.

When the water H is supplied from the pump P to the reactant inlet port 141 positioned at the front portion of the cell block 100 at the leftmost end, Formed by the opposing faces of the anode current collecting panel 200 and the cathode current collecting panel 300 of each cell block 100 via the reactant inlet port 141 formed in the cell block 100 of the cell block 100 and the reactant inlet hole 143 Oxygen in the air A filtered by the anode current collecting panel 200 flows into the reaction space and the cathode current collecting panel 300 receives oxygen and water H So that current or electrons are transferred to the anode current collecting electrode 230 of the cathode current collecting panel 200 and the cathode current collecting electrode 320 of the cathode current collecting panel 300. Then, The reactant is discharged to the outside storage space through the reactant outlet 143 and the reactant outlet 142 of each cell block 100 This operation is repeated to be output may be to have an improved current collecting efficiency.

When the plurality of cell blocks 100 are stacked in series as described above, the reactant inlet port 141 and the reactant outlet port 142 through which water H flows are sealed and communicated with each other through the concavo-convex structure A predetermined spacing space exists between the bodies 110 of the cell block 100. Only the oxygen in the air A from the outside can be introduced into the reaction space of the cell blocks 100 positioned at the center except for the leftmost and rightmost ends through the spacing space.

Therefore, according to the stack assembly SS using the unit cell structure S as described above, a pair of anode current collecting panels 200 having a panel shape on the front surface and the back surface of the single cell block 100, And a single cathode current collecting panel 300 having a panel shape facing the anode current collecting panel 200 and forming a predetermined reaction space is interposed between the unit cell structure S and the stack assembly SS Can be easily assembled and the assembling efficiency can be improved.

A plurality of unit cell structures S having the above-described structure may be formed after the anode current collector panel 200 and the cathode current collector panel 300 are formed of a unit cell structure S in a single cell block 100, So that it is possible to make large-capacity, large-scale and easy-to-expand.

Although the present invention has been described with reference to the specific embodiments, various modifications may be made without departing from the scope of the present invention. Accordingly, the scope of the invention is not to be determined by the embodiments described, but should be determined by equivalents of the claims and the claims.

Claims (12)

A cell block (100) having a block shape having a predetermined area and width and opening at a central portion; A pair of positive electrode current collecting panels 200 formed on the front and back sides of the cell block 100 to cover and seal the openings of the cell block 100; And a cathode current collecting panel 300 which is inserted into the opening portion from the side surface of the cell block 100 and is positioned facing the pair of cathode current collecting panels 200, The chemical reaction between the metal, oxygen and water H is carried out when the oxygen and water H in the air A are introduced into the confronting spaces between the cathode current collecting panel 200 and the cathode current collecting panel 300, A unit cell structure S for collecting positive and negative electrodes from the positive current collecting panel 200 and the negative current collecting panel 300;
And a cover frame (400) forming an outer appearance of the stack assembly while covering the pair of the anode current collecting panels (200) on the front and back sides of the cell block (100) . The stack assembly for a metal-air battery according to claim 1, wherein a plurality of unit cell structures (S) are stacked in series on the inside of the cover frame (400). The cell block according to claim 1, wherein the cell block (100)
A block-shaped body 110 having a predetermined area and width and opening at a central portion thereof;
A cathode current collector panel seating part 120 formed on the front and back surfaces of the body 110 to cover the openings of the body 110 so that the pair of cathode current collector panels 200 are respectively seated thereon;
A negative electrode current collecting panel inserting unit (200) for inserting the negative current collecting panel (300) from the side part of the body (110) while covering the opening part, 130);
The anode current collecting panel 300 is formed so as to pass through the front and rear surfaces of the body 110 in a state of being positioned at the upper and lower ends or the left and right ends of the body 110, respectively, and a pair of anode current collecting panels The water H is introduced into the reaction space of the anode current collecting panel 300 by the oxygen in the air A which is filtered by the water H and the cathode collecting panel 200, (140) for allowing the metal of the metal layer to be oxidized; And
And an expansion coupling part 150 formed at an edge part of the body 110 and penetrating from the front part toward the back part to fasten the plurality of cell blocks 100 in a stacked structure through serial stacking. Stack assemblies for metal air batteries. 4. The apparatus of claim 3, wherein the body (110)
(111) formed at a central portion thereof with a predetermined area and width. The battery pack according to claim 3, wherein the anode current collector panel seating portion (120)
A positive electrode current collecting panel mounting groove 121 formed in the front and back portions of the body 110 and configured to respectively receive a pair of the positive current collecting panels 200;
And a plurality of partition walls (122) and guide grooves (123) formed on the anode current collecting panel mounting grooves (121) at predetermined intervals. 4. The negative electrode current collector according to claim 3, wherein the negative electrode current collector panel inserting portion (130)
An insertion port 131 formed in a side surface of the body 110;
And a guide groove (132) formed in the inner peripheral surface of the opening portion of the body (110). 4. The apparatus according to claim 3, wherein the reactant inlet /
A reactant inlet port 141 and a reactant outlet port 142 formed to pass through toward or from the front and rear sides of the body 110, respectively, positioned at the upper and lower ends or the left and right ends of the body 110;
And a reactant inlet hole (143) and a reactant outlet hole (144) formed in the guide groove (132) formed in the inner peripheral surface of the opening portion of the body (110). 4. The connector according to claim 3, wherein the expansion joint (150)
And a plurality of fastening holes (151) located at edge portions of the body (110) and formed to pass from the front portion toward the rear portion. 4. The plasma display panel according to claim 3, wherein the positive electrode collector panel (200)
The edge of the anode current collector panel mounting groove 121 is adhered to the cell collector 100 with an area corresponding to the opening 111 of the cell block 100 so that only oxygen among the air A introduced from the outside is adhered to the anode current collector panel 300 A catalytic unit 210 for introducing the oxygen into the reaction space to oxidize and react the metal of the anode current collecting panel 300 with the oxygen in the reaction space;
The catalyst part 210 may be connected to the anode current collector panel mounting groove 121 by being bolted to each other from the upper edge of the catalyst part 210 or by being adhered to the upper surface of the catalyst part 210, And a reinforcing panel part (220) for increasing the overall rigidity of the catalytic part (210) so as to have a fixed state. 10. The fuel cell system according to claim 9, wherein the catalytic portion (210)
A carbon catalyst plate 211 made of carbon and exposed to the outside;
And a nickel catalyst mesh (212) facing the reaction space. ≪ RTI ID = 0.0 > 21. < / RTI > The negative electrode current collector according to claim 3, wherein the negative current collector panel (300)
The reaction space is formed so as to be spaced apart from the catalyst part 210 of the anode current collecting panel 200 with an area corresponding to the opening 111 of the cell block 100, And a metal fuel portion (310) for providing a fuel function through a metal oxidized by oxygen in the air (A). 12. The fuel cell system according to claim 11, wherein the metal fuel portion (310)
Wherein the metal plate is a metal plate (311) composed of any one or at least one of aluminum, zinc, and magnesium.

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