KR20070043099A - Semi passive type fuel cell system - Google Patents

Abstract

The present invention relates to a semi-passive fuel cell system. In particular, a duct is formed to connect a blower with an upper portion of a stack to serve as an air passage so that air can be uniformly supplied to an air passage formed in a bipolar plate of the stack. The present invention relates to a semi-passive fuel cell system.

Fuel Cell, Semi Passive, Blower, Duct, Air Supply

Description

Semi Passive Type Fuel Cell System

1 is an overall schematic diagram of a semi-passive fuel cell system according to an embodiment of the present invention.

2 is a perspective view of a stack according to an embodiment of the present invention.

3 is an exploded perspective view of the stack of FIG. 2.

4 is a perspective view illustrating a coupling relationship between the stack and the blower of FIG. 1.

5 is a cross-sectional view taken along the line A-A of FIG.

6 is a cross-sectional view showing the flow of air in the stack and the blowing means.

7 shows a schematic view of a stack and blowing means in a conventional semi-passive fuel cell system.

<Explanation of symbols for the main parts of the drawings>

10-stack 30-fuel supply

50-Air supply means 51-Blowing means

60-Duct 61-Primary Duct

71-2nd duct

[Patent Document 1] Japanese Patent Laid-Open No. 2001-6717

The present invention relates to a semi-passive fuel cell system. In particular, a duct is formed to connect a blower with an upper portion of a stack to serve as an air passage so that air can be uniformly supplied to an air passage formed in a bipolar plate of the stack. The present invention relates to a semi-passive fuel cell system.

A fuel cell is a power generation system that directly converts the chemical reaction energy of hydrogen and oxidant contained in hydrocarbon-based materials such as methanol, ethanol, and natural gas into electrical energy.

The fuel cell system is typically a polymer electrolyte fuel cell (PEMFC) system and a direct methanol fuel cell (DMFC) system. Can be mentioned.

In general, a PEMFC system includes a stack that generates electric energy by a reaction of hydrogen and oxygen, and a reformer that generates hydrogen by reforming a fuel. The PEMFC system has the advantages of high energy density and high output, but requires attention to handling hydrogen gas and fuel reformer for reforming methane, methanol and natural gas to produce hydrogen, fuel gas. You will need additional equipment.

In contrast, DMFC systems generate methanol by electrochemical reactions by directly supplying methanol fuel and oxygen as an oxidant to the stack. The DMFC system has a very high energy density and power density, and since liquid fuel such as methanol is directly used, no additional equipment such as a fuel reformer is required, and the fuel is easily stored and supplied.

This DMFC system is forced to supply air to the stack by using an air supply means such as an air compressor or an air pump. The DMFC system is portable, and its applicability to mobile devices such as laptops and mobile communication devices is being examined. However, the air supply means used in such a DMFC system has a problem that the noise is so severe that the user is uncomfortable due to the noise. Accordingly, such a DMFC system has been developed a passive DMFC system in which air to be supplied to the stack is supplied by natural convection, or a semi-passive DMFC system in which air is supplied by a blowing means such as a blower.

Since the passive DMFC system supplies air by natural convection, air is not supplied to each cathode sufficiently. Therefore, the passive DMFC system has a constraint that the stack is formed relatively in a planar manner without stacking the stacks.

On the other hand, since the semi-passive DMFC system uses a blowing means such as a blower, the amount of air supplied is increased compared to the passive DMFC fuel cell system. Thus, the semi-passive DMFC fuel cell system can be formed by stacking stacks. Japanese Patent Laid-Open No. 2001-6717 (Patent Document 1) discloses a fuel cell body in which a pair of electrodes made of a fuel electrode and an oxidizer electrode is incorporated (see FIG. 7). Referring to FIG. 7, air supply means 5 for introducing an oxidant gas to the oxidant inlet side is provided to supplement the consumption of oxygen by the electrode reaction in the oxidant electrode of the fuel cell body 1. A configuration is disclosed in which the cross-sectional area of the oxidant gas flow path formed in the oxidant electrode is reduced from the inlet to the outlet of the oxidant gas.

However, such a semi-passive DMFC system has a problem that it is difficult to uniformly supply air to the air passages formed in the bipolar plate of the stack even when using a blower. In addition, the semi-passive DMFC system has a problem that the amount of air supplied for each air passage is non-uniform due to the difference in resistance of the air flow according to the position of the air passage.

The present invention is to solve the problems as described above is connected to the upper portion of the blowing means and the stack is formed a duct that acts as a passage of the air so that the air is uniformly supplied to the air passage formed in the bipolar plate of the stack The purpose is to provide a semi-passive fuel cell system.

In order to solve the above problems, the fuel cell system of the present invention has a membrane-electrode assembly having a cathode electrode and an anode electrode formed on both sides of the electrolyte membrane and the electrolyte membrane, and disposed on both sides of the membrane-electrode assembly. A fuel cell system including a stack formed by sequentially stacking a plurality of unit cells having a bipolar plate, and a fuel supply means and an air supply means, wherein the bipolar plate of the stack is disposed on a surface in contact with the cathode electrode. An air passage is formed through the lower portion, wherein the air supply means is characterized in that it comprises a duct installed in the upper and lower portions of the stack and a blowing means for supplying air to the duct. At this time, the air passage of the bipolar plate may be formed in a straight shape from the top to the bottom of the stack.

In addition, in the present invention, the duct includes a first duct installed in the upper portion of the stack and a second duct installed in the lower portion of the stack, and the blowing means is formed to supply air to one side of the first duct. Can be. In this case, the first duct is provided with the blowing means inside one side, the other side is formed so as to cover the entire upper portion of the stack, the air inlet formed on the upper side of the blowing means on the upper side of the first duct And an air supply hole formed on a lower surface of the other side in a shape corresponding to a lower shape of the stack and supplying air to the stack. In addition, the upper surface of the other side of the first duct may be formed to be inclined at a predetermined inclination angle so that the inner height is smaller from the one side on which the blowing means is installed to the other end. In addition, one side of the first duct may be formed to have an internal height corresponding to the height of the blowing means, and the blowing means may be formed to suck air through the air suction port and supply the air to the other side of the first duct. have. In addition, the second duct may have an air inlet formed in a shape corresponding to a lower shape of the stack on an upper surface thereof, an air inlet through which air passing through the stack is introduced, and an air outlet formed at the other end to discharge air to the outside. have. At this time, the lower surface of the second duct may be formed to be inclined at a predetermined inclination angle so that the inner height is increased from one end to the other end. In addition, the lower surface of the second duct may be formed to be inclined at the same inclination angle as the upper surface of the first duct.

In addition, in the present invention, the blowing means may be formed with a blower or a fan.

In addition, the fuel cell system in the present invention may be made of a direct methanol fuel cell system or a polymer electrolyte fuel cell system.

Hereinafter, a fuel cell system according to the present invention will be described in detail with reference to the accompanying drawings and embodiments.

1 is an overall schematic diagram of a semi-passive fuel cell system according to an embodiment of the present invention. 2 is a perspective view of a stack according to an embodiment of the present invention. 3 is an exploded perspective view of the stack of FIG. 2. 4 is a perspective view illustrating a coupling relationship between the stack and the blower of FIG. 1. 5 is a cross-sectional view taken along the line A-A of FIG.

In the semi-passive fuel cell system according to an exemplary embodiment of the present invention, referring to FIGS. 1 to 5, the fuel supply means 30 and the stack 10 for supplying fuel to the stack 10 and the stack 10 are provided. It is formed including an air supply means 50 for supplying air to the. Here, a description will be given of a direct methanol fuel cell (DMFC) system that generates electric energy using methanol as a direct fuel. However, the fuel cell system according to the present invention is applied to a polymer electrolyte fuel cell (hereinafter referred to as "PEMFC") system that generates electric energy using hydrogen generated by reforming fuel as a fuel. Of course it can. However, the PEMFC system is configured to further include a reformer for generating hydrogen by reforming the liquid fuel.

The stack 10 is a unit cell including a membrane-electrode assembly (hereinafter referred to as "MEA") 12 and a bipolar plate 16 disposed on both sides of the MEA 12. It is formed by stacking a plurality of 10a. At this time, the bipolar plate 16 is formed so that the MEA 12 is in contact with both sides to be shared by the unit cells 10a adjacent to each other. In addition, the stack 10 supplies electricity to an external load through an end plate 16a, which is a bipolar plate located at outer sides of both sides. The stack 10 may be formed to include a support plate 16b coupled to the outside of the end plate 16a to fix the bipolar plate 16 and the MEA 12. The support plate 16b is provided with a predetermined passage (not shown) so that fuel supplied from the fuel supply means 30 is supplied to the bipolar plate 16. On the other hand, the end plate 16a may be formed to serve as a support plate at the same time, of course.

The stack 10 has a unit cell 10a formed on the left and right sides of the bipolar plate 16 based on the vertical center line. That is, the stack 10 is formed of unit cells independent of left and right when viewed from the front direction. The stack 10 includes first and second passages 17a and 17b which are fuel supply passages in a central region between unit cells formed at right and left sides. Therefore, the stack 10 is supplied with fuel through the first passage and the second passage 17a, 17b in the lateral direction. In addition, the stack 10 is supplied with air through an air passage 19 formed from top to bottom on one surface of the bipolar plate 16. Hereinafter, the structure of the MEA 12 and the bipolar plate 16 constituting the stack 10 will be described in detail. On the other hand, the stack 10 is a unit cell formed on the left and right with respect to the vertical center line may be formed integrally. Therefore, in this case, the first passages and the second passages 17a and 17b are formed on the left and right sides of the bipolar plate 16.

The MEA 12 is formed by stacking an electrolyte membrane 14 between an anode electrode 13 and a cathode electrode 15. At this time, the anode electrode 13 and the cathode electrode 15 are spaced apart from the left and right by a vertical center line on both surfaces of the electrolyte membrane 14, respectively, and the anode electrodes 13a and 13b and the cathode electrode 15a are provided in predetermined areas. , 15b) is formed. Accordingly, in the MEA 12, an unreacted region in which an anode electrode 13 and a cathode electrode 15 are not formed at both sides of the MEA 12 is formed, and in the unreacted region, fuel flows through the fuel. The first passage 17a and the second passage 17b, which are supply passages, are formed. In addition, the MEA 12 may have a fastening hole 20 through which a bolt for fastening the stack 10 passes between the first passage 17a and the second passage 17b.

The anode electrode 13 and the cathode electrode 15 include a fuel diffusion layer for supplying and diffusing fuel, a catalyst layer in which an oxidation / reduction reaction of the fuel occurs, and an electrode support. The anode electrode 13 separates electrons and hydrogen ions from the supplied fuel, and the electrolyte membrane 14 moves the hydrogen ions to the cathode electrode 15. The cathode electrode 15 generates water by reacting hydrogen and oxygen with electrons supplied from the anode electrode 13. Thus, the stack 10 generates electrical energy through an electrochemical reaction between hydrogen and oxygen.

The bipolar plate 16 is in close contact with the MEA 12 on both sides, the fuel passage 18 and the air passage 19 is formed on both sides. More specifically, the bipolar plate 16 has a fuel passage 18 and an air passage 19 formed in predetermined regions on both sides of the vertical center line. Accordingly, the bipolar plate 16 has unformed regions 16c and 16d in which a fuel passage 18 and an air passage 19 are not formed at the center thereof. The bipolar plate 16 is formed by contacting the anode electrode 13 of the MEA 12 on one surface and the cathode electrode 15 of the MEA 12 on the other surface. Accordingly, the bipolar plate 16 has a fuel passage 18 formed on the surface where the anode electrode 13 is in close contact with each other so that fuel is continuously supplied to the anode electrode 13. In addition, the bipolar plate 16 has an air passage 19 formed on the surface in which the cathode electrode 15 is in close contact with each other so that air is continuously supplied to the cathode electrode 15.

The bipolar plate 16 passes through the bipolar plate 16 in the unformed region 16d between the regions where the fuel passage 18 is formed, and is connected to one end and the other end of the fuel passage 18, respectively. The furnace 17a and the second passage 17b are formed up and down. Accordingly, the bipolar plate 16 allows the fuel supplied through the first passage 17a to be discharged through the second passage 17b after flowing through the fuel passage 18. The first passage 17a and the second passage 17b are formed at the same position in each of the bipolar plates 16 and the MEA 12 to form a passage of fuel that passes through the upper and lower portions of the stack 10 as a whole. do. Therefore, the stack 10 is supplied with fuel through the first through passage 17a at one side, and unreacted fuel and carbon dioxide as a reaction byproduct are discharged through the second through passage 17b at the other side. The bipolar plate 16 is provided with a fastening hole 20 into which a bolt (not shown) is inserted to fasten the stack 10 between the first passage 17a and the second passage 17b. . The first passage 17a and the second passage 17b are connected to the fuel supply means 30 through a predetermined passage (not shown) formed in the support plate 16b to allow fuel to flow. The passage formed in the support plate 16b may be formed in various ways according to the design of the stack 10.

The bipolar plate 16 is formed of a metallic material, for example a metal such as aluminum, copper, iron or an alloy, graphite or carbon composite thereof.

The fuel passage 18 is formed with a predetermined depth and width along one surface of the bipolar plate 16, that is, the surface on which the anode electrode 13 of the MEA 12 contacts the vertical center line. Therefore, the fuel passages 18a and 18b are formed on both sides of the unformed region 16d formed at the center, respectively. In addition, the fuel passage 18 is preferably formed in a zigzag shape so that the area of the fuel passage 18 is increased. Therefore, the fuel passage 18 increases the contact area of the anode electrode 13 of the MEA 12 while increasing the area of the anode electrode 13 in direct contact with the fuel. Since the stack 10 is supplied with fuel at a predetermined pressure by the fuel pump, the fuel may be smoothly supplied even when the fuel passage 18 is zigzag-shaped.

The air passage 19 has a predetermined width or depth along a plane from side to side on the other side of the bipolar plate 16, that is, the surface in contact with the anode electrode 15 of the MEA 12, with a predetermined cross-sectional area. It is formed to have. Accordingly, the air passages 19a and 19b are formed at both sides of the unformed region 16c formed at the center, respectively. The air passage 19 is preferably formed in a straight shape from the top to the bottom so that the air supplied from the top or bottom can flow smoothly. The air passage 19 is not connected to the first passage 17a and the second passage 17b unlike the fuel passage 18 on one surface.

Meanwhile, the MEA and the bipolar plate may not have a central unreacted region or an unformed region. That is, in the MEA, anode and cathode electrodes respectively formed on one surface and the other surface may be integrally formed without an unreacted region. In addition, the bipolar plate may be formed integrally with the fuel passage and the air passage formed on one surface and the other surface, respectively, without a central unformed region. In this case, the stack has a first passageway and a second passageway formed on the left and right sides of the bipolar plate and the MEA.

The fuel supply means 30 is formed to include a fuel tank 32 for storing fuel diluted to a predetermined concentration and a fuel pump 34 for supplying fuel to the stack 10. In addition, when the fuel tank is formed to mix the fuel feed solution and water supplied separately to dilute to a predetermined concentration, the fuel supply means 30 is a fuel feed tank (not shown) and the stock solution for storing the fuel feed solution It may be formed by further including a pump (not shown). On the other hand, the fuel tank 32 may be formed in the form of a cartridge in which the fuel diluted to a predetermined concentration is stored. In this case, when the fuel stored in the fuel tank 32 is exhausted, the fuel may be recharged or a new fuel tank may be installed.

The fuel tank 32 stores a liquid fuel such as methanol or ethanol diluted to a predetermined concentration. The fuel pump 34 is connected to the fuel tank, and supplies the fuel of the fuel tank 32 to the anode electrode of the stack 10. In addition, when the fuel tank is supplied with a fuel stock solution and diluted to a predetermined concentration, the fuel tank 32 may include unreacted fuel discharged from the anode electrode of the stack 10 and water discharged from the cathode electrode of the stack 10. This is connected to the anode electrode and the cathode electrode of the stack 10 by a separate pipe so as to recover.

The air supply means 50 is formed to include a blowing means 51 for sucking and blowing air and a duct 60 for supplying the air ejected from the blowing means 51 to the upper or lower portion of the stack 10. .

The blowing means 51 is sucked to the outside air to eject at a constant pressure, it is formed of a blower (fan) or a fan (fan). However, of course, the blowing means 51 may use various means for blowing air at a predetermined pressure.

The duct 60 includes a first duct 61 formed at an upper portion of the stack 10 and a second duct 71 installed at a lower portion of the stack 10, and the inside of the first duct or the second duct. Or the blowing means 51 is installed outside. The duct 60 guides the air supplied from the blowing means 51 to the upper portion of the stack 10 and supplies the air to the air passage 18. Here, the first duct 61 is formed at the upper portion and the second duct 71 is formed at the lower portion. However, the first duct is formed at the lower portion according to the specification or the method of use of the mobile communication device used. Of course, the second duct may be formed on the upper portion.

The first duct 61 is formed in a substantially plate-shaped box shape with a hollow inside, and a blowing means 51 is installed inside or outside of one side, and the other side is formed above the stack 10. (Here, one side of the first duct means a left side in which the blowing means is installed and is separated from the top of the stack in FIG. 5, and the other side means the right side portion installed on the top of the stack.) The first duct 61 is one side. Preferably, the blower means 51 is formed at a height corresponding to the height of the blower means 51, and the blower means 51 is installed therein, and an air suction port 62 is formed on the upper surface of the blower means. The air suction port 62 is preferably formed with an area corresponding to the upper area of the blowing means 51. At this time, one side of the first duct 61 is formed to have a uniform height as a whole so that the sucked air flows smoothly to the other side. In addition, one end 61a of the first duct 61 is closed to prevent the air sucked by the blowing means 51 from flowing out. Therefore, the first duct 61 allows the air sucked by the blowing means 51 to be ejected only to the other side.

The other side of the first duct 61 is formed to have a predetermined height and an area corresponding to at least an upper area of the stack 10 so as to cover the entire upper portion of the stack 10. At this time, the other side of the first duct 61 is opened in the lower region in contact with the upper portion of the stack 10 is formed with an air supply port (63). The air supply port 63 is preferably formed in a shape and area corresponding to the top shape and area of the stack. Thus, the first duct 61 is the air intake of the stack 10 through the air supply port 63 by the air sucked through the air inlet 62 of one side by the blowing means 51 is directed to the other side ( 18).

The other side of the first duct 61 is preferably formed such that the height inside thereof gradually decreases from one side of the stack 10 to the other side. That is, the other side of the first duct 61 is formed such that the upper surface 61c is inclined at a predetermined inclination angle with respect to the upper surface of the stack 10. Therefore, as the other side of the first duct 61 moves away from the blowing means 51, the cross-sectional area is reduced so that the velocity of air blown out of the blowing means 51 is not reduced. In general, when the cross-sectional area of the duct is constant, the ejected air is reduced in speed as it moves away from the blowing means, and the supply amount of air is reduced. This phenomenon increases as the amount of air blown out of the blowing means decreases. Accordingly, the other side of the first duct 61 may be appropriately formed according to the amount of air blown out from the blowing means 51 by the inclination angle of the upper surface 61c. That is, when the amount of air blown out by the blowing means 51 increases, the other side of the first duct 61 may have a lower inclination angle at the upper surface 61c. On the contrary, when the amount of air blown out by the blowing means 61 is small, the inclination angle of the upper surface 61c of the other side of the first duct 61 may be large.

Like the first duct 61, the second duct 71 is formed in a substantially plate-shaped box shape with a hollow inside. The second duct 71 is installed below the stack 10 to cover the bottom of the stack 10, and an air inlet 73 having an area corresponding to the bottom area of the stack 10 is formed on an upper surface thereof. . In addition, one end 71a of the second duct 71 is closed and the other end 71b of the second duct 71 is formed as an air outlet 72. Therefore, the second duct 71 discharges the air passing through the stack 10 to the outside.

In addition, the second duct 71 is formed to be inclined at a predetermined inclination angle from the one end (71a) to the other end (71b) when the internal height is gradually increased. In this case, the air introduced into the second duct 71 may be discharged smoothly as the air velocity at one end 71a is relatively faster than the other end 71c. The lower surface 71c of the second duct 71 is preferably inclined at an inclination angle corresponding to the inclination angle of the other upper surface 61c of the first duct 61. Therefore, the height of the fuel cell system is uniformly formed as a whole, and the height can be prevented from being partially increased by the duct 50. In this case, the stack 10 is inclined at an angle corresponding to the inclination angle of the top surface of the first duct 61 or the bottom surface of the second duct 71.

On the other hand, the second duct serves as a drain passage for the water discharged after the reaction from the cathode of the stack (10). Therefore, a separate pipe for recovering such water may be formed at the other end of the second duct.

Next, the operation of the fuel cell system according to the exemplary embodiment of the present invention will be described.

6 is a cross-sectional view of the stack 10 and the air supply means 50 in a fuel cell system according to an embodiment of the present invention. Here, the air supply means 50 will be described with reference to a method for supplying air to the stack 10. On the other hand, the method for supplying fuel to the stack 10 by the fuel supply means 30 may be used a general method known to those skilled in the art, the detailed description thereof will be omitted here.

The duct 60 has a first duct 61 coupled to the upper portion of the stack 10, and a second duct 71 coupled to the lower portion of the duct 60. The first duct 71 has a blowing means 51 is mounted on one side, the other side is coupled to the upper portion of the stack (10). Therefore, when the blower means 51 is operated, the blower means 51 sucks air through the upper air suction port 62 and blows it to the other side of the first duct 61 through the side of the blower means 51. Done. The first duct 61 allows the air blown out through the blowing means 51 to flow to the other side. The other side of the first duct 61 is formed such that the upper surface (61c) is inclined so that the air speed is not reduced in the region near the other end (61b), and the amount of air supplied is also not reduced. Therefore, the air passage 19 of the bipolar plate 16 on the other side of the first duct 61 is uniformly supplied with air regardless of the distance from the blowing means.

Air passing through the air passage 19 of the bipolar plate 16 flows to the bottom of the stack 10 and flows into the second duct 71 through the air inlet 73 of the second duct 71. Since the air passage 19 of the bipolar plate 16 is formed in a straight line in the vertical direction, air flows more smoothly. One side of the second duct 71 is coupled to the bottom of the stack 10 so that air flowing from the stack 10 flows to the other side. At this time, the second duct 71 has an internal height increases from one end (71a) to the other end (71b), so that the air flowing in the stack 10 flows smoothly from one end (71a) to the other end (71b). Air flowing from one end of the second duct 71 to the other end is discharged to the outside through an air outlet 72 formed at the other end.

As described above, the present invention is not limited to the specific preferred embodiments described above, and any person having ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Various modifications are possible, of course, and such changes are within the scope of the claims.

According to the fuel cell system according to the present invention, a blower means such as a blower or a fan is formed on one side of the upper part of the stack, and the air is supplied through the duct connecting the blower and the upper part of the stack. There is an effect that can uniformly supply air irrespective of the position in the air passage formed in the bipolar plate of the stack.

Claims (11)

 A stack formed by sequentially stacking a plurality of unit cells including an electrolyte membrane, a membrane-electrode assembly including a cathode electrode and an anode electrode formed on both sides of the electrolyte membrane, and a bipolar plate disposed on both sides of the membrane-electrode assembly. In the fuel cell system comprising a fuel supply means and an air supply means, The bipolar plate of the stack has an air passage formed to penetrate from the top to the bottom on the surface in contact with the cathode electrode, The air supply means is a semi-passive fuel cell system, characterized in that it comprises a duct installed on the top and bottom of the stack and a blowing means for supplying air to the duct. The method of claim 1, Semi-passive fuel cell system, characterized in that the air passage of the bipolar plate is formed in a straight shape from the top to the bottom of the stack. The method of claim 1, The duct includes a first duct installed in the upper portion of the stack and a second duct installed in the lower portion of the stack, The blowing means is a semi-passive fuel cell system, characterized in that formed to supply air to one side of the first duct. The method of claim 3, wherein The first duct is provided with the blowing means inside one side, the other side is formed to cover the entire upper part of the stack, An air inlet formed in an upper portion of the blower means on an upper surface of one side of the first duct, and an air supply hole formed in a shape corresponding to a lower shape of the stack on a lower surface of the other side and supplying air to the stack; Semi-passive fuel cell system characterized by. The method of claim 4, wherein Semi-passive fuel cell system, characterized in that the other upper surface of the first duct is formed to be inclined at a predetermined inclination angle so that the inner height is smaller from the one side where the blowing means is installed to the other end. The method of claim 4, wherein One side of the first duct is formed to a height that the inner height corresponding to the height of the blowing means, The air blowing means is a semi-passive fuel cell system, characterized in that the air intake through the air inlet is formed to supply to the other side of the first duct. The method of claim 5, The second duct is formed in a shape corresponding to the lower shape of the stack on the upper surface and has an air inlet through which air passing through the stack is introduced, and an air outlet formed at the other end to discharge the air to the outside. Semi-passive fuel cell system. The method of claim 7, wherein Semi-passive fuel cell system, characterized in that the lower surface of the second duct is inclined at a predetermined inclination angle so that the inner height is increased from one end to the other end. The method of claim 8, Semi-passive fuel cell system, characterized in that the lower surface of the second duct is inclined at the same inclination angle as the upper surface of the first duct. The method of claim 1, Semi-passive fuel cell system, characterized in that the blowing means is provided with a blower or a fan. The method of claim 1, The fuel cell system is a semi-passive fuel cell system, characterized in that consisting of a direct methanol fuel cell system or a polymer electrolyte fuel cell system.

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