JP2011049060A - Fuel cell - Google Patents

Abstract

A fuel cell having excellent output characteristics is provided.
A fuel cell includes a pair of fuel cell main bodies and a heat radiating member. The fuel cell main body 5 includes an electromotive unit and a fuel distribution mechanism. The pair of fuel cell main bodies 5 are arranged so that the anodes face each other. The heat dissipating member is disposed between the pair of fuel cell main bodies 5 and releases at least the secondary heat transmitted from the anode side of the pair of fuel cell main bodies 5 to the outside.
[Selection] Figure 2

Description

  The present invention relates to a fuel cell.

  In recent years, attempts have been made to use a fuel cell as a power source for portable electronic devices such as personal computers and mobile phones. A fuel cell enables a portable electronic device to be used for a long time without being charged. Fuel cells have the advantage that they can generate electricity simply by supplying fuel and air, and can continuously generate electricity if only the fuel is replenished / replaced. For this reason, if the size can be reduced, it can be said that the system is extremely advantageous for long-time operation of the portable electronic device.

  In particular, a direct methanol fuel cell (DMFC) is promising as a power source for small devices because it can be downsized and is easier to handle than hydrogen gas fuel.

  The DMFC fuel supply method includes gas supply type DMFC that vaporizes liquid fuel and then feeds it into the fuel cell with a blower, etc., liquid supply type DMFC that feeds liquid fuel directly into the fuel cell with a pump and the like, and liquid fuel An internal vaporization type DMFC that vaporizes in a cell is known.

  In addition, in order to obtain a desired high output, a fuel cell including a pair of electromotive parts (power generation bodies) is known. Each electromotive section has an anode, a cathode, and a membrane electrode assembly including an electrolyte membrane sandwiched between the anode and the cathode. A pair of electromotive parts is arrange | positioned with anodes facing each other (for example, refer patent document 1).

JP 2003-86207 A

  In the fuel cell, heat is generated at the electromotive unit in accordance with the power generation reaction at the electromotive unit. Since the anodes face each other in the pair of electromotive parts, heat tends to be accumulated on the anode side. When the temperature varies between the anode side and the cathode side, the power generation efficiency decreases.

For this reason, even in a fuel cell including a pair of electromotive parts with anodes facing each other, a fuel cell capable of suppressing deterioration of cell characteristics such as a decrease in output accompanying a temperature distribution between the anode and the cathode is required.
The present invention has been made in view of the above points, and an object thereof is to provide a fuel cell having excellent output characteristics.

In order to solve the above problems, a fuel cell according to an aspect of the present invention includes:
An electromotive portion having a membrane electrode assembly including an anode, a cathode, and an electrolyte membrane sandwiched between the anode and the cathode, a fuel discharge surface located on a surface facing the anode, and the fuel A fuel distribution mechanism provided with a part of the discharge surface opened and having a fuel discharge port for discharging fuel, and a pair of fuel cell main bodies arranged so that the anodes face each other;
And a heat dissipating member that is disposed between the pair of fuel cell main bodies and releases at least the secondary heat transmitted from the anode side of the pair of fuel cell main bodies to the outside.

  According to the present invention, a fuel cell excellent in output characteristics can be provided.

1 is a perspective view showing a fuel cell according to an embodiment of the present invention, and in particular, a view showing a fuel cell of Example 1. FIG. It is sectional drawing which shows the fuel cell along line AA of FIG. It is sectional drawing which shows the fuel cell along line BB of FIG. It is sectional drawing which shows the fuel cell module of the said fuel cell. It is another sectional view showing the fuel cell module. It is a perspective view which shows roughly the cross section of a part of membrane electrode assembly of the fuel cell module. It is a top view which shows the said membrane electrode assembly. It is a perspective view which shows the said fuel cell module, and is a figure which shows the pump, valve | bulb, and control part which were attached to the outer surface of the container. It is an expanded sectional view showing a part of the fuel cell. It is sectional drawing which shows a part of fuel cell of Example 5 which concerns on the said embodiment. It is a perspective view which shows the fuel cell module of the fuel cell shown in FIG.

Hereinafter, a fuel cell according to an embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, a direct methanol fuel cell will be described.
As shown in FIGS. 1, 2, and 3, the fuel cell includes a pair of fuel cell modules 1, a fuel supply source 2 that contains fuel and supplies fuel to the fuel cell module 1, a case 3, and a heat dissipation member. The two heat sinks 70, the two set covers 80, the top frame 91, the bottom frame 92, and the exterior cover 4 are provided.

  As shown in FIGS. 2, 3, 4, and 5, each fuel cell module 1 includes a fuel cell main body 5, a pump 7, a valve 8, and a control unit 9. Here, the configuration of each fuel cell module 1 is the same. Hereinafter, one fuel cell module 1 will be described.

  The fuel cell main body 5 includes an electromotive unit 6 having a membrane electrode assembly (MEA) 10, a current collector 11, an anode support plate 12, a fuel supply unit 13, a moisture retention plate 18, and a cover. Plate 19.

  As shown in FIGS. 4, 5, 6, and 7, the membrane electrode assembly 10 includes an anode 21 as a fuel electrode and a cathode 24 as an air electrode that is disposed opposite to the anode 21 with a predetermined gap. And an electrolyte membrane 27 sandwiched between the anode 21 and the cathode 24. As will be described later, the fuel supply source 2 accommodates the fuel 62 and supplies a fuel to the fuel distribution mechanism 15 of the fuel supply unit 13 through a cylindrical pipe 64 (see FIG. 9). And a sleeve 63 serving as a housing that accommodates a tank 61 (fuel accommodating portion).

  In the fuel cell of this embodiment, the fuel 62 supplied from the fuel distribution mechanism 15 to the membrane electrode assembly 10 is consumed by the power generation reaction, and then circulates back to the fuel distribution mechanism 15 or the tank 61. There is no. Since this type of fuel cell does not circulate the fuel, it is a method different from the conventional active method and does not impair the downsizing of the device. Further, since the pump 7 is used for supplying the liquid fuel, which is different from the conventional pure passive type such as the internal vaporization type, the fuel cell of this type can be called a semi-passive type.

  In this embodiment, the membrane electrode assembly 10 has a rectangular power generation region R1. The power generation region R1 has an effective region R2 effective for power generation and a non-effective region R3 surrounding the effective region R2. The effective region R2 is rectangular and has a long axis. The membrane electrode assembly 10 has one power generation element 20. The power generation element 20 has a rectangular shape, has a long axis, and overlaps the effective region R2.

  The anode 21 has an anode catalyst layer 22 and an anode gas diffusion layer 23 laminated on the anode catalyst layer 22. The cathode 24 has a cathode catalyst layer 25 and a cathode gas diffusion layer 26 laminated on the cathode catalyst layer 25.

  The anode catalyst layer 22 oxidizes the fuel supplied via the anode gas diffusion layer 23 and extracts electrons and protons from the fuel. The cathode catalyst layer 25 reduces oxygen and reacts electrons with protons generated in the anode catalyst layer 22 to generate water.

  Examples of the catalyst contained in the anode catalyst layer 22 and the cathode catalyst layer 25 include a simple substance of a platinum group element such as Pt, Ru, Rh, Ir, Os, and Pd, an alloy containing the platinum group element, and the like. For the anode catalyst layer 22, it is preferable to use Pt—Ru, Pt—Mo, or the like that has strong resistance to methanol, carbon monoxide, or the like. It is preferable to use Pt, Pt—Ni, or the like for the cathode catalyst layer 25. However, the catalyst is not limited to these, and various substances having catalytic activity can be used. The catalyst may be either a supported catalyst using a conductive support such as a carbon material or an unsupported catalyst.

  The electrolyte membrane 27 is a proton conductive film. The electrolyte membrane 27 is for transporting protons generated in the anode catalyst layer 22 to the cathode catalyst layer 25. The electrolyte membrane 27 is formed of a proton conductive material that does not have electronic conductivity and can transport protons.

  As a material for forming the electrolyte membrane 27, for example, a fluororesin such as a perfluorosulfonic acid polymer having a sulfonic acid group (Nafion (trade name, manufactured by DuPont), Flemion (trade name, manufactured by Asahi Glass Co., Ltd.), etc.) And organic materials such as hydrocarbon resins having sulfonic acid groups, or inorganic materials such as tungstic acid and phosphotungstic acid. However, proton conductive materials are not limited to these.

  The anode gas diffusion layer 23 serves to uniformly supply fuel to the anode catalyst layer 22 and has a current collecting function of the anode catalyst layer 22. The cathode gas diffusion layer 26 serves to uniformly supply the oxidant to the cathode catalyst layer 25, and has a current collecting function of the cathode catalyst layer 25. The anode gas diffusion layer 23 and the cathode gas diffusion layer 26 are made of a porous substrate.

  As shown in FIGS. 4 and 5, the current collector 11 has an anode current collector 31 and a cathode current collector 34. The anode current collector 31 and the cathode current collector 34 are made of, for example, a porous layer (for example, a mesh) or a foil made of a metal material such as gold or nickel, a conductive metal material such as a foil, a thin film, or stainless steel (SUS). A composite material coated with a highly conductive metal such as can be used.

  The membrane electrode assembly 10 in the fuel cell body 5 is liquid-tightly sealed by insulating O-rings (seal materials) 38 and 39. Various spaces and gaps are formed inside the fuel cell body 5 by these O-rings 38 and 39.

  The anode current collector 31 is formed in a rectangular shape corresponding to the power generation element 20 and has a long axis, and has a plurality of fuel passage holes. The cathode current collector 34 is formed in a rectangular shape having a long axis corresponding to the power generation element 20 and has a plurality of vent holes. The anode current collector 31 and the cathode current collector 34 are connected to the power generating element 20 constituting the membrane electrode assembly 10.

  The O-rings 38 and 39 are made of, for example, rubber as an insulating material. The O-ring 38 is formed in a frame shape so as to surround the outer periphery of the anode current collector 31. The O-ring 39 is formed in a frame shape so as to surround the outer periphery of the cathode current collector 34.

  As described above, when the membrane electrode assembly 10 and the anode current collector 31 are combined, the vaporized component of the fuel passes through the fuel passage hole (not shown) of the anode current collector 31 and the anode gas diffusion layer 23. And supplied to the anode catalyst layer 22. For this reason, the fuel cell main body 5 is formed so as to supply the vaporized component of the fuel to the anode gas diffusion layer 23 and the anode catalyst layer 22.

  For example, a gas-liquid separation film (not shown) is optionally provided between the anode current collector 31 and the fuel supply unit 13 to supply a fuel vaporized component to the anode gas diffusion layer 23 and the anode catalyst layer 22. Can do. Here, the O-ring (seal material) 38 has a function of preventing fuel leakage from the membrane electrode assembly 10.

  The air as the oxidant passes through the vent hole 19 a of the cover plate 19 and is supplied to the cathode gas diffusion layer 26 and the cathode catalyst layer 25 through the vent hole (not shown) of the cathode current collector 34. Here, the O-ring (sealing material) 39 has a function of preventing leakage of the oxidant from the membrane electrode assembly 10.

  In this embodiment, the membrane / electrode assembly 10 has an MEA structure in which one anode 21 and one cathode 24 are formed on the electrolyte membrane 27 so as to face each other. The structure of the joined body 10 is not limited to this example, and may be another structure. For example, the structure of the membrane electrode assembly 10 includes a plurality of (for example, four) anodes 21 and the same number (for example, four) of cathodes 24 formed on the same electrolyte membrane 27 so as to face each other. A structure electrically connected in series may be used.

  The anode support plate 12 is formed in a rectangular plate shape. The anode support plate 12 is sandwiched between the anode 21 and the fuel supply unit 13. In addition, the anode support plate 12 should just be provided as needed.

  The anode support plate 12 has a plurality of fuel passage holes (not shown) through which fuel passes through the membrane electrode assembly 10, more specifically, the anode 21. The fuel passage holes are provided in a matrix. The above-described anode support plate 12 is supplied with the vaporized component of the liquid fuel 62 as the fuel.

  Here, the liquid fuel 62 is not limited to a methanol fuel such as liquid methanol or an aqueous methanol solution. For example, an ethanol fuel such as an ethanol aqueous solution or pure ethanol, a propanol fuel such as a propanol aqueous solution or pure propanol, or an aqueous glycol solution. And glycol fuel such as pure glycol, dimethyl ether, formic acid, or other liquid fuel. In any case, liquid fuel corresponding to the fuel cell is used. The vaporized component of the liquid fuel 62 means vaporized methanol when liquid methanol is used as the liquid fuel 62, and from the vaporized component of methanol and the vaporized component of water when an aqueous methanol solution is used as the liquid fuel 62. Is a mixed gas.

  The fuel supply unit 13 includes a fuel distribution mechanism 15 and a fuel diffusion unit 16. The fuel distribution mechanism 15 is disposed on the opposite side of the electrolyte membrane 27 with respect to the anode 21. The fuel diffusion portion 16 is disposed between the anode 21 and the fuel distribution mechanism 15.

  The fuel distribution mechanism 15 includes a container 50 and thin tubes 57a, 57b, 57c formed in the container 50. The container 50 includes a bottom wall 51 and a peripheral wall 52 provided on the outer edge of the bottom wall 51. The bottom wall 51 and the peripheral wall 52 are integrally formed. The bottom wall 51 has a fuel discharge surface 51 </ b> S facing the anode 21. The container 50 is open on the side facing the fuel discharge surface 51S. The container 50 accommodates the electromotive unit 6 and the like on the inner surface side.

  The thin tube 57a is formed in the container 50 so as to communicate with a fuel inlet 53 and a fuel outlet 55a provided by opening a part of the outer surface of the container 50. Here, the fuel injection port 53 is provided in the peripheral wall 52, and the fuel discharge port 55 a is provided in the bottom wall 51.

  The thin tube 57b is formed in the container 50 so as to communicate a fuel intake port 55b and a fuel discharge port 56a provided by opening a part of the outer surface of the container 50. Here, the fuel intake port 55 b and the fuel discharge port 56 a are provided in the bottom wall 51.

  The narrow tube 57c is formed in the container 50 so as to communicate a fuel discharge port 54 provided by opening a part of the fuel discharge surface 51S and a fuel intake port 56b provided by opening a part of the outer surface of the container 50. Has been. Here, the fuel intake port 56 b is provided in the bottom wall 51. The fuel discharge ports 54 are provided at a plurality of locations, but the number, position, size, and the like can be variously modified. The fuel discharge port 54 may be provided only at one place.

  The liquid fuel 62 is injected from the fuel injection port 53. The liquid fuel 62 injected into the fuel injection port 53 is guided to the fuel discharge port 54 through the thin tube 57a, the thin tube 57b, the thin tube 57c, and the like. From the fuel discharge port 54, the liquid fuel 62 or its vaporized component is discharged. In this embodiment, the liquid fuel 62 is discharged from the fuel discharge port 54.

  The fuel diffusion portion 16 is disposed between the anode 21 and the fuel distribution mechanism 15. The fuel diffusion unit 16 diffuses the liquid fuel 62 supplied from the fuel distribution mechanism 15 and discharges it to the anode 21. The fuel diffusion portion 16 is provided as necessary.

  The fuel diffusion portion 16 is formed in a sheet shape. The fuel diffusion part 16 is disposed on the fuel discharge surface 51S. As described above, after the fuel is further diffused by the fuel diffusion portion 16, the fuel (vaporized fuel) is supplied from the fuel diffusion portion 16 to the anode 21.

  The liquid fuel 62 discharged from the fuel discharge port 54 is supplied to the anode 21 after being diffused in the surface direction. For this reason, the supply amount of the liquid fuel 62 can be averaged, and the liquid fuel 62 can be evenly diffused to the anode 21 regardless of the direction or position. For this reason, the uniformity of the power generation reaction in the membrane electrode assembly 10 can be enhanced.

  That is, the fuel distribution in the plane of the anode 21 is leveled, and the fuel required for the power generation reaction in the membrane electrode assembly 10 can be supplied as a whole without excess or deficiency. Therefore, it is possible to efficiently generate a power generation reaction in the membrane electrode assembly 10 without increasing the size or complexity of the fuel cell. As a result, the output of the fuel cell can be improved. In other words, the output and its stability can be improved without impairing the advantages of a passive fuel cell that does not circulate fuel.

  The moisturizing plate 18 is located outside the membrane electrode assembly 10 and is disposed to face the cathode gas diffusion layer 26. The moisturizing plate 18 impregnates part of the water generated in the cathode catalyst layer 25 to suppress water evaporation and uniformly introduce an oxidant into the cathode gas diffusion layer 26, so that the cathode catalyst layer 25 has a function of promoting uniform diffusion of the oxidant (air) to 25. The moisturizing plate 18 is made of, for example, a porous member, and specific constituent materials include polyethylene and polypropylene porous bodies. In this embodiment, the moisture retention plate 18 is a foamed polyethylene sheet.

  The cover plate 19 is located on the opposite side of the cathode current collector 34 with respect to the moisture retention plate 18. The cover plate 19 is substantially box-shaped in appearance and exhibits heat dissipation. The cover plate 19 is made of, for example, stainless steel (SUS). The cover plate 19 has a plurality of air holes 19a for taking in air as an oxidant. The ventilation holes are provided in a matrix, for example.

  The side surfaces of the fuel diffusion portion 16, the anode support plate 12, the membrane electrode assembly 10, the anode current collector 31, the cathode current collector 34, and the moisture retention plate 18 described above are covered with the peripheral wall 52. The cover plate 19 has, for example, a plurality of extending portions extending outward from the peripheral edge, and these extending portions are caulked or screwed to the outer surface of the container 50.

The pair of fuel cell main bodies 5 are arranged so that the anodes 21 face each other. In this embodiment, the pair of fuel cell modules 1 are arranged so that the anodes 21 face each other.
The fuel cell main body 5 is formed as described above.

  As shown in FIGS. 2 to 5 and FIG. 8, the pump 7 is attached to the outer surface of the container 50. In this embodiment, the pump 7 is a piezoelectric pump. The pump 7 is attached to the surface of the bottom wall 51 opposite to the fuel discharge surface 51S. The pump 7 is fixed to the bottom wall 51 by being screwed with a screw 7a. The pump 7 is connected to the fuel discharge port 56a and the fuel intake port 56b, respectively.

  The pump 7 sends the liquid fuel 62 introduced from the fuel discharge port 56a to the fuel intake port 56b. The pump 7 is not a circulation pump that circulates fuel, but a fuel supply pump that sends the liquid fuel 62 to the fuel intake port 56b. By supplying the liquid fuel 62 with such a pump 7 when necessary, the controllability of the fuel supply amount can be improved.

  The type of the pump 7 is not particularly limited, but from the viewpoint that a small amount of liquid fuel 62 can be fed with good controllability, and that further reduction in size and weight can be achieved, the above piezoelectric pump can be used. In addition, a rotary pump (rotary vane pump), an electroosmotic flow pump, a diaphragm pump, a squeezing pump, etc. can also be used.

  A rotary pump rotates a wing with a motor and feeds liquid. The electroosmotic flow pump uses a sintered porous material such as silica that causes an electroosmotic flow phenomenon. The diaphragm pump is a pump that feeds liquid by driving the diaphragm with an electromagnet or piezoelectric ceramics. The squeezing pump presses a part of the flexible fuel flow path and squeezes the fuel. Among these, it is more preferable to use an electroosmotic pump or a diaphragm pump having piezoelectric ceramics from the viewpoint of driving power, size, and the like.

  The pump 7 is operated when necessary to supply the liquid fuel 62 to the fuel supply unit 13. As described above, even when the liquid fuel 62 is fed to the fuel supply unit 13 by the pump 7, the fuel supply unit 13 functions effectively, so that the fuel supply amount to the membrane electrode assembly 10 can be made uniform. It becomes.

  As shown in FIGS. 5, 8, and 9, the valve 8 is attached to the outer surface of the container 50. In this embodiment, the valve 8 is a shutoff valve. The valve 8 is attached to the surface of the bottom wall 51 opposite to the fuel discharge surface 51S. The valve 8 is fixed to the bottom wall 51 by screwing a holding frame 8 a that presses the valve 8 against the bottom wall 51 with a screw 8 b. The valve 8 is connected to the fuel discharge port 55a and the fuel intake port 55b, respectively.

  The valve 8 is connected to the pump 7 through a thin tube 57b. The valve 8 switches between opening and closing whether the liquid fuel 62 introduced from the fuel discharge port 55a is fed to the fuel intake port 55b. The valve 8 controls the amount of liquid fuel 62 given to the pump 7.

  The valve 8 increases the stability and reliability of the fuel cell. The valve 8 can also avoid the consumption of a small amount of fuel inevitably generated even when the fuel cell is not used, the above-described suction failure when the pump is restarted, and the like.

As shown in FIGS. 2 to 5 and 8, the controller 9 is attached to the outer surface of the container 50. In this embodiment, the control unit 9 is a power conversion circuit. The controller 9 is attached to the surface of the bottom wall 51 opposite to the fuel discharge surface 51S. The control unit 9 is fixed to the bottom wall 51. The controller 9 is electrically connected to the pump 7 by a wiring 9a. The control unit 9 is electrically connected to the valve 8 by a wiring 9b. The control unit 9 adjusts the amount of power generated by the electromotive unit 6 by controlling the operation of the pump 7 and the opening and closing of the valve 8.
The fuel cell module 1 is formed as described above.

As shown in FIGS. 2 and 9, the fuel supply source 2 includes a tank 61 as a fuel storage portion and a sleeve 63 as a casing that stores the tank 61. A liquid fuel 62 is accommodated in the tank 61. The tank 61 and the fuel injection port 53 are connected by a cylindrical pipe 64. For this reason, the liquid fuel 62 is introduced from the tank 61 to the fuel discharge surface 51S through the pipe 64, the thin pipe 57a, the valve 8, the thin pipe 57b, the pump 7, and the thin pipe 57c. As described above, the fuel supply source 2 is formed.
Although not shown in the drawing, the sleeve 63 has two openings 63h. The openings 63h are formed at positions corresponding to the fuel injection ports 53 of the fuel cell module 1, respectively.

  As shown in FIGS. 2, 3, and 9, the two heat radiating plates 70 as the heat radiating members are disposed between the pair of fuel cell main bodies 5, and are transmitted from the anode 21 side of the pair of fuel cell main bodies 5. Dissipate heat to the outside. The heat sink 70 is excellent in thermal conductivity. In this embodiment, the two heat radiating plates 70 are disposed between the pair of fuel cell modules 1, and release at least the secondary radiant heat transmitted from the anode 21 side of the pair of fuel cell modules 1 to the outside. The fuel cell module 1 and the heat dissipation plate 70 are opposed to each other with a gap therebetween.

  Each heat dissipation plate 70 has an opening 70h. The opening 70h is for securing a space for the valve 8 and the holding frame 8a through the valve 8 and the holding frame 8a.

  The case 3 has a partition plate 3a and a peripheral wall 3b. The partition plate 3a and the peripheral wall 3b are integrally formed. The partition plate 3a is located between the pair of fuel cell modules 1 (the pair of fuel cell main bodies 5). The peripheral wall 3b is provided on the outer edge of the partition plate 3a so as to surround the pair of fuel cell modules 1 (the pair of fuel cell main bodies 5).

  The case 3 accommodates a pair of fuel cell modules 1 (a pair of fuel cell main bodies 5) and two heat radiating plates 70. Case 3 is adjacent to fuel supply source 2. Case 3 is formed of resin.

  The case 3 has an opening 3h1 formed in the partition plate 3a and two openings 3h2 (all not shown) formed in the peripheral wall 3b. Here, the opening 3h1 faces the opening 70h. The opening 3h1 is for securing a space for the valve 8 and the holding frame 8a through the valve 8 and the holding frame 8a. The openings 3h2 face the openings 63h, respectively. The openings 3h2 are formed at positions corresponding to the fuel injection ports 53 of the fuel cell module 1, respectively.

  As shown in FIGS. 2 and 3, the set cover 80 is formed to cover the fuel cell module 1 and close the opening of the case 3. In the region facing the cover plate 19, the set cover 80 is excellent in air permeability and is formed so as to take in air as an oxidant.

  As shown in FIG. 3, the top frame 91 and the bottom frame 92 are disposed to face the outer surface of the case 3 (the peripheral wall 3b). The top frame 91 and the bottom frame 92 are for fixing the fuel supply source 2 and the like to the case 3 using fasteners (not shown).

  In this embodiment, the heat sink 70 is in contact with the top frame 91 and the bottom frame 92 through the opening 3h3 formed in the case 3 (the peripheral wall 3b). The top frame 91 and the bottom frame 92 function as other heat radiating members. The top frame 91 and the bottom frame 92 release heat transmitted from the heat dissipation plate 70 to the outside. That is, the secondary radiant heat transmitted from the anode 21 side of the pair of fuel cell modules 1 to the heat radiating plate 70 can be released not only from the heat radiating plate 70 but also from the top frame 91 and the bottom frame 92.

  As shown in FIG. 9, each pipe 64 is formed in an opening 63 h formed in the sleeve 63 and an opening 3 h 2 formed in the peripheral wall 3 b of the case 3, and the tank 61 and the fuel inlet 53 of each fuel cell module 1. Are linked.

As shown in FIGS. 1 to 3, the exterior cover 4 includes a front cover 4a, a rear cover 4b, side covers 4c and 4d, a top cover 4e, and a bottom cover 4f.
The side covers 4 c and 4 d face the outer surface of the set cover 80 and the outer surface of the fuel supply source 2. Note that vent holes are formed in the side covers 4c and 4d. The front cover 4a faces the peripheral wall 3b and contacts the side covers 4c and 4d. The rear cover 4b faces the fuel supply source 2 and contacts the side covers 4c and 4d.

  The top cover 4e is disposed to face the top frame 91, contacts the front cover 4a, the rear cover 4b, and the side covers 4c and 4d, and bundles them. The bottom cover 4f is disposed to face the bottom frame 92, contacts the front cover 4a, the rear cover 4b, and the side covers 4c and 4d, and bundles them.

  As described above, the pair of fuel cell modules 1, the fuel supply source 2, the case 3, the two heat dissipation plates 70, the two set covers 80, the top frame 91, the bottom frame 92, and the pipe 64. And the fuel cell provided with the exterior cover 4 is formed.

  Next, the mechanism of power generation by the fuel cell will be described. In the fuel cell, the liquid fuel 62 is supplied from the fuel supply source 2 to the pair of fuel cell modules 1, and the pair of fuel cell modules 1 generate power simultaneously.

  First, under the control of the control unit 9, the valve 8 is switched to the open state, the pump 7 is operated, and from the fuel supply source 2 through the pipe 64, the thin pipe 57a, the valve 8, the thin pipe 57b, the pump 7, and the thin pipe 57c. Liquid fuel 62 is introduced into the fuel discharge surface 51S. The liquid fuel 62 is diffused by the fuel discharge surface 51S and the fuel diffusion portion 16.

  Although not shown, the fuel supply unit 13 may include, for example, a gas-liquid separation membrane provided between the anode current collector 31 and the fuel diffusion unit 16. Thereby, the vaporization component of the fuel can be supplied to the anode gas diffusion layer 23 and the anode catalyst layer 22.

In the membrane electrode assembly 10, the fuel diffuses in the anode gas diffusion layer 23 and is supplied to the anode catalyst layer 22. When methanol fuel is used as the liquid fuel 62, an internal reforming reaction of methanol shown in the formula (1) occurs in the anode catalyst layer 22. When pure methanol is used as the methanol fuel, the water generated in the cathode catalyst layer 25 or the water in the electrolyte membrane 27 is reacted with methanol to cause the internal reforming reaction of the formula (1). Alternatively, the internal reforming reaction is caused by another reaction mechanism that does not require water.
CH ₃ OH + H ₂ O → CO ₂ + 6H ⁺ + 6e ⁻ (1)
Electrons (e ⁻ ) generated by this reaction are led to the outside from a terminal (not shown) connected to the anode current collector 31, and after operating a portable electronic device or the like as so-called electricity, the cathode current collector A terminal (not shown) connected to 34 is led to the cathode 24. Further, protons (H ⁺ ) generated by the internal reforming reaction of the formula (1) are guided to the cathode 24 through the electrolyte membrane 27. Air is supplied to the cathode 24 as an oxidant. Electrons (e ⁻ ) and protons (H ⁺ ) reaching the cathode 24 react with oxygen in the air in the cathode catalyst layer 25 according to the formula (2), and water is generated in accordance with this reaction.
6e ⁻ + 6H ⁺ + (3/2) O ₂ → 3H ₂ O (2)
As described above, power generation by the fuel cell is performed.

  Next, an example of a fuel cell that can suppress a decrease in output due to a temperature distribution between the anode 21 and the cathode 24 by releasing heat generated between the pair of fuel cell modules 1 (between the anodes 21) to the outside. The fuel cells of Examples 1 to 5 will be described as follows. In order to evaluate the outputs of the fuel cells of Examples 1 to 5, the fuel cells of Comparative Example 1 and Comparative Example 2 will also be described.

(Comparative Example 1)
First, the fuel cell of Comparative Example 1 will be described. The fuel cell does not include the partition plate 3a and the heat dissipation plate 70. The pair of fuel cell modules 1 are in contact with each other. Other configurations are formed in the same manner as the fuel cell of the above-described embodiment.

  When the temperature of the outer surface of the bottom wall 51 of the fuel cell of Comparative Example 1 configured as described above was measured, it was a relatively high temperature. This is because heat generated between the pair of fuel cell modules 1 cannot be released to the outside, and heat is trapped between the pair of fuel cell modules 1.

Further, when the output of the fuel cell of Comparative Example 1 was measured, a sufficient output could not be obtained. This is because the temperature on the anode side is higher than that on the cathode side, and the temperature between the anode and the cathode varies.
As described above, a fuel cell with high output could not be realized.

Example 1
Next, the fuel cell of Example 1 will be described.
As shown in FIG. 1 thru | or FIG. 9, the heat sink 70 is formed with the copper alloy board. The heat conductivity of the heat sink 70 formed of a copper alloy plate is 403 W / m · k. Other configurations are formed in the same manner as the fuel cell of the above-described embodiment.

  When the temperature of the outer surface of the bottom wall 51 of the fuel cell of Example 1 configured as described above was measured, it was lower than that of Comparative Example 1. This is because the heat radiating plate 70 can release the sub-radiant heat transmitted from the anode 21 side of the pair of fuel cell modules 1 to the outside. This is because, in particular, the heat dissipating area is increased by the top frame 91 and the bottom frame 92 as other heat dissipating members, and the heat dissipating effect is improved.

Moreover, when the output of the fuel cell of Example 1 was measured, a sufficiently high output was obtained as compared with Comparative Example 1. This is because an efficient power generation reaction can be caused in the electromotive unit 6 by suppressing the variation in temperature between the anode 21 and the cathode 24. Thereby, the output of the fuel cell and its stability can be enhanced.
As described above, a fuel cell with high output could be realized.

(Example 2)
Next, the fuel cell of Example 2 will be described.
The heat radiating plate 70 is formed of a stainless steel plate. The heat conductivity of the heat sink 70 made of stainless steel (SUS) is 15 W / m · k. Other configurations are formed in the same manner as the fuel cell of Example 1 described above.

  When the temperature of the outer surface of the bottom wall 51 of the fuel cell of Example 2 configured as described above was measured, it was lower than that of Comparative Example 1. This is because the heat conductivity of the heat radiating plate 70, the top frame 91, and the bottom frame 92 can be obtained, although the heat conductivity of the heat radiating plate 70 is lower and the temperature drop is smaller than that of the first embodiment.

  Moreover, when the output of the fuel cell of Example 2 was measured, a sufficiently high output was obtained compared to Comparative Example 1. This is because an efficient power generation reaction can be caused in the electromotive unit 6 by suppressing the variation in temperature between the anode 21 and the cathode 24. Thereby, the output of the fuel cell and its stability can be enhanced.

Furthermore, since the heat sink 70 formed of stainless steel (SUS) is excellent in rigidity, the rigidity of the fuel cell can be sufficiently ensured.
As described above, a fuel cell with high output could be realized.

(Example 3)
Next, the fuel cell of Example 3 will be described.
The heat radiating plate 70 is formed of an aluminum alloy plate. The heat conductivity of the heat sink 70 made of an aluminum alloy is 236 W / m · k. Other configurations are formed in the same manner as the fuel cell of Example 1 described above.

  When the temperature of the outer surface of the bottom wall 51 of the fuel cell of Example 3 configured as described above was measured, it was lower than that of Comparative Example 1. This is because the effect of heat conduction by the heat radiating plate 70 equivalent to that in Example 1 could be obtained.

  Further, when the output of the fuel cell of Example 3 was measured, it was sufficiently higher than that of Comparative Example 1, and an output equivalent to that of Example 1 could be obtained. This is because an efficient power generation reaction can be caused in the electromotive unit 6 by suppressing the variation in temperature between the anode 21 and the cathode 24. Thereby, the output of the fuel cell and its stability can be enhanced.

Furthermore, since the heat dissipation plate 70 formed of an aluminum alloy has higher strength than the heat dissipation plate formed of a copper alloy (Example 1), the rigidity of the fuel cell can be sufficiently ensured as compared with Example 1.
As described above, a fuel cell with high output could be realized.

Example 4
Next, a fuel cell of Example 4 will be described.
The fuel cell does not include the heat radiating plate 70 as a heat radiating member. The fuel cell includes two heat pipes (not shown) as heat radiating members. The heat pipe is formed in a cylindrical shape. Each heat pipe is attached to the outer surface of the fuel cell module 1 (fuel cell body 5) on the side facing the anode 21. Each heat pipe is in contact with the top frame 91 and the bottom frame 92 through the opening 3h3 formed in the case 3 (the peripheral wall 3b). Other configurations are formed in the same manner as the fuel cell of the above-described embodiment.

  When the temperature of the outer surface of the bottom wall 51 of the fuel cell of Example 4 configured as described above was measured, the value was lower than that of Comparative Example 1. This is because heat transmitted from the anode 21 side of the pair of fuel cell modules 1 can be released to the outside by a heat pipe method.

Moreover, when the output of the fuel cell of Example 4 was measured, a sufficiently high output was obtained compared to Comparative Example 1. This is because an efficient power generation reaction can be caused in the electromotive unit 6 by suppressing the variation in temperature between the anode 21 and the cathode 24. Thereby, the output of the fuel cell and its stability can be enhanced.
Since it is difficult to form the heat pipe in a plate shape, the fuel cell is increased in size, but from the above, a high-output fuel cell can be realized.

(Example 5)
Next, a fuel cell of Example 5 will be described.
As shown in FIGS. 10 and 11, the fuel cell further includes a heat conductive tape 100. The heat conductive tape 100 is made of, for example, aluminum as a material exhibiting heat conductivity. The heat conductive tape 100 is affixed to the outer surface of the container 50 and affixed to the cover plate 19. Here, the heat conductive tape 100 covers the outer surface of the pump 7 and passes between the container 50 and the control unit 9.

  The heat conductive tape 100 conducts heat from the fuel cell module 1 (fuel cell body 5) on the side facing the anode 21 to the cover plate 19. As described above, the cover plate 19 is made of stainless steel (SUS) that exhibits heat dissipation. Other configurations are formed in the same manner as the fuel cell of the above-described embodiment.

  When the temperature of the outer surface of the bottom wall 51 of the fuel cell of Example 5 configured as described above was measured, it was lower than that of Comparative Example 1. This is because heat generated on the anode 21 side of the pair of fuel cell modules 1 is (2) incidentally incident on the heat radiating plate 70, and the top frame 91 and the bottom frame 92 release heat transmitted from the heat radiating plate 70 to the outside. 2) It is transmitted to the cover plate 19 (cathode 24 side) via the heat conductive tape 100.

Further, when the output of the fuel cell of Example 5 was measured, a sufficiently high output was obtained as compared with Comparative Example 1. This is because an efficient power generation reaction can be caused in the electromotive unit 6 by suppressing the variation in temperature between the anode 21 and the cathode 24. Thereby, the output of the fuel cell and its stability can be enhanced.
As described above, a fuel cell with high output could be realized.

(Comparative Example 2)
Next, the fuel cell of Comparative Example 2 will be described. The fuel cell includes a fan (not shown) instead of the heat radiating plate 70. The fuel cell module 1 (fuel cell main body 5) on the side facing the anode 21 is cooled by an air cooling method. Other configurations are formed in the same manner as the fuel cell of the above-described embodiment.

When the temperature of the outer surface of the bottom wall 51 of the fuel cell of Comparative Example 1 configured as described above was measured, it was lower than that of Comparative Example 1. However, since the fan is driven, power is lost and a sufficient output cannot be obtained.
Since the structure is provided with a fan, the fuel cell is increased in size and, as described above, a fuel cell with high output cannot be realized.

  According to the fuel cell configured as described above, the fuel cell includes a pair of fuel cell main bodies 5 disposed so that the anodes 21 face each other, and a heat radiating member. Each fuel cell main body 5 includes an electromotive unit 6 and a fuel distribution mechanism 15.

  The electromotive unit 6 includes a membrane electrode assembly 10 including an anode 21, a cathode 24, and an electrolyte membrane 27. The fuel distribution mechanism 15 is provided with fuel thin tubes 57a, 57b, 57c, a fuel discharge surface 51S located on the surface facing the anode 21, and a part of the fuel discharge surface 51S being opened and a thin tube 57c. And a fuel discharge port 54 for discharging the fuel.

  The heat dissipating member is disposed between the pair of fuel cell main bodies 5 and discharges at least a secondary radiant heat transmitted from the anode 21 side of the pair of fuel cell main bodies 5 to the outside. The heat radiating member is the heat radiating plate 70 in the first to sixth embodiments and the eighth embodiment, and is a heat pipe in the seventh embodiment.

  By the heat dissipating member (heat dissipating plate 70, heat pipe), the secondary heat transmitted from the anode 21 side of the pair of fuel cell modules 1 can be released to the outside, and the temperature variation between the anode 21 and the cathode 24 can be suppressed. For this reason, the sub-radiant heat transmitted from the anode 21 side of the pair of fuel cell modules 1 can be released to the outside.

The heat transmitted from the heat dissipation plate 70 can be released to the outside by the top frame 91 and the bottom frame 92 as other heat dissipation members. Compared with the case where the heat radiating plate 70 is not in contact with the top frame 91 and the bottom frame 92, the temperature variation between the anode 21 and the cathode 24 can be further suppressed. For this reason, the secondary radiant heat transmitted from the anode 21 side of the pair of fuel cell modules 1 can be further released to the outside.
For this reason, the auxiliary heat transmitted from the anode 21 side of the pair of fuel cell modules 1 can be released to the outside. Thereby, the output of the fuel cell and its stability can be enhanced.

In the fifth embodiment, heat can be transferred from the fuel cell module 1 (fuel cell body 5) on the side facing the anode 21 to the cover plate 19 by the heat conductive tape 100. Compared with the case where the heat conductive tape 100 is not provided, the temperature variation between the anode 21 and the cathode 24 can be further suppressed.
As described above, a fuel cell excellent in output characteristics can be obtained.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiments. For example, some components may be deleted from all the components shown in the embodiment.

  For example, the fuel cell may include a pair of fuel cell main bodies 5 arranged so that the anodes 21 face each other. For this reason, the pump 7, the valve 8, and the control unit 9 may not be located between the fuel cell main bodies 5.

  A configuration in which the fuel cell module 1 (fuel cell main body 5) on the side facing the anode 21 and the heat radiating plate 70 are in contact, and heat is directly conducted from the fuel cell module 1 (fuel cell main body 5) to the heat radiating plate 70. It may be. The heat radiating plate 70 may be configured so that the heat conductive tape 100 is in contact therewith.

The heat radiating member (heat radiating plate 70, heat pipe) may be connected to at least one of the top frame 91 and the bottom frame 92.
The other heat radiating members are not limited to the top frame 91 and the bottom frame 92, and may be any heat radiating body disposed facing the outer surface of the case 3.

  The heat dissipating member is not limited to the heat dissipating plate 70 and the heat pipe, but is disposed between the pair of fuel cell main bodies 5 and discharges at least the secondary radiant heat transmitted from the anode 21 side of the pair of fuel cell main bodies 5 to the outside. What is necessary is just to be formed.

  The present invention is not limited to a direct methanol fuel cell but can be applied to other fuel cells. The liquid fuel 62 is not necessarily limited to methanol fuel. The liquid fuel 62 is effective when various liquid fuels are used, and the type and concentration of the liquid fuel are not limited.

  Also, the liquid fuel supplied to the membrane electrode assembly 10 may be supplied entirely with the vapor of the liquid fuel, but the present invention can be applied even when a part of the liquid fuel is supplied in a liquid state. it can.

DESCRIPTION OF SYMBOLS 1 ... Fuel cell module, 2 ... Fuel supply source, 3 ... Case, 3a ... Partition plate, 3b ... Perimeter wall, 4 ... Exterior cover, 5 ... Fuel cell main body, 6 ... Electromotive part, 7 ... Pump, 8 ... Valve, DESCRIPTION OF SYMBOLS 9 ... Control part, 10 ... Membrane electrode assembly, 13 ... Fuel supply part, 15 ... Fuel distribution mechanism, 19 ... Cover plate, 20 ... Power generation element, 21 ... Anode, 24 ... Cathode, 27 ... Electrolyte membrane, 50 ... Container ,
51 ... bottom wall, 51S ... fuel discharge surface, 52 ... peripheral wall, 53 ... fuel inlet, 54 ... fuel outlet, 57a, 57b, 57c ... thin tube, 61 ... tank, 62 ... liquid fuel, 70 ... heat sink, 91 ... top frame, 92 ... bottom frame, 100 ... heat conduction tape.

Claims (7)

An electromotive portion having a membrane electrode assembly including an anode, a cathode, and an electrolyte membrane sandwiched between the anode and the cathode, a fuel discharge surface located on a surface facing the anode, and the fuel A fuel distribution mechanism provided with a part of the discharge surface opened and having a fuel discharge port for discharging fuel, and a pair of fuel cell main bodies arranged so that the anodes face each other;
A fuel cell comprising: a heat dissipating member that is disposed between the pair of fuel cell main bodies and that releases at least a secondary radiant heat transmitted from an anode side of the pair of fuel cell main bodies to the outside.   The fuel cell according to claim 1, wherein the heat radiating member is formed of a heat radiating plate.   The fuel cell according to claim 1, wherein the heat radiating member is made of an aluminum alloy. A case housing the pair of fuel cell main bodies and the heat dissipation member;
2. The fuel according to claim 1, further comprising: another heat dissipating member disposed opposite to an outer surface of the case, contacting the heat dissipating member, and releasing heat transmitted from the heat dissipating member to the outside. battery. A partition plate located between the pair of fuel cell main bodies, and a peripheral wall provided at an outer edge of the partition plate so as to surround the pair of fuel cell main bodies, and accommodates the pair of fuel cell main bodies and the heat dissipation member. A case,
2. The fuel cell according to claim 1, wherein each of the heat radiating members is formed of a pair of heat radiating plates provided between the partition plate and the fuel cell main body.   The pair of fuel cell main bodies are attached to the outer surface of the heat-dissipating cover plate and the fuel distribution mechanism, which are positioned to face the cathode, and are attached to the cover plate and face the anode. 2. The fuel cell according to claim 1, further comprising a heat conductive tape for transferring heat from the fuel cell body on the side to the cover plate. 3.   The fuel cell according to claim 6, wherein the heat conductive tape is made of aluminum.

Images