JP4796750B2 - Fuel cell - Google Patents

Description

  The present invention relates to a fuel cell, and more particularly to a small fuel cell suitable for use as a power source for portable electronic devices such as a mobile phone, a notebook computer, and a PDA.

  In general, a fuel cell includes a fuel cell in which an air electrode layer, an electrolyte layer, and a fuel electrode layer are stacked, a fuel supply unit for supplying fuel as a reducing agent to the fuel electrode layer, and an oxidant for the air electrode layer. As a battery, various types of batteries are used to generate an electrochemical reaction in the fuel cell by the fuel and oxygen in the air to obtain electric power outside. Things are being developed.

In recent years, due to increasing awareness of environmental issues and energy conservation, the use of fuel cells as clean energy sources for various applications has been studied. In particular, power can be generated simply by supplying liquid fuel containing methanol and water directly. Fuel cells have attracted attention (see, for example, Patent Documents 1 and 2).
Among these, each liquid fuel cell etc. which utilized capillary force for supply of liquid fuel are known (for example, refer to patent documents 3-7).
Since the liquid fuel cell described in each of these patent documents supplies liquid fuel from a fuel tank to the fuel electrode by capillary force, there is an advantage in downsizing such as not requiring a pump for pumping liquid fuel.

  However, although the liquid fuel cell using only the capillary force of the porous body and / or fiber bundle provided in the fuel storage tank is suitable for downsizing in terms of configuration, the fuel is directly liquid at the fuel electrode. Because it is supplied in a state, it is mounted on a small portable device, and in a usage environment where the front, back, left, right, top and bottom of the battery part constantly changes, fuel tracking becomes incomplete during a long period of use, causing problems such as shutting off the fuel supply This is a cause of hindering the constant supply of fuel to the electrolyte layer.

  Further, as one of solutions to these drawbacks, for example, after introducing liquid fuel into the cell by capillary force, the liquid fuel is vaporized in the fuel vaporization layer and used (for example, Patent Document 8). However, there is a problem that the lack of fuel followability, which is a basic problem, has not been improved, and a fuel cell of this structure is used as a fuel after vaporizing a liquid For this reason, there are problems such as difficulty in miniaturization.

As described above, in the conventional fuel cell, when the liquid fuel is supplied directly to the fuel electrode, the fuel supply is unstable and the output value during operation varies, or the stable output is maintained. At present, it is difficult to reduce the size to the extent that it can be mounted.
In addition, when a normal resin, such as polyethylene, is used as the material of the fuel tank, the resin itself permeates liquid fuel during long-term storage, and from the joints of the fuel tank components. It is conceivable that liquid fuel may evaporate and leak, resulting in fuel loss. Here, in order to prevent the evaporation and leakage of the fuel, if the resin members are formed so as to be thick enough to prevent evaporation and leakage, the purpose of reducing the size of the fuel cell body cannot be achieved. Or the subject that it becomes difficult to check the remaining amount of liquid fuel arises. Furthermore, when a material such as metal or glass is used as the material constituting the fuel tank, it is impossible to check the remaining amount of fuel in the metal because it is not possible to check the remaining amount of fuel in the fuel tank. In the case of glass, there are problems such as troublesome management at the time of processing and assembly and high cost, and deformation and destruction easily occur.
JP-A-5-258760 (Claims, Examples, etc.) JP-A-5-307970 (Claims, Examples, etc.) JP 59-66066 A (Claims, Examples, etc.) JP-A-6-188008 (Claims, Examples, etc.) JP 2003-229158 A (Claims, Examples, etc.) JP 2003-299946 A (Claims, Examples, etc.) JP-A-2003-340273 (Claims, Examples, etc.) JP 2001-102069 A (Claims, Examples, etc.)

  The present invention has been made in order to solve the above-described problems and current situation of the conventional fuel cell, and stably supplies liquid fuel directly to the fuel electrode of the fuel cell main body to An object of the present invention is to provide a fuel cell that can be easily visually recognized, has no loss of liquid fuel during storage, and can be downsized.

  As a result of intensive studies on the above-described conventional problems, the present inventors have a fuel cell main body and a fuel storage tank that stores liquid fuel that can be connected to the fuel cell main body. Is a fuel cell which is a cartridge structure in which liquid fuel is supplied via a fuel supply body connected to the fuel storage tank and the fuel storage tank is replaceable, and the cartridge structure has a specific structure As a result, the above-described fuel cell was successfully obtained and the present invention was completed.

That is, the present invention resides in the following (1) to (12).
(1) A fuel cell main body and a fuel storage tank for storing liquid fuel that can be connected to the fuel cell main body. The fuel cell main body is liquid via a fuel supply body connected to the fuel storage tank. A fuel cell having a cartridge structure in which fuel is supplied and the fuel storage tank is replaceable. The cartridge structure includes a fuel storage container that stores liquid fuel, a fuel outflow portion, and fuel consumption. A fuel cell comprising: a moving follower; and the liquid fuel inside the cartridge structure is visible.
(2) The fuel cell main body is constructed by constructing an electrolyte layer on the outer surface of the fuel electrode body, and connecting a plurality of unit cells formed by constructing an air electrode layer on the outer surface of the electrolyte layer. The fuel cell according to (1), wherein the cell is connected to a fuel supply body connected to a fuel storage tank to supply liquid fuel.
(3) The fuel cell according to (1) or (2), wherein the fuel container is made of a gas-impermeable material.
(4) As described in any one of the above (1) to (3), in the fuel container, at least a wall surface in contact with the liquid fuel is adjusted to be lower than a surface free energy of the liquid fuel. Fuel cell.
(5) The fuel cell according to any one of (1) to (4), wherein the fuel container is made of a material having a light transmittance of 50% or more.
(6) The fuel container is formed of a material having an oxygen gas permeability of 100 cc · 25 μm / m ² · 24 hr · atm (25 ° C., 65% RH) or less. The fuel cell according to any one of 5).
(7) Gas impermeable material is polyvinyl alcohol, ethylene / vinyl alcohol copolymer resin, polyacrylonitrile, nylon, cellophane, polyethylene terephthalate, polycarbonate, polystyrene, polyvinylidene chloride, polyvinyl chloride alone or two or more gases The fuel cell as described in (6) above, which is made of an impermeable resin.
(8) The fuel container has a multilayer structure having two or more resin layers, and at least one of the resin layers is a gas-impermeable resin, any one of the above (1) to (7) A fuel cell according to any one of the above.
(9) The fuel cell according to any one of (1) to (8), wherein the fuel container has a multilayer structure formed by applying a gas-impermeable resin.
(10) The fuel cell as described in (8) or (9) above, wherein the thickness of the gas-impermeable resin layer is 10 to 2000 μm.
(11) The fuel cell according to any one of (1) to (10), wherein the fuel container is covered with a gas-impermeable thin film member.
(12) The fuel cell according to (11), wherein the gas-impermeable thin film member is at least one selected from metal foil, metal oxide deposit, and diamond-like carbon coating.
In addition, the "light transmittance" prescribed | regulated by this invention (including the Example etc. mentioned later) means the light transmittance measured by prescription | regulation by JISK7105-1981.

According to the present invention, liquid fuel is stably supplied directly from the cartridge structure serving as a fuel storage tank to the fuel cell main body, the use state of the fuel can be easily visually confirmed, there is no loss of liquid fuel during storage, and A fuel cell capable of reducing the size of the fuel cell is provided.
According to the second to twelfth aspects of the present invention, it is possible to obtain a fuel cell in which the use status of the fuel can be visually recognized more easily and the loss of liquid fuel is extremely small during storage.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
1 to 3 show a basic form (first embodiment) of a fuel cell (hereinafter simply referred to as “fuel cell”) A showing a basic embodiment of the present invention.
As shown in FIGS. 1 to 3, the fuel cell A includes a fuel storage tank 10 that stores liquid fuel, and an electrolyte layer 23 on the outer surface of a fuel electrode body 21 made of a microporous carbon body. A fuel supply having a unit cell (fuel cell) 20, 20 to be a fuel cell body formed by constructing an air electrode layer 24 on the outer surface of the layer 23, and an infiltration structure connected to the fuel storage tank 10 A unit 30 and a spent fuel storage tank 40 provided at the end of the fuel supply body 30, and the unit cells 20, 20 serving as the fuel cell body are connected in series so that fuel is sequentially supplied by the fuel supply body 30. The fuel storage tank 10 is composed of a replaceable cartridge structure.
The cartridge structure 10 serving as a fuel storage tank includes a tube-type fuel storage container 12 that stores liquid fuel 11, a fuel outflow portion 13, and a follower 14 that moves as fuel is consumed, and the cartridge structure 10. The internal fuel is visible and has a structure supported by a support 15 made of a resin having visibility.

Examples of the liquid fuel 11 stored in the fuel storage container 12 include a methanol liquid composed of methanol and water, and hydrogen ions (H ⁺ ) are efficiently generated from a compound supplied as fuel in a fuel electrode body described later. As long as electrons (e ⁻ ) can be obtained, the liquid fuel is not particularly limited, and depends on the structure of the fuel electrode body, for example, dimethyl ether (DME), ethanol solution, formic acid, hydrazine, ammonia solution, etc. Liquid fuel can also be used.

  In this embodiment, as shown in FIGS. 1A to 1B and FIG. 2A, the liquid fuel 11 is directly stored, and becomes a fuel outflow portion at the lower part of the fuel storage container 12 that stores the liquid fuel 11. Fuel is supplied by a fuel supply body 30 inserted into the check valve 13.

The check valve serving as the fuel outflow portion 13 has the same configuration as a member used in a writing instrument and the like, and as shown in FIGS. A check valve body 13b having a slit portion 13a having a dome-like central portion for preventing foreign matters such as air entering the liquid fuel 11 directly contained from the periphery of the fuel supply pipe 31, and the check valve body It consists of a valve adapter 13c that supports 13b and a stopper body 13d that holds the check valve body 13b, and has a structure that prevents foreign substances such as air from entering even when it is not used (not used). . This is to prevent accidents such as fuel leakage and jetting due to an increase in pressure in the liquid fuel storage tank 10 due to intrusion of air or the like.
The check valve 13 including these check valve bodies 13 b is made of a material having storage stability, durability, gas impermeability, and elasticity that can be in close contact with the fuel supply pipe 31 with respect to the liquid fuel contained therein. If there is, there is no particular limitation, polyvinyl alcohol, ethylene-vinyl alcohol copolymer resin, polyacrylonitrile, nylon, cellophane, polyethylene terephthalate, polycarbonate, polystyrene, polyvinylidene chloride, polyvinyl chloride and other synthetic resins, natural rubber, isoprene Rubber, butadiene rubber, 1,2-polybutadiene rubber, styrene-butadiene rubber, chloroprene rubber, nitrile rubber, butyl rubber, ethylene-propylene rubber, chlorosulfonated polyethylene, acrylic rubber, epichlorohydrin rubber, polysulfide rubber, silicone rubber, fluorine rubber Rubber such as urethane rubber, elastomer and the like, can be produced by such conventional injection molding and vulcanization.

Moreover, as a material of the tube-type fuel storage container 12 constituting the fuel storage tank wall surface, storage stability, durability, and gas impermeability with respect to the liquid fuel to be stored are the same as the check valve described above. (Gas impermeability to oxygen gas, nitrogen gas, etc.) is required. Furthermore, light transmittance is required so that the remaining amount of liquid fuel can be visually recognized.
The light transmittance with which the remaining amount of the liquid fuel can be visually recognized is visible regardless of the material and its thickness, as long as the light transmittance is 50% or more. Preferably, if there is light transmittance of 80% or more, there is no practical problem, and the visibility of the liquid fuel is further improved.
Further, for preventing leakage and evaporation of liquid fuel, and preventing air or the like from entering the fuel storage tank, it is preferable that the material is made of a gas-impermeable material, more preferably oxygen gas permeability (oxygen gas impermeability). If it is 100 cc · 25 μm / m ² · 24 hr · atm (25 ° C., 65% RH) or less, there is no problem in practical use.

As a material of the fuel container 12 (including the fuel supply pipe 31), if light transmittance is not required, possible materials include metals such as aluminum and stainless steel, synthetic resins, and glass. In view of the visibility of the remaining amount of liquid fuel, gas impermeability, cost reduction during production and assembly, and ease of production, polyvinyl alcohol, ethylene / vinyl alcohol copolymer resin, polyacrylonitrile, nylon, cellophane are preferred. , Polyethylene terephthalate, polycarbonate, polystyrene, polyvinylidene chloride, polyvinyl chloride, and the like are preferably used alone or in combination of two or more resins, and more preferably these resins have a light transmittance of 50% or more. In particular, it is desirable to select a material that is 80% or more
Particularly preferred are polyvinyl alcohol, ethylene / vinyl alcohol copolymer resin, polyacrylonitrile, cellophane, and polyvinylidene chloride, which are gas impermeable and have a light transmittance of 80% or more.

The fuel container 12 preferably has a multilayer structure of two or more layers, and at least one layer is composed of two or more layers composed of the above-described resin group having gas impermeability and light transmittance. A multilayer structure is desirable. If at least one layer of the multilayer structure is made of a resin having the above-described performance (gas permeability), the remaining layers may be ordinary resins without any problem in practical use. Such a tube having a multilayer structure can be manufactured by extrusion molding, injection molding, coextrusion molding or the like.
Further, instead of at least one gas-impermeable layer provided by these moldings, a gas-impermeable layer can be provided by applying a resin solution selected from the resin group described above. In this coating method, it is possible to sequentially manufacture without requiring special manufacturing equipment as compared with manufacturing by molding such as extrusion molding and injection molding.

The gas impermeable layer provided by each of these molding methods and application is preferably 10 to 2000 μm thick. When the thickness is less than 10 μm, gas impermeability cannot be exhibited. On the other hand, when the thickness exceeds 2000 μm, the performance of the entire container such as light transmittance and flexibility is deteriorated.
Moreover, it can coat | cover with gas-impermeable thin film members, such as a gas-impermeable film, instead of the gas-impermeable layer by shaping | molding or application | coating mentioned above. The gas-impermeable thin film member to be coated preferably includes at least one selected from metal foils such as aluminum foils, metal oxide deposits such as alumina and silica, and diamond-like carbon coatings. By covering the outer surface portion of the fuel container 12 with the thin film member, the gas impermeability as described above can be exhibited. In addition, as for the thickness of this impervious thin film member, it is desirable to set it as 10-2000 micrometers similarly to the above. Further, the gas-impermeable thin film member member having no visibility, for example, in the case of such Aluminum foil, grid-like, by coating in stripes or the like can be ensured visibility and gas impermeability.

  The fuel storage container 12, the check valve 13 serving as a fuel outflow portion, and the fuel supply pipe 31 are joined by fitting or the like. At this time, when each member is higher than the surface free energy of the liquid fuel, the possibility that the liquid fuel leaks is likely to easily enter the gap of the joint. Therefore, it is desirable that at least the wall surfaces of these members in contact with the liquid fuel are adjusted to be lower than the surface free energy of the liquid fuel. This adjustment method can be performed by applying a water repellent film forming process to a wall surface in contact with the liquid fuel, such as a fuel container, by a coating using a silicon-based or fluorine-based water repellent.

The follower 14 contacts the rear end surface of the liquid fuel stored in the fuel storage container 12 and moves with fuel consumption, and prevents the fuel in the fuel storage container from leaking and evaporating. It is.
Examples of the material of the follower 14 include petroleum oils such as mineral oil, polyglycol, polyester, polybutene, and silicone oil, aliphatic metal soap, modified clay, silica gel, carbon black, natural or synthetic rubber, and various synthetic polymers. Examples thereof include those having a viscosity increased by adding a solvent or the like.
The follower 14 is required not to be dissolved or diffused in the liquid fuel 11. In the case where the liquid fuel 11 is dissolved and diffused, the fuel in the fuel storage container 12 serving as a fuel storage tank leaks and evaporates, so that the liquid fuel 11 cannot serve as a fuel storage tank. It is conceivable that the substances constituting the follower 14 enter the fuel electrode of the fuel cell and adversely affect the reaction. Further, it is desirable that the follower 14 has a surface free energy lower than that of the liquid fuel 11. As in the case of the fuel container 12, the check valve 13, and the fuel supply pipe 31, the fuel container 12, the follower 14, and the like. It is possible to increase the possibility that liquid fuel can be prevented from entering and leaking outside. In view of these conditions, the material, surface state, and the like of the follower 14 can be selected as appropriate.
Further, a follow-up auxiliary member may be provided between the follower 14 and the liquid fuel 11 in order to prevent the follower 14 and the liquid fuel 11 from reversing.

  As shown in FIGS. 3A and 3B, each fuel cell (unit cell) 20 serving as a fuel cell main body has a fuel electrode body 21 made of a micro-columnar carbon porous body, and a central portion thereof. The structure has a through-hole 22 that penetrates the fuel supply body 30, an electrolyte layer 23 is constructed on the outer surface of the fuel electrode body 21, and an air electrode layer 24 is constructed on the outer surface of the electrolyte layer 23. Yes. A theoretical electromotive force of about 1.2 V is generated for each fuel cell 20.

  The fine columnar carbon porous body constituting the fuel electrode body 21 may be a porous structure having minute communication holes, and is composed of, for example, a three-dimensional network structure or a point-sintered structure, and includes amorphous carbon and carbon. Carbon composite molded body composed of powder, isotropic high-density carbon molded body, carbon fiber papermaking molded body, activated carbon molded body, etc., preferably, reaction control at the fuel electrode of the fuel cell is easy and reaction From the viewpoint of further improving efficiency, a carbon composite molded body having fine communication holes made of amorphous carbon and carbon powder is desirable.

The carbon powder used for the production of the carbon composite having the porous structure includes highly oriented pyrolytic graphite (HOPG), quiche graphite, natural graphite, artificial graphite, carbon nanotube, At least one (single or a combination of two or more) selected from fullerenes is preferred.
Further, a platinum-ruthenium (Pt-Ru) catalyst, an iridium-ruthenium (Ir-Ru) catalyst, a platinum-tin (Pt-Sn) catalyst, and the like are present on the outer surface of the fuel electrode body 21. For example, a solution containing a metal fine particle precursor, such as impregnation or dipping treatment, a reduction treatment, a metal fine particle electrodeposition method, or the like.

Examples of the electrolyte layer 23 include ion exchange membranes having proton conductivity or hydroxide ion conductivity, for example, fluorine ion exchange membranes including Nafion (Nafion, manufactured by Du Pont), heat resistance, Good suppression of methanol crossover, for example, a composite membrane using an inorganic compound as a proton conducting material and a polymer as a membrane material, specifically, using a zeolite as the inorganic compound and a styrene-butadiene system as the polymer Examples thereof include a composite film made of rubber, a hydrocarbon-based graft film, and the like.
As the air electrode layer 24, carbon having a porous structure in which platinum (Pt), palladium (Pd), rhodium (Rh) or the like is supported by a method using a solution containing the above-mentioned metal fine particle precursor or the like. A porous body is mentioned.

  The fuel supply body 30 is not particularly limited as long as the fuel supply body 30 is inserted into the check valve 13 of the fuel storage tank 10 and has a permeation structure capable of supplying the liquid fuel to each unit cell 20. For example, felt, sponge, etc. Or porous bodies having a capillary force composed of sintered bodies such as resin particle sintered bodies and resin fiber sintered bodies, natural fibers, animal hair fibers, polyacetal resins, acrylic resins, polyester resins , Polyamide resins, polyurethane resins, polyolefin resins, polyvinyl resins, polycarbonate resins, polyether resins, polyphenylene resins, and the like. The porosity and the like of these porous bodies and fiber bundles are appropriately set according to the supply amount to each unit cell 20.

The spent fuel storage tank 40 is disposed at the end of the fuel supply body 30. At this time, there is no problem even if the spent fuel storage tank 40 is brought into direct contact with the end of the fuel supply body 30 and the spent fuel is occluded directly by the occlusion body or the like. A porous body or a fiber bundle may be provided as a relay core to form a spent fuel discharge path.
Further, the liquid fuel supplied by the fuel supply body 30 is used for the reaction in the fuel battery cell 20, and the fuel supply amount is linked to the fuel consumption amount. There is almost no liquid fuel to be discharged, and unlike the conventional liquid fuel cell, there is no need for a processing system on the fuel outlet side, but liquid fuel that is not used for the reaction is stored in the event of excessive supply depending on the operating conditions. It has a structure that can be stored in the tank 40 to prevent the inhibition reaction.
In addition, 50 connects the fuel storage tank 10 and the spent fuel storage tank 40, and reliably supplies liquid fuel directly from the fuel storage tank 10 to each of the unit cells 20, 20 via the fuel supply body 30. It is a member made of a mesh structure or the like.

The fuel cell A of the present embodiment configured as described above is supplied from the fuel storage tank 10 to the fuel supply body 30 inserted into the check valve 13 serving as a fuel supply section or the fuel electrode body 21 having a permeation structure, Liquid fuel is introduced into the fuel cells 20 and 20 by any of the permeation structures.
In the present embodiment, the cartridge structure that can replace the fuel storage tank includes a fuel storage container that stores liquid fuel, a fuel outflow portion, and a follower that moves as the fuel is consumed, and the liquid inside the cartridge structure. Since the fuel can be visually recognized, the use state of the fuel can be easily visually recognized, and the follower does not lose liquid fuel during storage. Further, in the present embodiment, at least the fuel electrode body 21 and / or the fuel supply body 30 in contact with the fuel electrode body 21 has a capillary force, and the capillary force causes the unit cells 20 and 20 from the fuel storage tank 10 to have a capillary force. The liquid fuel can be supplied stably and continuously without causing direct backflow or interruption of the liquid fuel. More preferably, by setting the fuel electrode body 21 and / or the capillary force of the fuel supply body 30 in contact with the fuel electrode body 21 <the capillary force of the spent fuel storage tank 40 (relay core), the fuel storage tank 10, The liquid fuel can be made to flow stably and continuously without the direct flow or interruption of the direct flow from the unit cells 20, 20 to the spent fuel storage tank.
Moreover, in the fuel cell A of this embodiment, since it becomes a structure that can smoothly supply liquid fuel as it is without vaporization without using an auxiliary device such as a pump, a blower, a fuel vaporizer, and a condenser in particular, It becomes possible to reduce the size of the fuel cell.
The fuel cell A according to the first embodiment configured as described above has a permeation structure in which fuel is supplied to the unit cells 20 and 20 serving as the fuel cell main body directly connected from the end of the fuel storage tank 10. By connecting the fuel supply body 30, it is possible to achieve downsizing of the fuel cell composed of a plurality of cells.
Therefore, in the fuel cell A of the present embodiment, the entire fuel cell can be formed into a cartridge, and a small fuel cell that can be used as a power source for portable electronic devices such as a mobile phone and a notebook computer is provided. It becomes.
In addition, although the form which used the two fuel battery cells 20 was shown in the said embodiment, the required electromotive force etc. are increased by increasing the number of connection (series or parallel) of the fuel battery cells 20 by the use use of a fuel battery. It can be.

4 and 5 show a fuel cell B according to a second embodiment of the present invention. In the following embodiments, those that exhibit the same configuration and effects as the fuel cell A of the first embodiment are denoted by the same reference numerals as those in FIG.
As shown in FIGS. 4 and 5, this fuel cell B is connected to the fuel supply body 30 through a fuel supply pipe 31 inserted into the check valve 13, and a resin made of PP in the follower body 14. This is different from the fuel cell A of the first embodiment in that a follow-up assisting member 14a made of a body is provided.
Although not shown, the tip of the fuel supply body 30 (in the direction of the arrow in FIGS. 4 and 5) is connected in series or in parallel to the fuel cells 20, 20... As in the first embodiment. It has become.

  In the fuel cell B of the second embodiment configured as described above, the cartridge structure 10 in which the fuel storage tank can be replaced includes the fuel storage container 12 that stores the liquid fuel 11 and the fuel outflow portion 13 that includes a check valve. And the follower 14 that moves as the fuel is consumed, and the liquid fuel inside the cartridge structure can be visually recognized, so that the use state of the fuel can be easily seen and the follower does not lose liquid fuel during storage. As a result, the liquid force can be stably and continuously supplied from the fuel container 12 to each unit cell directly without backflow or interruption by the capillary force of the fuel supply body 30. Become.

The fuel cell of the present invention is not limited to the above embodiments, but can be variously modified within the scope of the technical idea of the present invention.
For example, the fuel cell 20 is a cylindrical one, but may have other shapes such as a prismatic shape or a plate shape, and the connection to the fuel supply body 30 is not only a series connection but also a parallel connection. It may be.
Moreover, in the said embodiment, although the non-return valve 13 shown to Fig.2 (a)-(d) was used as a fuel outflow part, the liquid fuel 11 accommodated directly in the fuel storage tank 10 by atmospheric pressure, temperature change, etc. In order to prevent foreign matters such as air entering from the periphery of the fuel supply pipe 31, the fuel supply body 30 is particularly limited as long as the fuel supply body 30 is inserted and the liquid fuel can be supplied to the fuel supply body 30. is not.
Furthermore, although the direct methanol type fuel cell has been described in the above embodiment, it has a fuel storage tank that stores liquid fuel that can be connected to the fuel cell body, and the fuel cell body is connected to the fuel storage tank. A fuel cell having a cartridge structure in which liquid fuel is supplied via a fuel supply body and the fuel storage tank is replaceable, wherein the cartridge structure contains a liquid fuel, and a fuel The present invention is not limited to the direct methanol fuel cell as long as it has an outflow portion and a follower that moves with fuel consumption and the liquid fuel inside the cartridge structure is visible. The present invention can also be suitably applied to a polymer-modified membrane type fuel cell including a modified type.
Furthermore, as the fuel cell body, an electrolyte layer was constructed on the outer surface portion of the fuel electrode body made of a fine carbon porous body, and the fuel cell body was constructed by constructing an air electrode layer on the outer surface portion of the electrolyte layer. The structure of the fuel cell body is not particularly limited. For example, a unit cell in which a carbonaceous porous body having electrical conductivity is used as a base material, and each layer of electrode / electrolyte / electrode is formed on the surface of the base material or the unit cell is provided. A fuel cell main body comprising two or more connected bodies, in which liquid fuel is infiltrated into the base material via a fuel supply body, and an electrode surface formed on the outer surface of the base material is exposed to air It is good.

  EXAMPLES Next, although an Example and a comparative example demonstrate this invention further in full detail, this invention is not limited to the following Example.

[Examples 1 to 5 and Comparative Example 1]
A tube-type fuel container (cartridge structure) having the following structure was produced.
Each fuel container obtained was filled with 2 g of a 30 wt% methanol aqueous solution, and then sealed with 0.2 g of a follower having the following composition. Thereafter, 10 mm ³ of air was injected and left at 50 ° C.-35% RH for 1 month, and the growth rate of bubbles was evaluated by the following evaluation method.
These results are shown in Table 1 below. The oxygen gas impermeability is a value at 25 ° C. and 65% RH.

(Configuration of fuel container: tubes 1 to 6)
Tube 1: length 100 mm, outer diameter 8 mm, inner diameter 6 mm, nylon extruded tube [light transmittance 90%, oxygen gas permeability 100 cc · 25 μm / m ² · 24 hr · atm]
Tube 2: length 100 mm, outer diameter 8 mm, inner diameter 6 mm, extruded tube made of polyvinyl chloride (light transmittance 80%, oxygen gas permeability 150 cc · 25 μm / m ² · 24 hr · atm)
Tube 3: Polyvinyl alcohol (oxygen gas permeability 0.1 cc · 25 μm / m ² · 24 hr · atm) applied to the outer surface portion, length 100 mm, outer diameter 8 mm, inner diameter 6 mm, polypropylene tube [light transmittance 95 %, Oxygen gas permeability 2500 cc · 25 μm / m ² · 24 hr · atm]. The film thickness of polyvinyl alcohol was 20 μm.
Tube 4: length 100 mm, outer diameter 8 mm, inner diameter 6 mm, ethylene / vinyl alcohol copolymer resin (EVOH: oxygen gas permeability 0.5 cc · 25 μm / m ² · 24 hr · atm layer (outer layer) and polypropylene (light transmission) 90% rate, oxygen gas permeability 2500 cc · 25 μm / m ² · 24 hr · atm] layer (inner layer) co-extruded tube (light transmittance 95%), EVOH layer thickness was 20 μm.
Tube 5: A tube in which a silica vapor deposition film (GL-N, manufactured by Toppan Printing Co., Ltd.) is wound around a polypropylene tube having a length of 100 mm, an outer diameter of 8 mm, and an inner diameter of 6 mm [light transmittance: 95%, oxygen gas permeability: 100 cc / 25 μm / m ² · 24 hr · atm].
Tube 6: length 100 mm, outer diameter 8 mm, inner diameter 6 mm, extruded tube made of polypropylene (light transmittance 95%, oxygen gas permeability 1,000 cc · 25 μm / m ² · 24 hr · atm (O ₂ , 25 ° C.)) )

Fuel discharge part (check valve, conforming to FIG. 2): Length 5 mm, outer diameter 6 mm, inner diameter 1 mm, made of butyl rubber Liquid fuel: 30% methanol solution methanol (specific gravity 0.95 g / cc)
Follower composition:
A gel follower (specific gravity 0.90 g / cc) having the following composition was used.
Mineral oil: Diana process oil MC-W90 (manufactured by Idemitsu Kosan) 93 parts by weight Hydrophobic silica: Aerosil R-974D 6 parts by weight (manufactured by Nippon Aerosil Co., Ltd., BET surface area 200 m ² / g)
Silicone surfactant: 1 part by weight of SILWET FZ-2171 (manufactured by Nihon Unicar)

(Evaluation method of bubble growth rate)
The bubble volume was obtained visually after standing for 1 month at 50 ° C.-35% RH, and evaluated according to the following evaluation criteria. The bubble growth rate was calculated based on the bubble volume before being left standing.
Evaluation criteria:
○: Bubbles did not grow or disappeared.
Δ: Bubble growth rate is less than 200%.
X: The bubble growth rate is 200% or more.

  As is clear from the results of Table 1 above, Examples 1 to 5 that are within the scope of the present invention have no or no growth of bubbles as compared with Comparative Example 1 that is outside the scope of the present invention. I found out. In Examples 1 to 5, it was found that as a fuel cell, there was no loss of liquid fuel during storage and the visibility was excellent.

(A) is schematic sectional drawing which shows the fuel cell of 1st Embodiment of this invention in a longitudinal cross-sectional aspect, (b) is sectional drawing which shows the replaceable cartridge structure used as a fuel storage tank in a longitudinal cross-sectional aspect. (A)-(d) shows the non-return valve used as the fuel outflow part of this invention, (a) is a longitudinal cross-sectional view of a non-return valve, (b) is a longitudinal cross-sectional view of a valve adapter, (c) ) Is a longitudinal sectional view of the check valve body, and (d) is a plan view of the check valve body. (A) is a perspective view of the fuel unit cell of the fuel cell of 1st Embodiment of this invention, (b) is a longitudinal cross-sectional view of a fuel unit cell. It is a fragmentary sectional view which shows the state before attachment of the exchangeable cartridge structure used as the fuel storage tank of the fuel cell which shows 2nd Embodiment of this invention. It is a fragmentary sectional view which shows the state which attached the replaceable cartridge structure used as the fuel storage tank of the fuel cell which shows 2nd Embodiment of this invention.

Explanation of symbols

A Fuel cell 10 Fuel storage tank (cartridge structure)
DESCRIPTION OF SYMBOLS 11 Liquid fuel 12 Fuel container 13 Fuel supply part 14 Follower body 20 Unit cell 30 Fuel supply body 40 Used fuel storage tank

Claims (12)

A fuel cell main body and a fuel storage tank for storing liquid fuel that can be connected to the fuel cell main body, and the fuel cell main body is supplied with liquid fuel via a fuel supply body connected to the fuel storage tank The fuel storage tank has a replaceable cartridge structure, and the cartridge structure includes a fuel storage container that stores liquid fuel, a fuel outflow portion, and a gel that moves with fuel consumption. And a liquid follower, and the liquid fuel inside the cartridge structure is visible.   The fuel cell main body is constructed by constructing an electrolyte layer on the outer surface of the fuel electrode body, and a plurality of unit cells formed by constructing an air electrode layer on the outer surface of the electrolyte layer. The fuel cell according to claim 1, wherein a fuel supply body connected to the fuel storage tank is connected to supply liquid fuel.   The fuel cell according to claim 1 or 2, wherein the fuel container is made of a gas-impermeable material.   The fuel cell according to any one of claims 1 to 3, wherein at least a wall surface in contact with the liquid fuel is adjusted to be lower than a surface free energy of the liquid fuel.   The fuel cell according to any one of claims 1 to 4, wherein the fuel container is made of a material having a light transmittance of 50% or more.   6. The fuel container according to claim 1, wherein the fuel container is made of a material having an oxygen gas permeability of 100 cc · 25 μm / m 2 · 24 hr · atm (25 ° C., 65% RH) or less. A fuel cell according to claim 1.   Gas impermeable material is polyvinyl alcohol, ethylene / vinyl alcohol copolymer resin, polyacrylonitrile, nylon, cellophane, polyethylene terephthalate, polycarbonate, polystyrene, polyvinylidene chloride, polyvinyl chloride alone or two or more types of gas impermeable The fuel cell according to claim 6, comprising a resin.   The fuel container has a multi-layer structure having two or more resin layers, and at least one of the resin layers is a gas-impermeable resin. Fuel cell.   The fuel cell according to any one of claims 1 to 8, wherein the fuel container has a multilayer structure formed by applying a gas-impermeable resin.   The fuel cell according to claim 8 or 9, wherein the gas-impermeable resin layer has a thickness of 10 to 2000 µm. The fuel cell according to any one of claims 1 to 10, wherein the fuel container is covered at least partially with a gas-impermeable thin film member. The fuel cell according to claim 11 , wherein the gas-impermeable thin film member is at least one selected from a metal foil, a metal oxide deposit, and a diamond-like carbon coating.

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