JP3740455B2 - Fuel cell container and fuel cell - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a small and highly reliable fuel cell container made of ceramics that can accommodate an electrolyte member, and a fuel cell using the same.
[0002]
[Prior art]
In recent years, development of small fuel cells that operate at a lower temperature than before has been actively conducted. Depending on the type of electrolyte used for the fuel cell, a polymer electrolyte fuel cell (hereinafter referred to as PEFC), a phosphoric acid fuel cell, or a solid electrolyte fuel cell is known. ing.
[0003]
Among them, PEFC has a low operating temperature of about 80-100 ° C.
(1) The output density is high, and it is possible to reduce the size and weight.
(2) Since the electrolyte is not corrosive and the operating temperature is low, since there are few restrictions on the battery constituent materials from the viewpoint of corrosion resistance, cost reduction is easy.
(3) Since it can be started at room temperature, the startup time is short.
It has excellent features such as For this reason, PEFC takes advantage of the above features, not only for driving power sources for vehicles and home cogeneration systems, but also for mobile phones, PDAs (Personal Digital Assistants), laptop computers, digital cameras, The use as a power source for portable electronic devices having an output of several watts to several tens of watts has been considered.
[0004]
The PEFC is roughly divided, for example, a fuel electrode (cathode) composed of a carbon electrode to which catalyst fine particles such as platinum and platinum-ruthenium are adhered, and an air electrode (anode) composed of a carbon electrode to which catalyst fine particles such as platinum are adhered, A film-like electrolyte member (hereinafter referred to as an electrolyte member) interposed between the fuel electrode and the air electrode is configured. Here, the fuel electrode is provided with hydrogen gas (H₂) Is supplied to the air electrode, while oxygen gas (O₂) Is generated (electric power generation) by the electrochemical reaction, and electric energy serving as a driving power source (voltage / current) for the load is generated.
[0005]
Specifically, hydrogen gas (H₂) Is supplied, as shown in the following chemical reaction formula (1), electrons (e^-) Separated hydrogen ions (protons; H⁺) Are generated and pass through the electrolyte member to the air electrode side, and electrons (e^-) Is taken out and supplied to the load.
3H₂ → 6H⁺+ 6e^- ... (1)
On the other hand, when air is supplied to the air electrode, as shown in the following chemical reaction formula (2), electrons (e^-) And hydrogen ions (H⁺) And oxygen gas (O₂) Reacts with water (H₂O) is generated.
6H⁺+ 3 / 2O₂+ 6e^- → 3H₂O (2)
Such a series of electrochemical reactions (formula (1) and formula (2)) proceeds at a relatively low temperature condition of approximately 80 to 100 ° C., and by-products other than electric power are basically water (H₂O) only.
[0006]
The ion conductive film (exchange membrane) constituting the electrolyte member is a polystyrene-based cation exchange membrane having a sulfonic acid group, a mixed membrane of fluorocarbon sulfonic acid and polyvinylidene fluoride, and trifluoroethylene grafted on a fluorocarbon matrix. Recently, a perfluorocarbon sulfonic acid membrane (for example, Nafion: trade name, manufactured by DuPont) or the like has been used.
[0007]
FIG. 3 is a cross-sectional view showing the configuration of a conventional fuel cell (PEFC). In the figure, 21 is a PEFC, 23 is an electrolyte member, 24 and 25 are arranged on the electrolyte member 23 so as to sandwich the electrolyte member, and a pair of porous electrodes functioning as a gas diffusion layer and a catalyst layer, that is, A fuel electrode and an air electrode, 26 is a gas separator, 28 is a fuel flow path, and 29 is an air flow path.
[0008]
The gas separator 26 is provided so as to penetrate the separator portion and the gas inflow / outflow frame that form the outer shape of the gas separator 26, the separator portion that separates the fuel passage 28 and the air passage 29, and the separator portion. The electrode member is configured to correspond to the fuel electrode 24 and the air electrode 25 of the electrolyte member 23. The fuel electrode 24 and the air electrode 25 of the electrolyte member 23 are stacked in large numbers via a gas separator 26 so that the fuel electrode 24 and the air electrode 25 are electrically connected in series and / or in parallel. A general PEFC body is a stack in which a stack is housed.
[0009]
A fuel gas containing water vapor (a gas rich in hydrogen) is supplied from the reformer to the fuel electrode 24 through the fuel flow path 28 formed in the gas separator 26, and the air electrode 25 is supplied to the atmosphere through the air flow path 29 in the atmosphere. Then, air is supplied as an oxidant gas, and power is generated by a chemical reaction in the electrolyte member 23.
[0010]
[Patent Document 1]
JP 2001-266910 A
[Patent Document 2]
Special table 2001-507501 gazette
[0011]
[Problems to be solved by the invention]
However, the fuel cell 21 that has been conventionally proposed and developed as such a high-voltage / high-capacity battery is a large-sized, large-sized battery having a stack structure and a large area, and a small battery. Conventionally, the use of the fuel cell has been hardly considered.
[0012]
That is, in the conventional gas separator 26 in such a fuel cell 21, in the laminated body in which the electrolyte member 23 is laminated using the gas separator 26, the side surface of the electrolyte member 23 is exposed to the outside, so that it falls when being carried. As a result, there is a problem that the mechanical reliability of the entire fuel cell 21 is difficult to be secured.
[0013]
In addition, in order to mount the fuel cell 21 in a portable electronic device, a fuel cell container that is different from conventional large-sized fuels and has excellent compactness, simplicity, and safety is required. That is, in order to be applied as a portable power source such as a general-purpose chemical battery, the fuel cell container is reduced in size and height to shorten the temperature rise to the operating temperature and to reduce the heat capacity. In the conventional fuel cell 21, the gas separator 26, which occupies most of the heat capacity, is thinned, particularly in the case of the gas separator 26 in which the flow path is formed by cutting on the surface of the carbon plate. Since it becomes brittle, a thickness of several mm is required. For this reason, there also existed a problem that size reduction and height reduction were difficult.
[0014]
Further, the output voltage of the fuel cell 21 is determined by the partial pressure of the gas supplied to the electrodes 24 and 25 on the front and back surfaces of the electrolyte member 23. That is, when the fuel gas supplied to the electrolyte member 23 travels through the gas flow path 28 and is consumed in the power generation reaction, the partial pressure of the fuel gas on the surface of the fuel electrode 24 decreases and the output voltage decreases. In the same manner, when the air also travels through the air flow path 29 and is consumed, the partial pressure of oxygen on the surface of the air electrode 25 decreases, and the output voltage decreases. Therefore, it is necessary to supply the fuel gas evenly. However, the gas separator 26 of the conventional fuel cell 21 has a flow path formed by cutting on the surface of the carbon plate in particular. Since the groove is narrow, there is a problem that the flow resistance is increased and it is difficult to supply a uniform gas.
[0015]
Further, a combination of the plurality of electrolyte members 23 and the opposed fuel electrode 24 / air electrode 25 and gas separator 26 is arbitrarily and efficiently connected in series or in parallel to adjust the overall output voltage and output current. However, in the conventional fuel cell 21, in order to take out electricity from the fuel electrode and the air electrode sandwiching the electrolyte member 23, it is possible to draw out and connect to the outside, or the gas separator 26 is stacked as a conductive material. There is only a method of connecting them in series, and there is a problem that it is difficult in a small fuel cell.
[0016]
The present invention has been completed in view of the problems of the conventional techniques as described above, and an object of the present invention is a small and robust fuel cell container capable of accommodating an electrolyte member, and an equal gas. It is an object of the present invention to provide a reliable fuel cell container capable of achieving uniform supply and temperature gradient in the fuel cell container and highly efficient electrical connection, and a fuel cell using the same.
[0017]
[Means for Solving the Problems]
  The fuel cell container of the present invention includes a base body made of ceramics having a concave portion for accommodating an electrolyte member having first and second electrodes on the lower and upper main surfaces, respectively, and the lower main surface of the electrolyte member. And a first fluid flow path formed from the bottom surface of the recess facing the outer surface of the base body, and a conductor paste is baked to be integrally formed with the base body and facing the first electrode of the electrolyte member A first wiring conductor having one end disposed on the bottom surface of the recess and the other end led to the outer surface of the base, and attached to the top surface of the base around the recess covering the recess. A lid that hermetically seals the recess, a second fluid channel formed from the lower surface of the lid facing the upper main surface of the electrolyte member to the outer surface of the lid, and firing the conductor paste Integrated with the lid And a second wiring conductor having one end disposed on the lower surface of the lid facing the second electrode of the electrolyte member and the other end led to the outer surface of the lid. It is what.
  In the fuel cell container of the present invention, the first wiring conductor is formed so as to protrude 10 μm or more from the bottom surface of the recess, or the second wiring conductor protrudes from the bottom surface of the lid body by 10 μm or more. It is formed as follows.
[0018]
  In the fuel cell of the present invention, an electrolyte member is accommodated in the recess of the fuel cell container having the above-described configuration, and the lower and upper main surfaces of the electrolyte member are connected to the first and second fluid flow paths. The first and second electrodes are electrically connected to the first and second wiring conductors, respectively, so that each fluid can be supplied or discharged between them. The cover is attached to the upper surface so as to cover the recess.
[0019]
According to the fuel cell container of the present invention, a base body made of ceramics having a concave portion for accommodating an electrolyte member having first and second electrodes on the lower and upper main surfaces, respectively, and a periphery of the concave portion of the base body Since the upper surface of the fuel cell container is hermetically sealed, a fluid such as a gas leaks. In addition, since it is not necessary to provide a container such as a package in addition to this container, it is possible to obtain a fuel cell that can be operated efficiently and to be effective for miniaturization. In addition, since a plurality of electrolyte members can be housed in a box formed by a ceramic body having a concave portion on the upper surface and a lid that seals the concave portion, a fuel cell can be obtained. The mechanical reliability of the entire fuel cell is improved without being exposed to the outside and being damaged. In addition to the first and second wiring conductors, one end of which is disposed inside the container constituted by the recess and the lid, unnecessary electrical contact with the electrolyte member itself can be avoided, so that reliability and safety are ensured. High fuel cell can be obtained. Furthermore, by using ceramics as the constituent material of the fuel cell container, it is possible to obtain a fuel cell having excellent corrosion resistance against fluids including various gases.
[0020]
Also, a first fluid channel formed from the bottom surface of the recess facing the lower main surface of the electrolyte member to the outer surface of the substrate, and formed from the lower surface of the lid body facing the upper main surface of the electrolyte member to the outer surface of the lid body. Since each of the plurality of fluid flow paths is provided on the inner wall surfaces facing each other across the electrolyte member, the fluid supplied to the electrolyte member The uniform supply performance can be improved. According to such a fluid path, since the fluid flows perpendicularly to the electrolyte member, for example, when the fluid is hydrogen gas and air (oxygen) gas, the electrolyte member has on the lower and upper main surfaces, respectively. Each gas partial pressure supplied to the first and second electrodes does not decrease, and there is an effect that a predetermined stable output voltage can be obtained. Further, since the pressure of the fluid to be supplied, for example, the gas partial pressure is stabilized, the distribution of the internal temperature of the fuel cell container is made uniform, and as a result, the thermal stress generated in the electrolyte member can be suppressed. Reliability can be improved. Furthermore, since each fluid flow path is formed in the base and the lid, each of the flow paths is excellent in hermeticity, and originally two types of raw material fluids (for example, oxygen gas and hydrogen) that should be isolated in the flow path are used. Gas or methanol, etc.) will not function as a fuel cell, and there is no risk of ignition or explosion after a flammable fluid is mixed at a high temperature. A safe fuel cell can be provided.
[0021]
According to the fuel cell of the present invention, the electrolyte member is accommodated in the recess of the fuel cell container of the present invention, and the lower and upper main surfaces of the electrolyte member are between the first and second fluid flow paths. And the first and second electrodes are electrically connected to the first and second wiring conductors respectively, and the upper surface of the periphery of the recess of the base is covered with the recess so as to cover the lid. Since it is attached, it is compact and robust with the features of the fuel cell container of the present invention as described above, uniform gas supply, uniform temperature gradient in the fuel cell container, and high efficiency. A reliable fuel cell capable of achieving electrical connection can be obtained.
[0022]
Therefore, according to the fuel cell container and the fuel cell of the present invention, the fuel that is excellent in compactness, simplicity, and safety and that can be stably operated over a long period of time by uniform supply of fluid and highly efficient electrical connection. A battery can be provided.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Next, the present invention will be described in detail with reference to the accompanying drawings.
[0024]
FIG. 1 is a cross-sectional view showing an example of an embodiment of a fuel cell container and a fuel cell using the same according to the present invention. In FIG. 1, 1 is a fuel cell, 2 is a fuel cell container, 3 is an electrolyte member, 4 is a first electrode, 5 is a second electrode, 6 is a base, 7 is a lid, 8 is a first fluid flow path, 9 is a second fluid flow path, 10 is a first wiring conductor, and 11 is a second wiring conductor.
[0025]
For example, the electrolyte member 3 faces the first electrode 4 formed on the lower main surface and the second electrode 5 formed on the upper main surface on both main surfaces of the ion conductive film (exchange membrane). A fuel electrode (not shown) serving as an anode side electrode and an air electrode (not shown) serving as a cathode side electrode are integrally formed. And the electric current generated with the electrolyte member 3 can be sent to the 1st electrode and the 2nd electrode, and it can take out outside.
[0026]
The ion conductive film (exchange membrane) of the electrolyte member 3 is made of a proton conductive ion exchange resin such as perfluorocarbon sulfonic acid resin, for example, Nafion (trade name, manufactured by DuPont). Further, the fuel electrode and the air electrode are gas diffusion electrodes in a porous state, and have both functions of a porous catalyst layer and a gas diffusion layer. These fuel electrode and air electrode are composed of a conductive material carrying a catalyst such as platinum, palladium, or an alloy thereof, for example, a porous material in which carbon fine particles are held by a hydrophobic resin binder such as polytetrafluoroethylene. Has been.
[0027]
The first electrode 4 on the lower main surface and the second electrode 5 on the upper main surface of the electrolyte member 3 are a method of hot pressing a carbon electrode with catalyst fine particles such as platinum or platinum-ruthenium on the electrolyte member 3, or Further, it is formed by a method of applying or transferring a mixture of a carbon electrode material with catalyst fine particles such as platinum or platinum-ruthenium and a solution in which an electrolyte material is dispersed onto the electrolyte.
[0028]
The fuel cell container 2 includes a base 6 having a recess and a lid 7, and has a function of mounting the electrolyte member 3 inside the recess and hermetically sealing the aluminum oxide (Al₂O_Three) Sintered sinter / Mullite (3Al₂O_Three・ 2SiO₂) Sintered body, silicon carbide (SiC) sintered body, aluminum nitride (AlN) sintered body, silicon nitride (Si)_ThreeN_Four) It is made of a ceramic material such as a quality sintered body and a glass ceramic sintered body.
[0029]
The glass ceramic sintered body is composed of a glass component and a filler component.₂-B₂O_ThreeSystem, SiO₂-B₂O_Three-Al₂O_ThreeSystem, SiO₂-B₂O_Three-Al₂O_Three-MO system (where M represents Ca, Sr, Mg, Ba or Zn), SiO₂-Al₂O_Three-M¹OM²O system (however, M¹And M²Are the same or different and represent Ca, Sr, Mg, Ba or Zn), SiO₂-B₂O_Three-Al₂O_Three-M¹OM²O system (however, M¹And M²Is the same as above), SiO₂-B₂O_Three-M^Three ₂O system (however, M^ThreeRepresents Li, Na or K), SiO₂-B₂O_Three-Al₂O_Three-M^Three ₂O system (however, M^ThreeIs the same as described above), Pb-based glass, Bi-based glass and the like.
[0030]
Moreover, as a filler component, for example, Al₂O_Three, SiO₂, ZrO₂And TiO, a complex oxide of alkaline earth metal oxides₂Al oxide of alkaline earth metal oxide, Al₂O_ThreeAnd SiO₂And composite oxides containing at least one selected from (for example, spinel, mullite, cordierite).
[0031]
The fuel cell container 2 is composed of a base 6 having a recess and a lid 7, and covers the recess around the recess of the base 6 to attach the lid 7 so that the recess is hermetically sealed. Bonding with metal bonding materials such as silver brazing, bonding with resin materials such as epoxy, bonding with a seal ring made of iron alloy etc. on the upper surface around the recess with seam weld, electron beam, laser etc. The lid body 7 is attached to the base body 6 by a welding method or the like. The lid 7 may be formed with a recess similar to the base 6.
[0032]
In order to reduce the thickness of the base body 6 and the lid body 7 and to reduce the height of the fuel cell 1, the bending strength, which is mechanical strength, is preferably 200 MPa or more.
[0033]
The base body 6 and the lid body 7 are preferably formed of an aluminum oxide sintered body made of a dense material having a relative density of 95% or more, for example. In that case, for example, rare earth oxide powder and a sintering aid are first added to and mixed with the aluminum oxide powder to adjust the raw material powder of the aluminum oxide sintered body. Next, an organic binder and a dispersion medium are added to and mixed with the raw material powder of the aluminum oxide sintered body to form a paste, and from this paste, an organic binder is added to the raw material powder by a press blade method, press forming, rolling forming, etc. Thus, a green sheet having a predetermined thickness is produced. Then, through the green sheet, through holes as the first fluid flow path 8 and the second fluid flow path 9, and the first wiring conductor 10 and the second wiring conductor are formed by punching with a mold, micro drill, laser, or the like. A through-hole for arranging 11 is formed.
[0034]
The first wiring conductor 10 and the second wiring conductor 11 are preferably formed of tungsten and / or molybdenum in order to prevent oxidation. In that case, for example, 100 parts by mass of tungsten and / or molybdenum powder as an inorganic component, Al₂O_Three3 to 20 parts by mass, Nb₂O_FiveIs prepared at a ratio of 0.5 to 5 parts by mass. The conductor paste is filled into the through hole of the green sheet to form a via conductor as a through conductor.
[0035]
In these conductor pastes, in order to improve the adhesion of the substrate 6 and the lid 7 to the ceramic, aluminum oxide powder or the same composition powder as the ceramic component forming the substrate 6 and the lid 7 is used. It is also possible to add 0.05 to 2% by volume.
[0036]
The formation of the first wiring conductor 10 and the second wiring conductor 11 on the surface layer and the inner layer of the base body 6 and the lid body 7 is the same as before or after forming the via conductor by filling the through hole with the conductive paste. The conductive paste is formed by printing and applying to a predetermined pattern on the green sheet by a method such as screen printing or gravure printing.
[0037]
Then, after aligning and laminating and pressing a predetermined number of sheet-like molded bodies filled with printed conductor paste, the laminated body is heated at a maximum firing temperature of 1200 to 1500 ° C., for example, in a non-oxidizing atmosphere. To obtain the target ceramic substrate 6, lid 7, first wiring conductor 10 and second wiring conductor 11.
[0038]
Moreover, it is preferable that the base | substrate 6 and the cover body 7 which consist of ceramics shall be 0.2 mm or more in thickness. If the thickness is less than 0.2 mm, the strength tends to be covered, and therefore the base 6 and the lid 7 tend to be easily cracked by the stress generated when the lid 7 is attached to the base 6. On the other hand, if the thickness exceeds 5 mm, it will be difficult to reduce the thickness and height, making it unsuitable as a fuel cell to be mounted on a small portable device, and increasing the heat capacity. It tends to be difficult to quickly set an appropriate temperature corresponding to the conditions.
[0039]
The first wiring conductor 10 and the second wiring conductor 11 are electrically connected to the first electrode 4 and the second electrode 5 of the electrolyte member 3, respectively, and the current generated by the electrolyte member 3 is supplied to the fuel cell container 2. It functions as a conductive path for taking it out.
[0040]
  The first wiring conductor 10 is formed such that one end is disposed at a portion of the bottom surface of the recess of the base 6 facing the first electrode 4 of the electrolyte member 3 and the other end is led out to the outer surface of the base 6. The first wiring conductor 10 is formed integrally with the base body 6 as described above, and protrudes by 10 μm or more from the bottom surface of the recess of the base body 6 so that the first wiring conductor 10 can be easily brought into contact with the first electrode 4. It is desirable to form so as to. In order to obtain this height, as described above, the printing conditions may be set to be thick when the conductor paste is formed by printing and coating. Further, it is desirable that a plurality of first wiring conductors 10 be arranged opposite to the first electrode 4 to reduce the electric loss due to the first wiring conductors 10, and the penetration portion of the base 6 of the first wiring conductor 10 is φ50 μm or more. It is preferable to set it as the diameter.
[0041]
  The second wiring conductor 11 is formed such that one end is disposed on the lower surface of the lid 7 facing the second electrode 5 of the electrolyte member 3 and the other end is led out to the outer surface of the lid 7. . Similar to the first wiring conductor 10, the second wiring conductor 11 is also formed integrally with the lid body 7, and the lower surface of the lid body 7 so that the second wiring conductor 11 can be easily brought into contact with the second electrode 5. Therefore, it is desirable to form so as to protrude 10 μm or more. In order to obtain this height, as described above, the printing conditions may be set to be thick when the conductor paste is formed by printing and coating. A plurality of second wiring conductors 11 are preferably arranged opposite to the second electrode 5 to reduce electrical loss due to the second wiring conductors 11 and the through-hole portion of the lid 7 of the second wiring conductor 11 is φ50 μm. It is preferable to set it as the above diameter.
[0042]
The first wiring conductor 10 and the second wiring conductor 11 are coated by plating with a metal having good conductivity made of nickel and having good corrosion resistance and wettability with the brazing material on the exposed surface. In this case, the electrical connection between the first wiring conductor 10 and the second wiring conductor 11, the first wiring conductor 10, the second wiring conductor 11, and the external electric circuit can be improved. Therefore, the first wiring conductor 10 and the second wiring conductor 11 are formed by depositing a metal having good conductivity made of nickel and having good corrosion resistance and wettability with the brazing material on the exposed surface. It is preferable to keep.
[0043]
The first and second wiring conductors 10 and 11 and the first and second electrodes 4 and 5 are electrically connected to each other by sandwiching the electrolyte member 3 between the base 6 and the lid 7. What is necessary is just to carry out by the structure of making the 2nd wiring conductor 10 * 11 and the 1st and 2nd electrode 4 * 5 contact | connect by crimping | contacting and electrically connecting.
[0044]
In addition, a first fluid channel 8 and a second fluid channel 9 are disposed on the bottom surface of the recess of the base 6 facing the first electrode 4 and the second electrode 5 and the bottom surface of the lid body 7, respectively. The first fluid channel 8 is formed over the outer surface of the base 6, and the second fluid channel 9 is formed over the outer surface of the lid 7. These first and second fluid flow paths 8 and 9 are formed by electrolytes such as fuel gas, for example, reformed gas rich in hydrogen, or oxidant gas, such as air, through through holes or grooves formed in the base body 6 and the lid body 7, respectively. It is provided as a passage for fluid supplied to the member 3 or as a passage for fluid discharged from the electrolyte member 3 after the reaction, such as water produced by the reaction.
[0045]
Through holes or grooves formed in the base body 6 and the lid body 7 as the first fluid flow path 8 and the second fluid flow path 9 allow fluid such as fuel gas and oxidant gas to be supplied to the electrolyte member 3 evenly. In addition, the diameter and number of through holes or the width, depth, and arrangement of the grooves may be determined according to the specifications of the fuel cell 1.
[0046]
In the fuel cell container 2 and the fuel cell 1 of the present invention, the first fluid channel 8 and the second fluid channel 9 preferably have a diameter of 0.1 mm in order to allow fluid to flow through the electrolyte member 3 with uniform pressure. It is preferable that the holes have the above diameters and are arranged with a constant interval.
[0047]
In this way, the first fluid flow path 8 is made to face the lower main surface on which the first electrode 4 of the electrolyte member 3 is formed, and the second fluid flow is made to face the upper main surface on which the second electrode 5 is formed. By forming the passage 9, fluid can be exchanged between the lower and upper main surfaces of the electrolyte member 3 and the first and second fluid flow paths 8, 9. Will be discharged. For example, in the case of supplying a gas as a fluid, it is possible to prevent the partial pressure of the gas supplied to the first electrode 4 and the second electrode 5 of the electrolyte member 3 from decreasing, and a predetermined stable output voltage. Can be obtained. Further, since the supplied gas partial pressure is stabilized, the internal pressure of the fuel cell 1 is made uniform, and as a result, the thermal stress generated in the electrolyte member 3 can be suppressed, so that the reliability of the fuel cell 1 is improved. Can be made.
[0048]
With the above configuration, a small and robust fuel cell container 2 capable of accommodating the electrolyte member 3 as shown in FIG. 1 is obtained, and the fuel cell 1 of the present invention capable of high efficiency control is obtained.
[0049]
It should be noted that the present invention is not limited to the embodiments described above, and various modifications can be made without departing from the scope of the present invention. For example, with respect to the first fluid channel and the second fluid channel, an inflow port from the side surface of the base body or the lid may be provided in order to reduce the thickness of the entire fuel cell. This is effective in reducing the size especially for portable electronic devices. Furthermore, about the 1st and 2nd wiring conductor, you may arrange | position so that the other end derived | led-out to the outer surface of a base | substrate and a cover body may each be pulled out to the side surface of the same side. According to this, wiring and flow paths can be integrated on one side of the fuel cell, facilitating miniaturization and protection of joints to the outside, enabling a highly reliable design, and The fuel cell can be operated stably.
[0050]
Further, a plurality of electrolyte members may be accommodated in the concave portion of the base body, and these may be electrically connected by the first and second wiring conductors to obtain a high voltage or large current output as a whole. .
[0051]
FIG. 2 is a cross-sectional view showing another example of the fuel cell container of the present invention and the fuel cell using the same, and an electrolyte member 3 is provided in each of the recesses of the substrate 6 having a plurality of recesses. And the third wiring conductor 12 is disposed between the end portions of the adjacent recesses, and electricity is provided between the first electrodes 4 of the plurality of electrolyte members 3 or between the first electrode 4 and the second electrode 5. The first wiring conductor 10 and the second wiring conductor 11 may be electrically connected to each other so as to extract the output as a whole from the electrolyte member 3 disposed at both ends. According to this, since wiring can be freely performed three-dimensionally by the first to third wiring conductors, a plurality of electrolyte members can be arbitrarily connected in series or in parallel. As a result, the overall output voltage and output current can be adjusted efficiently, so that the fuel cell that can satisfactorily extract the electricity electrochemically generated by the electrolyte member is obtained.
[0052]
【The invention's effect】
According to the fuel cell container of the present invention, a base body made of ceramics having a concave portion for accommodating an electrolyte member having first and second electrodes on the lower and upper main surfaces, respectively, and a periphery of the concave portion of the base body Since the upper surface of the fuel cell container is hermetically sealed, a fluid such as a gas leaks. In addition, since it is not necessary to provide a container such as a package in addition to this container, it is possible to obtain a fuel cell that can be operated efficiently and to be effective for miniaturization. In addition, since a plurality of electrolyte members can be housed in a box formed by a ceramic body having a concave portion on the upper surface and a lid that seals the concave portion, a fuel cell can be obtained. The mechanical reliability of the entire fuel cell is improved without being exposed to the outside and being damaged. In addition to the first and second wiring conductors, one end of which is disposed inside the container constituted by the recess and the lid, unnecessary electrical contact with the electrolyte member itself can be avoided, so that reliability and safety are ensured. High fuel cell can be obtained. Furthermore, by using ceramics as the constituent material of the fuel cell container, it is possible to obtain a fuel cell having excellent corrosion resistance against fluids including various gases.
[0053]
Also, a first fluid channel formed from the bottom surface of the recess facing the lower main surface of the electrolyte member to the outer surface of the substrate, and formed from the lower surface of the lid body facing the upper main surface of the electrolyte member to the outer surface of the lid body. Since each of the plurality of fluid flow paths is provided on the inner wall surfaces facing each other across the electrolyte member, the fluid supplied to the electrolyte member The uniform supply performance can be improved. According to such a fluid path, since the fluid flows perpendicularly to the electrolyte member, for example, when the fluid is hydrogen gas and air (oxygen) gas, the electrolyte member has on the lower and upper main surfaces, respectively. Each gas partial pressure supplied to the first and second electrodes does not decrease, and there is an effect that a predetermined stable output voltage can be obtained. Further, since the pressure of the fluid to be supplied, for example, the gas partial pressure is stabilized, the distribution of the internal temperature of the fuel cell container is made uniform, and as a result, the thermal stress generated in the electrolyte member can be suppressed. Reliability can be improved. Furthermore, since each fluid flow path is formed in the base and the lid, each of the flow paths is excellent in hermeticity, and originally two types of raw material fluids (for example, oxygen gas and hydrogen) that should be isolated in the flow path are used. Gas or methanol, etc.) will not function as a fuel cell, and there is no risk of ignition or explosion after a flammable fluid is mixed at a high temperature. A safe fuel cell can be provided.
[0054]
According to the fuel cell of the present invention, the electrolyte member is accommodated in the recess of the fuel cell container of the present invention, and the lower and upper main surfaces of the electrolyte member are defined as the first and second fluid flow paths. The first and second electrodes are electrically connected to the first and second wiring conductors, respectively, and the upper surface around the concave portion of the base is covered with the concave portion. Since the lid is attached, the electrolyte member is not exposed and damaged, and the first and second wiring conductors having one end disposed inside the container constituted by the recess and the lid In addition, since unnecessary electrical contact with the electrolyte member is not required, a highly reliable and safe fuel cell can be obtained. In addition, since the first and second fluid flow paths are provided on the bottom surface of the concave portion of the base body and the lower surface of the lid body, which are the inner wall surfaces facing each other with the electrolyte member interposed therebetween, the gas supplied to the electrolyte member The uniform supply can be improved, and the partial pressure of gas supplied to the first and second electrodes of the electrolyte member can be prevented from being lowered, so that a predetermined stable output voltage can be obtained. And the stress which arises in an electrolyte member can also be controlled and reliability can be improved.
[0055]
Therefore, according to the fuel cell container and the fuel cell of the present invention, the fuel that is excellent in compactness, simplicity, and safety, and that can be stably operated over a long period of time by uniform gas supply and high-efficiency electrical connection. Batteries could be provided.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing an example of an embodiment of a fuel cell container of the present invention and a fuel cell of the present invention using the same.
FIG. 2 is a cross-sectional view showing another example of an embodiment of a fuel cell container of the present invention and a fuel cell of the present invention using the same.
FIG. 3 is a cross-sectional view showing an example of a conventional fuel cell.
[Explanation of symbols]
1: Fuel cell
2: Container for fuel cell
3: Electrolyte member
4: First electrode
5: Second electrode
6: Substrate
7: Lid
8: First fluid flow path
9: Second fluid flow path
10: First wiring conductor
11: Second wiring conductor
12: Third wiring conductor

Claims (3)

  A base made of ceramics having a recess on the upper surface for accommodating an electrolyte member having first and second electrodes on the lower and upper main surfaces, respectively, and a bottom surface of the recess facing the lower main surface of the electrolyte member A first fluid flow path formed over the outer surface of the substrate, a conductor paste is baked and formed integrally with the substrate, and one end is disposed on the bottom surface of the recess facing the first electrode of the electrolyte member. A first wiring conductor provided at the other end to the outer surface of the base body, and a lid body hermetically sealing the concave section, which is attached to the upper surface around the concave section of the base body so as to cover the concave section And a second fluid channel formed from the lower surface of the lid body facing the upper main surface of the electrolyte member to the outer surface of the lid body, and a conductor paste is baked to be integrally formed with the lid body. And the electrolysis A fuel cell container comprising: a second wiring conductor having one end disposed on the lower surface of the lid facing the second electrode of the member and the other end led to the outer surface of the lid. . The first wiring conductor is formed so as to protrude 10 μm or more from the bottom surface of the recess, or the second wiring conductor is formed so as to protrude from the bottom surface of the lid body by 10 μm or more. The fuel cell container according to claim 1. An electrolyte member is housed in the recess of the fuel cell container according to claim 1 or 2, and the lower and upper main surfaces of the electrolyte member are respectively between the first and second fluid flow paths. The first and second electrodes are electrically connected to the first and second wiring conductors, respectively, and the upper surface around the recess of the base is disposed on the upper surface of the base. A fuel cell comprising a cover and a cover attached thereto .

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