JP2005038670A - Electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic apparatus with a small size, low height, and high performance, using a fuel cell capable of receiving a uniform fuel supply and capable of being electrically connected with high efficiency, which can be used in a stable state. <P>SOLUTION: The electronic apparatus has a fuel cell 1, and the fuel cell 1 has a fuel cell container 2. The fuel cell container 2 houses a first electrode 4 of an electrolyte member 3 formed so that a solid electrolyte projects toward the perimeter, on which a first and a second electrodes 4, 5 are formed, and has a substrate 6 composed of a multi-layered ceramic having a first concave part having a mounting part 19a mounting a protrusion 20 of the solid electrolyte at its outer peripheral part. Further, the fuel cell comprises a first fluid passage 8, a first wiring conductor 10, a lid 7 housing the second electrode 5 mounted on a top face of the substrate 6, having a second concave part at its underside having a contact part 19b contacting the protrusion 20 at its outer peripheral part, a second fluid passage 9, a second wiring conductor 11, a terminal 12 for external connection. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic device having a fuel cell as a power source and having a small and highly reliable fuel cell made of multilayer ceramics that can accommodate an electrolyte member.
[0002]
[Prior art]
In recent years, power consumption tends to increase as functions of portable electronic devices increase. In addition, secondary batteries need to be charged after a certain amount of power is used, and charging facilities and charging time are required. Therefore, many problems remain in long-time driving of portable electronic devices.
[0003]
Due to such demands, electronic devices such as mobile phones and notebook PCs (personal computers) equipped with small fuel cells as power sources have been proposed. The fuel cell can be used continuously as long as the supply of fuel and oxygen is continued. As small-sized fuel cells, there are known solid polymer electrolyte fuel cells (hereinafter referred to as PEFC) and direct methanol fuel cells (hereinafter referred to as DMFC). Yes.
[0004]
These fuel cells have 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 aspect of corrosion resistance, cost reduction is easy.
(3) Compared to other fuel cells, it can be started at room temperature, so the startup time is short.
It has excellent features such as For this reason, PEFC and DMFC are not only applied to driving power sources for vehicles, home cogeneration systems, etc., but also to cellular phones, PDAs (Personal Digital Assistants), notebook type PCs (PCs), taking advantage of the above features. Personal computers), digital cameras, videos, and the like have been considered for use as power sources for portable electronic devices with outputs of several watts to several tens of watts.
[0005]
PEFC and DMFC are roughly classified into, 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. And a film-like electrolyte member (hereinafter, referred to as an electrolyte member) interposed between the fuel electrode and the air electrode. In the case of DMFC, methanol (CH₃(OH) aqueous solution is supplied, while the air electrode has (O) in the atmosphere.₂) 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.
[0006]
Specifically, methanol (CH₃When an OH) aqueous solution is supplied, electrons (e) are produced by the catalyst as shown in the following chemical reaction formula (1).⁻) 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.
[0007]
CH₃OH + H₂O → CO₂+ 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.
[0008]
6H⁺+ 3 / 2O₂+ 6e⁻  → 3H₂O (2)
Such a series of electrochemical reactions (formula (1) and formula (2)) proceeds under a relatively low temperature condition of about room temperature to 100 ° C., and by-products other than electric power are basically water (H₂O) only.
[0009]
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.
[0010]
FIG. 12 is a sectional view showing the structure of a conventional fuel cell (PEFC). In the figure, 201 is a PEFC, 203 is an electrolyte member, 204 and 205 are arranged on the electrolyte member 203 so as to sandwich the electrolyte member, and a pair of porous electrodes having functions as a gas diffusion layer and a catalyst layer, that is, A fuel electrode and an air electrode, 206 is a gas separator, 208 is a fuel flow path, and 209 is an air flow path.
[0011]
The gas separator 206 is provided so as to penetrate through the separator and the gas inflow / outflow frame that form the outer shape of the gas separator 206, the separator that separates the fuel channel 208 and the air channel 209, and the separator. The electrode is arranged so as to correspond to the fuel electrode 204 and the air electrode 205 of the electrolyte member 203. The fuel electrode 204 and the air electrode 205 of the electrolyte member 203 are stacked in large numbers via a gas separator 206 so that the fuel electrode 204 and the air electrode 205 are electrically connected in series and / or in parallel. A typical PEFC main body is a stack in a box.
[0012]
A fuel gas containing water vapor (a gas rich in hydrogen) is supplied from the reformer to the fuel electrode 204 through the fuel flow path 208 formed in the gas separator 206, and the air electrode 205 is supplied into the atmosphere through the air flow path 209. Then, air is supplied as an oxidant gas, and power is generated by a chemical reaction in the electrolyte member 203.
[0013]
[Patent Document 1]
JP 2001-266910 A
[0014]
[Patent Document 2]
Special table 2001-507501 gazette
[0015]
[Problems to be solved by the invention]
However, the fuel cell 201 that has been conventionally proposed and developed as such a high-voltage, high-capacity battery is a large, large-sized battery having a stack structure and a large area, and is a small battery. Conventionally, the use of the fuel cell has been hardly considered.
[0016]
That is, in the conventional gas separator 206 in such a fuel cell 201, the side surface of the electrolyte member 203 is exposed to the outside in the laminated body in which the electrolyte member 203 is laminated using the gas separator 206. As a result, there is a problem that the mechanical reliability of the entire fuel cell 201 is difficult to be secured.
[0017]
In order to mount the fuel cell 201 on a portable electronic device, a fuel cell container that is different from conventional large-sized fuels and is excellent in 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 201, the gas separator 206, which occupies most of the heat capacity, is thinned, particularly in the case of the gas separator 206 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 is a problem that it is difficult to reduce the size and height.
[0018]
Further, the output voltage of the fuel cell 201 is determined by the partial pressure of the gas supplied to the electrodes 204 and 205 on the front and back surfaces of the electrolyte member 203. That is, when the fuel gas supplied to the electrolyte member 203 travels through the gas flow path 208 and is consumed in the power generation reaction, the partial pressure of the fuel gas on the surface of the fuel electrode 204 decreases and the output voltage decreases. Similarly, when the air also travels through the air flow path 209 and is consumed, the partial pressure of oxygen on the surface of the air electrode 205 decreases and the output voltage decreases. Therefore, it is necessary to supply the fuel gas evenly. However, the gas separator 206 of the conventional fuel cell 201 has a flow path formed by cutting on the surface of the carbon plate. Since the groove of the passage becomes narrow, there is a problem that the flow passage resistance increases and uniform fuel supply is difficult.
[0019]
Further, a combination of the plurality of electrolyte members 203 and the opposed fuel electrode 204, air electrode 205, and gas separator 206 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 201, in order to take out electricity from the fuel electrode and the air electrode sandwiching the electrolyte member 203, a method of connecting to the outside or connecting the gas separator 206 as a conductive material is used. There is only a method of connecting them in series, and it is difficult to connect to a motherboard or the like for forming an electronic circuit that is the main component of the electronic device in a limited space when used in a portable electronic device. There was also a problem.
[0020]
Further, in the electronic device using the conventional fuel cell 201, a current collecting plate for taking out electricity generated in the electrolyte member 203 to a mother board or the like for forming the main electronic circuit of the electronic device, and the fuel cell Insulating materials such as silicon rubber for insulating the container containing the gas, screws and fastening jigs for attaching the gas separator 206, the electrolyte member 203, the current collector plate and the insulating material to the fuel cell container ( There is a problem that the number of parts such as not shown) is large, and it is difficult to reduce the size and the height.
[0021]
As a method for adjusting the overall output voltage and output current, a plurality of combinations of the electrolyte member 203 and the opposed fuel electrode 204, air electrode 205, and gas separator 206 are arranged on the same plane. The technique is being studied. However, when arranged on the same plane in this way, it is effective for lowering the height compared to the stack structure that has been widely used in the past, but an insulating member for ensuring insulation between adjacent electrolyte members is newly provided. It becomes necessary, and the trouble that the number of parts increases will be induced. Further, since the flow path processing is performed by machining or molding, the inner layer flow path processing in a planar direction that connects adjacent fuel cells cannot be performed, and a conductive material is used. In addition, there is a problem that it is impossible to integrate functions such as an electric circuit by mounting an electronic component or the like.
[0022]
In addition, when mounting such a fuel cell on a portable electronic device, the fuel cell is formed with a terminal for connection with a motherboard or the like for forming an electronic circuit that is the main component of the electronic device, and the portable electronic device It is necessary to provide a terminal corresponding to the connection terminal on the side, but the structure requires a relatively complicated design for both the terminal on the portable electronic device side and the terminal on the fuel cell container side. There was a problem. Furthermore, in the case of using a cartridge type in which the fuel cell can be freely attached / detached from the viewpoint of convenience when using a portable electronic device or carrying it, it is necessary to devise such a terminal that allows such attachment / detachment freely. Therefore, there is a problem that more difficulty occurs.
[0023]
Furthermore, the fuel supplied to the fuel electrode side is consumed with the power generation, and the power generation efficiency decreases as the concentration decreases. Therefore, in order to increase the power generation efficiency in the fuel cell, an oxygen supply mechanism that forcibly distributes oxygen to the air electrode and a fuel supply mechanism that forcibly supplies and supplies fuel to the fuel electrode are required. is there. However, since these forced oxygen and fuel supply mechanisms are bulky, the entire fuel cell also becomes large, which is inappropriate for use as a compact power source for portable electronic devices.
[0024]
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 to use a reliable fuel cell that can perform uniform fuel supply and highly efficient electrical connection. An object of the present invention is to provide an electronic device that is small, low in profile, high in function, and can be used stably.
[0025]
[Means for Solving the Problems]
The first electronic device of the present invention is an electronic device having a fuel cell as a power source, and the fuel cell has a first electrode on the lower main surface of the plate-shaped solid electrolyte and a second electrode on the upper main surface. A first recess having a mounting portion for accommodating at least the first electrode of the electrolyte member formed so that the solid electrolyte projects around the electrode, and mounting the solid electrolyte projecting portion on the outer peripheral portion; A base made of multi-layer ceramics on the upper surface, a first fluid flow path formed from the bottom surface of the first recess facing the lower main surface of the electrolyte member to the outer surface of the base, and a first electrode facing the first electrode of the electrolyte member. A first wiring conductor having one end disposed on the bottom surface of the first recess and the other end led to the outer surface of the base; and a second wiring covering the first recess on the upper surface around the first recess of the base. Place the electrode in contact with the overhang on the outer periphery while accommodating the electrode A lid having a second recess having an abutting portion sandwiching the overhanging portion on the lower surface, hermetically sealing the first recess, and a lid from the lower surface of the lid facing the upper main surface of the electrolyte member A second fluid flow path formed over the outer surface of the body, 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; And a fuel cell container having an external connection terminal formed on at least one of the base body and the lid, and the electrolyte member is mounted on the mounting portion of the fuel cell container. The lower and upper main surfaces are arranged so that the respective fluids can exchange with the first and second fluid flow paths, and the first and second electrodes are electrically connected to the first and second wiring conductors, respectively. Connected to the external connection terminals and connected to the external connection terminals respectively. It is characterized in that formed by attaching a lid to cover the first recess on the upper surface of the surrounding recess.
[0026]
In the second electronic device of the present invention, the base has a plurality of first recesses, one end faces the first electrode of the electrolyte member at one bottom surface of the first recess, and the other end However, a third wiring conductor facing the first electrode of the electrolyte member is formed on the other bottom surface of the first recess.
[0027]
In the third electronic device of the present invention, the base has a plurality of first recesses, one end faces the first electrode of the electrolyte member at one bottom surface of the first recess, and the other end Has a fourth wiring conductor led to the upper surface to which the lid of the base is attached, one end facing the second electrode of the other electrolyte member of the first recess on the lower surface of the lid, and the other end A fifth wiring conductor led out so as to face the other end of the fourth wiring conductor is formed on the lower surface obtained on the upper surface of the base of the lid body.
[0028]
In the fourth electronic device of the present invention, the base is formed with a first recess for accommodating a plurality of electrolyte members, and one end faces one first electrode of the electrolyte member at the bottom of the first recess. In addition, a sixth wiring conductor facing the other first electrode of the electrolyte member is formed at the other end at the bottom surface of the first recess.
[0029]
In the fifth electronic device of the present invention, the base is formed with a first recess for accommodating a plurality of electrolyte members, and one end faces one first electrode of the electrolyte member at the bottom surface of the first recess. And the other end of the seventh wiring conductor led out to the upper surface to which the lid of the base is attached, the other end facing the other second electrode of the electrolyte member on the lower surface of the lid, and the other end Is characterized in that an eighth wiring conductor led out to face the other end of the seventh wiring conductor is formed on the lower surface attached to the upper surface of the base of the lid.
[0030]
The sixth electronic device of the present invention is an electronic device having a fuel cell as a power source, and the fuel cell is provided on the lower main surface of the plate-shaped solid electrolyte on the first electrode and the upper main surface. The second electrode has a recess having a mounting portion for accommodating at least the first electrode of the electrolyte member formed so that the solid electrolyte protrudes to the surroundings and mounting the protruding portion of the solid electrolyte on the outer peripheral portion. A base made of multilayer ceramics on the upper surface, 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 base, and the bottom surface of the recess facing the first electrode of the electrolyte member A first wiring conductor having one end disposed on the outer surface of the base and the other end led to the outer surface of the base; and a lid that is attached to the upper surface around the concave of the base so as to cover the concave and seals the concave. Or the lower surface of the lid facing the upper main surface of the electrolyte member A second fluid conductor formed on one end of the second fluid flow path formed over the outer surface of the lid and 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 And an external connection terminal formed on at least one of the base body and the lid body, and the electrolyte member is mounted on the mounting portion of the fuel cell container. The lower and upper main surfaces are arranged so that the respective fluids can exchange with 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 connecting to the external connection terminals respectively, and covering the recesses on the upper surface around the recesses of the base body and attaching a lid.
[0031]
In the seventh electronic device of the present invention, the base has a plurality of recesses, one end faces the first electrode of the electrolyte member at one bottom surface of the recess, and the other end is the other recess. A third wiring conductor facing the first electrode of the electrolyte member is formed on one bottom surface of the electrode member.
[0032]
In the eighth electronic device according to the present invention, the base has a plurality of recesses, one end faces the first electrode of the electrolyte member on one bottom surface of the recess, and the other end is a lid of the base. A fourth wiring conductor led to the upper surface to which the body is attached, one end facing the second electrode of the other electrolyte member of the recess at the lower surface of the lid, and the other end of the upper surface of the base of the lid The fifth wiring conductor led out so as to face the other end of the fourth wiring conductor is formed on the lower surface obtained in step (b).
[0033]
In the ninth electronic device according to the present invention, the base has a recess for accommodating a plurality of electrolyte members, one end faces the first electrode of the electrolyte member at the bottom of the recess, and the other A sixth wiring conductor is formed, the end of which is a bottom surface of the concave portion and is opposed to the other first electrode of the electrolyte member.
[0034]
In the tenth electronic device of the present invention, the base has a recess for accommodating a plurality of electrolyte members, one end faces the first electrode of the electrolyte member at the bottom of the recess, and the other The seventh wiring conductor led to the upper surface to which the lid of the base body is attached, one end facing the other second electrode of the electrolyte member on the lower surface of the lid, and the other end of the lid An eighth wiring conductor led out so as to face the other end of the seventh wiring conductor is formed on the lower surface attached to the upper surface of the base.
[0035]
In the first to fifth electronic devices according to the present invention, at least one of the first wiring conductor and the second wiring conductor is formed around the opening of the first fluid flow path on the bottom surface of the first recess or on the lower surface of the lid. It is formed around the opening of the second fluid flow path so as to contact the first electrode or the second electrode.
[0036]
In addition, in the sixth to tenth electronic devices of the present invention, at least one of the first wiring conductor and the second wiring conductor is a second portion around the opening of the first fluid flow path on the bottom surface of the recess or on the lower surface of the lid. It is formed around the opening of the fluid flow path so as to contact the first electrode or the second electrode.
[0037]
Further, according to the first to tenth electronic devices of the present invention, the base is formed with an internal circuit.
[0038]
In the first to tenth electronic devices according to the present invention, the base is provided with an electronic component electrically connected to an internal circuit on the surface thereof.
[0039]
In addition, the first to tenth electronic devices of the present invention are characterized in that a piezoelectric pump is provided in the middle of at least one of the first and second fluid flow paths.
[0040]
According to the first to tenth electronic devices of the present invention, a substrate made of multilayer ceramics having a first concave portion or a concave portion on the upper surface for accommodating an electrolyte member having first and second electrodes on the lower and upper main surfaces, respectively. And a lid that is attached to the upper surface around the first concave portion or the concave portion of the base so as to cover the first concave portion or the concave portion and hermetically seals the first concave portion or the concave portion, By sealing the inside of the fuel cell container in an airtight manner, there is no leakage of fluid such as gas, and it is not necessary to provide a container such as a package in addition to this container, so it can be operated efficiently and safely. It is possible to obtain an electronic device that can be used with high functionality and can be used stably, and is also effective in reducing the size and height.
[0041]
Also, a plurality of electrolyte members are housed in a box formed by a base body made of multilayer ceramics having a first recess or recess on the upper surface and a lid for sealing the first recess or recess, thereby forming a fuel cell. Therefore, the electrolyte member is not exposed to the outside of the container and is not damaged, and the mechanical reliability of the entire fuel cell is improved. Therefore, since the protective member for the fuel cell is unnecessary, a small and low-profile electronic device can be provided.
[0042]
In addition to the first and second wiring conductors having one end disposed inside the container constituted by the first concave portion or the concave portion and the lid body, unnecessary electrical contact with the electrolyte member itself can be avoided. A highly reliable and safe fuel cell can be obtained, and an electronic device with high long-term reliability and safety can be provided.
[0043]
In addition, since such a fuel cell has external connection terminals (a positive electrode terminal and a negative electrode terminal) on at least one of the base and the lid, it can be easily electrically connected to a circuit board of an electronic device. Can be attached and detached freely. Therefore, the fuel cell can be easily replaced with a new one without using a facility equipped with special safety equipment, and the convenience of the electronic device can be enhanced.
[0044]
Furthermore, by using multilayer ceramics as the constituent material of the fuel cell container, various gases and liquids can be used without considering corrosivity, and the power supply efficiency can be easily improved. In addition, since wiring conductors can be freely formed on the ceramics of each layer forming the multilayer ceramic by a conventionally well-known metallization method, the electric wiring of the fuel cell can be freely performed. Connection is easy, and the electronic device can be dramatically reduced in size, height and weight. That is, according to the second and seventh electronic devices of the present invention, one end formed on the base is opposed to the first electrode of the electrolyte member at the first recess or one bottom surface of the recess, and the other end is the first. Since the third wiring conductor facing the first electrode of the electrolyte member is provided at one recess or another bottom surface of the recess, the plurality of electrolyte members are electrically connected to each other in parallel. It becomes possible to do. As a result, since the output current of the entire fuel cell can be adjusted, the electricity electrochemically generated by the electrolyte member can be taken out in a good state, the current is stable over a long period, and the reliability is excellent. An electronic device can be provided.
[0045]
According to the third and eighth electronic devices of the present invention, one end formed on the base is opposed to the first electrode of the electrolyte member at the first recess or one bottom surface of the recess, and the other end is the base. A fourth wiring conductor led to the upper surface to which the lid is attached, one end facing the second electrode of the first recess or the other electrolyte member of the recess on the lower surface of the lid, and the other end Since the lower surface obtained on the upper surface of the base body of the lid body has a fifth wiring conductor led out to face the other end of the fourth wiring conductor, a plurality of electrolyte members are electrically connected. By doing so, it becomes possible to connect them in series. As a result, even when the voltage is generated by each electrolyte member, even if it is a minute voltage, the total voltage can be adjusted by series connection. Therefore, the electricity generated electrochemically by the electrolyte member can be externally maintained in good condition. An electronic device that can be taken out, has a stable voltage over a long period, and has excellent reliability can be provided.
[0046]
According to the fourth and ninth electronic devices of the present invention, one end formed on the base is opposed to one first electrode of the electrolyte member at the first recess or the bottom surface of the recess, and the other end is the first. Since it has a sixth wiring conductor that faces one other first electrode of the electrolyte member at one recess or the bottom surface of the recess, they are connected in parallel by electrically connecting a plurality of electrolyte members It becomes possible to do. As a result, since the output current of the entire fuel cell can be adjusted, the electricity electrochemically generated by the electrolyte member can be taken out in a good state, the current is stable over a long period, and the reliability is excellent. An electronic device can be provided.
[0047]
According to the fifth and tenth electronic devices of the present invention, one end formed on the base is opposed to one first electrode of the electrolyte member at the first recess or the bottom of the recess, and the other end is the base. A seventh wiring conductor led to the upper surface to which the lid is attached, one end facing the other one second electrode of the electrolyte member at the lower surface of the lid, and the other end of the upper surface of the base of the lid In such a fuel cell, a plurality of electrolytes are provided. The fuel cell includes the eighth wiring conductor led out so as to face the other end of the seventh wiring conductor on the lower surface obtained in the above. They can be connected in series by electrically connecting the members. As a result, even when the voltage is generated by each electrolyte member, even if it is a minute voltage, the total voltage can be adjusted by series connection. Therefore, the electricity generated electrochemically by the electrolyte member can be externally maintained in good condition. It is possible to provide an electronic device that can be taken out, has a stable voltage over a long period of time, and has excellent reliability.
[0048]
Further, in such a fuel cell, the first fluid passage formed from the first concave portion facing the lower main surface of the electrolyte member or the bottom surface of the concave portion to the outer surface of the substrate, and the upper main surface of the electrolyte member are opposed. Since the second fluid flow path formed from the lower surface of the lid body to the outer surface of the lid body is provided, the plurality of fluid flow paths are provided on the inner wall surfaces facing each other with the electrolyte member interposed therebetween. Therefore, the uniform supply property of the fluid supplied to the electrolyte member 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 or an aqueous methanol solution and air (oxygen) gas, the electrolyte member is on the lower side and There is an effect that a predetermined stable output voltage can be obtained without lowering each gas partial pressure supplied to the first and second electrodes respectively provided on the upper main surface.
[0049]
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. Therefore, it is possible to provide an electronic device with higher reliability.
[0050]
Furthermore, since each fluid flow path is formed in the base body and the lid, each channel is excellent in hermeticity, and a solid electrolyte overhang is provided on the first recess or the outer periphery of the recess on the top surface of the base. Since the first fluid channel is separated from the second fluid channel by the electrolyte member in order to be placed on the placed part, two kinds of raw material fluids (for example, oxygen gas and hydrogen gas or aqueous methanol solution) are used. As a result, the function as a fuel cell will not be manifested by mixing, and there is no risk of ignition or explosion after a flammable fluid is mixed at a high temperature. Can be provided.
[0051]
According to the first to tenth electronic devices of the present invention, the electrolyte member is mounted on the mounting portion of the fuel cell container, and the lower and upper main surfaces of the electrolyte member are the first and second main surfaces. The first and second electrodes are arranged so that each fluid can exchange with the fluid flow path, and the first and second wiring conductors, the first to third wiring conductors, and the first and second wirings are arranged. , 4th and 5th wiring conductors, 1st, 2nd and 6th wiring conductors, and 1st, 2nd, 7th and 8th wiring conductors, respectively, and an external connection terminal And the lid is attached to the upper surface around the first recess or recess of the base so as to cover the first recess or recess. Thus, the features of the fuel cell container of the present invention as described above can be obtained. Equipped with small size, robust, uniform fuel supply, high efficiency Using a fuel cell that is reliable can perform electrical connection, lower profile, highly functional, it can be high efficiency obtain an electronic apparatus capable.
[0052]
According to the first to tenth electronic devices of the present invention, at least one of the first wiring conductor and the second wiring conductor is a periphery of the opening of the first fluid flow path or the lid of the first recess or the bottom surface of the recess. The first electrode or the second electrode of the electrolyte member is formed around the opening of the second fluid channel on the lower surface of the body so as to contact the first electrode or the second electrode of the electrolyte member. The entire region excluding the opening of the first fluid channel or the second fluid channel and the first wiring conductor or the second wiring conductor can be directly contacted and electrically connected. Therefore, the contact area between the first electrode and the first wiring conductor of the electrolyte member and the contact area between the second electrode and the second wiring conductor can be increased and can be directly connected, and the electrical resistance is increased and the contact is poor. Therefore, it is possible to provide an electronic device having high power generation efficiency.
[0053]
According to the first to tenth electronic devices of the present invention, since the substrate is made of multilayer ceramic, the metal layer is formed in various shapes and electrical characteristics on the surface of the ceramic layer located inside by metallization method or the like. Therefore, an electronic circuit element that functions as resistance, capacitance, inductance, or the like can be formed inside the substrate. Therefore, for example, when a large capacity capacitor is formed in parallel with the fuel cell, when the current output from the fuel cell becomes insufficient, the insufficient current is compensated to meet the target output current. It is possible to ensure a sufficient current supply. In addition, since a booster circuit can be formed, a voltage necessary for the electronic device can be secured.
[0054]
Further, according to the first to tenth electronic devices of the present invention, since the internal circuit is formed on the base body, it is possible to mount an electronic component that is electrically connected to the internal circuit on the surface of the base body. Therefore, the functionality of the electronic device can be improved by the electronic component mounted on the substrate surface.
[0055]
Further, according to the first to fifth electronic devices of the present invention, since the electronic component electrically connected to the internal circuit is provided on the surface of the base, for example, a sensor, a control IC or the like is used as the electronic component. By using the concentration sensor to detect the concentration of the fuel in the fluid flow path, it is possible to suppress optimal circulation, fuel dilution, and reduction in fuel utilization efficiency.
[0056]
In addition, according to the first to tenth electronic devices of the present invention, since the piezoelectric pump is provided in the middle of at least one of the first and second fluid flow paths, a small size attached to the fluid flow path. Piezoelectric pumps can prevent backflow of fuel and consequently prevent contamination of unused fuel by reactants, etc. Also, since the remaining air is discharged, the air staying in the operation of electronic equipment Avoiding adverse effects. Furthermore, the fuel is supplied at a constant rate. As a result, stable power generation is performed and the fuel is smoothly supplied, so that the startup time can be increased. As a result, for example, even after a fuel cell or fuel cartridge is replaced with a new one or after fuel is replenished, the electronic device can be used immediately, compared to a conventional electronic device using a chemical cell or the like. In addition, it is possible to provide an electronic device having convenience that is comparable to the above.
[0057]
From the above, according to the electronic device of the present invention, by using a fuel cell that is excellent in compactness, simplicity, and safety, and that enables uniform supply of fluid and highly efficient electrical connection, In addition, it is possible to provide an electronic device that can be stably operated over a long period of time and is excellent in safety and convenience.
[0058]
DETAILED DESCRIPTION OF THE INVENTION
Next, the present invention will be described in detail with reference to the accompanying drawings.
[0059]
FIG. 1 is a cross-sectional view showing an example of an embodiment of a fuel cell incorporated in a first electronic device of the present invention, and FIG. 6 is a fuel cell incorporated in a sixth electronic device of the present invention.
[0060]
In these drawings, reference numeral 1, 61 denotes a fuel cell, 2 62 denotes a fuel cell container, 3 denotes an electrolyte member, 4 denotes a first electrode, 5 denotes a second electrode, 6, 66 denotes a base body, and 7 and 67 denote lid bodies. , 8 is a first fluid channel, 9 is a second fluid channel, 10 is a first wiring conductor, 11 is a second wiring conductor, 12 is an external connection terminal, 19a is a mounting portion, 19b is a contact portion, Reference numeral 20 denotes an overhang portion. 1 and 6, the same reference numerals indicate the same parts. Note that these electronic devices are mobile phones, PDAs (Personal Digital Assistants), digital cameras, and the like. Specific examples thereof will be described later.
[0061]
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). In addition, a fuel electrode (not shown) serving as an anode electrode and an air electrode (not shown) serving as a cathode 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.
[0062]
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 made of a conductive material carrying a catalyst such as platinum, palladium or an alloy thereof, for example, a porous body in which carbon fine particles are held by a hydrophobic resin binder such as polytetrafluoroethylene. It is configured.
[0063]
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. At this time, the 1st electrode 4 and the 2nd electrode 5 are not formed in the peripheral part of electrolyte, but the overhang | projection part 20 is formed.
[0064]
The fuel cell containers 2 and 62 include a base body 6 having a first recess or a base body 66 having a recess, and a lid 7 or a lid body 67 having a second recess, and the electrolyte member 3 is made up of the first recess and the second recess. It is mounted inside the recess or inside the recess and has a role of hermetically sealing, and aluminum oxide (Al₂O₃) Quality sintered body, mullite (3Al₂O₃・ 2SiO₂) Sintered body, silicon carbide (SiC) sintered body, aluminum nitride (AlN) sintered body, silicon nitride (Si)₃N₄) It is made of ceramic materials such as quality sintered body and glass ceramic sintered body.
[0065]
The fuel cell containers 2 and 62 include a base body 6 having a first recess or a base body 66 having a recess, and a lid 7 or a lid body 67 having a second recess, and the first recess or recess of the bases 6 and 66. In order to hermetically seal the first concave portion or the concave portion by covering the first concave portion or the concave portion and attaching the lids 7 and 67 around the periphery, bonding with a metal bonding material such as solder or silver solder, epoxy or the like The lid 7, by a method of joining with a resin material, joining a seal ring made of an iron alloy or the like to the first recess or the upper surface around the recess and welding with a seam weld, electron beam, laser, or the like 67 is attached to the substrates 6 and 66.
[0066]
In order to reduce the thickness of each of the substrates 6 and 66 and the lids 7 and 67 and to reduce the height of the fuel cells 1 and 61, the bending strength, which is mechanical strength, is preferably 200 MPa or more. .
[0067]
The base bodies 6 and 66 and the lid bodies 7 and 67 are preferably made of a ceramic material made of a dense material having a relative density of 95% or more. For example, in the case of an aluminum oxide sintered body, first, a rare earth oxide powder or a sintering aid is 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 the raw material powder of the aluminum oxide sintered body and mixed to form a paste. 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. The green sheet is punched by a die, micro drill, laser, or the like, and the first fluid passage 8 and the through holes as the second fluid passage 9, and the first wiring conductor 10 and the second wiring conductor. A through hole for disposing 11 is formed. The first fluid channel 8 and the second fluid channel 9 may be grooves formed in a surface layer and an inner layer formed by punching with a mold, press molding, or the like.
[0068]
When an aluminum oxide sintered body is used as the ceramic material, 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, with respect to 100 parts by mass of tungsten and / or molybdenum powder as an inorganic component, Al₂O₃3 to 20 parts by mass, Nb₂O₅Is 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.
[0069]
In these conductor pastes, the same ceramic components as the aluminum oxide powder and the bases 6, 66 and the lids 7, 67 are formed in order to improve the adhesion of the bases 6, 66 and the lids 7, 67 to the ceramics. It is also possible to add the composition powder at a ratio of 0.05 to 2% by volume, for example.
[0070]
The first wiring conductor 10 and the second wiring conductor 11 are formed on the surface layers and the inner layers of the bases 6 and 66 and the lid bodies 7 and 67 before and after forming the via conductor by filling the through holes with the conductive paste. At the same time, a similar conductive paste is formed on a green sheet by applying it in a predetermined pattern by screen printing, gravure printing or the like.
[0071]
Then, after aligning and laminating and pressure-bonding a predetermined number of sheet-like molded bodies filled with conductive 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 bases 6 and 66, the lid bodies 7 and 67, the first wiring conductor 10, and the second wiring conductor 11.
[0072]
Further, the external connection terminals 12 are joined to at least one of the bases 6 and 66 and the lids 7 and 67 by soldering or brazing. It is desirable that the external connection terminal 12 has a shape that allows good electrical connection with a motherboard or the like for forming an electronic circuit that is a main component of the electronic device. As such a shape, for example, a rod shape, a saddle shape, a conical shape, etc. that can be easily electrically and mechanically connected to each other by connecting or inserting terminals to an electronic circuit that is a main part of an electronic device. Is used. In addition, it is preferable to provide a fitting portion (a hole or the like) corresponding to the external connection terminal in a portion to which the external connection terminal 12 is connected in the electronic circuit that is the main of the electronic device. . Furthermore, by arranging the external connection terminals 12 on the side surfaces of the bases 6 and 66 and the lids 7 and 67, the height of the electronic device can be reduced.
[0073]
Moreover, it is preferable that the base | substrates 6 and 66 and the lid bodies 7 and 67 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. Therefore, the base 6, 66 and the lids 7, 67 are cracked by the stress generated when the bases 6, 66 and the lids 7, 67 are attached. Tends to occur. On the other hand, if the thickness exceeds 5 mm, it is difficult to reduce the height and height, making it difficult to use as a fuel cell 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 chemical reaction conditions.
[0074]
In the example of the fuel cell incorporated in the first electronic device of the present invention shown in FIG. 1, the shape of the first recess of the base 6 is a so-called two-step recess, and the shape of the second recess of the lid 7 is Although it is a 1 step | paragraph recessed part, the shape of these recessed parts may be reversed, the shape of the 1st recessed part of the base | substrate 6 may be made into a 1 step recessed part, and the shape of the 2nd recessed part of the cover body 7 may be made into a 2 step recessed part.
[0075]
Further, in the example of the fuel cell incorporated in the sixth electronic device of the present invention shown in FIG. 6, the shape of the concave portion of the base body 66 is a so-called two-step concave portion, and the lid body 67 is also provided with a concave portion. Although the shape is a one-step recess, as in another example of the embodiment shown in the cross-sectional view similar to FIG. 6 in FIG. 13, the shape of the recess of the base 66 ′ and the recess provided in the lid 67 ′ The shape of the recesses of the base body 66 ″ is a two-step recess, as shown in a cross-sectional view similar to FIG. The bases 66 ′ and 66 ″ and the lids 67 ′ and 67 ″ may be easily manufactured by forming a flat plate shape having no recess.
[0076]
In FIGS. 13 and 14, the same parts as those in FIG. 6 are denoted by the same reference numerals, but 61 'and 61 "are fuel cells, 62' and 62" are fuel cell containers, and 3 is an electrolyte member. 4 is a first electrode, 5 is a second electrode, 66 'and 66 "are bases, 67' and 67" are lids, 8 is a first fluid flow path, 9 is a second fluid flow path, and 10 is a first flow path. A wiring conductor, 11 is a second wiring conductor, 19a is a placement portion, and 20 is an overhang portion.
[0077]
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 out 62.
[0078]
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.
[0079]
The first wiring conductor 10 is formed such that one end is disposed at a portion facing the first electrode 4 of the electrolyte member 3 on the bottom surface of the recess of the bases 6 and 66 and the other end is led out to the outer surface of the bases 6 and 66. ing. Such a first wiring conductor 10 is formed integrally with the bases 6 and 66 as described above. From the bottom surface of the recesses of the bases 6 and 66 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 be higher by 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.
[0080]
In addition, it is desirable that a plurality of first wiring conductors 10 be arranged opposite to the first electrode 4 to reduce electrical loss due to the first wiring conductors 10. It is preferable to set the diameter to φ50 μm or more.
[0081]
The second wiring conductor 11 has one end disposed on the lower surface of the lid 7, 67 facing the second electrode 5 of the electrolyte member 3, and the other end led to the outer surface of the lid 7, 67. Is formed. Similar to the first wiring conductor 10, the second wiring conductor 11 is also formed integrally with the lid bodies 7 and 67, and the lid body 7 so that the second wiring conductor 11 can be easily brought into contact with the second electrode 5. , 67 is preferably formed so as to be 10 μm or more higher than the bottom surface of the recess. 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.
[0082]
In addition, it is desirable that a plurality of second wiring conductors 11 be arranged opposite to the second electrode 5 to reduce electrical loss due to the second wiring conductor 11, and the through portions of the lid bodies 7 and 67 of the second wiring conductor 11 Is preferably a diameter of φ50 μm or more.
[0083]
The first wiring conductor 10, the second wiring conductor 11, and the external connection terminal 12 are nickel, copper, or gold that has good conductivity on the exposed surface and good corrosion resistance and wettability with the brazing material. When a metal such as platinum and palladium is deposited by plating, the first wiring conductor 10, the second wiring conductor 11, the first wiring conductor 10, the second wiring conductor 11, the external connection terminal 12, and the electrons The electrical connection with a mother board or the like for forming an electronic circuit as a main device can be made favorable.
[0084]
The electrical connection between the first and second wiring conductors 10 and 11 and the first and second electrodes 4 and 5 is such that the electrolyte member 3 is sandwiched between the bases 6 and 66 and the lids 7 and 67. By housing, the first and second wiring conductors 10 and 11 and the first and second electrodes 4 and 5 may be brought into pressure contact and electrically connected.
[0085]
Further, a first fluid channel 8 and a second fluid channel are provided on the bottom surface of the first concave portion or the concave portion of the bases 6 and 66 facing the first electrode 4 and the second electrode 5 and the bottom surface of the lid bodies 7 and 67, respectively. 9, the first fluid channel 8 is formed over the outer surfaces of the bases 6 and 66, and the second fluid channel 9 is formed over the outer surfaces of the lids 7 and 67. The first and second fluid flow paths 8 and 9 are respectively formed of a reformed gas rich in a fuel gas, such as hydrogen, or an oxidant gas, such as air, through through holes or grooves formed in the substrates 6 and 66 and the lids 7 and 67, respectively. As a passage for fluid supplied to the electrolyte member 3 or as a passage for fluid discharged from the electrolyte member 3 after the reaction, such as water generated by the reaction.
[0086]
Through holes or grooves formed in the base bodies 6 and 66 and the lid bodies 7 and 67 as the first fluid flow path 8 and the second fluid flow path 9, fluids such as fuel gas and oxidant gas are evenly distributed in the electrolyte member 3. According to the specifications of the fuel cells 1 and 61, the diameter and number of the through holes (or the width, depth, and arrangement of the grooves) may be determined.
[0087]
In the fuel cell containers 2 and 62 and the fuel cells 1 and 61, the first fluid channel 8 and the second fluid channel 9 preferably allow the fluid to flow through the electrolyte member 3 at a uniform pressure. It is preferable that the hole diameter is 1 mm or more, and the intervals are fixed.
[0088]
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 and 9, and the fluid is supplied through the respective flow paths. 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. Furthermore, since the supplied gas partial pressure is stabilized, the internal pressure of the fuel cells 1 and 61 is made uniform. As a result, the thermal stress generated in the electrolyte member 3 can be suppressed. Reliability can be improved.
[0089]
In the fuel cell incorporated in the first electronic device of the present invention as shown in FIG. 1, the electrolyte member 3 includes the mounting portion 19 a provided on the outer peripheral portion of the first recess on the upper surface of the base 6 and the lid body 7. The overhanging portion 20 is sandwiched and stored by the contact portion 19b provided on the outer peripheral portion of the second concave portion on the lower surface. For this reason, the first fluid channel 8 and the second fluid channel 9 are isolated from each other by the electrolyte member 3, and two kinds of raw material fluids (for example, oxygen gas and hydrogen gas or aqueous methanol solution) are mixed. As a result, the function as a fuel cell is not lost, and there is no risk of ignition or explosion after a combustible fluid is mixed at a high temperature. Therefore, a safe fuel cell can be provided. . Further, since the protruding portion 20 of the electrolyte member 3 is sandwiched between the mounting portion 19a of the base 6 and the contact portion 19b of the lid body 7, the electrolyte member 3 can be easily placed inside the fuel cell container 2. It can be stored fixedly.
[0090]
The space between the mounting portion 19a and the contact portion 19b ensures that the electrolyte member 3 is securely fixed to the fuel cell container 2 and that the airtightness between the first fluid channel 8 and the second fluid channel 9 is improved. In order to make sure, it is good to make it below the thickness of the overhang | projection part 20 of the electrolyte member 3. FIG. In addition, it is preferable to set the dimension of the opening of the first recess to the same dimension as the outer dimension of the electrolyte member 3 because the alignment when the electrolyte member 3 is placed on the base 6 is facilitated. Further, in order to increase the airtightness between the first fluid channel 8 and the second fluid channel 9, a sealing material is provided between at least one of the placement portion 19a and the contact portion 19b and the overhang portion 20. You may arrange. If this sealing material has adhesiveness, the electrolyte member 3 can be more reliably fixed.
[0091]
Further, in the sixth fuel cell container 62 as shown in FIG. 6, the electrolyte member 3 is placed and housed on a placement portion 19 a provided on the outer peripheral portion of the recess on the upper surface of the base 66. For this reason, the first fluid channel 8 and the second fluid channel 9 are isolated from each other by the electrolyte member 3, and two kinds of raw material fluids (for example, oxygen gas and hydrogen gas or aqueous methanol solution) are mixed. As a result, the function as a fuel cell is not lost, and there is no risk of ignition or explosion after a combustible fluid is mixed at a high temperature. Therefore, a safe fuel cell can be provided. . In addition, since it is not necessary to match the depth of the concave portion with the overhanging portion 20 of the thin electrolyte member 3, the base 66 can be easily manufactured.
[0092]
When the electrolyte member 3 is placed on the placement portion 19a through an adhesive having a sealing property between them, the electrolyte member 3 is fixed and the first fluid channel 8 and the second fluid channel 9 are fixed. The airtightness between the two can be ensured. Examples of such an adhesive include fluororesin-based, silicone-based, ethylene-propylene-based, polyurethane-based, polysulfide-based, butyl rubber-based, acrylic-based, and epoxy-based rubber materials and resin materials.
[0093]
With the above configuration, a small and robust fuel cell container 2 and 62 that can accommodate the electrolyte member 3 as shown in FIGS. 1 and 6 is obtained, and incorporated in the electronic apparatus of the present invention capable of high efficiency control. The fuel cells 1 and 61 are obtained.
[0094]
Next, FIG. 2 to FIG. 5 and FIG. 7 to FIG. 10 are sectional views showing other examples of the embodiment of the fuel cell incorporated in the second to fifth and seventh to tenth electronic devices of the present invention. is there.
[0095]
In these figures, 21, 31, 41, 51, 71, 81, 91, 101 are fuel cells, 22, 32, 42, 52, 72, 82, 92, 102 are fuel cell containers, 3 is an electrolyte member, 4 is a first electrode, 5 is a second electrode, 6 and 66 are bases, 7 and 67 are lid bodies, 8 is a first fluid flow path, 9 is a second fluid flow path, 10 is a first wiring conductor, and 11 is Second wiring conductor, 12 is an external connection terminal, 13 is a third wiring conductor, 14 is a fourth wiring conductor, 15 is a fifth wiring conductor, 16 is a sixth wiring conductor, 17 is a seventh wiring conductor, and 18 is a first wiring conductor. 8 wiring conductors, 19a is a mounting portion, 19b is a contact portion, and 20 is an overhang portion.
[0096]
2 to 5 and FIGS. 7 to 10, the same reference numerals as those in FIG. 1 denote the same parts as those shown in FIG.
[0097]
The third wiring conductor 13 of FIGS. 2 and 7 has one end disposed at a portion facing the first electrode 4 of the electrolyte member 3 on the bottom surface of one of the plurality of first recesses or recesses of the substrates 6 and 66, The other end is disposed at a portion facing the first electrode 4 of the other electrolyte member 3 on the first recess or another bottom surface of the recess and is formed integrally with the bases 6 and 66. Further, it is desirable that the third wiring conductor 13 is formed so as to be at least 10 μm higher than the first concave portion of the bases 6 and 66 or the bottom surface of the concave portion so that both ends thereof are easily brought into contact with the first electrode 4. In order to obtain this height, as described above, when the conductor paste is formed by printing and coating, the printing conditions may be set so as to increase the coating thickness. Further, it is desirable to arrange a plurality of third wiring conductors 13 so as to face the first electrode 4 to reduce electrical loss due to the third wiring conductors 13. It is preferable to set the diameter to φ50 μm or more.
[0098]
The fourth wiring conductor 14 in FIGS. 3 and 8 has one end disposed at a portion facing the first electrode 4 of the electrolyte member 3 on the bottom surface of one of the plurality of first recesses or recesses of the bases 6 and 66, The other end is led out to a part to which the lid bodies 7 and 67 on the upper surface of the bases 6 and 66 are attached. Also, the fifth wiring conductor 15 has one end disposed on the lower surface of the lid bodies 7 and 67 at a portion facing the second electrode 5 of the first recess or the other electrolyte member 3 of the other recess, and the other end is It is led out and formed so as to be opposed to the other end of the fourth wiring conductor 14 at a portion attached to the upper surface of the base body 6, 66 on the lower surface of the lid bodies 7, 67.
[0099]
Similar to the third wiring conductor 13, the fourth wiring conductor 14 is formed integrally with the bases 6 and 66, and the first wiring base 14 is easily connected to the first electrode 4 at one end thereof. It is desirable to form the recess so as to be 10 μm or more higher than the bottom surface of the recess. In order to obtain this height, as described above, when the conductor paste is formed by printing and coating, the printing conditions may be set so as to increase the coating thickness. Further, it is desirable that a plurality of fourth wiring conductors 14 be arranged opposite to the first electrode 4 to reduce the electric loss caused by the fourth wiring conductors 14. It is preferable to set the diameter to φ50 μm or more.
[0100]
Similarly to the second wiring conductor 11, the fifth wiring conductor 15 is also formed integrally with the lid bodies 7 and 67, and the lower surfaces of the lid bodies 7 and 67 so that one end of the fifth wiring conductor 15 can easily come into contact with the second electrode 5. It is desirable to form it higher than 10 μm. In order to obtain this height, as described above, when the conductor paste is formed by printing and coating, the printing conditions may be set so as to increase the coating thickness. Further, it is desirable that a plurality of fifth wiring conductors 15 are also arranged opposite to the second electrode 5 to reduce the electric loss caused by the fifth wiring conductors 15, and the through portion of the lid 7 of the fifth wiring conductor 15 is φ50 μm. It is preferable to set it as the above diameter.
[0101]
The sixth wiring conductor 16 of FIGS. 4 and 9 has one end disposed at a portion facing the first electrode 4 of the electrolyte member 3 on the first recess of the bases 6 and 66 or the bottom of the recess, and the other end is The same first concave portion or the bottom surface of the concave portion is disposed at a portion facing the other first electrode 4 of the electrolyte member 3 and is integrally formed with the bases 6 and 66.
[0102]
The sixth wiring conductor 16 is preferably formed to be 10 μm or more higher than the first concave portion of the bases 6 and 66 or the bottom surface of the concave portion so that both ends thereof are easily brought into contact with the first electrode 4. In order to obtain this height, as described above, when the conductor paste is formed by printing and coating, the printing conditions may be set so as to increase the coating thickness. Further, it is desirable that a plurality of third wiring conductors 13 be arranged opposite to the first electrode 4 to reduce the electrical loss due to the sixth wiring conductor 16. It is preferable to set the diameter to φ50 μm or more.
[0103]
The seventh wiring conductor 17 of FIGS. 5 and 10 is provided with one end at a portion facing the first electrode 4 of the plurality of electrolyte members 3 at the first recess of the bases 6 and 66 or the bottom surface of the recess, The other end is led out to a part to which the lid bodies 7 and 67 on the upper surface of the bases 6 and 66 are attached. The eighth wiring conductor 18 has one end disposed on the lower surface of the lids 7 and 67 facing the other second electrode 5 of the plurality of electrolyte members 3, and the other end disposed on the lid 7 and 67. 67 is formed so as to be opposed to the other end of the seventh wiring conductor 17 at a portion attached to the upper surface of the base body 6, 66 on the lower surface of 67.
[0104]
Similar to the third wiring conductor 13, the seventh wiring conductor 17 is formed integrally with the bases 6 and 66, and has a concave portion of the bases 6 and 66 so that one end thereof can be easily brought into contact with the first electrode 4. It is desirable to form it 10 μm or more higher than the bottom surface. In order to obtain this height, as described above, when the conductor paste is formed by printing and coating, the printing conditions may be set so as to increase the coating thickness. Further, it is desirable to arrange a plurality of seventh wiring conductors 17 so as to face the first electrode 4 to reduce the electrical loss due to the seventh wiring conductors 17. It is preferable to set the diameter to φ50 μm or more.
[0105]
Similarly to the second wiring conductor 11, the eighth wiring conductor 18 is also formed integrally with the lid bodies 7 and 67, and the lower surfaces of the lid bodies 7 and 67 so that one end of the eighth wiring conductor 18 can easily come into contact with the second electrode 5. It is desirable to form it higher than 10 μm. In order to obtain this height, as described above, when the conductor paste is formed by printing and coating, the printing conditions may be set so as to increase the coating thickness. In addition, it is desirable that a plurality of the eighth wiring conductors 18 be arranged to face the second electrode 5 to reduce the electric loss caused by the eighth wiring conductor 18, and the through portions of the lid bodies 7 and 67 of the eighth wiring conductor 18 are reduced. Is preferably a diameter of φ50 μm or more.
[0106]
As shown in FIGS. 2, 3, 7, and 8, the fuel cell containers 22, 32, 72, and 82 incorporated in the second, third, seventh, and eighth electronic devices of the present invention and the second According to the third, seventh, and eighth fuel cells 21, 31, 71, 81, the electrolyte member 3 is provided in each of the first recesses or recesses of the bases 6, 66 having a plurality of first recesses or recesses. The third wiring conductor 13, or the fourth wiring conductor 14 and the fifth wiring conductor 15 are arranged between the adjacent first concave portions or the end portions of the concave portions, and the first electrodes 4 of the plurality of electrolyte members 3 are accommodated. Or the first electrode 4 and the second electrode 5 are electrically connected to each other, and the first wiring conductor 10 and the second wiring conductor 10 are connected to the electrolyte member 3 arranged at both ends so as to extract the output as a whole. By electrically connecting the wiring conductors 11 to each other, first to first Since the wiring conductors 10, 11, 13 and the first, second, fourth, and fifth wiring conductors 10, 11, 14, 15 can be freely wired three-dimensionally, a plurality of electrolyte members 3 can be arbitrarily arranged. Can be connected in series or in parallel. As a result, the overall output voltage and output current can be adjusted efficiently, so that a fuel cell that can satisfactorily take out the electricity electrochemically generated by the plurality of electrolyte members 3 is provided. Become.
[0107]
As shown in FIGS. 4, 5, 9, and 10, the fuel cell containers 42, 52, 92, 102 and the fourth built in the fourth, fifth, ninth, and tenth electronic devices of the present invention. According to the fifth, ninth, and tenth fuel cells 41, 51, 91, 101, the plurality of electrolyte members 3 are accommodated in the first recesses or recesses of the substrates 6, 66 and the sixth wiring conductor 16. Alternatively, the seventh wiring conductor 17 and the eighth wiring conductor 18 are arranged to electrically connect 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 are electrically connected to the electrolyte member 3 disposed at both ends so as to take out the output as a whole, whereby the first, second, second 6 wiring conductors 10, 11, 16 and first, second, seventh and eighth wirings Since the body 10,11,17,18 can three-dimensionally freely wiring, it is possible to arbitrarily connected in series connection or in parallel a plurality of electrolyte member 3. As a result, the overall output voltage and output current can be adjusted efficiently, so that a fuel cell that can satisfactorily take out the electricity electrochemically generated by the plurality of electrolyte members 3 is provided. Become.
[0108]
Various modifications can be made without departing from the scope of the present invention. For example, the first fluid channel 8 and the second fluid channel 9 may be provided with inflow ports from the side surfaces of the base bodies 6 and 66 or the lid bodies 7 and 67 in order to reduce the overall height of the fuel cell. Good. This is effective in reducing the size especially for portable electronic devices. Further, the first and second wiring conductors 10 and 11 are arranged so that the other ends led out to the outer surfaces of the base bodies 6 and 66 and the lid bodies 7 and 67 are drawn out to the side surfaces on the same side, respectively. The terminals 12 may be aggregated. 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.
[0109]
Next, an electronic device according to the present invention having the fuel cell as a power source will be described.
[0110]
Since the electronic device of the present invention has the fuel cell as described above as a power source, it has various effects as described below and can be stably operated over a long period of time with a small size and a low profile. Furthermore, it is superior in safety and convenience.
[0111]
According to the electronic device of the present invention, in the fuel cell as a power source, the external connection terminal 12 (positive electrode terminal and negative electrode terminal) portion can be easily electrically connected to the circuit board of the electronic device and is detachable. For example, replacement with a new fuel cell is very easy and the convenience is very high.
[0112]
Further, since the fuel cell and the fuel cell container composed of the bases 6 and 66 using the multilayer ceramic are used as the power source, the electric wiring of the fuel cell can be freely performed. It is easy to connect in series, and the electronic device can be reduced in size, height, and weight.
[0113]
Furthermore, since the bases 6 and 66 are made of multilayer ceramics, resistance, capacitance, and inductance can be formed inside the base.
[0114]
As described above, when a large capacity capacitance is formed in the bases 6 and 66 in parallel with the fuel cell, for example, when the current output from the fuel cell becomes insufficient, the insufficient current is generated. It is possible to ensure the current supply according to the target output current by compensating for the amount. Similarly, since a booster circuit can be formed using resistance, capacitance, and inductance, it is possible to secure a voltage necessary for an electronic device.
[0115]
In addition, when forming resistance, a capacitance, and an inductance in the inside of the base | substrates 6 and 66 in this way, it is preferable that the base | substrates 6 and 66 consist of a glass ceramic sintered compact.
[0116]
For example, a glass ceramic sintered body is composed of a glass component and a filler component.₂-B₂O₃System, SiO₂-B₂O₃-Al₂O₃System, SiO₂-B₂O₃-Al₂O₃-MO system (where M represents Ca, Sr, Mg, Ba or Zn), SiO₂-Al₂O₃-M¹OM²O system (however, M¹And M²Are the same or different and represent Ca, Sr, Mg, Ba or Zn), SiO₂-B₂O₃-Al₂O₃-M¹OM²O system (however, M¹And M²Is the same as above), SiO₂-B₂O₃-M³ ₂O system (however, M³Represents Li, Na or K), SiO₂-B₂O₃-Al₂O₃-M³ ₂O system (however, M³Is the same as described above), Pb-based glass, Bi-based glass and the like.
[0117]
Moreover, as a filler component, for example, Al₂O₃, SiO₂, ZrO₂And TiO, a complex oxide of alkaline earth metal oxides₂Al oxide of alkaline earth metal oxide, Al₂O₃And SiO₂And composite oxides containing at least one selected from (for example, spinel, mullite, cordierite).
[0118]
Moreover, it is preferable that the mixing ratio of these glass and a filler is 40: 60-99: 1 by mass ratio.
[0119]
As the organic binder blended in the glass ceramic green sheet, those conventionally used for ceramic green sheets can be used. For example, acrylic (acrylic acid, methacrylic acid or ester homopolymer or copolymer) Polymer, specifically acrylic ester copolymer, methacrylic ester copolymer, acrylic ester-methacrylic ester copolymer, etc.), polyvinyl butyral, polyvinyl alcohol, acrylic-styrene, polypropylene Examples include carbonate-based and cellulose-based homopolymers or copolymers.
[0120]
The glass ceramic green sheet is obtained by adding a predetermined amount of plasticizer and solvent (organic solvent, water, etc.) to the glass powder, filler powder, and organic binder as necessary to obtain a slurry, which is then used as a doctor blade, rolled, calender. It is obtained by molding to a thickness of about 50 to 500 μm with a roll, a die press or the like.
[0121]
In order to form a conductor pattern on the surface of the glass ceramic green sheet, for example, a paste of conductor material powder is printed by a screen printing method or a gravure printing method, or a metal foil having a predetermined pattern shape is transferred. A method is mentioned. Examples of the conductor material include one or more of Au, Ag, Pd, Pt, and the like. In the case of two or more, any form such as mixing, alloy, coating, etc. may be used.
[0122]
In the case of forming a high-capacity capacitance, for example, a layer made of an inorganic powder having a high dielectric constant such as barium titanate (hereinafter referred to as a barium titanate layer) is formed inside a substrate made of glass ceramic. In this case, first, a slurry containing ceramic powder and glass powder is formed to obtain a plurality of green sheets, and then a metal paste to be a lower electrode layer is printed on the green sheets, and then A dielectric layer made of barium titanate or the like is printed on the lower electrode layer by screen printing to form a dielectric layer, and a metal paste is printed on the dielectric layer to form an upper electrode layer. These green sheets are laminated and the laminate is fired.
[0123]
When the resistor is formed inside the substrate, RuO₂, IrO₂, RhO₂, SnO₂And LaB₆Is formed by applying a resistor paste mainly composed of, for example, a predetermined pattern to the green sheet by a method such as screen printing or gravure printing in the same manner as the first wiring conductor 10 and the second wiring conductor 11. be able to.
[0124]
In addition, an internal circuit is preferably formed on the bases 6 and 66 of the fuel cell 1. Thereby, the electronic component electrically connected to the internal circuit on the surface of the base 6 can be mounted. Therefore, the functionality of the electronic device can be improved by the electronic components mounted on the surfaces of the substrates 6 and 66.
[0125]
Moreover, it is preferable that electronic parts electrically connected to the internal circuit are provided on the surfaces of the bases 6 and 66 of the fuel cell 1. As a result, the concentration of the fuel in the fluid flow paths 8 and 9 is detected by the concentration sensor using, for example, a sensor or a control IC as an electronic component, so that optimal circulation, fuel dilution, and fuel use efficiency can be achieved. It is possible to suppress the decrease.
[0126]
In the fuel cell 1, for example, lead zirconate titanate (PZT; composition formula: Pb (Zr, Ti) O) is provided in the middle of at least one of the first and second fluid flow paths 8 and 9.₃A piezoelectric pump using a piezoelectric material such as a so-called micro pump is preferably provided. As a result, the small piezoelectric pump can prevent the back flow of the fuel, thereby preventing the contamination of the unused fuel by the reactants, etc., and the remaining air is discharged, so that the operation of the electronic device It is possible to avoid the air staying in the air from being adversely affected. Further, the fuel is supplied at a constant rate. As a result, stable power generation is performed, and the fuel is smoothly supplied, so that the startup time is shortened.
[0127]
The piezoelectric pump includes an inflow portion, a variable volume portion, and an outflow portion. The volume variable portion can be manufactured by, for example, providing a piezoelectric material outside the first and second fluid flow paths 8 and 9, and utilizing the expansion and contraction of the piezoelectric material according to the applied voltage. The portion above the first and second fluid flow paths 8 and 9 can be vibrated. Thereby, the volume of the 1st and 2nd fluid flow paths 8 and 9 can be varied, and it can function as a pump.
[0128]
The inflow portion and the outflow portion are composed of first and second fluid flow paths 8 and 9 connected to the variable volume portion, and are used to flow fuel into and out of the variable volume portion. Preferably, the cross-sectional area of the outflow portion is larger than the cross-sectional area of the inflow portion. Thereby, when the pressure of the fuel in the outflow portion is reduced and the volume variable portion functions as a pump, the fuel flows to the outflow portion side where the pressure is small, and the fuel can be sent well in a certain direction. Note that a backflow prevention valve that prevents backflow of fuel may be provided in the inflow portion and the outflow portion.
[0129]
In such a piezoelectric pump, an organic or inorganic material is used as a piezoelectric material, and the piezoelectric material is bonded after firing a ceramic green sheet serving as a base body 6 or a lid body 7, or In the case of using a ceramic piezoelectric material such as PZT, the ceramic piezoelectric material can be manufactured by attaching the ceramic piezoelectric material to a predetermined position of the ceramic green sheet and firing it at the same time.
[0130]
Further, the fuel cell 1 does not need to make unnecessary electrical contact with the electrolyte member 3 other than the first and second wiring conductors 10 and 11 having one end disposed inside the container. Because it is highly reliable, it is excellent in reliability and safety.
[0131]
As described above, according to the electronic device of the present invention, an electronic device that is excellent in compactness, simplicity, and safety, and can be stably operated over a long period of time by an even supply of fluid and highly efficient electrical connection. Can be provided.
[0132]
Specifically, the electronic device of the present invention includes portable electronic devices such as mobile phones, PDAs (Personal Digital Assistants), toys such as digital cameras, video cameras, and game machines, and notebook PCs (personal computers). ) And other portable printers, fax machines, televisions, communication equipment, audio-video equipment, electric appliances such as electric fans, and electronic equipment such as electric tools.
[0133]
In recent years, these electronic devices have been added with a function of moving image display using a liquid crystal display device or the like. Such a video display consumes a large amount of power, so that an electronic device using a conventional storage battery cannot be operated in a short time, whereas the electronic device of the present invention supplies a very long time power. It is equipped with a fuel cell that can perform long-time operation even when moving images are displayed.
[0134]
As the electronic apparatus of the present invention, for example, in the case of a mobile phone, as shown in the block diagram of FIG. 11, a central processing unit (CPU) 111, a control unit 112, a random access memory (RAM) 113, a read-on memory ( ROM) 114, input unit 115 for inputting data operated by the user to CPU 111, antenna 116, and a signal received by antenna 116 is demodulated and supplied to control unit 112 and supplied from control unit 112 The radio unit (RF) 117 that modulates the received signal and transmits it from the antenna 116, the speaker 118 that makes a sound based on the ringing signal from the control unit 112, and the light emission that is turned on, off, or blinks under the control of the control unit 112 A diode (LED) 119, a display unit 120 for displaying information by a signal from the control unit 112, and a control unit A vibrator 121 that vibrates in accordance with a drive signal from 12, a voice signal from a user that is converted into a voice signal and transmitted to the control unit 112, and a voice signal from the control unit 112 that is converted into a voice and output; The power supply unit 123 supplies power to each unit, and the power supply unit 123 incorporates the fuel cell and the fuel cell container of the present invention.
[0135]
In this case, the fuel cell and the fuel cell container are excellent in compactness, simplicity and safety, and can supply power for a long time with an even supply of fuel and highly efficient electrical connection. It is possible to reduce the height and weight.
[0136]
Also, considering that recent mobile phones are sufficient in terms of miniaturization and low profile, the space created by miniaturization and low profile of the fuel cell in this way, for example, a camera or video Electronic components having functions other than the telephone function can be newly incorporated, and further multi-function can be achieved.
[0137]
Further, instead of newly incorporating an electronic component, an impact absorbing material, a preventing member or the like can be provided so as to protect the main electronic circuit. In this case, it is also possible to have a structure that can make the impact resistance when a shock is applied to the mobile phone main body due to dropping or the like, the waterproofness when used in rain, etc. stronger than before.
[0138]
In addition, by making it possible to reduce the size of the electric circuit inside the mobile phone body, there are fewer restrictions on the external shape of the mobile phone body, for example, making the mobile phone a shape that is easy for an elderly person or child to grip. It becomes possible to form an outer shape with excellent design.
[0139]
Further, when the structure of the power supply unit 123 is a structure in which the fuel cell and the fuel cell container are detachable as described above, if a spare fuel cell and the fuel cell container are prepared, the battery will run out. Can be easily replaced with a spare fuel cell and a fuel cell, or the fuel cell can be taken out and refueled or replaced. It is more convenient than the one used as a power source.
[0140]
In addition, since the replaced (used) fuel cell can be reused immediately by replenishing fuel, it is more convenient than charging, and resources can be used effectively. In addition, there is an advantage that it can be used in an emergency such as a long-term power outage due to a natural disaster or the like or outdoors.
[0141]
In the case of a notebook PC (personal computer), a personal computer main body, a first housing containing a keyboard for inputting predetermined data to the personal computer main body, data input by the keyboard, or a personal computer And a second housing containing a display for displaying data processed by the main body, the second housing is attached to the first housing so as to be openable and closable, and power is supplied to each part. The power supply unit to be configured has a basic configuration in which the first casing is configured, and a fuel cell and a fuel cell container are incorporated in the power supply unit. In this case, similar to the above-described mobile phone, the fuel cell and the fuel cell container incorporated in the electronic device of the present invention are excellent in compactness, simplicity and safety, and are long due to the uniform supply of fuel and highly efficient electrical connection. Since power can be supplied for a long time, the laptop PC (personal computer) can be made compact, low-profile, lighter and more multifunctional, and can accommodate larger displays and higher resolutions. It is possible to supply a large current stably and over a long period of time, making the display easy to see, and reducing the burden on the weight and volume when carrying the portable PC (personal computer). be able to.
[0142]
If the fuel cell and the fuel cell container are detachable in the power source, the spare fuel cell and the fuel cell container can be prepared, so that 2 In the situation where only the secondary battery is used, there is an advantage that it is possible to supply power for a long time as compared with the conventional case. Further, even when used in a public place as described above, since it is excellent in safety, it can be used without being restricted and is extremely convenient.
[0143]
It should be noted that the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention. For example, in the above-described embodiments, methanol is used as a fuel as a fuel cell. However, it is also possible to use a fuel cell using various liquids such as dimethyl ether as fuel.
[0144]
【The invention's effect】
According to the first to tenth electronic devices of the present invention, a substrate made of multilayer ceramics having a first concave portion or a concave portion on the upper surface for accommodating an electrolyte member having first and second electrodes on the lower and upper main surfaces, respectively. And a lid that is attached to the upper surface around the first concave portion or the concave portion of the base so as to cover the first concave portion or the concave portion and hermetically seals the first concave portion or the concave portion, By sealing the inside of the fuel cell container in an airtight manner, there is no leakage of fluid such as gas, and it is not necessary to provide a container such as a package in addition to this container, so it can be operated efficiently and safely. It is possible to obtain an electronic device that can be used with high functionality and can be used stably, and is also effective in reducing the size and height.
[0145]
Also, a plurality of electrolyte members are housed in a box formed by a base body made of multilayer ceramics having a first recess or recess on the upper surface and a lid for sealing the first recess or recess, thereby forming a fuel cell. Therefore, the electrolyte member is not exposed to the outside of the container and is not damaged, and the mechanical reliability of the entire fuel cell is improved. Therefore, since the protective member for the fuel cell is unnecessary, a small and low-profile electronic device can be provided.
[0146]
In addition to the first and second wiring conductors having one end disposed inside the container constituted by the first concave portion or the concave portion and the lid body, unnecessary electrical contact with the electrolyte member itself can be avoided. A highly reliable and safe fuel cell can be obtained, and an electronic device with high long-term reliability and safety can be provided.
[0147]
In addition, since such a fuel cell has external connection terminals (a positive electrode terminal and a negative electrode terminal) on at least one of the base and the lid, it can be easily electrically connected to a circuit board of an electronic device. Can be attached and detached freely. Therefore, the fuel cell can be easily replaced with a new one without using a facility equipped with special safety equipment, and the convenience of the electronic device can be enhanced.
[0148]
Furthermore, by using multilayer ceramics as the constituent material of the fuel cell container, various gases and liquids can be used without considering corrosivity, and the power supply efficiency can be easily improved. In addition, since wiring conductors can be freely formed on the ceramics of each layer forming the multilayer ceramic by a conventionally well-known metallization method, the electric wiring of the fuel cell can be freely performed. Connection is easy, and the electronic device can be dramatically reduced in size, height and weight. That is, according to the second and seventh electronic devices of the present invention, one end formed on the base is opposed to the first electrode of the electrolyte member at the first recess or one bottom surface of the recess, and the other end is the first. Since the third wiring conductor facing the first electrode of the electrolyte member is provided at one recess or another bottom surface of the recess, the plurality of electrolyte members are electrically connected to each other in parallel. It becomes possible to do. As a result, since the output current of the entire fuel cell can be adjusted, the electricity electrochemically generated by the electrolyte member can be taken out in a good state, the current is stable over a long period, and the reliability is excellent. An electronic device can be provided.
[0149]
According to the third and eighth electronic devices of the present invention, one end formed on the base is opposed to the first electrode of the electrolyte member at the first recess or one bottom surface of the recess, and the other end is the base. A fourth wiring conductor led to the upper surface to which the lid is attached, one end facing the second electrode of the first recess or the other electrolyte member of the recess on the lower surface of the lid, and the other end Since the lower surface obtained on the upper surface of the base body of the lid body has a fifth wiring conductor led out to face the other end of the fourth wiring conductor, a plurality of electrolyte members are electrically connected. By doing so, it becomes possible to connect them in series. As a result, even when the voltage is generated by each electrolyte member, even if it is a minute voltage, the total voltage can be adjusted by series connection. Therefore, the electricity generated electrochemically by the electrolyte member can be externally maintained in good condition. An electronic device that can be taken out, has a stable voltage over a long period, and has excellent reliability can be provided.
[0150]
According to the fourth and ninth electronic devices of the present invention, one end formed on the base is opposed to one first electrode of the electrolyte member at the first recess or the bottom surface of the recess, and the other end is the first. Since it has a sixth wiring conductor that faces one other first electrode of the electrolyte member at one recess or the bottom surface of the recess, they are connected in parallel by electrically connecting a plurality of electrolyte members It becomes possible to do. As a result, since the output current of the entire fuel cell can be adjusted, the electricity electrochemically generated by the electrolyte member can be taken out in a good state, the current is stable over a long period, and the reliability is excellent. An electronic device can be provided.
[0151]
According to the fifth and tenth electronic devices of the present invention, one end formed on the base is opposed to one first electrode of the electrolyte member at the first recess or the bottom of the recess, and the other end is the base. A seventh wiring conductor led to the upper surface to which the lid is attached, one end facing the other one second electrode of the electrolyte member at the lower surface of the lid, and the other end of the upper surface of the base of the lid In such a fuel cell, a plurality of electrolytes are provided. The fuel cell includes the eighth wiring conductor led out so as to face the other end of the seventh wiring conductor on the lower surface obtained in the above. They can be connected in series by electrically connecting the members. As a result, even when the voltage is generated by each electrolyte member, even if it is a minute voltage, the total voltage can be adjusted by series connection. Therefore, the electricity generated electrochemically by the electrolyte member can be externally maintained in good condition. It is possible to provide an electronic device that can be taken out, has a stable voltage over a long period of time, and has excellent reliability.
[0152]
Further, in such a fuel cell, the first fluid passage formed from the first concave portion facing the lower main surface of the electrolyte member or the bottom surface of the concave portion to the outer surface of the substrate, and the upper main surface of the electrolyte member are opposed. Since the second fluid flow path formed from the lower surface of the lid body to the outer surface of the lid body is provided, the plurality of fluid flow paths are provided on the inner wall surfaces facing each other with the electrolyte member interposed therebetween. Therefore, the uniform supply property of the fluid supplied to the electrolyte member 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 or an aqueous methanol solution and air (oxygen) gas, the electrolyte member is on the lower side and There is an effect that a predetermined stable output voltage can be obtained without lowering each gas partial pressure supplied to the first and second electrodes respectively provided on the upper main surface.
[0153]
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. Therefore, it is possible to provide an electronic device with higher reliability.
[0154]
Furthermore, since each fluid flow path is formed in the base body and the lid, each channel is excellent in hermeticity, and a solid electrolyte overhang is provided on the first recess or the outer periphery of the recess on the top surface of the base. Since the first fluid channel is separated from the second fluid channel by the electrolyte member in order to be placed on the placed part, two kinds of raw material fluids (for example, oxygen gas and hydrogen gas or aqueous methanol solution) are used. As a result, the function as a fuel cell will not be manifested by mixing, and there is no risk of ignition or explosion after a flammable fluid is mixed at a high temperature. Can be provided.
[0155]
According to the first to tenth electronic devices of the present invention, the electrolyte member is mounted on the mounting portion of the fuel cell container, and the lower and upper main surfaces of the electrolyte member are the first and second main surfaces. The first and second electrodes are arranged so that each fluid can exchange with the fluid flow path, and the first and second wiring conductors, the first to third wiring conductors, and the first and second wirings are arranged. , 4th and 5th wiring conductors, 1st, 2nd and 6th wiring conductors, and 1st, 2nd, 7th and 8th wiring conductors, respectively, and an external connection terminal And the lid is attached to the upper surface around the first recess or recess of the base so as to cover the first recess or recess. Thus, the features of the fuel cell container of the present invention as described above can be obtained. Equipped with small size, robust, uniform fuel supply, high efficiency Using a fuel cell that is reliable can perform electrical connection, lower profile, highly functional, it can be high efficiency obtain an electronic apparatus capable.
[0156]
According to the first to tenth electronic devices of the present invention, at least one of the first wiring conductor and the second wiring conductor is a periphery of the opening of the first fluid flow path or the lid of the first recess or the bottom surface of the recess. The first electrode or the second electrode of the electrolyte member is formed around the opening of the second fluid channel on the lower surface of the body so as to contact the first electrode or the second electrode of the electrolyte member. The entire region excluding the opening of the first fluid channel or the second fluid channel and the first wiring conductor or the second wiring conductor can be directly contacted and electrically connected. Therefore, the contact area between the first electrode and the first wiring conductor of the electrolyte member and the contact area between the second electrode and the second wiring conductor can be increased and can be directly connected, and the electrical resistance is increased and the contact is poor. Therefore, it is possible to provide an electronic device having high power generation efficiency.
[0157]
According to the first to tenth electronic devices of the present invention, since the substrate is made of multilayer ceramic, the metal layer is formed in various shapes and electrical characteristics on the surface of the ceramic layer located inside by metallization method or the like. Therefore, an electronic circuit element that functions as resistance, capacitance, inductance, or the like can be formed inside the substrate. Therefore, for example, when a large capacity capacitor is formed in parallel with the fuel cell, when the current output from the fuel cell becomes insufficient, the insufficient current is compensated to meet the target output current. It is possible to ensure a sufficient current supply. In addition, since a booster circuit can be formed, a voltage necessary for the electronic device can be secured.
[0158]
Further, according to the first to tenth electronic devices of the present invention, since the internal circuit is formed on the base body, it is possible to mount an electronic component that is electrically connected to the internal circuit on the surface of the base body. Therefore, the functionality of the electronic device can be improved by the electronic component mounted on the substrate surface.
[0159]
Further, according to the first to fifth electronic devices of the present invention, since the electronic component electrically connected to the internal circuit is provided on the surface of the base, for example, a sensor, a control IC or the like is used as the electronic component. By using the concentration sensor to detect the concentration of the fuel in the fluid flow path, it is possible to suppress optimal circulation, fuel dilution, and reduction in fuel utilization efficiency.
[0160]
In addition, according to the first to tenth electronic devices of the present invention, since the piezoelectric pump is provided in the middle of at least one of the first and second fluid flow paths, a small size attached to the fluid flow path. Piezoelectric pumps can prevent backflow of fuel and consequently prevent contamination of unused fuel by reactants, etc. Also, since the remaining air is discharged, the air staying in the operation of electronic equipment Avoiding adverse effects. Furthermore, the fuel is supplied at a constant rate. As a result, stable power generation is performed and the fuel is smoothly supplied, so that the startup time can be increased. As a result, for example, even after a fuel cell or fuel cartridge is replaced with a new one or after fuel is replenished, the electronic device can be used immediately, compared to a conventional electronic device using a chemical cell or the like. In addition, it is possible to provide an electronic device having convenience that is comparable to the above.
[0161]
From the above, according to the electronic device of the present invention, by using a fuel cell that is excellent in compactness, simplicity, and safety, and that enables uniform supply of fluid and highly efficient electrical connection, In addition, it is possible to provide an electronic device that can be stably operated over a long period of time and is excellent in safety and convenience.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing an example of an embodiment of a fuel cell incorporated in an electronic apparatus of the present invention.
FIG. 2 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the present invention.
FIG. 3 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the present invention.
FIG. 4 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the present invention.
FIG. 5 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the present invention.
FIG. 6 is a cross-sectional view showing an example of an embodiment of a fuel cell incorporated in an electronic device of the present invention.
FIG. 7 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the present invention.
FIG. 8 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the present invention.
FIG. 9 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the present invention.
FIG. 10 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the present invention.
FIG. 11 is a block diagram illustrating an example of an embodiment of an electronic apparatus according to the invention.
FIG. 12 is a cross-sectional view of a conventional fuel cell.
FIG. 13 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the invention.
FIG. 14 is a cross-sectional view showing another example of the embodiment of the fuel cell incorporated in the electronic apparatus of the invention.
[Explanation of symbols]
1, 21, 31, 41, 51, 61, 71, 81, 91, 101: fuel cell
2,22,32,42,52,62,72,82,92,102: Container for fuel cell
3: Electrolyte member
4: First electrode
5: Second electrode
6,66: substrate
7, 67: Lid
8: First fluid flow path
9: Second fluid flow path
10: First wiring conductor
11: Second wiring conductor
12: External connection terminal
13: Third wiring conductor
14: Fourth wiring conductor
15: Fifth wiring conductor
16: Sixth wiring conductor
17: Seventh wiring conductor
18: Eighth wiring conductor
19a: Placement part
19b: contact part
20: Overhang
111: Central processing unit (CPU)
112: Control unit
113: Random access memory (RAM)
114: Read-on memory (ROM)
115: Input unit
116: Antenna
117: Radio unit (RF)
118: Speaker
119: Light emitting diode (LED)
120: Display unit
121: Vibrator
122: Transmitter / receiver
123: Power supply unit

Claims (15)

An electronic device having a fuel cell as a power source, wherein the fuel cell has a first electrode on a lower main surface of a plate-shaped solid electrolyte and a second electrode on an upper main surface, and the solid electrolyte is around From multilayer ceramics having a first concave portion on the upper surface, which accommodates at least the first electrode of the electrolyte member formed so as to project and has a mounting portion for mounting the protruding portion of the solid electrolyte on the outer periphery. And a first fluid passage formed from the bottom surface of the first recess facing the lower main surface of the electrolyte member to the outer surface of the substrate, and the first electrode of the electrolyte member facing the first electrode. A first wiring conductor having one end disposed on the bottom surface of the first recess and the other end led to the outer surface of the base, and the upper surface of the base surrounding the first recess covering the first recess The second electrode is received Both of the first recesses are hermetically sealed, the second recesses having an abutment part that abuts the extension part on the outer peripheral part and sandwiches the extension part with the mounting part. A lid, a second fluid flow path formed from a lower surface of the lid facing the upper main surface of the electrolyte member to an outer surface of the lid, and the lid facing the second electrode of the electrolyte member A fuel comprising: a second wiring conductor having one end disposed on the lower surface of the body and the other end led to the outer surface of the lid; and an external connection terminal formed on at least one of the base and the lid A battery container, the electrolyte member is placed on the mounting portion of the fuel cell container, and the lower and upper main surfaces of the electrolyte member are the first and second fluid flow paths. Between the first and second fluids so that each fluid can exchange with each other. And the second electrode are electrically connected to the first and second wiring conductors and to the external connection terminals, respectively, and the first recess is formed on the upper surface of the base around the first recess. An electronic apparatus comprising: a cover attached to the cover. The base includes a plurality of the first recesses, one end facing the first electrode of the electrolyte member at one bottom surface of the first recess, and the other end of the first recess. 2. The electronic device according to claim 1, wherein a third wiring conductor facing the first electrode of the electrolyte member is formed on one bottom surface. The base includes a plurality of the first recesses, one end facing the first electrode of the electrolyte member at one bottom surface of the first recess, and the other end of the lid of the base. A fourth wiring conductor led to the upper surface to which the first and second electrodes are attached, one end facing the second electrode of the other electrolyte member of the first recess on the lower surface of the lid, and the other end of the fourth wiring conductor 2. The electron according to claim 1, wherein a fifth wiring conductor led out so as to face the other end of the fourth wiring conductor is formed on a lower surface acquired on the upper surface of the base body of the lid. machine. The base is formed with the first recess for accommodating a plurality of the electrolyte members, one end of the base is opposed to one first electrode of the electrolyte member at the bottom of the first recess, and the other end is The electronic device according to claim 1, wherein a sixth wiring conductor facing the other first electrode of the electrolyte member is formed on a bottom surface of the first recess. The base is formed with the first recess for accommodating a plurality of the electrolyte members, one end of the base is opposed to one first electrode of the electrolyte member at the bottom of the first recess, and the other end is A seventh wiring conductor led out to an upper surface of the base body to which the lid body is attached; one end of the seventh wiring conductor facing the other second electrode of the electrolyte member on the lower surface of the lid body; The eighth wiring conductor led out so as to face the other end of the seventh wiring conductor is formed on a lower surface attached to the upper surface of the base body of the lid. Electronic equipment. An electronic device having a fuel cell as a power source, wherein the fuel cell has a first electrode on a lower main surface of a plate-shaped solid electrolyte and a second electrode on an upper main surface, and the solid electrolyte is around A base body made of multilayer ceramics that has at least the first electrode of the electrolyte member formed so as to be overhanged, and has a concave portion on the upper surface that has a mounting portion for mounting the protruding portion of the solid electrolyte on the outer periphery A first fluid flow path 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 a bottom surface of the recess facing the first electrode of the electrolyte member. A first wiring conductor having one end disposed and the other end led out to the outer surface of the base, and the upper surface around the concave portion of the base covering and attaching the concave portion is hermetically sealed. And the electrolyte One end of the second fluid flow path formed from the lower surface of the lid facing the upper main surface of the material to the outer surface of the lid, and the lower surface of the lid facing the second electrode of the electrolyte member A fuel cell container comprising: a second wiring conductor disposed at the other end and led to the outer surface of the lid; and an external connection terminal formed on at least one of the base and the lid. The electrolyte member is placed on the mounting portion of the fuel cell container, and the lower and upper main surfaces of the electrolyte member are respectively disposed between the first and second fluid flow paths. The base is arranged so that fluid can be exchanged, and the first and second electrodes are electrically connected to the first and second wiring conductors and electrically connected to the external connection terminals, respectively. The recess on the upper surface around the recess An electronic apparatus characterized by comprising by attaching the lid body cover. The base is formed with a plurality of the recesses, one end is opposed to the first electrode of the electrolyte member at one bottom surface of the recess, and the other end is another bottom surface of the recess. The electronic device according to claim 6, wherein a third wiring conductor facing the first electrode of the electrolyte member is formed. The base has a plurality of recesses, one end faces the first electrode of the electrolyte member at one bottom surface of the recess, and the other end is attached to the lid of the base. A fourth wiring conductor led to the upper surface, one end of the lower surface of the lid opposite the second electrode of the other electrolyte member of the recess, and the other end of the base of the lid The electronic device according to claim 6, wherein a fifth wiring conductor led out so as to face the other end of the fourth wiring conductor is formed on a lower surface acquired on the upper surface. The base is formed with the recess for accommodating a plurality of the electrolyte members, one end is opposed to one first electrode of the electrolyte member at the bottom surface of the recess, and the other end is a bottom surface of the recess. The electronic device according to claim 6, wherein a sixth wiring conductor facing the other first electrode of the electrolyte member is formed. The base is formed with the recess for accommodating a plurality of the electrolyte members, one end of the base is opposed to one first electrode of the electrolyte member at the bottom of the recess, and the other end is the base of the base. A seventh wiring conductor led to the upper surface to which the lid is attached; one end of the seventh wiring conductor facing the other second electrode of the electrolyte member on the lower surface of the lid; and the other end of the lid The electronic device according to claim 6, wherein an eighth wiring conductor led out so as to face the other end of the seventh wiring conductor is formed on a lower surface attached to the upper surface of the base. At least one of the first wiring conductor and the second wiring conductor is a periphery of the opening of the first fluid channel on the bottom surface of the first recess or a periphery of the opening of the second fluid channel on the bottom surface of the lid The electronic apparatus according to claim 1, wherein the electronic apparatus is formed so as to abut against the first electrode or the second electrode. At least one of the first wiring conductor and the second wiring conductor is around the opening of the first fluid channel on the bottom surface of the recess or around the opening of the second fluid channel on the bottom surface of the lid. The electronic apparatus according to claim 6, wherein the electronic apparatus is formed so as to abut on the first electrode or the second electrode. The electronic device according to claim 1, wherein an internal circuit is formed on the base body. The electronic device according to claim 13, wherein an electronic component electrically connected to the internal circuit is provided on a surface of the base body. 15. The electronic device according to claim 1, wherein a piezoelectric pump is provided in the middle of at least one of the first and second fluid flow paths.

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