JP2006065770A - Reactor and electric and electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a reactor provided with an apparatus, especially, a small heater capable of cooling a CPU and heating fuel in which heat exchange is performed by forming a path through which the fuel flows into the apparatus generating heat by the operation of an electric and electronic apparatus, and to provide the electric and electronic apparatus on which a fuel cell provided with the reactor. <P>SOLUTION: In order to downsize an apparatus configuration with a reformer 17, the reactor is provided with: a heater 22 provided with a flow path for cooling the apparatus down by depriving the heat of the apparatus generating heat by the operation of the electric and electronic apparatus and heating the fuel so that it is served as both reforming materials reformed by the reformer 17 after heating the fuel efficiently and a cooling catalyst for cooling down the heating apparatus, and the reformer 17 provided with a reforming catalyst for reforming the fuel heated by the heater 22 to hydrogen. Also, the electric and electronic apparatus mounts the fuel cell. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a reaction apparatus and an electric / electronic device, and more particularly to a reaction device including a heater and an electric / electronic apparatus including the reaction device.

  In recent years, fuel cells that have a low environmental impact and can achieve relatively high energy efficiency have been rapidly researched and developed. This fuel cell is classified into solid polymer type, alkaline type, phosphoric acid type, molten carbonate type and solid oxide type, and ion-exchange membrane, potassium hydroxide, phosphoric acid, sodium carbonate / lithium carbonate and yttria stable, respectively. Zirconia electrolyte is used. Since each fuel cell differs in operating temperature, power generation efficiency, scale of power generation device, etc., its use in fields suitable for each fuel cell is being promoted.

  In order to use fuel cells in a wide range of fields, the use frequency and heat durability are improved through research and development of electrolyte materials, the conversion efficiency from chemical energy to electrical energy, and the internal structure of reactors such as reformers and vaporizers Research on improving power generation efficiency by improving control methods and the like has been conducted. In addition, fuel cells and reactors are made smaller using microfabrication technology such as semiconductors and micromachines, and power generation efficiency is improved and research and development for mounting on electric and electronic devices, especially small electronic devices, is being conducted. Yes.

  In particular, in electronic devices that have the advantage of being portable, such as mobile phones and notebook personal computers (hereinafter referred to as personal computers), there is a rapid trend toward miniaturizing fuel cells and reactors as a whole. As a fuel cell and a reaction device used in such an electronic device, a solid polymer using methanol, which can obtain high energy efficiency at an operating temperature exceeding normal temperature, and using a sulfonic acid fluororesin or a carboxylic acid fluororesin as an electrolyte Research on the type of power generation and the internal structure of each reactor and the laminated structure has been conducted to increase the power generation efficiency.

  In addition, a circuit of a central processing unit (hereinafter referred to as a CPU) of an electronic device, in particular a personal computer, is becoming more complex with higher performance of processing power. As the circuit of the CPU becomes complicated, the amount of heat generated by the CPU also increases, and the CPU is liable to malfunction due to heat. For this reason, in order to prevent the CPU from malfunctioning, the computer has heat sink fins that dissipate the heat generated by the CPU at the top of the CPU and is heated by the CPU while taking external air into the side of the computer body. It has a cooling fan that exhausts the air.

  In a desktop personal computer, since the personal computer itself is large, the space between the CPU and a device such as a hard disk drive (hereinafter referred to as HDD) is wide, and the CPU is equipped with a large heat radiation fin and a large cooling fan to cool the CPU. CPU malfunction is prevented from occurring. On the other hand, in a notebook personal computer, the personal computer itself is small, and a space between a CPU and a device such as an HDD is closely attached. For this reason, there is a natural limit to the cooling performance of the radiating fins and cooling fans that radiate the heat generated by the CPU using room temperature air, and there is a high possibility that the CPU will malfunction. In recent years, desktop personal computers are also becoming more multifunctional by integrating with electric devices such as televisions and HDD players, and it is necessary to make the interior of the apparatus smaller. These electric devices are often used continuously for a long time, and it is necessary to cool the CPU heat generated by continuous use for a long time so that the CPU does not malfunction.

For example, as shown in Patent Document 1, there is a notebook personal computer that reduces malfunctions by forcibly cooling a CPU that generates heat by using a condenser unit or an evaporator constituting a heat pipe having a capillary structure as a cooling means. Proposed.
JP 2004-54837 A

  However, by providing the cooling device in the electronic device, it is possible to reliably cool the CPU that has generated heat and suppress malfunction, but in order to further include the cooling device in the electric / electronic device including the reaction device and the fuel cell, There is a problem that it is difficult to significantly reduce the size of each device while maintaining the performance of each device. Further, there is a problem that a large amount of electric energy for operating the cooling device is consumed to cool the CPU that has generated heat.

  The present invention has been made in view of the above-described points, and forms a path through which fuel flows into an apparatus that generates heat by the operation of an electric / electronic device, performs heat exchange to remove heat, and generates heat, particularly a CPU. It is an object of the present invention to provide a reactor capable of cooling the fuel and heating the fuel, and an electric / electronic device equipped with a fuel cell equipped with the reactor.

  The present invention relates to one or a plurality of heaters each having a flow path for heating the fuel while removing the heat of the device that generates heat by the operation of the electric / electronic device, and the fuel heated by the heater. One or a plurality of reformers including a reforming catalyst for reforming into hydrogen.

  According to the present invention, the apparatus that generates heat by depriving the heat by one or a plurality of the heaters having a flow path for heating the fuel by depriving the heat of the apparatus that generates heat by the operation of an electric / electronic device. It can be cooled and the fuel can be heated efficiently.

  The invention according to claim 2 is the reaction apparatus according to claim 1, wherein the heat generating device is at least one of a device including a CPU, a device including a drive source, a device including a light source, and a device including a voltage regulator. It is characterized by being one.

  According to the second aspect of the present invention, the device that generates heat is a device that includes the CPU, a device that includes a drive source, a device that includes the light source, and a device that includes the voltage regulator. One of them is normally operated and generates heat, so that it is possible to stably heat the fuel and cool the device that generates heat.

  According to a third aspect of the present invention, in the reaction apparatus according to the first or second aspect, the heater forms the flow path at least inside the apparatus that generates heat, or outside the apparatus that generates heat. The flow path is formed in the above.

  According to the third aspect of the present invention, by forming the flow path at least inside the device that generates heat or outside the device, the heat can be easily exchanged, and heat is taken away from the device that generates heat. The device that generates heat can be cooled while heating the fuel.

  According to a fourth aspect of the present invention, in the reactor according to the second aspect, the heater is bonded to at least a bonding metal film formed outside the CPU by anodic bonding.

  According to the fourth aspect of the present invention, the CPU is cooled by the inflowing fuel and the fuel is heated by the heat generated by the CPU by being bonded by anodic bonding to the bonding metal film formed by bonding to the outside of the CPU. While making the heater small, it is possible to easily join by reducing distortion during formation of the heater.

  According to a fifth aspect of the present invention, in the reaction apparatus according to the second aspect, the heater is joined to at least the outside of the CPU with an adhesive.

  According to the fifth aspect of the present invention, the heater is bonded to the outside of the CPU by the adhesive, thereby cooling the CPU by the inflowing fuel and heating the fuel by the heat generated by the CPU. The heater can be easily joined while reducing the size of the heater.

  The invention according to claim 6 is the reaction apparatus according to any one of claims 1 to 5, wherein a material of the substrate of the heater is a glass substrate, a plastic substrate, a metal substrate, or a semiconductor substrate. It is characterized by being any one or a composite thereof.

  According to the invention described in claim 6, the heater is any one of the glass substrate, the plastic substrate, the metal substrate, and the semiconductor substrate, or a combination thereof, so that the heater Can be easily and inexpensively formed.

  The invention according to claim 7 is the reaction apparatus according to any one of claims 1 to 6, wherein the shape of the flow path to be heated is a meandering shape or a parallel shape.

  According to the invention described in claim 7, by making the shape of the flow path to be heated the meandering shape or the parallel shape, a contact surface for heat exchange can be widened, and the heat generating device It is easy to exchange heat by depriving of the heat generated.

  The invention described in claim 8 is an electrical / electronic device comprising the reactor according to any one of claims 1 to 7 and a fuel cell.

  According to the eighth aspect of the invention, the power generation efficiency of the fuel cell can be increased by including the reaction device.

  The present invention can remove the heat from the heat generated by the device that generates heat by the operation of the electric / electronic device, efficiently heats the fuel, and then reforms the fuel with the reformer. In addition, since it is also used as a cooling medium, there is an effect that the apparatus structure having the reformer can be reduced in size.

  Embodiments according to the present invention will be described below with reference to FIGS. 1 to 4. However, the embodiments described below are given various technically preferable limitations for carrying out the present invention, but the scope of the invention is not limited to the following embodiments and illustrated examples.

As shown in FIGS. 1 and 2, a notebook personal computer 1 that can be folded in two in the middle includes a display unit 2 that is an output unit and an operation unit 3 that includes an input unit and an arithmetic processing unit. It has been.
The display unit 2 includes a display 4 such as an LCD on which data processed by the arithmetic processing means is output and displayed.
A keyboard (not shown) that is a user input means is provided on the upper surface of the operation unit 3, and a CPU 5 that performs various types of arithmetic processing of a personal computer is built in the downward direction and near the center of the keyboard. .

  A fuel tank 12 for storing fuel in which a carbon compound containing hydrogen atoms such as methanol and ethanol, water, and the like are mixed is inserted in the diagonally rightward direction of the CPU 5. An attachment hole 13 through which the fuel tank 12 can be taken in and out from the outside is provided on the side of the operation unit 3 located in the right direction of the fuel tank 12, and the fuel tank 12 is connected to the operation unit from the attachment hole 13. When it is inserted into 3, the fuel is transferred and connected to the fuel transfer path 14 communicating with the outside. In the middle of the CPU 5 in the middle of the fuel transfer path 14, there is provided a heater 22 that heats the fuel while the CPU 5 cools the CPU 5 by taking heat from the CPU 5, and the fuel tank 12 and the heater 22 are connected to each other. In the meantime, a pump 19 for transferring fuel to the heater 22 through the fuel transfer path 14 is provided.

  Further, downstream of the heater 22 in the middle of the fuel transfer path 14, a vaporizer 16 that takes the heat of the CPU 5 by the heater 22 and vaporizes the heated fuel, and the following chemical reaction formula (1) and chemical reaction formula: As shown in (2), a reformer 17 that reforms the vaporized fuel into hydrogen, and as shown in the following chemical reaction formula (3), carbon monoxide generated during reforming is oxidized into carbon dioxide. A carbon oxide remover 18 and a fuel cell 11 that generates electric power by an electrochemical reaction of hydrogen and oxygen are sequentially arranged as shown in the following chemical reaction formulas (4) and (5). These heater 22, vaporizer 16, reformer 17, and carbon monoxide remover 18 constitute a reaction apparatus 10.

CH ₃ OH + H ₂ O → 3H ₂ + CO ₂ (1)
2CH ₃ OH + H ₂ O → 5H ₂ + CO + CO ₂ (2)
2CO + O ₂ → 2CO ₂ (3)
2H ₂ → 4H ⁺ + 2e ⁻ (4)
4H ⁺ + O ₂ + 2e ⁻ → H ₂ O (5)

  The vaporizer 16 includes two substrates bonded to each other at the bonding surface. Fuel flows into the bonding surface of one or both of the two substrates, and meanders. A path including a concave groove is formed. On the outer wall surfaces of the two substrates, a thin film heater including a heating resistor that generates heat when a voltage is applied and an electric heating material of a thermal semiconductor is formed. The thin film heater is heated by a heater 22. The generated fuel is further heated and vaporized. When the CPU 5 is operating, since the fuel is preheated by the heater 22 by the heat of the CPU 5, the amount of heat required for the vaporization unit 16 to vaporize the fuel can be suppressed.

  At a position adjacent to the carburetor 16, reforming is performed to reform the fuel supplied from the carburetor 16 into hydrogen as shown in the chemical reaction formula (1) and the chemical reaction formula (2). A reformer 17 is provided via a fuel transfer path 14. The reformer 17 emits combustion heat in the lower portion of the reformer 17 by oxidizing the fuel supplied from the vaporizer 16, and the catalytic reaction of the reformer 17. A combustor for raising the temperature is provided (not shown). In addition, you may provide the path | route separately so that a fuel may be directly supplied from the heater 22 to a combustor.

  At a position adjacent to the reformer 17, as shown in the chemical reaction formula (3), carbon monoxide is removed by oxidizing carbon monoxide by-product generated in the reformer 17 to remove carbon monoxide. A vessel 18 is provided via the fuel transfer path 14. The carbon monoxide remover 18 is provided with an air inlet 25 for taking in oxygen necessary for oxidizing carbon monoxide from the outside, and the carbon monoxide remover 18 has a fuel transfer path. 14 is connected to the fuel cell 11.

  The fuel cell 11 includes a fuel electrode carrying catalyst fine particles as shown in the chemical reaction formula (4), an air electrode carrying catalyst fine particles as shown in the chemical reaction formula (5), a fuel electrode, A solid polymer electrolyte membrane (not shown) between the air electrodes, an external circuit (not shown) through which the separated electrons pass, and oxygen in the air from outside An air inlet 26 and an outlet 27 for discharging water generated by a chemical reaction are provided.

  The carbon monoxide is removed by the carbon monoxide remover 18 and the fluid containing hydrogen generated by the reformer 17 flows into the fuel electrode, and is provided in the fuel electrode as shown in the chemical reaction formula (4). Hydrogen is separated into hydrogen ions and electrons by the produced catalyst particles. Hydrogen ions are conducted to the air electrode through the solid polymer electrolyte membrane, and electrons are taken out through an external circuit (not shown). External air flows into the air electrode, and as shown in the chemical reaction formula (5), electrons moved to the air electrode, oxygen in the air, and the solid polymer electrolyte by catalyst particles provided in the air electrode. Passed hydrogen ions are synthesized into water.

  In the left direction of the fuel cell 11, a secondary battery 28 such as a nickel cadmium battery or a nickel metal hydride battery that charges the electric energy generated by the fuel cell 11 is provided. The secondary battery 28 receives electric energy. The fuel cell 11 and the CPU 5 for sending electric energy are connected via an electric circuit.

  On the left side of the secondary battery 28 is provided a transformer 8 that transforms electrical energy generated in the fuel cell 11 via an electric circuit into a current corresponding to the storage input / output device. In the left direction, an HDD 6 and a removable media drive 7 serving as data storage means are provided via an electric circuit. Further, a connection terminal such as a USB for connecting to an external input / output device is provided in the vicinity of the HDD 6 or the removable media drive 7 (not shown).

  The CPU 5 is connected to each device and controls the operation of each device individually and comprehensively. Note that the fuel cell 11, the reactor 10, the HDD 6, the removable media drive 7 and the like may be provided outside the notebook personal computer as long as they are connected to the CPU 5. In addition, the ROM serving as the storage means stores a program for controlling the operation of the pump 19 and the reaction temperature of the reaction apparatus 10 in the power generation of the fuel cell 11.

  The fuel is a simple substance or a composite of a hydrocarbon-based compound containing hydrogen atoms of alcohols such as methanol and ethanol, and gasolines, and may be mixed with water or stored separately. . These hydrocarbon compounds are preferable because they become fuels and have high volatility, so that they can easily take heat from the CPU 5 and vaporize and diffuse to quickly cause a reforming reaction in the reformer 17.

  The material of the reforming catalyst of the reformer 17 is a simple substance of tin, lead, bismuth, antimony, indium, molybdenum and tantalum or a composite thereof, for example, copper-lead oxide, copper-lead oxide-aluminum oxide, copper -Silicon dioxide, lead-zinc oxide, lead-aluminum oxide and platinum-aluminum oxide.

  The material of the carbon monoxide removal catalyst of the carbon monoxide remover 18 is a simple substance of platinum or a composite in which ruthenium or the like is combined with platinum, for example, platinum-aluminum oxide and platinum-ruthenium. The porous carrier at this time is, for example, alumina, silica, titania, zirconia, or the like.

  As shown in FIG. 3, an insulating film 20 that is oxidized at a high temperature to form silicon dioxide is formed above the substrate of the CPU 5, and the upper portion of the insulating film 20 of the CPU 5 has excellent heat conductivity. A bonding metal film 21 is formed. On the upper part of the bonding metal film 21 of the CPU 5, a heater 22 is provided in which a flow path 23 including a concave serpentine groove is provided on a surface in contact with the upper part of the bonding metal film 21. Two protruding inflow pipes 24 a and 24 b in a cylindrical shape are formed at both ends of the concave flow path 23 in the upper surface direction of the heater 22, and are connected to the fuel transfer path 14. . The heater 22 vaporizes the fuel by heating the flow path 23 by heating the heat taken by the bonding metal film 21 from the CPU 5 through the insulating film 20 and heating the fuel passing through the flow path 23. The CPU 5 is cooled while being easily vaporized.

  The material of the heater 22 is a glass substrate, a plastic substrate, a metal substrate, or a semiconductor substrate, and may be a composite substrate having these layers. At this time, a glass substrate that is inexpensive and easy to form, and is excellent in heat resistance and heat dissipation is most preferable. For plastic substrates, heat-resistant resins are preferable, for example, polyarylate, polyimide, caprolactam polyurethane thermoplastic elastomer, polyether ether ketone, polyether ketone, polyether sulfone, polyester thermoplastic elastomer, polycarbonate, polysulfone. Fluorine-based thermoplastic elastomers and fluororesins are preferred. The metal substrate is preferably a metal that is easy to form and easily dissipates heat, and is preferably a simple substance such as iron, copper, zinc, aluminum, nickel, tin, titanium, or an alloy thereof.

  When the heater 22 is a glass substrate, the material of the glass substrate is amorphous made of silicon oxide, alumina, alkali metal oxide, alkaline earth metal oxide, or the like. When the heater 22 is anodically bonded to the bonding metal film 21, the higher the alkali component content in the glass, the easier it is to bond at a low temperature. Therefore, silicate glass, borosilicate glass, aluminosilicate glass, phosphorus The thing of the various glass composition containing alkali metal ions, such as acid salt glass and fluorinate glass, is preferable.

  The shape of the cross section in the vertical direction of the flow path 23 formed in the heater 22 is preferably a triangular shape, a quadrangular shape, a polygonal shape, a circular shape, or a semicircular shape that has a wide surface in contact with the CPU 5 and easily takes the heat of the CPU 5. A semicircular shape that is structurally stable when the volume of the fuel expands is more preferable. Moreover, the shape of the horizontal cross section of the flow path 23 formed in the heater 22 is preferably a meandering shape or a parallel shape that can widen the surface in contact with the CPU 5 and easily take the heat of the CPU.

  The shape of the inflow pipe 24a and the outflow pipe 24b may be any shape as long as the shape can be joined to the fuel transfer path 14, such as a triangular shape, a quadrangular shape, or a polygonal shape, in addition to the cylindrical shape. Moreover, the direction of the protrusions 24 and 24 may be provided in any direction of the side surface direction and the lower surface direction in addition to the upper surface direction of the heater 22, and the number of the inflow pipes 24a and the outflow pipes 24b is as follows. There is no particular limitation.

  The flow path 23 of the heater 22 is formed by using a fine processing technique such as a sand blast method, an etching method, an electron beam exposure method, an ultrasonic processing method, and the shape formed by the CPU 5 when the fuel passes. It is preferable to use a flow path that easily removes heat, such as a meandering concave shape or a parallel concave shape. Etching methods include wet etching for wafer cleaning, plasma etching / excited gas etching, etc., such as sputter etching by dry etching ions or plasma and reactive etching utilizing excitation activity.

  For bonding the bonding metal film 21 and the heater 22 which is a glass substrate on which a flow path is formed, anodic bonding or a high temperature adhesive is used. Since the glass substrate is bonded at a temperature in the vicinity of softening, anodic bonding that is less likely to cause deformation of the glass substrate is preferable to the high-temperature adhesive that easily causes deformation of the glass substrate.

  The material of the bonding metal film 21 is tantel, aluminum, titanium, chromium, iron, cobalt, nickel, cadmium, tin, indium, copper, zinc, tungsten, silicon, etc. from the viewpoint of heat transfer and oxidization at the time of anodic bonding It is a conductor thin film of a simple substance or an alloy.

A method for manufacturing the heater will be described below.
(A) The upper surface which is the back surface of the CPU substrate is polished by a chemical mechanical polishing method, washed with a chemical such as hydrogen peroxide, and then heated at a high temperature in a vacuum to form a silicon dioxide film.
(B) The glass substrate is formed with a concave shape that meanders by a fine processing technique such as sandblasting.
(C) A bonding metal such as titanium is formed on the silicon dioxide film, and the formed glass substrate is bonded by anodic bonding. In this case, anodic bonding is performed with a voltage of 300 V to 800 V, but the insulating film 20 insulates and protects the CPU.
(D) Alternatively, after the glass substrate is heated to a high temperature, the silicon dioxide film formed on the CPU and the glass substrate are bonded with a high-temperature adhesive.

The operation of this embodiment will be described.
Methanol and water, which are fuels, flow from the fuel tank 12 to the flow path 23 formed in the heater 22 through the inflow pipe 24a by the pump 19. The inflowing methanol and water take the heat of the CPU 5 that generates heat below the heater 22 and cool the CPU 5 to lower the temperature of the CPU 5 and heat the fuel itself by heat transfer. The heated methanol and water flow into the carburetor 16 through the fuel transfer path 14 through the outflow pipe 24b, and are further reliably vaporized by heating of the thin film heater provided in the carburetor 16.

  When the vaporized methanol and water flow into the reformer 17 heated by the combustor heated by the methanol supplied from the fuel tank 12 below the reformer 17 via the fuel transfer path 14, the temperature is increased. Hydrogen is generated from the fuel by the reforming catalyst of the reformer 17 that has risen and the reforming reaction has been promoted. The carbon monoxide generated during the reforming is reacted with oxygen in the air taken in from the air inlet 25 by the carbon dioxide remover 18 and oxidized to carbon dioxide.

  The generated hydrogen and carbon dioxide flow into the fuel electrode, which is the fuel cell 11, and separate electrons and hydrogen ions from the hydrogen that flows through the fuel electrode. The separated hydrogen ions move to the air electrode through the electrolyte. On the other hand, electrons pass through an external circuit inside the fuel cell 11 without passing through the electrolyte to obtain electric energy and move to the air electrode. Water is generated by hydrogen ions and electrons that have moved to the air electrode and oxygen in the air taken in from the air inlet 26.

  The obtained electrical energy operates the LCD 4, the removable media drive 7, the HDD 6 and the like of each device of the notebook computer 1 through the transformer 8, and the surplus electrical energy is charged in the secondary battery 28.

From the above, the heater can be formed on the CPU in a small size. Furthermore, even if a large-scale cooling device is not separately provided, a small heater is provided inside or outside the device that generates heat when the electric / electronic device is driven. The heated fuel flows into the vaporizer, and the energy consumed when vaporizing the thin film heater or the like can be reduced by the energy of heating the fuel. Further, since the cooling is performed by taking the heat of the CPU that generates heat from the fuel flowing through the heater, the malfunction of the CPU can be reduced.
Therefore, it is possible to cool the CPU without reducing the size of each device, and to increase the power generation efficiency of the fuel cell.

As shown in FIG. 4, a high temperature adhesive can be used in addition to metal bonding. At this time, the silica film 20 is formed on the upper surface of the CPU 5, and the cooler heating 22 is joined to the upper part of the silica film 20 via a high temperature adhesive. It is possible to take the heat of the CPU, cool the CPU and warm the fuel of the vaporizer in the same manner as the above-described effects.
Further, a heater may be formed inside the substrate of the CPU, and the inside of the heater may have a laminated structure.

Further, although the heater is connected to the vaporizer via the fuel transfer path, the heater may be connected in the middle of the vaporizer and the reformer in order to maintain the temperature of the vaporized fuel.
Furthermore, the device that generates heat by the heater is not limited to the CPU, and any device that generates heat by the operation of the electric / electronic device may be used. For example, as a device that generates heat, a device including a CPU, a device including a drive motor such as an HDD, a compact disk drive (CD), and a digital versatile disk drive (DVD), and a light source such as a backlight and a fluorescent lamp are provided. Examples include a device including a voltage regulator such as a device, an AC adapter, and a transformer. A heater is formed inside or outside to take away heat generated by these operations. Moreover, you may provide a heater in these some apparatus.

Moreover, it is not limited to a notebook computer that can be folded in two in the middle, but may be a flat-plate one.
Furthermore, a heater for a device that generates heat by the operation of the electric / electronic device in an electric / electronic device such as a portable electronic device, a small electronic device or a large electric device equipped with a reaction device and a fuel cell that generates heat by the operation of the electric / electronic device May be provided. Examples of electrical / electronic devices include PDAs, desktop personal computers, televisions, vacuum cleaners, refrigerators, washing machines, CD / DVD / HDD players, and video decks.

  As described above, the heat generated by the operation of the electric / electronic device is taken and cooled, and the energy consumed when vaporizing the fuel with the vaporizer or maintaining the vaporization of the fuel until the reforming reaction is reduced. In addition, the power generation efficiency of the fuel cell can be increased.

It is the schematic of the notebook computer carrying the reaction apparatus provided with the heater, and the fuel cell. It is the schematic of the reaction apparatus and fuel cell provided with the heater. It is the schematic of the heater joined via CPU and the joining metal film. It is the schematic of the heater joined by CPU and the high temperature adhesive agent.

Explanation of symbols

5 CPU
10 Reactor 11 Fuel Cell 22 Heater 23 Fuel Transfer Path

Claims (8)

One or a plurality of heaters having a flow path for heating the fuel while depriving the heat of the device that generates heat by the operation of the electric / electronic device and cooling the device;
One or more reformers comprising a reforming catalyst for reforming the fuel heated by the heater into hydrogen;
A reaction apparatus comprising:   2. The reaction apparatus according to claim 1, wherein the heat generating device is at least one of a device including a CPU, a device including a drive source, a device including a light source, and a device including a voltage regulator. apparatus.   3. The reaction apparatus according to claim 1, wherein the heater forms the flow path at least inside the heat generating apparatus or outside the heat generating apparatus.   3. The reaction apparatus according to claim 2, wherein the heater is bonded to at least a bonding metal film formed outside the CPU by anodic bonding.   3. The reaction apparatus according to claim 2, wherein the heater is joined to at least the outside of the CPU with an adhesive.   6. The reaction apparatus according to claim 1, wherein a material of a substrate of the heater is any one of a glass substrate, a plastic substrate, a metal substrate, and a semiconductor substrate, or a combination thereof. A reactor characterized by being.   The reaction apparatus according to any one of claims 1 to 6, wherein a shape of the heating flow path is a meandering shape or a parallel shape.   An electrical / electronic device comprising the reactor according to any one of claims 1 to 7 and a fuel cell.

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