JP2004319213A - Hydrogen generating device for portable fuel cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a hydrogen generating device for a portable fuel cell for applying to portable equipment by eliminating the need for the use of an off gas and cooling water from the fuel cell. <P>SOLUTION: A partial oxidizing chamber 5, a water vapor reforming chamber 6, a CO oxidizing processing chamber 8, a fuel vaporizing chamber 3, a hydrogen storage alloy chamber 9 and a fuel preheating chamber 2 repeat alternately heat generating and heat absorbing in the order of a partial oxidizing reaction, a water vapor reforming reaction, a CO selection oxidizing reaction, a fuel vaporizing reaction, a hydrogen storage reaction and fuel preheating, respectively, from a high temperature side, and are disposed so as to freely exchange heat with each adjacent reaction. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a hydrogen generator applied to a fuel cell mounted on a portable device, and more particularly to a hydrogen generator configured to generate hydrogen by partial oxidation of a liquid fuel such as dimethyl ether or methanol.
[0002]
[Prior art]
Conventional fuel cell fuel gas generators include an evaporator that vaporizes a liquid raw fuel to generate a fuel vapor, and a fuel gas generated by the evaporator to which reformed air is added to partially oxidize fuel gas to generate hydrogen. Autothermal reformer that generates a reformed gas containing nitrogen, and CO removal that generates a fuel gas from which carbon monoxide has been removed by adding CO-removed air to the reformed gas generated by the autothermal reformer The supply amount of the reforming air when the reformer is warmed up is made larger than the reforming air supply amount during the idling operation after the warming-up is completed. As a result, oxygen in the air excessively supplied to the reformer during warm-up is burned by the catalyst in the reformer, and the heat of combustion heats the reformer and the reformed gas. The quality gas flows downstream and heats the CO remover and the gas flow path in the system to realize early warm-up. (For example, see Patent Document 1)
[0003]
[Patent Document 1]
JP-A-2002-198081 (paragraphs 0007, 0008, FIG. 1)
[0004]
[Problems to be solved by the invention]
A conventional fuel gas generator for a fuel cell is intended to be applied to a fuel cell mounted on an automobile, and can be applied to a fuel cell mounted on a portable device such as a personal computer in terms of size. Was not.
In the conventional fuel gas generator for fuel cells, off-gas from the fuel cell is supplied to a catalytic combustor in an evaporator, burned in the catalytic combustor, and supplied to the evaporator by the heat of combustion. The raw liquid fuel for use and the reformed air are heated, and the fuel gas generated by the CO remover is cooled by cooling water. However, the use of off-gas from the fuel cell to heat the reforming liquid raw fuel and the reforming air, or the use of cooling water to cool the fuel gas, is a practical means to be applied to portable devices. Was not.
[0005]
The present invention has been made in order to solve the above-described problems, and supplies heat generated in an exothermic reaction section in a hydrogen generation process to an endothermic reaction section, thereby eliminating the need for using off-gas or cooling water from a fuel cell. An object of the present invention is to provide a small-sized hydrogen generator for a portable fuel cell that can be applied to portable equipment.
[0006]
[Means for Solving the Problems]
A hydrogen generator for a portable fuel cell according to the present invention is a hydrogen generator for a portable fuel cell that supplies hydrogen to a fuel cell mounted on a portable device, wherein a partial oxidation chamber that generates hydrogen from fuel by a partial oxidation reaction; A hydrogen generator having a steam reforming chamber for generating hydrogen from the fuel by a steam reforming reaction, wherein the partial oxidation chamber and the steam reforming reaction chamber are arranged adjacently so as to be capable of heat exchange, The heat generated by the oxidation reaction is absorbed by the endotherm of the steam reforming reaction to suppress the temperature rise in the partial oxidation chamber.
[0007]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
Embodiment 1 FIG.
FIG. 1 is a block diagram illustrating a configuration of a hydrogen generator for a portable fuel cell according to Embodiment 1 of the present invention.
[0008]
In FIG. 1, the hydrogen generator includes a liquid pump 1, a fuel preheating chamber 2, a fuel vaporization chamber 3, a partial oxidation air blower 4, a partial oxidation chamber 5, a steam reforming chamber 6, a CO oxidation air blower 7, a CO oxidation. A processing chamber 8, a hydrogen storage alloy chamber 9 as a hydrogen storage alloy tank, a three-way switching valve 10, and a control device 11 are provided. The hydrogen storage alloy chamber 9 is adjacent to the fuel preheating chamber 2, the fuel vaporization chamber 3 is adjacent to the hydrogen storage alloy chamber 9, the CO oxidation treatment chamber 8 is adjacent to the fuel vaporization chamber 3, and the steam reforming chamber 6 is A partial oxidation chamber 5 is disposed adjacent to the CO oxidation treatment chamber 8 and further adjacent to the steam reforming chamber 6, so that heat exchange can be performed between adjacent parts.
Here, the partial oxidation reaction in the partial oxidation chamber 5, the CO selective oxidation reaction in the CO oxidation treatment chamber 8, and the hydrogen storage in the hydrogen storage alloy chamber 9 are all exothermic reactions, and the temperature of each part rises. On the other hand, the steam reforming reaction in the steam reforming chamber 6 and the vaporization of the fuel in the fuel vaporizing chamber 3 are endothermic reactions. Further, a hydrogen generator is constituted by the fuel preheating chamber 2, the fuel vaporization chamber 3, the partial oxidation chamber 5, the steam reforming chamber 6, the CO oxidation processing chamber 8, and the like.
[0009]
The fuel preheating chamber 2 is connected to the liquid pump 1 via a three-way switching valve 10 so that a liquid fuel composed of methanol and water is supplied. Then, the fuel supplied to the fuel preheating chamber 2 is preheated by using heat generated by hydrogen storage in the hydrogen storage alloy chamber 9 as a heat source. Here, since the vaporization temperature of methanol is 65 ° C., the preheating temperature of the fuel is 65 ° C. or less.
The fuel vaporization chamber 3 is connected to the fuel preheating chamber 2 so that preheated fuel is supplied. Then, the fuel supplied to the fuel vaporization chamber 3 is vaporized using heat generated by the CO selective oxidation reaction in the CO oxidation processing chamber 8 as a heat source. Here, since the vaporization temperature of water is 100 ° C., the temperature of the fuel vaporized in the fuel vaporization chamber 3 becomes 100 ° C. or higher.
[0010]
The partial oxidation chamber 5 has a partial oxidation catalyst therein, and is supplied with air from the air blower 4. Further, the partial oxidation chamber 5 is connected to the liquid pump 1 via the three-way switching valve 10 and to the fuel vaporization chamber 3, and is vaporized by the liquid fuel from the liquid pump 1 or the fuel vaporization chamber 3. Fuel is supplied. Then, in the partial oxidation chamber 5, hydrogen is generated from the fuel supplied together with the air from the air blower 4 by the partial oxidation reaction represented by the equation (1).
CH ₃ OH + O ₂ /2+1.88N ₂ → CO ₂ + 2H ₂ + 1.88N ₂ Equation (1)
In the partial oxidation reaction, a reverse shift reaction represented by the formula (2) is accompanied, and CO is generated as a by-product.
H ₂ + CO ₂ → CO + H ₂ O Formula (2)
Here, this partial oxidation reaction needs to be suppressed to 300 ° C. or lower because the CO concentration sharply increases when the temperature exceeds 300 ° C.
[0011]
The steam reforming chamber 6 includes a steam reforming catalyst therein and is connected to the fuel vaporizing chamber 3 so that the fuel vaporized in the fuel vaporizing chamber 3 is supplied. Then, in the steam reforming chamber 6, hydrogen is generated from the fuel vaporized by the steam reforming reaction represented by the equation (3) using heat generated by the partial oxidation reaction in the adjacent partial oxidation chamber 5 as a heat source.
CH ₃ OH + H ₂ O → CO ₂ + 3H ₂ -60 kJ / mol Formula (3)
[0012]
The CO oxidation treatment chamber 8 has a CO oxidation catalyst therein and is connected to the partial oxidation chamber 5 and the steam reforming chamber 6, so that the gas generated in the partial oxidation chamber 5 and the steam reforming chamber 6 is supplied. ing. Then, in the CO oxidation treatment chamber 8, the CO in the produced gas is reduced to CO by the CO selective oxidation reaction shown in the equation (4). ₂ Oxidizes to
CO + O ₂ / 2 → CO ₂ Equation (4)
Here, in the CO selective oxidation reaction, if the temperature exceeds 200 ° C., it is difficult to suppress the CO concentration to 10 ppm or less with the current catalyst. Therefore, the optimum temperature of the CO selective oxidation reaction is 150 to 200 ° C.
[0013]
The hydrogen storage metal chamber 9 has a hydrogen storage metal therein and is connected to the CO oxidation processing chamber 8 to supply a hydrogen-rich gas oxidized in the CO oxidation processing chamber 8. Then, in the hydrogen storage alloy chamber 9, hydrogen in the hydrogen-rich gas is stored in the hydrogen storage alloy, and the remaining N is stored. ₂ , CO ₂ Exhaust. Here, the appropriate temperature for hydrogen storage depends on the type of the hydrogen storage alloy, but the optimal operating temperature in the case of a Ti-Cr-V-based hydrogen storage alloy having the largest amount of hydrogen storage is 50 to 100 ° C. .
The controller 11 monitors the temperatures of the partial oxidation chamber 5 and the hydrogen storage alloy chamber 9 and determines that the warm-up is completed when one of the temperatures of the partial oxidation chamber 5 and the hydrogen storage alloy chamber 9 reaches a predetermined temperature. Then, the three-way switching valve 10 is switched so as to supply the liquid raw material to the fuel preheating chamber 2. Here, the temperature of the partial oxidation chamber 5 for determining that the warm-up is completed is, for example, 300 ° C., and the temperature of the hydrogen storage alloy chamber 9 is, for example, 100 ° C.
[0014]
Here, as the partial oxidation catalyst, a catalyst in which a metal such as platinum (Pt), ruthenium (Ru), and nickel (Ni) is supported on alumina or ceramic is used. A catalyst in which a metal such as palladium (Pd) is supported on alumina or ceramic is used as the steam reforming catalyst. A catalyst in which a metal such as platinum (Pt) is supported on alumina or ceramic is used as the CO oxidation catalyst.
[0015]
Next, the operation of the hydrogen generator configured as described above will be described.
First, at the time of startup, since the temperature of one of the partial oxidation chamber 5 and the hydrogen storage alloy chamber 9 is not the predetermined temperature, the control device 11 controls the three-way switching valve so as to supply the liquid fuel to the partial oxidation chamber 5. Switch 10 Thereby, the fuel from the liquid pump 1 is supplied to the partial oxidation chamber 5 together with the air from the air blower 4. Then, in the partial oxidation chamber 5, hydrogen is generated from the fuel by the partial oxidation reaction represented by the equation (1). This generated gas is heated by the heat generated in the partial oxidation reaction, flows from the CO oxidation processing chamber 8 to the hydrogen storage alloy chamber 9 through the flow path, and the flow paths, the CO oxidation processing chamber 8 and the hydrogen storage alloy chamber 9 Heated. Further, the steam reforming chamber 6 adjacent to the partial oxidation chamber 5 is heated by heat generated by the partial oxidation reaction. Thereby, warm-up of the steam reforming chamber 6, the CO oxidation processing chamber 8, and the hydrogen storage alloy chamber 9 is promoted.
Then, in the CO oxidation treatment chamber 8, the gas generated by the partial oxidation reaction is supplied together with the air from the air blower 7, and CO is removed by the CO selective oxidation reaction. Next, the hydrogen-rich gas from which CO has been removed is supplied to the hydrogen storage alloy chamber 9, and hydrogen is stored in the hydrogen storage alloy.
[0016]
When the temperature of one of the partial oxidation chamber 5 and the hydrogen storage alloy chamber 9 reaches a predetermined temperature, the control device 11 determines that the warm-up is completed, and controls the three-way control so that the liquid raw material is supplied to the fuel preheating chamber 2. The switching valve 10 is switched.
Then, the liquid fuel supplied to the fuel preheating chamber 2 is heated by heat generated by hydrogen storage in the adjacent hydrogen storage alloy chamber 9. Next, the heated fuel is supplied to the fuel vaporization chamber 3 and is heated and vaporized by the heat generated by the CO selective oxidation reaction in the adjacent CO oxidation processing chamber 8.
[0017]
The vaporized fuel is supplied to the partial oxidation chamber 5 and the steam reforming chamber 6. Then, in the partial oxidation chamber 5, hydrogen is generated from the fuel vaporized by the partial oxidation reaction, and the generated gas is supplied to the CO oxidation processing chamber 8. Further, in the steam reforming chamber 6, hydrogen is generated from the fuel vaporized by the steam reforming reaction, and the generated gas is supplied to the CO oxidation processing chamber 8. Next, the hydrogen-rich gas from which CO in the generated gas has been removed in the CO oxidation treatment chamber 8 is supplied to the hydrogen storage alloy chamber 9, and hydrogen is stored in the hydrogen storage alloy.
This steam reforming reaction is performed by absorbing heat generated by the partial oxidation reaction in the adjacent partial oxidation chamber 5. The ratio between the partial oxidation and the steam reforming, that is, the ratio between the supply amount of the fuel to the partial oxidation chamber 5 and the supply amount of the fuel to the steam reforming chamber 6, determines the partial oxidation chamber 5 and the steam reforming chamber 6. Can be adjusted to a temperature suitable for each reaction. Here, the cross-sectional area of the flow path from the fuel vaporization chamber 3 to the partial oxidation chamber 5 and the temperature of the steam from the fuel vaporization chamber 3 are set so that the temperature of the partial oxidation chamber 5 becomes 300 ° C. and the temperature of the steam reforming chamber 6 becomes 250 ° C. The cross-sectional area of the flow path to the reforming chamber 6 is set.
[0018]
As described above, in the first embodiment, the partial oxidation chamber 5 and the steam reforming chamber 6 are arranged adjacent to each other so that heat can be exchanged. It can be used as a heat source for the quality room 6. Therefore, it is not necessary to newly provide a cooling mechanism for the partial oxidation chamber 5 and a heating mechanism for the steam reforming chamber 6, and the size can be reduced.
[0019]
Further, since the CO oxidation processing chamber 8 and the fuel vaporization chamber 3 are arranged adjacent to each other so that heat can be exchanged, the heat generated in the CO oxidation processing chamber 8 is generated by the heat source of the fuel vaporization in the fuel vaporization chamber 3. Available as Therefore, there is no need to newly provide a cooling mechanism for the CO oxidation processing chamber 8 or a heating mechanism for the fuel vaporization chamber 3, and the size can be reduced.
[0020]
Further, the partial oxidation chamber 5, the steam reforming chamber 6, the CO oxidation processing chamber 8, the fuel vaporization chamber 3, the hydrogen storage alloy chamber 9, and the fuel preheating chamber 2 are partially oxidized, steam reformed, and CO selected from the high temperature side. Heat generation and heat absorption are alternately repeated in the order of oxidation reaction, fuel vaporization reaction, hydrogen storage reaction, and fuel preheating, and are arranged so that heat exchange is possible between adjacent reactions, so that overheating due to the exothermic reaction is suppressed, and The heat balance is good and each room can be maintained at an appropriate temperature. Further, since the warm-up is promoted by using the heat generated by the partial oxidation reaction, the hydrogen generator can be quickly started.
[0021]
Then, the heat generated in the partial oxidation chamber 5 is absorbed by the endothermic heat of the steam reforming reaction in the steam reforming chamber 6, and the excessive temperature rise in the partial oxidation chamber 5 is suppressed, and the temperature is controlled to 300 ° C. or lower. The CO concentration in the gas can be reduced. Further, the heat generated in the CO oxidation processing chamber 8 is absorbed by the endothermic fuel vaporization in the fuel vaporization chamber 3, and an excessive rise in temperature of the CO oxidation processing chamber 8 is suppressed. Can be suppressed to 10 ppm or less. Further, since the hydrogen storage alloy chamber 9 is disposed adjacent to both the fuel preheating chamber 2 and the fuel vaporization chamber 3, the temperature of the hydrogen storage alloy chamber 9 is maintained at 50 to 100 ° C, and hydrogen storage is efficiently performed. Is performed.
Further, the hydrogen storage alloy chamber 9 and the fuel preheating chamber 2 are arranged adjacent to each other, and the heat generated in the hydrogen storage alloy chamber 9 can be used as a heat source for fuel preheating in the fuel preheating chamber 2. Therefore, it is not necessary to newly provide a cooling mechanism for the hydrogen storage alloy chamber 9 and a heating mechanism for the fuel preheating chamber 2, and the size can be reduced.
[0022]
As described above, this hydrogen generator can be downsized, and it is not necessary to use cooling water to cool the partial oxidation chamber 5, the CO oxidation processing chamber 8, and the hydrogen storage alloy chamber 9, which are heat generating parts. Can be applied.
When the hydrogen generator is mounted on a portable device, the hydrogen storage alloy chamber 9 and the anode electrode of the fuel cell are connected via a hydrogen supply pipe. Then, when the hydrogen storage amount exceeds the storage capacity of the storage alloy, the supply of fuel and air is stopped. Further, when the fuel cell connected to the portable device generates power, hydrogen is supplied from the hydrogen storage alloy. When hydrogen is released from the storage alloy, heat is absorbed, but heat generated by the power generation of the fuel cell is used. As a result, hydrogen is supplied to the anode electrode of the fuel cell, and power generation of the fuel cell is performed. When the hydrogen occluded in the hydrogen storage alloy chamber 9 is depleted, the hydrogen generator can be operated to supply hydrogen to the hydrogen storage alloy chamber 9, so that the hydrogen storage alloy chamber is removed and the hydrogen storage alloy chamber is removed. This eliminates the need for complicated operations such as replenishing hydrogen from a hydrogen generator separately prepared.
[0023]
Here, the hydrogen storage alloy will be described.
The hydrogen storage alloy stores hydrogen gas molecules in a reduced size of approximately 1/1000 due to the generation of metal hydride by the intrusion of hydrogen in the form of atoms between crystal lattices near normal temperature and normal pressure. This hydrogen storage alloy has high safety, high volume density, and has characteristics of generating heat when storing hydrogen and absorbing heat when releasing hydrogen. The hydrogen storage alloy is easily poisoned by water vapor, CO, CO2, and the like.
[0024]
Next, the operation of the hydrogen storage alloy will be described with reference to FIG. FIG. 2 shows LaNi ₅ FIG. 3 shows a pressure-composition isotherm of the H system.
In FIG. 2, the hydride is LaNi ₅ In the case of, when the alloy is kept at a temperature of 20 ° C and a hydrogen pressure of 0.2 MPa or more, ₅ H _6.7 Produces hydroxide. The hydrogen content is represented by the hydrogen composition H / M, LaNi ₅ In the case of 1, the number of metal atoms in lanthanum 1 and nickel 5 is 1 + 5 = 6, and a hydride containing hydrogen up to 6.7 is generated, so that H / M = 6.7 / 6 = 1.12.
Although not shown in FIG. 2, when represented by weight% of hydrogen in the metal hydride, LaNi ₅ Since 439 g of hydride of the alloy contains 6.7 g of hydrogen, the hydrogen content is 1.5% by weight.
In FIG. 2, when a hydride of composition C at 20 ° C. is heated to 60 ° C., hydrogen at a pressure of 0.6 MPa is released until it becomes a hydride of composition B. That is, by storing hydrogen at a low temperature and releasing it at a high temperature, the hydrogen storage amount between the composition B and the composition C can be used. As described above, in the plateau region, a large amount of hydrogen is occluded or released from the solid phase at a constant temperature and low pressure, and thus it can be seen that the alloy has properties convenient for application. Since the width of the plateau region becomes the effective hydrogen storage amount, it is desirable to use an alloy having a plateau region as large as possible.
[0025]
Embodiment 2 FIG.
FIG. 3 is a perspective view schematically showing a hydrogen generator for a portable fuel cell according to Embodiment 2 of the present invention, and FIG. 4 illustrates the configuration of a hydrogen generator for liquid fuel cells according to Embodiment 2 of the present invention. FIG.
[0026]
3 and 4, the hydrogen generator includes a fuel holding unit 15 as a fuel tank, a fuel preheating chamber 16, a fuel vaporization chamber 17, a reforming unit 18, and a hydrogen tank unit 24 as a hydrogen storage alloy tank. . The hydrogen supply port of the hydrogen tank unit 24 is connected to an anode electrode of the fuel cell 14 which is disposed adjacently through a hydrogen supply pipe (not shown). Here, the fuel holding unit 15, the fuel preheating chamber 16, the fuel vaporization chamber 17, the reforming unit 18, and the like constitute a hydrogen generator. Further, the fuel holding unit 15 is configured to be detachable, and the fuel holding unit 15 is detached to replenish the fuel.
[0027]
The reformer 18 includes a closed cylindrical partial oxidation chamber 19 having a partial oxidation catalyst therein, and a closed cylindrical steam chamber formed to surround the partial oxidation chamber 19 and having a steam reforming catalyst therein. It comprises a reforming chamber 20, a closed cylindrical CO oxidation treatment chamber 21 formed so as to surround the steam reforming chamber 20, and having a CO oxidation catalyst therein. An air blowing channel 23 that supplies air to the CO processing chamber 20 and the CO processing chamber 21 is formed.
[0028]
The fuel holding unit 15 is a tank for storing a liquid fuel composed of methanol and water, and is provided between the reforming unit 18 and the hydrogen tank unit 24. A fuel vaporization chamber 17 is formed between the fuel holding unit 15 and the reforming unit 18, and absorbs heat generated in the CO oxidation processing chamber 21 to vaporize liquid fuel. Further, the fuel vaporization chamber 17 and the partial oxidation chamber 20 communicate with each other via a flow path (not shown), and the fuel vaporization chamber 17 and the steam reforming chamber 21 communicate with each other via a flow path (not shown). The fuel vaporized in the fuel vaporization chamber 17 can be supplied to the partial oxidation chamber 19 and the steam reforming chamber 20.
[0029]
Further, the fuel passage 25 is formed so as to extend from the fuel outlet provided on the hydrogen tank portion 24 side of the fuel holding portion 15 to the fuel vaporization chamber 17 side via the outer periphery of the fuel holding portion 15. A branch valve (not shown) such as an electromagnetic valve is provided so as to selectively supply the fuel flowing through the fuel passage 25 to one of the fuel vaporization chamber 17 and the partial oxidation chamber 19. Further, a hydrogen gas flow path 26 is formed so as to communicate the CO oxidation treatment chamber 21 and the hydrogen tank unit 24. Here, since the fuel passage 25 is formed along the hydrogen tank 24 and the hydrogen gas passage 26, the fuel passage 25 absorbs heat generated in the hydrogen tank 24 and heat of the hydrogen-rich gas flowing through the hydrogen gas passage 26. To form a fuel preheating chamber 16 for preheating fuel.
[0030]
Next, the operation of the hydrogen generator configured as described above will be described.
First, at the time of startup, since the temperature of one of the partial oxidation chamber 19 and the hydrogen tank 24 is not at the predetermined temperature, the control device (not shown) controls the branch valve so as to supply the fuel to the partial oxidation chamber 19. Switch. As a result, the fuel flows from the fuel holding section 15 through the fuel preheating chamber 16 (fuel flow path 25) and is supplied to the partial oxidation chamber 19. At the same time, air is supplied from the air intake 22 to the partial oxidation chamber 19 through the air blowing passage 23. Then, in the partial oxidation chamber 19, hydrogen is generated from the fuel by the partial oxidation reaction represented by the equation (1). This generated gas is heated by the heat generated by the partial oxidation reaction, flows from the CO oxidation processing chamber 21 to the hydrogen tank section 24 via the hydrogen gas flow path 26, and is then subjected to the CO oxidation processing chamber 21, the hydrogen gas flow path 26, and the hydrogen tank section. 24 is heated. Further, the steam reforming chamber 20 adjacent to the partial oxidation chamber 19 is heated by heat generated by the partial oxidation reaction. Thereby, warm-up of the steam reforming chamber 20, the CO oxidation processing chamber 21, and the hydrogen tank unit 24 is promoted. Further, the fuel flowing through the fuel preheating chamber 16 is heated by absorbing the heat of the hydrogen tank 24 and the heat of the hydrogen-rich gas flowing through the hydrogen gas flow path 26.
Then, in the CO oxidation treatment chamber 21, a gas generated by the partial oxidation reaction is supplied from the partial oxidation chamber 19, and air is supplied from the air intake port 22 through the air blowing passage 23, and the CO selection shown in the equation (4) is performed. CO in the product gas is removed by the oxidation reaction. Next, the hydrogen-rich gas from which CO has been removed is supplied to the hydrogen tank 24 via the hydrogen gas flow path 26, and hydrogen is stored in the hydrogen storage alloy contained in the hydrogen tank 24.
[0031]
Then, when one of the temperatures of the partial oxidation chamber 19 and the hydrogen tank section 24 reaches a predetermined temperature, the control device determines that the warm-up is completed, and switches the branch valve so as to supply the fuel to the fuel vaporization chamber 17. .
Then, the fuel preheated in the fuel preheating chamber 16 is supplied to the fuel vaporizing section 17, and is heated and vaporized by the heat generated by the CO selective oxidation reaction in the CO oxidation processing chamber 21.
[0032]
The vaporized fuel is supplied to the partial oxidation chamber 19 and the steam reforming chamber 20, respectively. Then, in the partial oxidation chamber 19, hydrogen is generated from the fuel vaporized by the partial oxidation reaction, and the generated gas is supplied to the CO oxidation processing chamber 21. Further, in the steam reforming chamber 20, hydrogen is generated from the fuel vaporized by the steam reforming reaction represented by the formula (3), and the generated gas is supplied to the CO oxidation processing chamber 21. Next, the generated gas is subjected to removal of CO in the CO oxidation treatment chamber 21 to become a hydrogen-rich gas, and this hydrogen-rich gas is supplied to the hydrogen tank unit 24 through the hydrogen gas flow path 26, and hydrogen is stored in the hydrogen storage alloy. .
[0033]
Then, when the hydrogen storage amount of the hydrogen tank section 24 exceeds the storage capacity of the storage alloy, the supply of fuel and air is stopped. When the fuel cell 14 connected to the portable device generates power, hydrogen is supplied from the hydrogen tank 24 to the anode electrode of the fuel cell 14. When hydrogen is released from the storage alloy, heat is absorbed, but the heat generated by the power generation of the fuel cell 14 is used. As a result, hydrogen is supplied to the anode electrode of the fuel cell 14, and air is supplied to the cathode electrode from, for example, a supercharger (not shown), so that the fuel cell 14 performs power generation.
[0034]
Also in the second embodiment, the partial oxidation chamber 19 and the steam reformer 20 are arranged adjacent to each other so that heat exchange can be performed. Therefore, similarly to the first embodiment, since the heat generated in the partial oxidation chamber 19 can be used as a heat source for the steam reforming chamber 20, a cooling mechanism for the partial oxidation chamber 19 and a heating mechanism for the steam reforming chamber 20 are newly provided. There is no need to provide this, the size can be reduced, and the heat generated in the partial oxidation chamber 19 is absorbed by the steam reforming chamber 20 and an excessive rise in the temperature of the partial oxidation chamber 19 is suppressed. Can be reduced.
[0035]
Further, since the CO oxidation processing chamber 21 and the fuel vaporization chamber 17 are arranged adjacent to each other so that heat can be exchanged, heat generated in the CO oxidation processing chamber 21 is generated by the heat source of the fuel vaporization in the fuel vaporization chamber 17. Available as Therefore, similarly to the first embodiment, it is not necessary to newly provide a cooling mechanism for the CO oxidation processing chamber 21 and a heating mechanism for the fuel vaporization chamber 17, and the size can be reduced.
[0036]
Further, the heat generated in the hydrogen tank chamber 24 is transmitted to the fuel vaporization chamber 17 via the fuel flowing through the fuel preheating chamber 16. Therefore, the partial oxidation chamber 19, the steam reforming chamber 20, the CO oxidation processing chamber 21, the fuel vaporization chamber 17, and the hydrogen tank chamber 24 are partially oxidized from a high temperature side, a steam reforming reaction, a CO selective oxidation reaction, and a fuel vaporization reaction. In addition, heat generation and heat absorption are alternately repeated in the order of the hydrogen storage reaction, and are arranged so that heat exchange is possible between adjacent reactions. Therefore, similarly to the first embodiment, overheating due to the exothermic reaction is suppressed, and each chamber can be maintained at an appropriate temperature.
[0037]
Embodiment 3 FIG.
5 is a sectional view showing a hydrogen generator for a portable fuel cell according to Embodiment 3 of the present invention, FIG. 6 is a sectional view taken along line VI-VI of FIG. 5, and FIG. 7 is a sectional view taken along line VII-VII of FIG. FIG.
[0038]
5 to 7, the hydrogen generator includes a hydrogen generator 30 and a hydrogen storage alloy tank 31 as a hydrogen storage alloy chamber having a hydrogen storage alloy therein. The hydrogen generator 30 includes an external container 33, a fuel tank 34, a flow path body 37, a small booster pump 55, and the like.
The hydrogen storage alloy tank 31 is attached to a flat mounting surface 33a formed on the upper part of the outer container 33 by a coupler 32 and is detachably mounted. Further, the fuel tank 34 is disposed on the side of the outer container 33 on which the hydrogen storage alloy tank is installed, and the flow path body 37 is insulated and supported in the housing 33 by the heat insulating materials 46 and 47. It is arranged on the alloy tank installation side.
[0039]
The fuel tank 34 is disposed adjacent to the mounting surface 33a on the upper side in the outer container 33, and is configured to supply and store liquid fuel via a fuel inlet 35. A band-shaped fuel conductor 36 is spirally wound around the outer periphery of the fuel tank 34 with one end extending into the fuel tank 34. The fuel guide 36 is in close contact with the inner wall surface of the outer container 33. Note that the fuel conductor 36 only needs to have hygroscopicity, heat resistance and solvent resistance, and fibers such as cellulose fibers are used.
[0040]
The flow path body 37 is provided in a lower part of the fuel tank 34 and is insulated and supported in the outer container 33 by heat insulating materials 46 and 47 and a space. A space formed between the flow path body 37, the outer container 33, and the fuel tank 34 constitutes a fuel vaporization chamber 38.
In the flow path body 37, a partial oxidation chamber 40, a steam reforming chamber 42, and a CO oxidation processing chamber 44, each of which is defined as a U-shaped elongated flow path by a partition plate 39 as a partition wall, have a mounting surface 33a. And are arranged concentrically on the same plane parallel to. Then, the partial oxidation catalyst 41 is applied and formed on the wall surface of the partial oxidation chamber 40, the steam reforming catalyst 43 is applied and formed on the wall surface of the steam reforming chamber 42 on the side of the partial oxidation chamber 40, and the CO oxidation catalyst 45 is further formed by CO oxidation. It is formed on the wall surface of the processing chamber 44 on the steam reforming chamber 42 side. Here, the partition plate 39 is made of a good heat conductive material such as aluminum, and has an inclination of an angle θ (θ = 30 degrees) with respect to the mounting surface 33a of the external container 33 to which the hydrogen storage alloy tank 31 is mounted. It is arranged in. The portion of the fuel vaporization chamber 38 on the outer peripheral side of the CO oxidation processing chamber 44 is formed as an elongated flow path along the outer circumference of the CO oxidation processing chamber 44, and the partial oxidation chamber 40, the steam reforming chamber 42, and the CO oxidation Together with the processing chamber 44, it is located on the same plane parallel to the mounting surface 33a.
[0041]
Further, a first hydrogen gas flow path 48 is formed between the lower end of the flow path body 37 and the bottom of the outer container 33, being isolated from the fuel vaporization chamber 38 by the heat insulating material 46. The partial oxidation chamber 40, the steam reforming chamber 42, and the CO oxidation processing chamber 44 are connected to the first hydrogen gas flow path 48 via a hydrogen permeable film 49 made of, for example, Pd in a hydrogen permeable state. A vaporized fuel flow path 52 is provided such that the first air intake flow path 50 communicates the outside with the partial oxidation chamber 40 and the second air intake flow path 51 communicates the outside with the CO oxidation processing chamber 44. Communicates with the fuel vaporization chamber 38 and the partial oxidation chamber 40 and the steam reforming chamber 42 so that CO ₂ The external vessels 33 are connected so that the exhaust passage 53 connects the CO oxidation chamber 44 to the outside, and the second hydrogen gas passage 54 connects the first hydrogen gas passage 48 and the coupler 32. Is formed.
[0042]
In addition, the small boost pump 55 includes a small motor 56 driven by a small battery, a household power supply, or the like. The small booster pump 55 acts on the second hydrogen gas flow path 54 to increase the pressure of the hydrogen gas generated in the partial oxidation chamber 40 and the steam reforming chamber 42 and send it to the hydrogen storage alloy tank 31 in the first pump chamber. A first air supply unit 58 as a second pump chamber that acts on the first air intake passage 50 to supply air (oxygen) to the partial oxidation chamber 40, and a second air intake unit A second air supply unit 59 serving as a third pump chamber that acts on the flow path 51 to supply air (oxygen) to the CO oxidation processing chamber 44; ₂ The CO generated in the CO oxidation treatment chamber 44 acts on the exhaust passage 53. ₂ As a fourth pump chamber for exhausting air to the outside ₂ A pump function for preventing the flow of a small amount of liquid raw material into the respective reaction chambers when the pump is stopped, and a valve function for preventing the flow of fuel whose pressure is increased when hydrogen is generated, thereby driving the rotation of the pump. And a pump power unit 61 as a fifth pump chamber having a function of assisting the pumping. Then, the hydrogen pressurizing section 57, the first and second air supply sections 58 and 59, CO ₂ The exhaust unit 60 and the pump power unit 61 are configured to rotate in the same direction by a single drive shaft 56a driven by a small motor 56, so that pressure increase, intake, and exhaust are smoothly performed for each pump chamber. ing.
[0043]
The same materials as in the first embodiment are used for the partial oxidation catalyst, the steam reforming catalyst, the CO oxidation catalyst, and the hydrogen storage alloy.
[0044]
Next, the operation of the hydrogen generator configured as described above will be described.
First, liquid fuel composed of a mixture of methanol and water is filled into the fuel tank 34 from the fuel inlet 35 and permeates into the fuel guide 36. The liquid fuel permeated into the fuel guide 36 is guided to the outside of the fuel tank 34 to be vaporized, and fills the fuel vaporization chamber 38.
[0045]
Therefore, when the small motor 56 is driven to rotate, the vaporized fuel filled in the fuel vaporization chamber 38 passes through the vaporized fuel flow path 52 to the partial oxidation chamber 40 and the steam reforming chamber 42 by the operation of the pump power unit 61. While being supplied, the air is supplied to the partial oxidation chamber 40 through the first air intake passage 50 by the operation of the first air supply unit 58. At this time, the vaporized fuel contacts the partial oxidation catalyst 41 and the steam reforming catalyst 43 along the elongated flow paths of the partial oxidation chamber 40 and the steam reforming chamber 42 as indicated by arrows in FIG. Flowing in the direction. Thereby, a partial oxidation reaction is started near the partial oxidation catalyst 41. Then, when the temperature of the partial oxidation chamber 40 rises due to the heat generated by the partial oxidation reaction, heat is transmitted to the steam reforming chamber 42 through the partition plate 39. Then, the steam reforming catalyst 43 applied to the partition plate 39 between the partial oxidation chamber 40 and the steam reforming chamber 42 is heated. Then, the generated gas generated in the partial oxidation chamber 40 flows to the CO oxidation processing chamber 44, and the CO oxidation catalyst 45 is heated. Further, the hydrogen permeable film 49 is heated by the generated gas generated in the partial oxidation chamber 40. Thereby, the steam reforming chamber 42, the CO oxidation processing chamber 44, and the hydrogen permeable membrane 49 are warmed up.
[0046]
Therefore, the steam reforming reaction is started near the steam reforming catalyst 43 formed on the partition plate 39 between the partial oxidation chamber 40 and the steam reforming chamber 42.
The product gas generated by the partial oxidation reaction and the steam reforming reaction is supplied from the partial oxidation chamber 40 and the steam reforming chamber 42 to the CO oxidation processing chamber 44. At this time, these generated gases flow in one direction while being in contact with the CO oxidation catalyst 45 along the elongated flow path of the CO oxidation processing chamber 44, as indicated by arrows in FIG. On the other hand, the air is supplied to the CO oxidation processing chamber 44 through the second air intake passage 51 by the operation of the second air supply unit 59. Thus, a CO selective oxidation reaction is started near the CO oxidation catalyst 45 in the CO oxidation treatment chamber 44, and CO in the generated gas is removed. Then, the CO generated in the CO oxidation treatment chamber 44 ₂ But CO ₂ By operating the exhaust unit 60, CO 2 ₂ The air is exhausted to the outside through the exhaust passage 53.
[0047]
Further, the hydrogen in the product gas in the partial oxidation chamber 40, the steam reforming chamber 42, and the CO oxidation processing chamber 44 moves through the heated hydrogen permeable membrane 49 into the first hydrogen gas flow path 48. Then, the hydrogen that has moved into the first hydrogen gas flow path 48 is pressurized to about 0.5 MPa by the operation of the hydrogen pressurizing section 57, and is passed through the second hydrogen gas flow path 54 and the coupler 32. And is stored in the hydrogen storage alloy tank 31.
[0048]
As described above, also in the third embodiment, the partial oxidation chamber 40 and the steam reformer 42 are arranged adjacent to each other so that heat exchange can be performed. Therefore, similarly to the first embodiment, since the heat generated in the partial oxidation chamber 40 can be used as a heat source for the steam reforming chamber 42, a cooling mechanism for the partial oxidation chamber 40 and a heating mechanism for the steam reforming chamber 42 are newly provided. There is no need to provide this, and downsizing is achieved, and the heat generated in the partial oxidation chamber 40 is absorbed by the steam reforming chamber 42, and warm-up of the steam reforming chamber 42 is promoted.
[0049]
Further, since the CO oxidation processing chamber 44 and the fuel vaporization section 38 are arranged adjacent to each other so that heat can be exchanged, heat generated in the CO oxidation processing chamber 41 can be used as a heat source of the fuel vaporization section 38. Therefore, it is not necessary to newly provide a cooling mechanism for the CO oxidation processing chamber 44 and a heating mechanism for the fuel vaporization section 38, and the size can be reduced.
[0050]
The partial oxidation chamber 40, the steam reforming chamber 42, the CO oxidation processing chamber 44, the fuel vaporization chamber 38, and the hydrogen storage alloy tank 31 are partially oxidized from the high temperature side, a steam reforming reaction, a CO selective oxidation reaction, and a fuel vaporization. The heat generation and the heat absorption are alternately repeated in the order of the reaction and the hydrogen storage reaction, and the arrangement is such that heat exchange is possible between adjacent reactions. Thus, similarly to Embodiment 1, overheating due to the exothermic reaction is suppressed, and each chamber can be maintained at an appropriate temperature.
[0051]
As a result, the heat generated in the partial oxidation chamber 40 is absorbed by the endothermic heat of the steam reforming reaction in the steam reforming chamber 42, and an excessive rise in the temperature of the partial oxidation chamber 40 is suppressed. The CO concentration in the generated gas can be reduced. In addition, the heat generated in the CO oxidation processing chamber 44 is absorbed by the endothermic fuel vaporization in the fuel vaporization chamber 38, and an excessive temperature rise in the CO oxidation processing chamber 44 is suppressed, and the CO oxidation processing chamber 44 is controlled to 200 ° C. or less. Can be suppressed to 10 ppm or less. Further, since the hydrogen storage alloy tank 31 is arranged adjacent to the fuel vaporization chamber 38, the temperature of the hydrogen storage alloy tank 31 is controlled to 100 ° C. or less, and hydrogen storage is performed efficiently.
[0052]
Further, the hydrogen storage alloy chamber 31 and the fuel vaporization section 38 are arranged adjacent to each other, and heat generated in the hydrogen storage alloy chamber 9 can be used as a heat source of the fuel preheating section 2. Therefore, it is not necessary to newly provide a cooling mechanism for the hydrogen storage alloy chamber 9 and a heating mechanism for the fuel preheating unit 2, and the size can be reduced.
In addition, since aluminum is used for the partition plate 39, heat conduction between the chambers 38, 40, 42, and 44 is efficiently performed, and warm-up can be promoted.
Further, since the partition plate 39 is formed as an inclined surface having an angle θ of 30 degrees with respect to the mounting surface 33a of the external container 33, the space of each of the chambers 40, 42, and 44 can be reduced to increase the heat transfer area. Therefore, the size of the hydrogen generator 30 can be reduced, and the state of the hydrogen generator 30 can be quickly warmed up, and the rising characteristics of the hydrogen generator 30 can be improved. Further, since the coating formation area of each of the catalysts 41 and 43 can be increased, hydrogen is efficiently generated.
[0053]
Further, the partial oxidation chamber 40, the steam reforming chamber 42, and the CO oxidation processing chamber 44 are formed in an elongated flow path, and the fuel and the reaction gas flow in the length direction of the flow path, that is, in one direction. Therefore, there is no localization of the reaction molecules of the fuel and the reaction gas in the flow path, and the probability that the reaction molecules come into contact with the catalysts 41, 43, and 45 is increased, and the reaction efficiency can be increased. Further, since the steam reforming catalyst 43 is formed on the partition plate 39 on the side of the partial oxidation chamber 40 of the flow path constituting the steam reforming chamber 42, heat in the partial oxidation chamber 40 is applied to the steam reforming catalyst 43. It is quickly conducted and promotes warm-up of the steam reformer 42 where the steam reforming reaction is started. Further, since the CO oxidation catalyst 45 is applied to the partition plate 39 on the steam reforming chamber 42 side of the flow path constituting the CO oxidation processing chamber 44, heat in the steam reforming chamber 42 is applied to the CO oxidation catalyst 45. It is quickly conducted and promotes warm-up of the CO oxidation treatment chamber 44 where the CO selective oxidation reaction is started.
[0054]
Further, since the fuel guide 36 is spirally wound around the outer periphery of the fuel tank 34, the fuel that permeates the fuel guide 36 and is vaporized outside the fuel tank 34 passes through the space between the fuel guides 36 and is vaporized. It moves to the room 38 promptly. Further, since the fuel conductor 36 is in contact with the inner wall surface on the mounting surface 33 a side of the outer container 33, heat generated by hydrogen storage in the hydrogen storage alloy tank 31 is transmitted to the fuel conductor 36 via the outer container 33. The preheating of the fuel takes place. Since the fuel conductor 36 is in contact with the CO oxidation chamber 44 via the fuel vaporization chamber 38, the heat in the CO oxidation chamber 44 is conducted to the fuel conductor 36, and the vaporization of the fuel is promoted.
[0055]
Further, since the hydrogen storage alloy tank 31 is adjacent to the fuel conductor 36, heat generated in the hydrogen storage alloy tank 31 is absorbed by preheating and vaporization of the fuel in the fuel conductor 36. Thereby, an excessive rise in the temperature of the hydrogen storage alloy tank 31 is suppressed, and hydrogen storage is performed efficiently.
In addition, since the partial oxidation chamber 40, the steam reforming chamber 42, the CO oxidation processing chamber 44, and the fuel liquefaction chamber 38 are disposed on the same plane parallel to the mounting surface 33a, a planar mounting surface is provided. The area of 33a can be increased. Therefore, the contact area between the hydrogen storage alloy tank 31 and the mounting surface 33a increases, and the heat conduction from the hydrogen storage alloy tank 31 to the mounting surface 33a is improved.
[0056]
Further, since the partial oxidation chamber 40, the steam reforming chamber 42, and the CO oxidation processing chamber 44 communicate with the first hydrogen gas flow path 48 in a hydrogen permeable state through the hydrogen permeable membrane 49, the first hydrogen gas flow path CO or CO to 48 ₂ Is stopped. As a result, CO and CO ₂ The poisoning of the hydrogen storage alloy and the fuel cell in the hydrogen storage alloy tank 31 is prevented, and a stable operation can be performed for a long time.
[0057]
Further, since the hydrogen that has moved to the first hydrogen gas flow path 48 is pressurized to about 0.5 MPa by the small pressurizing pump 55 and is conveyed to the hydrogen storage alloy tank 31, the internal pressure of the hydrogen storage alloy tank 31 becomes higher than normal pressure. In addition, hydrogen is efficiently stored. In addition, since the suction by the small pressure pump 55 increases the permeation efficiency of hydrogen through the hydrogen permeable membrane 49, hydrogen is transferred from the partial oxidation chamber 40, the steam reforming chamber 42, and the CO oxidation treatment chamber 44 to the first through the hydrogen permeable membrane 49. It effectively moves to the hydrogen gas flow path 48, and the hydrogen storage efficiency is improved.
Further, hydrogen is sucked by the small pressurizing pump 55, and CO ₂ Exhaust of air and air to the outside creates a flow of fuel from the fuel vaporization chamber 38 to the partial oxidation chamber 40 and the steam reforming chamber 42, preventing the backflow of the reaction gas and allowing each reaction to proceed smoothly. .
[0058]
Further, when hydrogen is generated, the pressure caused by the vaporization of the fuel introduced into the pump power unit 61 and the flow of the vaporized fuel serve as power to rotate the drive shaft of the small booster pump 55. Power is assisted, and labor is saved.
Further, since the hydrogen storage alloy tank 31 is configured to be detachable, by exposing the hydrogen storage alloy tank 31 attached to the portable device to the outside, it is possible to remove the hydrogen storage alloy tank 31 from the portable device. In addition, hydrogen can be stored in the hydrogen storage alloy tank 31. In order to enable heat exchange between the hydrogen storage alloy tank 31 and the hydrogen generator 30, it is desirable that the hydrogen storage alloy tank 31 and the outer container 33 be made of a material having excellent heat conductivity, for example, aluminum.
[0059]
In the third embodiment, the partition plate 39 is formed at an angle of 30 degrees with respect to the mounting surface 33a of the external container 33. However, the angle θ of the partition plate 39 with respect to the mounting surface 33a is determined by machining. It is desirable to set the angle to 30 to 60 degrees in consideration of the properties, the area of the partition plate 39, the shape of the outer container 33, and the like.
In the third embodiment, a small motor 56 and a small booster pump 55 using a battery as a power source are used. However, a pump using spring power as a power source may be used.
[0060]
Further, in the third embodiment, when the partial oxidation reaction is unlikely to be started only by the supply of air by the small booster pump 55, a heater is provided in the flow passage body 37 in proximity to the partial oxidation chamber 40. Alternatively, the heater may be energized at the time of startup to accelerate the start of the partial oxidation reaction. In this case, if the partial oxidation reaction is started, a warm-up state is generated by the heat generated by the exothermic reaction. Therefore, heating by the heater is necessary only for starting the reaction, and the power consumed by the heater is extremely small.
[0061]
Further, in each of the above embodiments, methanol and water are used as the fuel, but the fuel is not limited to this, and for example, dimethyl ether and water may be used.
[0062]
【The invention's effect】
As described above, the present invention includes a hydrogen generator having a partial oxidation chamber for generating hydrogen from fuel by a partial oxidation reaction, and a steam reforming chamber for generating hydrogen from fuel by a steam reforming reaction, The oxidation chamber and the steam reforming reaction chamber are arranged adjacent to each other so that heat can be exchanged, and the heat generated by the partial oxidation reaction is absorbed by the endothermic heat of the steam reforming reaction, so that the temperature rise in the partial oxidation chamber is suppressed. Thus, a small-sized hydrogen generator for a portable fuel cell which can be applied to a portable device without using off-gas or cooling water from the fuel cell is obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of a portable fuel cell hydrogen generator according to Embodiment 1 of the present invention.
FIG. 2 LaNi ₅ It is a pressure-composition isotherm diagram of -H system.
FIG. 3 is a perspective view schematically showing a hydrogen generator for a portable fuel cell according to Embodiment 2 of the present invention.
FIG. 4 is an internal configuration diagram for describing a configuration of a hydrogen generator for a liquid fuel cell according to Embodiment 2 of the present invention.
FIG. 5 is a sectional view showing a hydrogen generator for a portable fuel cell according to Embodiment 3 of the present invention.
6 is a sectional view taken along the line VI-VI in FIG.
7 is a sectional view taken along the line VII-VII in FIG.
[Explanation of symbols]
3 fuel vaporization chamber, 5 partial oxidation chamber, 6 steam reforming chamber, 8 CO oxidation treatment chamber, 9 hydrogen storage alloy chamber (hydrogen storage alloy tank), 15 fuel holding unit (fuel tank), 17 fuel vaporization chamber, 19 parts Oxidation chamber, 20 steam reforming chamber, 21 CO oxidation treatment chamber, 24 hydrogen tank (hydrogen storage alloy tank), 30 hydrogen generator, 31 hydrogen storage alloy tank, 33 external container, 33a mounting surface, 34 fuel tank, 36 Fuel conductor, 38 fuel vaporization chamber, 39 partition plate (partition wall), 40 partial oxidation chamber, 41 partial oxidation catalyst, 42 steam reforming chamber, 43 steam reforming catalyst, 44 CO oxidation treatment chamber, 45 CO oxidation catalyst, 48 first hydrogen gas flow path, 49 hydrogen permeable membrane, 54 second hydrogen gas flow path, 55 small booster motor, 56a drive shaft, 57 hydrogen booster (first pump chamber), 58 first air supply unit (second Pong Pump chamber), 59 2nd air supply section (3rd pump chamber), 60 CO ₂ Exhaust section (fourth pump chamber), 61 pump power section (fifth pump chamber).

Claims (11)

In a hydrogen generator for a portable fuel cell that supplies hydrogen to a fuel cell mounted on a portable device, a partial oxidation chamber that generates hydrogen from fuel by a partial oxidation reaction, and steam that generates hydrogen from the fuel by a steam reforming reaction A hydrogen generator having a reforming chamber is provided, and the partial oxidation chamber and the steam reforming reaction chamber are arranged adjacently so as to be able to exchange heat, and heat generated by the partial oxidation reaction is absorbed by heat absorption of the steam reforming reaction. A hydrogen generator for a portable fuel cell, wherein the hydrogen is absorbed to suppress a rise in the temperature of the partial oxidation chamber. The hydrogen generator includes a CO oxidation processing chamber that oxidizes CO in a product gas generated in the partial oxidation chamber, and a fuel vaporization chamber adjacent to the CO oxidation processing chamber and heat-exchangeable. Absorbing heat generated by the CO selective oxidation reaction in the CO oxidation treatment chamber to vaporize the fuel in the fuel vaporization chamber and supply the fuel to the partial oxidation chamber and the steam reforming chamber. The hydrogen generator for a portable fuel cell according to claim 1. A hydrogen storage alloy tank for storing and storing hydrogen in the product gas generated in the partial oxidation chamber and the steam reforming chamber; the partial oxidation chamber, the steam reforming chamber, the CO oxidation treatment chamber, The fuel vaporization chamber and the hydrogen storage alloy tank alternately repeat heat generation and heat absorption in the order of a partial oxidation reaction, a steam reforming reaction, a CO selective oxidation reaction, a fuel vaporization reaction, and a hydrogen storage reaction from the high temperature side, and are adjacent to each other. 3. The hydrogen generator for a portable fuel cell according to claim 2, wherein the hydrogen generator is arranged so that heat can be exchanged between the reactions. The partial oxidation chamber is formed by coating a partial oxidation catalyst on an inner wall surface of an elongated partial oxidation flow path in which the fuel flows in one direction, and the steam reforming chamber is formed in the partial oxidation flow path in which the fuel flows in one direction. A steam reforming catalyst is applied and formed on the inner wall surface of a long and narrow steam reforming flow path along the CO oxidation treatment chamber. In the CO oxidation treatment chamber, the generated gas from the partial oxidation chamber and the steam reforming chamber flows in one direction. A CO oxidation catalyst is applied and formed on the inner wall surface of the elongated CO oxidation flow path along the flowing steam reforming flow path, and the fuel vaporization chamber is an elongated fuel vaporization flow path along the CO oxidation flow path. The steam reforming catalyst is formed on the inner wall surface of the steam reforming channel on the partial oxidation channel side, and the CO oxidation catalyst is formed on the inner wall surface of the CO oxidation channel on the steam reforming channel side. It is noted that Portable hydrogen generator for the fuel cell according to claim 3,. The hydrogen generator includes a fuel tank for storing the fuel, and a rectangular parallelepiped external container. The hydrogen storage alloy tank is mounted in close contact with a planar mounting surface of the external container. Is disposed in the outer container adjacent to the mounting surface, and the partial oxidation channel, the steam reforming channel, the CO oxidation processing channel, and the fuel vaporization channel are parallel to the mounting surface. 5. The hydrogen generator for a portable fuel cell according to claim 4, wherein the hydrogen generator is disposed below the fuel tank in the outer container so as to be located on the same plane. 6. The hydrogen generator for a portable fuel cell according to claim 3, wherein the hydrogen storage alloy tank is configured to be detachable. A hydrogen gas flow path for supplying hydrogen to the hydrogen storage alloy tank is provided, and the partial oxidation chamber, the steam reforming chamber, and the CO oxidation processing chamber are connected to the hydrogen gas flow path via a hydrogen permeable membrane. The hydrogen generator for a portable fuel cell according to claim 5, wherein: A partition wall that separates the partial oxidation flow path, the steam reforming flow path, the CO oxidation flow path, and the adjacent flow path of the fuel vaporization flow path is inclined with respect to the mounting surface. The hydrogen generator for a portable fuel cell according to claim 5. 8. The hydrogen generator for a portable fuel cell according to claim 7, further comprising a booster pump for increasing the pressure of the hydrogen in the hydrogen gas flow path and sending the hydrogen to the hydrogen storage alloy tank. The booster pump includes a first pump chamber for increasing the pressure of hydrogen in the hydrogen gas flow path and pumping the hydrogen to the hydrogen storage alloy tank, a second pump chamber for supplying air to the partial oxidation chamber, and a CO oxidation treatment chamber. A third pump chamber for supplying air, a fourth pump chamber for exhausting the reaction gas in the CO oxidation treatment chamber to the outside, and the partial oxidation chamber and the steam reforming for the fuel vaporized in the fuel vaporization chamber. A fifth pump chamber that supplies the fuel to the chamber, wherein the first to fifth pump chambers are operated by a single drive shaft, and when the hydrogen is generated, the fuel vaporized in the fuel vaporization chamber is supplied to the fifth pump chamber. And the first to fifth pump chambers are configured such that the drive shaft is rotated using the pressure generated by the vaporization of the fuel and the flow of the vaporized fuel as a power source to operate the first to fifth pump chambers. Claim 9 Placing the portable hydrogen generator for the fuel cell. A band-shaped fuel conductive material having hygroscopicity is wound around the fuel tank with one end extending into the fuel tank, and the fuel in the fuel tank penetrates the fuel conductive material so as to penetrate the fuel tank. The device is configured to be heated and vaporized by absorbing heat generated by hydrogen storage in the hydrogen storage alloy tank and heat generated by a CO oxidation reaction in the CO oxidation treatment chamber. Item 6. A hydrogen generator for a portable fuel cell according to item 5.

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