JP3780782B2 - Reformer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a reforming apparatus including a reforming section that generates a reformed gas rich in hydrogen by a steam reforming reaction and a combustion section that supplies combustion gas that becomes thermal energy of the reaction.
[0002]
[Prior art]
Conventionally, as a device constituting a fuel cell, a raw material such as natural gas or naphtha is used, a reforming section that generates a reformed gas rich in hydrogen by a steam reforming reaction from the raw material and steam, and the steam 2. Description of the Related Art A reformer having a combustion section that burns fuel by using a burner or the like to generate combustion gas as heat energy for the reforming reaction is known (for example, JP-A-10-218602). The reformed gas is generated by a steam reforming reaction by introducing a raw material and steam into a reforming section filled with a reforming catalyst, being heated by the combustion gas.
[0003]
[Problems to be solved by the invention]
In recent years, with the expansion of the range of use of fuel cells, miniaturization and weight reduction are required. For example, when butane gas is used as a raw material for the reformed gas, the steam reforming reaction of the butane gas is preferably performed at a high temperature of 500 ° C. or higher. Fever. From the viewpoint of miniaturization, weight reduction, and energy saving, there is a need for a reformer that efficiently uses the thermal energy of the combustion gas generated in the combustion section.
[0004]
The present invention has been made in view of the above circumstances, and an object thereof is to provide a reformer that efficiently uses the thermal energy of combustion gas.
[0005]
[Means for Solving the Problems]
The reforming apparatus according to claim 1, wherein a reforming unit that generates a reformed gas rich in hydrogen by a steam reforming reaction from a raw material and steam, and a combustion that supplies a combustion gas that becomes thermal energy of the steam reforming reaction In the reformer provided with a section, the reformer is disposed above the combustion section and outside the reformer having a substantially cylindrical shape, and the combustion gas flows inside the reformer A flow path is formed, and an air chamber in which air is sealed is provided inside the combustion gas flow path. By the above, the combustion gas passes through the vicinity of the inside of the reforming unit so that the heat of the combustion gas is not discharged to the outside of the reforming system without being transmitted to the reforming unit. It is. Further, the reformer prevents the heat transfer area of the reforming part and the combustion gas from decreasing, and the air chamber also functions as a heat insulating layer that suppresses the heat of the combustion gas from being radiated. Is something that can be done. Therefore, the reformer efficiently transmits the thermal energy of the combustion gas to the reforming unit.
[0006]
The reformer according to claim 2 is the reformer according to claim 1, wherein the reformer is connected to the combustion gas flow path formed inside the reformer, and the gas flows outside the reformer. A flow path is formed. As described above, the heat of the combustion gas can be transmitted to the reforming unit also from the outside of the reforming unit. Therefore, the reformer can transmit the thermal energy of the combustion gas to the reformer more efficiently.
[0007]
The reformer according to claim 3 is the reformer according to claim 1 or 2, wherein the reformer and the heat transfer surface of the combustion gas facing the reforming portion and the heat transfer surface of the combustion gas are provided on the wall surface of the flow path. A radiant heat transfer body is provided. By the above, since the heat radiated from the reforming part is reflected by the high radiation heat transfer body, the reforming part can be warmed. Therefore, since the reforming apparatus is provided with a high radiation heat transfer body, the heat energy of the combustion gas can be more efficiently transmitted to the reforming section.
[0008]
A reformer according to a fourth aspect of the present invention is the reformer according to any one of the first to third aspects, further comprising a heat exchanger for exchanging heat between the combustion gas supplied with thermal energy to the reformer and the outside air. And a means for introducing outside air that has passed through the heat exchanger into the combustion section. By the above, since the air introduced into the combustion section is introduced in a heated state, the heat generation of the combustion gas can be accelerated.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a schematic view showing an example of an embodiment corresponding to the reforming apparatus according to claims 1 to 3. The reformer 1 includes a reformer 2 that generates a reformed gas rich in hydrogen from a raw material and steam by a steam reforming reaction, and a combustor 3 that supplies a combustion gas that becomes thermal energy of the steam reforming reaction. It has. The reformer 1 has a substantially cylindrical shape. The reformer 2 forms a circular layer over the outer periphery of the reformer 1 above the combustor 3 at the bottom and the combustor 3. In addition, a combustion gas flow path 4 is formed in the ring of the reforming section 2 forming the annular layer. In addition, the arrow in a figure shows the direction through which combustion gas, a raw material, or reformed gas flows.
[0010]
The combustion unit 3 is disposed at the center of the substantially cylindrical reformer 1, and is open upward with the axial direction set up and down, and includes a burner as combustion means. A fuel supply path 5 for introducing fuel gas and combustion air is connected to the lower end of the combustion section 3. The combustion section 3 burns the fuel gas and air introduced from the fuel supply path 5 with a burner, and supplies the generated high-temperature combustion gas to the combustion gas flow path 4 formed above the combustion section 3. As the combustion means, a combustion catalyst such as Pt, Ru, Pd, Rh or the like may be used.
[0011]
The reforming section 2 is formed by filling a reforming catalyst, and is heated by the combustion gas generated in the combustion section 3. The reforming section includes a raw material introduction path 6 for introducing the raw material and water vapor at the lower end, and a reformed gas supply path 7 for discharging the reformed gas generated in the reforming section 2 at the upper end. The above reforming catalyst generates a reformed gas rich in hydrogen by bringing the raw material and steam into contact with each other at a high temperature, and causes a so-called steam reforming reaction. Metals such as nickel, ruthenium and rhodium are used. Is supported on a carrier made of alumina, zirconia or the like. In the reforming unit 2, the mixed gas of the raw material and the steam passes through the gaps between the particles of the reforming catalyst. At this time, the steam reforming reaction is caused by the mixed gas coming into contact with the reforming catalyst. Is performed to generate reformed gas. This steam reforming reaction is an endothermic reaction, and is heated by the thermal energy of the combustion gas to supply reaction heat. As the raw material, an alcohol fuel such as methanol or a hydrocarbon fuel gas such as natural gas, butane or propane is used. In this connection, the steam reforming reaction can be performed satisfactorily when the reaction temperature is 500 ° C. or higher when butane gas is used as a raw material.
[0012]
In the reformer 1, the reforming section 2 forms an annular layer, and the combustion gas flow path 4 is formed inside the reforming section 2 forming the annular layer. The combustion gas channel 4 is formed in an annular shape adjacent to the inner side 8 of the reforming unit 2 in a plan sectional view of the reformer 1. The reformer 1 is provided with an air chamber 11 in which air is sealed inside the combustion gas flow path 4. The reformer 1 includes the air chamber 11 so that the heat of the combustion gas is reduced from being discharged out of the reformer 1 without being transmitted to the reformer 2. Passes through the vicinity of the inside 8 of the reforming section 2. Further, since the combustion gas passes through the vicinity of the inner side 8 of the reforming unit 2, the reformer 1 can efficiently transmit the thermal energy of the combustion gas to the reforming unit 2.
[0013]
In addition, the reformer 1 reduces the cross-sectional area of the flow path so that the combustion gas passes near the inside 8 of the reforming unit 2, and accordingly, the heat transfer area between the reforming unit 2 and the combustion gas is reduced. It is intended not to decrease. In addition, air is a good heat insulating layer as compared with, for example, glass wool, and the air chamber 11 is a heat insulating member that suppresses the heat of the combustion gas from being dissipated outside the system of the reformer 1. It also functions as a layer.
[0014]
Furthermore, the reformer 1 has a gas flow path 10 formed outside the reformer 2, and the combustion gas flow path 4 and the gas flow path 10 are connected at the upper end of the reformer 1. Has been. In the reformer 1, the combustion gas that has flowed inside the reformer 2 bypasses the upper end of the reformer 1 and flows outside the reformer 2. Since the heat of the combustion gas is transmitted to the reforming unit 2 also from the outside 9 of the unit, the thermal energy of the combustion gas can be efficiently supplied to the reforming unit 2.
[0015]
Further, the reformer 1 is provided with a high radiant heat transfer body on the wall surface of the flow path facing the reforming section 2 and the heat transfer surface of the combustion gas. That is, the reforming device 1 is provided on the wall surface 12 of the air chamber 11 facing the inner surface 8 of the reforming section 2 and the wall surface 13 of the gas flow path 10 facing the outer surface 9 of the reforming section 2. The high radiation heat transfer body 14 is attached. The high radiant heat transfer body 14 is a heat transfer body having an emissivity of 0.4 or more, and examples thereof include alumina and silver. The emissivity is measured with a widely used emissometer. The high radiation heat transfer body 14 can be attached by coating the wall surfaces 12 and 13 with a mixed liquid containing the high radiation heat transfer body 14. Since the reforming apparatus 1 is provided with the high radiant heat transfer body 14, the heat radiated from the reforming unit 2 is reflected by the high radiant heat transfer body 14 and can warm the reforming unit 2. Therefore, the reforming apparatus 1 can supply the thermal energy of the combustion gas to the reforming unit 2 more efficiently by attaching a high radiation heat transfer body.
[0016]
FIG. 2 is a schematic view showing an example of an embodiment corresponding to the reforming apparatus of the fourth aspect. Only differences from the reformer of FIG. 1 will be described. The reformer 1 includes a heat exchanger 20 connected to a gas flow path 10 formed over the outer side 9 of the reformer 2. In the heat exchanger 20, heat exchange is performed from the exhaust gas passage 21 to the outside air passage 22 between the exhaust gas passage 21 through which the combustion gas that has supplied thermal energy to the reforming unit 2 flows and the outside air passage 22 through which the outside air flows. And the outside air is heated. Reference numeral 22 in the drawing is a heat insulating layer made of glass wool or the like that covers the exhaust gas passage 21 and the outside air passage 22.
[0017]
In the reformer 1, the outside air path 22 is connected to the fuel supply path 5. Thereby, since the said reformer 1 can introduce the heated air into the combustion part 3 with fuel gas, since it introduces in the state with which the air was heated, it can accelerate the heat_generation | fever of combustion gas. . Therefore, the reformer 1 can use the thermal energy of the combustion gas more efficiently.
[0018]
Further, since the reformed gas generated in the reforming unit 2 contains CO and the like in addition to hydrogen, the reformed gas is supplied to a fuel cell or the like via a CO oxidizing device (not shown) in order to remove CO. The The combustion gas that has passed through the exhaust gas passage 21 can also be used for heating the CO oxidation device.
[0019]
【The invention's effect】
In the reforming apparatus according to the first aspect, since the combustion gas passes in the vicinity of the inside of the reforming section, the thermal energy of the combustion gas can be efficiently transmitted to the reforming section. The reformer prevents the heat transfer area of the reforming section and the combustion gas from decreasing. Moreover, the said reformer can function the air chamber as a heat insulation layer which suppresses that the heat | fever of combustion gas is thermally radiated. Therefore, the reformer can efficiently use the thermal energy of the combustion gas.
[0020]
Further, the reforming apparatus according to claim 2 can transmit the heat energy of the combustion gas to the reforming section more efficiently because the heat of the combustion gas can be transmitted to the reforming section even from the outside of the reforming section. I can tell you well.
[0021]
Further, the reforming apparatus according to claim 3 is particularly capable of heating the reforming section because the heat radiated from the reforming section is reflected by the high radiant heat transfer body and reforms the thermal energy of the combustion gas. Can be transmitted to the department more efficiently.
[0022]
Furthermore, since the reforming apparatus according to the fourth aspect is introduced in a state where the air introduced into the combustion section is heated, the heat generation of the combustion gas can be accelerated. Therefore, the reformer can use the thermal energy of the combustion gas more efficiently.
[Brief description of the drawings]
FIG. 1 is a schematic view showing an example of an embodiment of a reforming apparatus of the present invention.
FIG. 2 is a schematic view showing an example of an embodiment of another reformer of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Reformer 2 Reforming part 3 Combustion part 4 Combustion gas flow path 5 Fuel supply path 11 Air chamber 14 High radiation heat transfer body

Claims (4)

In a reforming apparatus comprising a reforming unit that generates a reformed gas rich in hydrogen from a raw material and steam by a steam reforming reaction, and a combustion unit that supplies combustion gas that becomes thermal energy of the steam reforming reaction, The reforming unit is disposed above the combustion unit and outside the reformer having a substantially cylindrical shape, and a combustion gas passage is formed inside the reforming unit to flow combustion gas. A reformer characterized in that an air chamber in which air is sealed is provided inside a passage. The reforming apparatus according to claim 1, wherein a gas flow path through which the combustion gas flows is formed outside the reforming section so as to be connected to the combustion gas flow path formed inside the reforming section. . 3. The modification according to claim 1, wherein a high radiation heat transfer body is attached to a wall surface of the flow path through which the combustion gas flows, facing the reforming section and the heat transfer surface of the combustion gas. Quality equipment. A heat exchanger for exchanging heat between the combustion gas supplied with heat energy to the reforming section and the outside air, and means for introducing the outside air that has passed through the heat exchanger into the combustion section. The reformer according to any one of claims 1 to 3.

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