KR102398437B1 - Steam Hydrocarbon Reformer - Google Patents

Abstract

The present invention relates to a steam hydrocarbon reformer, and more particularly, to a first space in which combustion gas is generated through a combustion reaction of fuel gas at the center, a lower chamber having a first communication hole at an upper portion, and a second inside An upper chamber having a space and having a second communication hole communicating with the first communication hole at a lower portion, an air supply unit supplying air to the first space for a combustion reaction, and combustion for burning fuel gas and air to supply heat A reforming unit, at least a portion of which is disposed in the lower chamber and the upper chamber to perform a reforming reaction, a source gas supply unit for supplying a source gas to the reforming unit, and a reforming unit for discharging the reformed gas generated through the reaction in the reforming unit A source gas inlet, which includes a gas discharge unit, increases the heat exchange efficiency between the source gas, the combustion gas, and the catalyst to increase the yield of hydrogen through the reforming reaction, and the source gas supply unit is formed to be connected to the outside on the side of the upper chamber; and a source gas heating tube provided in the second space to heat the source gas before the source gas is supplied to the reforming unit, wherein the source gas heating tube heats the source gas with the combustion gas to discharge the combustion gas It relates to a steam hydrocarbon reformer capable of promoting an efficient hydrogen reforming reaction by heating the raw material gas prior to reforming in advance by increasing the temperature of the raw material gas without an additional heat source.

Description

Steam Hydrocarbon Reformer

The present invention relates to a steam hydrocarbon reformer, and more particularly, to a first space in which combustion gas is generated through a combustion reaction of fuel gas at the center, a lower chamber having a first communication hole at an upper portion, and a second inside An upper chamber having a space and having a second communication hole communicating with the first communication hole at a lower portion, an air supply unit supplying air to the first space for a combustion reaction, and combustion for burning fuel gas and air to supply heat A reforming unit, at least a portion of which is disposed in the lower chamber and the upper chamber to perform a reforming reaction, a source gas supply unit for supplying a source gas to the reforming unit, and a reforming unit for discharging the reformed gas generated through the reaction in the reforming unit It includes a gas discharge part, increases the heat exchange efficiency between the raw material gas, the combustion gas, and the catalyst to increase the yield of hydrogen through the reforming reaction, and the raw material gas supply part includes a raw material gas inlet connected to the outside through the opening, and the second space and a raw material gas heating tube provided in the to heat the raw material gas before the raw material gas is supplied to the reforming unit, wherein the raw material gas heating tube is reformed in the process of exhausting the combustion gas by heating the raw material gas by the combustion gas. It relates to a steam hydrocarbon reformer capable of promoting an efficient hydrogen reforming reaction by heating the raw material gas in advance without an additional heat source by heating the previous raw material gas.

Hydrogen energy is a powerful next-generation energy source, and there is a trend to participate in global development to reduce greenhouse gas and fine dust. In the meantime, hydrogen energy has been limitedly used in special fields, but the scope of practical use is expanding. Hydrogen energy can be obtained by electrolysis of water, steam reforming or partial oxidation of fossil fuels, and gasification or carbonization of biomass. Hydrogen energy can also be obtained by converting energy from all energy sources such as sunlight, solar heat, and fossil fuels.

Among various methods for obtaining hydrogen, the hydrogen reforming technology for producing hydrogen from natural gas is to reform natural gas, etc., in which methane is the main component, through a combustion roll of fuel. Natural gas and steam used for hydrogen reforming are called raw material gas, and reforming is performed by burning a mixture of natural gas and natural gas obtained as a by-product in the reforming process with a predetermined amount of natural gas. The natural gas and off-gas used are called fuel gas. The offgas contains about 32-40% hydrogen to promote combustion.

The steam hydrocarbon reformer is a device that converts the raw material gas into hydrogen by burning natural gas and off-gas, which are fuel gases, together with air, so that hydrogen can be produced by using natural gas or the like as a raw material. Natural gas steam reforming accounts for a significant portion of the world's total hydrogen production. Hydrogen can be produced by mixing water vapor (steam) and natural gas and heating it to 700 to 1000 degrees, preferably 700 to 850 degrees, and reacting under a predetermined pressure in a catalytic reactor. 1 is a view showing a general hydrogen reforming method using natural gas. After desulfurizing raw material gas through a desulfurization device, it reacts with fuel gas and water vapor in the reformer to obtain reformed hydrogen. Thereafter, purified hydrogen can be obtained through a transition process and a gas removal process, and off-gas, a by-product of the process, can be used together with fuel for hydrogen reforming. The reforming that occurs in such a hydrogen reformer entails many reactions, but the essential chemical transformation is as follows.

CH ₄ + H ₂ O → CO + 3H ₂ [Equation 1]

CH ₄ + 2H ₂ O → CO ₂ + 4H ₂ [Equation 2]

The reforming reaction of Equation 1 corresponds to an endothermic reaction, and the water gas conversion reaction of Equation 2 corresponds to an exothermic reaction. Since a lot of heat is required for the endothermic reaction of Equation 1, a catalyst is added at a high temperature to promote the reaction. To this end, a conventional hydrogen reformer burns fuel gas in a furnace or chamber, and injects raw material gas into a reaction tube containing a catalyst to obtain hydrogen at a high temperature.

However, in the conventional steam hydrocarbon reformer, heat due to combustion of combustion gas escapes without being able to completely transfer heat to the reaction tube containing the catalyst, so the heat exchange efficiency is lowered, and there is a problem in that the hydrogen reforming efficiency is low.

In addition, when the temperature of the air and raw material gas flowing into the furnace is much lower than the temperature at which the reforming reaction takes place and the temperature is not sufficiently increased until the reforming reaction, the reforming reaction by the catalyst does not occur well despite the high temperature in the furnace, and the reaction by the catalyst is incomplete. The reaction tube was often clogged due to byproducts such as carbon being generated, and there was a problem in that an additional heat source had to be provided to increase the temperature of the raw material gas and the fuel gas.

The combustion rate of hydrogen is about 8 times faster than that of methane (hydrogen 291 cm/s, methane 37 cm/s), and the high combustion rate of hydrogen locally increases the flame temperature during combustion, which is high when burning fuel gas containing hydrogen. There is a problem that can cause environmental pollution because it can generate a level of Nox. There is a problem in that the reaction tube is damaged due to wide flammability and high temperature, and the catalyst is brittle by flame.

Further, in the furnace, the combustion reaction usually proceeds in the central part of the furnace, and the reaction tube is radially arranged with respect to the center of the combustion space. In this case, the heat by the combustion gas is not uniformly transmitted to the reaction tube, so that the reforming reaction does not occur evenly in the individual reaction tube, and the hydrogen reforming efficiency is deteriorated because it is generated only in a part of the reaction tube.

In addition, when the heated raw material gas is introduced into the reaction tube for efficient hydrogen reforming or the reformed high-temperature reformed gas is discharged, the conduit is damaged or deformed due to high pressure and high temperature.

Accordingly, the industry is in demand for a hydrogen reformer or a steam hydrocarbon reformer that supplements the above-described problems.

Korean Patent Publication No. 10-0209989 (April 22, 1999)

The present invention has been devised to solve the above problems,

It is an object of the present invention to provide a steam hydrocarbon reformer capable of obtaining a high hydrogen yield by increasing the heat exchange efficiency between combustion gas and fuel gas.

It is an object of the present invention to provide a steam hydrocarbon reformer in which an efficient reforming reaction can occur by heating air and raw material gas introduced into the chamber through combustion gas without another heat source before the reforming reaction occurs.

It is an object of the present invention to provide a steam hydrocarbon reformer in which a small amount of nitrogen oxide is generated through a constant flame when a fuel gas containing hydrogen is burned.

It is an object of the present invention to provide a steam hydrocarbon reformer which prevents the reforming from being destroyed or damaged by flames.

It is an object of the present invention to provide a steam hydrocarbon reformer in which heat by combustion gas or flame is uniformly transferred to a reforming unit so that the reforming reaction within the reforming unit is uniformly progressed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a steam hydrocarbon reformer that prevents conduits from being damaged or deformed by high-pressure and high-temperature gas when heated raw material gas or reformed gas flows.

An object of the present invention is to have a first space in which combustion gas is generated through a combustion reaction of fuel gas in the center, a lower chamber having a first communication hole at an upper portion, a second space therein, and the first communication at a lower portion An upper chamber having a second communication hole communicating with the hole, an air supply unit for supplying air to the first space for a combustion reaction, a combustion unit for burning fuel gas and air to supply heat, at least a portion of the lower chamber and A separate chamber including a reforming unit disposed in the upper chamber to perform a reforming reaction, a source gas supply unit supplying a source gas to the reforming unit, and a reforming gas discharge unit discharging the reformed gas generated through the reaction in the reforming unit. It is to provide a steam hydrocarbon reformer that heats the raw material gas and the catalyst while the combustion gas flows in the furnace.

An object of the present invention is to provide a source gas inlet provided in the second space and a source gas inlet formed on the side surface of the upper chamber to connect the source gas to the source gas supply unit to heat source gas before the source gas is supplied to the reformer. It includes a heating tube, wherein the raw material gas heating tube is to provide a steam hydrocarbon reformer for heating the raw material gas by combustion gas.

An object of the present invention is to supply heat to the source gas heating tube while the combustion gas is introduced into the second space through the first communication hole and the second communication hole, and discharged through an opening formed in the upper chamber. To provide a steam hydrocarbon reformer.

An object of the present invention is to provide a steam hydrocarbon reformer in which the raw material gas flows in the raw material gas heating tube and heat exchanges with the combustion gas by forming a spiral shape.

An object of the present invention is to provide a steam hydrocarbon reformer in which the raw material gas heating tube includes an outer spiral and an inner spiral, and the outer spiral and the inner spiral communicate with each other to maximize heat exchange with combustion gas.

An object of the present invention is that the source gas supply unit further includes a distribution header for distributing the heated source gas to the reforming unit, the source gas inlet is connected to the outer spiral, and the inner spiral is connected to communicate with the distribution header and introduced An object of the present invention is to provide a steam hydrocarbon reformer in which the raw material gas is heated primarily through an outer spiral and is secondarily heated through an inner spiral.

An object of the present invention is that the raw material gas supply unit further includes a spiral support part for supporting the outer spiral and the inner spiral, and the outer spiral and the inner spiral are provided spaced apart from the inner surface of the upper chamber by the spiral support part to flow around it. It is to provide a steam hydrocarbon reformer in which the raw material gas is efficiently heated by the combustion gas.

An object of the present invention is that the spiral support includes an outer support for supporting the outer spiral and an inner support for supporting the inner spiral, the outer support and the inner support are formed as a wall, and spaced between the outer support and the inner support It is to provide a steam hydrocarbon reformer in which a space is formed to induce a flow of combustion gases.

An object of the present invention is to provide a steam hydrocarbon reformer in which a flow path guide is provided inside the upper chamber to guide the flow of combustion gas, and the flow guide part allows combustion gas to flow along the spiral-shaped raw material gas heating tube. will do

An object of the present invention is that the flow guide part is coaxially aligned with the upper chamber, has a cylindrical shape of a predetermined height to surround the plurality of reforming parts, is spaced apart from a plurality of second communication holes, and extends upwardly from the lower surface of the upper chamber. Heat transfer to the raw material gas by including the first flow path guide part and the second flow path guide part spaced apart from the first flow path guide part to the outside and extending downward from the upper surface of the upper chamber so that the combustion gas flows from the lower side to the upper side and from the upper side to the lower side It is to provide a steam hydrocarbon reformer that promotes

An object of the present invention is that the first communication hole and the second communication hole are coaxially aligned, and the first communication hole and the second communication hole receive the reformed part through and the reformed part is disposed over the first space and the second space, , The reforming unit includes an outer tube connected to the source gas supply unit to receive the heated source gas, and an inner tube coaxially aligned with the outer tube in the outer tube, wherein the diameters of the first communication hole and the second communication hole are outside It is to provide a steam hydrocarbon reformer that is formed to be larger than the diameter of the tube and heats the reforming unit while the combustion gas flows toward the first communication hole and the second communication hole and proceeds to the second space.

An object of the present invention is that the reforming unit further comprises a catalyst for performing a reforming reaction on the raw material gas, the catalyst is formed in an outer tube disposed in the first space, and the outer tube has an upper side of the combustion gas supply unit and It is connected and the lower side is closed, and the inner tube has an open lower side and an upper side connected to the reformed gas discharge unit, so that the reformed gas that has passed through the catalyst descends in the outer tube rises through the inner tube and is discharged. Provide a steam hydrocarbon reformer will do

The present invention is implemented by an embodiment having the following configuration in order to achieve the above object.

According to an embodiment of the present invention, the present invention includes a first space in which combustion gas is generated through a combustion reaction of fuel gas at the center, a lower chamber having a first communication hole at the upper portion, and a second space therein. and an upper chamber having a second communication hole communicating with the first communication hole at a lower portion thereof, an air supply unit supplying air to the first space for a combustion reaction, a combustion unit burning fuel gas and air to supply heat; At least a portion of the reforming unit is disposed in the lower chamber and the upper chamber to perform a reforming reaction, a source gas supply unit for supplying a source gas to the reforming unit, and a reformed gas discharge unit for discharging the reformed gas generated through the reaction in the reforming unit It is characterized by including wealth.

According to an embodiment of the present invention, in the present invention, the source gas supply unit is provided in the second space and the source gas supply unit is provided in the second space and the source gas inlet is formed on the side surface of the upper chamber to be connected to the outside. and a source gas heating tube for heating the source gas before being supplied to the unit, wherein the source gas heating tube heats the source gas by combustion gas.

According to one embodiment of the present invention, in the present invention, the combustion gas is introduced into the second space through the first communication hole and the second communication hole, and is discharged through the opening formed in the upper chamber, while the raw material gas It is characterized in that heat is supplied to the heating tube.

According to one embodiment of the present invention, the source gas heating tube is characterized in that the source gas flows therein, and forms a spiral shape to exchange heat with the combustion gas.

According to an embodiment of the present invention, the source gas heating tube includes an outer spiral and an inner spiral, and the outer spiral and the inner spiral are in communication with each other.

According to an embodiment of the present invention, the source gas supply unit further includes a distribution header for distributing the heated source gas to the reforming unit, the source gas inlet is connected to the outer spiral, and the inner spiral is the distribution It is characterized in that the source gas connected to communicate with the header is heated primarily through the outer spiral and is secondarily heated through the inner spiral.

According to an embodiment of the present invention, the source gas supply unit further includes a spiral support for supporting the outer spiral and the inner spiral, and the outer spiral and the inner spiral are separated from the inner surface of the upper chamber by the spiral support unit. It is characterized in that it is provided spaced apart.

According to an embodiment of the present invention, the spiral support unit is characterized in that it includes an outer support for supporting the outer spiral and an inner support for supporting the inner spiral.

According to an embodiment of the present invention, the outer support and the inner support are formed as a wall, and a spaced space is formed between the outer support and the inner support to induce the flow of combustion gas.

According to an embodiment of the present invention, a flow path guide is provided inside the upper chamber to guide the flow of combustion gas, and the flow path guide unit allows the combustion gas to flow along the spiral-shaped raw material gas heating tube. characterized by doing so.

According to an embodiment of the present invention, the flow path guide portion is coaxially aligned with the upper chamber and has a cylindrical shape of a predetermined height so as to surround the plurality of reforming portions.

According to one embodiment of the present invention, in the present invention, the flow guide part is spaced apart from the plurality of second communication holes and extends upward from the lower surface of the upper chamber to the first flow guide part and the first flow guide part are spaced apart from each other to the outside. It is characterized in that it comprises a second flow path guide extending downward from the upper surface of the upper chamber.

According to an embodiment of the present invention, in the present invention, the first communication hole and the second communication hole are coaxially aligned, and the first communication hole and the second communication hole receive through the reforming unit, so that the reforming unit is formed in a first space and It is disposed over the second space, and the reforming unit includes an outer tube connected to the source gas supply unit to receive the heated source gas, and an inner tube coaxially aligned with the outer tube in the outer tube, the first communication hole and The diameter of the second communication hole is characterized in that larger than the diameter of the outer tube.

According to an embodiment of the present invention, the reforming unit further includes a catalyst for performing a reforming reaction on the raw material gas, and the catalyst is formed in the outer tube disposed in the first space. .

According to an embodiment of the present invention, in the present invention, the upper side of the outer tube is connected to the combustion gas supply unit and the lower side is closed, and the inner tube has an open lower side and an upper side is connected to the reformed gas discharge unit in the outer tube. It is characterized in that the reformed gas, which descends from and passes through the catalyst, rises through the inner tube and is discharged.

The present invention can obtain the following effects by the configuration, combination, and use relationship described below with the present embodiment.

The present invention has a first space in which combustion gas is generated through a combustion reaction of fuel gas at the center, a lower chamber having a first communication hole at an upper portion, a second space therein, and the first communication hole at a lower portion An upper chamber having a second communication hole to communicate with, an air supply unit for supplying air to the first space for a combustion reaction, a combustion unit for burning fuel gas and air to supply heat, at least a portion of the lower chamber and the upper chamber Combustion in a separate chamber, including a reforming unit disposed in the interior to perform a reforming reaction, a source gas supply unit supplying source gas to the reforming unit, and a reforming gas discharge unit discharging reformed gas generated through the reaction in the reforming unit There is an effect of providing a steam hydrocarbon reformer that heats the raw material gas and the catalyst while the gas flows.

In the present invention, the source gas supply unit includes one or more openings, and the source gas supply unit is provided in the second space and the source gas inlet connected to the outside through the opening so that the source gas is supplied to the reforming unit. and a raw material gas heating tube for heating the raw material gas, wherein the raw material gas heating tube has an effect of providing a steam hydrocarbon reformer for heating the raw material gas by combustion gas.

The present invention provides an effect of supplying heat to the raw material gas heating tube while the combustion gas is introduced into the second space through the first communication hole and the second communication hole, and discharged through the opening formed in the upper chamber. accompanying

The present invention has the effect of providing a reformer in which the raw material gas flows in the raw material gas heating tube, and forms a spiral shape to exchange heat with the combustion gas.

In the present invention, the raw material gas heating tube includes an outer spiral and an inner spiral, and the outer spiral and the inner spiral communicate with each other to maximize heat exchange with the combustion gas.

In the present invention, the source gas supply unit further includes a distribution header for distributing the heated source gas to the reforming unit, the source gas inlet is connected to the outer spiral, and the inner spiral is connected to communicate with the distribution header and the introduced raw material It has the effect of providing a steam hydrocarbon reformer in which the gas is heated primarily through the outer helix and secondarily through the inner helix.

According to the present invention, the source gas supply unit further includes a spiral support unit for supporting the outer spiral and the inner spiral, and the outer spiral and the inner spiral are provided to be spaced apart from the inner surface of the upper chamber by the spiral support unit, so that the combustion gas flowing around it To provide a steam hydrocarbon reformer in which the raw material gas is efficiently heated.

In the present invention, the spiral support includes an outer support for supporting the outer spiral and an inner support for supporting the inner spiral, the outer support and the inner support are formed by a wall, and a spaced space between the outer support and the inner support is provided. It has the effect of providing a steam hydrocarbon reformer that is formed to induce a flow of flue gases.

The present invention provides an effect of providing a steam hydrocarbon reformer in which a flow path guide is provided inside the upper chamber to guide the flow of combustion gas, and the flow guide allows the combustion gas to flow along the spiral-shaped raw material gas heating tube. brings

In the present invention, the flow path guide portion is coaxially aligned with the upper chamber, has a cylindrical shape of a predetermined height to surround the plurality of reforming portions, is spaced apart from the plurality of second communication holes, and extends upward from the lower surface of the upper chamber. It includes a guide part and a second flow path guide part that is spaced apart from the outside of the first flow path guide part and extends downward from the upper surface of the upper chamber, so that the combustion gas flows from the lower side to the upper side and from the upper side to the lower side to promote heat transfer to the raw material gas To derive the effect of providing a steam hydrocarbon reformer.

In the present invention, the first communication hole and the second communication hole are coaxially aligned, the first communication hole and the second communication hole receive the reformed part through and the reformed part is disposed over the first space and the second space, The reforming unit includes an outer tube connected to the combustion gas supply unit to receive the heated raw material gas, and an inner tube aligned coaxially with the outer tube in the outer tube, wherein the diameters of the first communication hole and the second communication hole are of the outer tube. It has the effect of providing a steam hydrocarbon reformer that is formed to be larger than the diameter and heats the reforming unit while the combustion gas flows toward the first communication hole and the second communication hole and proceeds to the second space.

In the present invention, the reforming unit further includes a catalyst for performing a reforming reaction on the raw material gas, the catalyst is formed in an outer tube disposed in the first space, and the outer tube has an upper side connected to the combustion gas supply unit, The lower side of the inner tube is closed, the lower side is open, and the upper side is connected to the reformed gas discharge part, descends in the outer tube, and the reformed gas passing through the catalyst rises through the inner tube and is discharged. Provide a steam hydrocarbon reformer.

1 is a view showing a hydrogen reforming method using a general natural gas
2 is a perspective view of a steam hydrocarbon reformer according to an embodiment of the present invention;
3 is a cut-away perspective view of a steam hydrocarbon reformer according to an embodiment of the present invention;
4 is a cross-sectional view taken along line AA' of FIG. 2;
5 is a view showing an air supply unit 20 according to an embodiment of the present invention.
6 is a view showing heat is transferred to the air heating tube (23)
7 is a cut-away perspective view of the combustion unit 30 according to an embodiment of the present invention;
8 is an enlarged view of the combustion unit 30 of FIG. 4 .
9 is an enlarged view of the upper part of FIG.
10 is a top perspective view of a steam hydrocarbon reformer according to the present invention;
11 is a perspective view of a source gas supply unit 40 according to an embodiment of the present invention.
12 is a view showing a spiral support according to an embodiment of the present invention;
13 is a view showing a source gas supply unit 40 according to another embodiment of the present invention.
14 is a view showing a state in which the distribution pipe 47 according to an embodiment of the present invention is provided while connecting between the distribution header 45 and the reforming unit 50
15 is a view illustrating that combustion gas is discharged while flowing along the first space 117 and the second space 155 according to an embodiment of the present invention;
16 is a view showing the flow of combustion gas in the upper chamber (15)
17 is a view showing a cross-section of the reforming unit 50 according to an embodiment of the present invention.
18 is a view showing that the reforming unit 50 is disposed to pass through the first communication hole 119 and the second communication hole 157
19 is a cross-sectional view showing a cross section BB' of FIG.
20 is a cross-sectional view showing the CC' section of FIG.
FIG. 21 is an enlarged view of a part of FIG. 19; FIG.
22 is a view showing the arrangement of the second transmission body 553 according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the steam hydrocarbon reformer according to the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Unless otherwise specified, all terms in this specification have the same general meaning as understood by those of ordinary skill in the art to which the present invention belongs, and in case of conflict with the meaning of the terms used in this specification, the According to the definition used in the specification.

Throughout the specification, when a part "includes" a certain component, it does not exclude other components unless otherwise stated, meaning that other components may also be further included. That a component is "connected" with another component may be directly connected, but does not exclude the connection through another component. Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings.

2 is a perspective view of a steam hydrocarbon reformer 1 according to an embodiment of the present invention, FIG. 3 is a cutaway perspective view of the steam hydrocarbon reformer 1 according to an embodiment of the present invention, and FIG. 4 is A-A of FIG. ' It is a cross section. 2 to 4, the steam hydrocarbon reformer 1 increases the heat exchange efficiency between the raw material gas, the combustion gas, and the catalyst, thereby increasing the yield of hydrogen through the reforming reaction, and reforming in the process of discharging the combustion gas By preheating the raw material gas before, the temperature of the raw material gas can be raised without an additional heat source to promote an efficient hydrogen reforming reaction. The steam hydrocarbon reformer includes a body 10, an air supply unit 20, a combustion unit 30, a raw material gas supply unit 40, a reformer 50, and a reformed gas discharge unit 60, and the reforming unit ( 50) is provided in plurality so that the hydrogen reforming reaction can be performed in each reforming unit.

The body 10 forms the overall appearance of the steam hydrocarbon reformer 1 according to an embodiment of the present invention, and a plurality of means for the hydrogen reforming reaction therein may be provided in stages. The body 10 may have a cylindrical shape with an empty interior as a whole, and includes a lower chamber 11 and an upper chamber 15 separated by a diaphragm 13 .

The lower chamber 11 may have a cylindrical shape having a space therein, and preferably may have a cylindrical shape having at least one or more openings. In the lower chamber 11, combustion gas and air are combusted to generate combustion gas, and a reforming reaction may proceed due to the heat of the combustion gas. The lower chamber 11 may be supplied with gas necessary for combustion, such as air and combustion gas, through an opening formed for the inflow or outflow of the fluid, which is sealed as a whole. The lower chamber 11 may include a lower housing 111 , a first layer 113 , a second layer 115 , and a first communication hole 119 .

The lower housing 111 forms the outer shape of the lower chamber 11, has an upper plate, a lower plate, and a side plate, is preferably formed in a cylindrical shape having a space therein, and is completely sealed. A first communication hole 119 may be formed in an upper portion of the lower housing 111 , and an opening may be formed in a side surface thereof.

The first layer 113 is a layer formed inside the lower housing 111, and it is preferable that a heat insulating layer is formed so as not to dissipate heat due to the combustion gas therein to the outside.

The second layer 115 is a layer formed inside the first layer 113, and a fire resistant layer is formed so that the first layer 113 or the lower housing 111 is not destroyed by an internal flame. Do. The second layer 115 may be formed as a heat insulating layer, but is preferably provided to transmit a predetermined heat. The first layer 113 and the second layer 115 may be fixed or connected to the lower housing 111 by being fastened with an anchor or the like, and a space between the first layer 113 and the second layer 115 to be described later. The air heating tube 23 is provided to heat the air flowing in from the outside to a sufficient temperature before combustion.

The first space 117 is a space in which combustion gas is generated through a combustion reaction between fuel gas and external air in the lower chamber 11 , and is defined in the lower housing 111 that is completely sealed. By combustion, the combustion gas flows with high heat and transfers heat to the reforming unit 50 disposed in the first space 117 so that the raw material gas can be converted into hydrogen in the reforming unit 50 . The flow of combustion gas will be described later.

The first communication hole 119 is formed in an upper portion of the lower chamber 11 , and is preferably formed as a hole having a predetermined diameter in the upper plate of the lower housing 111 , and may be formed in plurality. The plurality of first communication holes 119 may pass through and receive the plurality of reforming parts 50 , communicate with the second communication holes 157 to be described later, and may be coaxially aligned. The first communication hole 119 may be formed radially with respect to the center of the lower chamber 11 . The first communication hole 119 is preferably circular, and may be formed to correspond to the planar shape of the reforming unit 50 . As will be described later, the diameter d2 of the first communication hole 119 and the second communication hole 157 is formed to be larger than the diameter d1 of the outer tube 51 of the reforming part 50, so that the first communication hole 119 ) and the second communication hole 157 and the outer tube 51 may form a flow path through which the combustion gas flows.

The diaphragm 13 divides the lower chamber 11 and the upper chamber 15, and preferably has the shape of a disk having a predetermined thickness. The diaphragm 13 may include at least one or more openings 13a. The openings 13a are formed to correspond to the first communication hole 119 and the second communication hole 157 to correspond to the first communication hole ( 119) and the second communication hole 157 are coaxially aligned and have the same diameter, and each opening 13a preferably receives the reformed portion 50 through it.

The upper chamber 15 may have a cylindrical shape having a space therein, and preferably may have a cylindrical shape having at least one or more openings. In the upper chamber 15, while the combustion gas flows for discharge, the heat of the combustion gas is transferred to a source gas heating tube to be described later, and the source gas flowing in the source gas heating tube can be heated due to the transferred heat. there is. The upper chamber is entirely sealed, but an opening is formed so that the raw material gas can be supplied through the opening and the combustion gas can be discharged. The upper chamber may be separated or divided so as not to vertically overlap with the lower chamber. The first space in the lower chamber 11 and the second space in the upper chamber may not overlap, that is, the first space and the second space may not be formed simultaneously at a specific height of the reformer. The upper chamber 15 may include an upper housing 151 , a heat insulating layer 153 , a second communication hole 157 , and an upper hole 159 .

The upper housing 151 forms the outer shape of the upper chamber 15, has an upper plate, a lower plate, and a side plate, and is preferably formed in a cylindrical shape having a space therein. The upper housing 151 is formed to be completely sealed, a second communication hole 157 is formed in a lower plate of the upper housing 151, an upper hole 159 may be formed in the upper plate, and an opening is formed in the side of the fuel Gases can be received or flue gases can be emitted.

The heat insulating layer 153 is a layer formed inside the upper housing 151, and preferably does not radiate heat due to combustion gas flowing therein to the outside. The heat insulating layer is preferably formed of a ceramic fiber, but the material is not limited thereto.

The second space 155 is a space in which combustion gas flows in the upper chamber 15 . The combustion gas flows with high heat to be discharged through the opening formed in the side plate of the upper housing in the upper chamber 15 and transfers heat to the source gas heating tube 43 disposed in the second space 155 to heat the source gas. It can be heated first.

The second communication hole 157 is formed in the lower portion of the upper chamber 15, and may be formed in plurality. The plurality of second communication holes 157 may pass through and receive the plurality of reforming parts 50 , communicate with the first communication hole 119 and the opening 13a of the diaphragm, and may be coaxially aligned. The second communication hole 157 may be formed radially with respect to the center of the upper chamber 15 . The second communication hole 157 is preferably circular, but may be formed to correspond to the planar shape of the reforming part 50 .

The upper hole 159 is formed in the upper portion of the upper chamber 15, and may be formed in plurality. The plurality of upper holes 159 may pass through and receive the plurality of reforming portions 50 . Unlike the first communication hole 119 and the second communication hole 157 , the upper hole 159 does not form a flow path through which the combustion gas flows but is blocked by the outer tube 51 of the reforming unit. It may correspond to the diameter (d1) of the outer tube.

FIG. 5 is a view showing the air supply unit 20 according to an embodiment of the present invention, and FIG. 6 is a view showing that heat is transferred to the air heating tube 23 . 2 to 6 , the air supply unit 20 is provided to supply air to the first space 117 for a combustion reaction. At least a part of the air supply unit 20 is located in the lower chamber 11 to heat the outside air through the heat of the combustion gas generated in the first space 117 in the lower chamber 11 . The air supply unit 20 includes an air inlet 21 , an air heating tube 23 , and an air outlet 25 .

The air inlet 21 is provided to receive the outside air, and is preferably formed to pass through the lower chamber 11, and communicates with the outside through the opening formed on the side surface of the lower housing to introduce the outside air. At this time, as can be seen in FIG. 4 , the incoming air has a temperature of about 20 to 30 degrees because it is air at room temperature.

The air heating tube 23 is provided to heat the external air flowing in the air heating tube 23 by the heat of the combustion gas. Air introduced from the outside may be supplied to the combustion unit 30 by raising the temperature to 200 to 250 degrees without supplying an additional heat source. The combustion reaction in the combustion unit 30, which will be described later, generates heat necessary for the reforming reaction by burning natural gas and off-gas, which are fuel gases, and requires external air having a sufficiently elevated temperature for smooth combustion. Accordingly, the air heating tube 23 is provided in the lower chamber 15 to receive heat from the combustion gas in the first space 117 to heat the air. The air heating tube 23 may be provided between the first layer 113 and the second layer 115 , and forms a coil shape between the first layer and the second layer while forming the outer peripheral surface of the second layer 115 . may be provided accordingly. Referring to FIG. 6 , the heat from the first space 117 is preferably transferred to the second layer 115 , which is a fireproof layer, and the heat that is blocked by the first layer 113 , which is a heat insulating layer, cannot proceed to the outside. Heat is transferred to the air heating tube (23). The number of windings of the air heating tube 23 to form a coil is not limited.

The air outlet 25 is connected to the air heating tube 23 and injects air heated from the air heating tube 23 side into the combustion unit 30 to be described later. At least a portion of the combustion housing 31 may be formed to protrude outside the lower chamber 11, preferably to the lower side. ) and may be directly connected to the combustion housing 31 of the combustion unit 30 while being provided on the lower side.

7 is a cut-away perspective view of the combustion unit 30 according to an embodiment of the present invention, and FIG. 8 is an enlarged view of the combustion unit 30 of FIG. 4 . 2 to 4 and 7 to 8, the combustion unit 30 generates combustion gas by burning fuel gas and air, and the combustion gas can supply heat required for the reforming reaction. there is. The combustion unit 30 may be provided at a lower center of the lower chamber 11 . The combustion unit 30 includes a combustion housing 31 , a mixing unit 32 , and a fuel gas supply unit 33 , and may further include a first stirring unit 34 and a second stirring unit 35 . .

The combustion housing 31 forms the overall appearance of the combustion unit 30 and allows a series of processes necessary for the generation of combustion gas to be performed therein. In one embodiment of the present invention, the combustion unit 30 is provided at the lower center of the lower chamber 11, and generates combustion gas by a combustion reaction and flows the combustion gas upward. A combustion reaction occurs in the upper portion of the combustion housing 31 and fuel gas and external air may be supplied for the combustion reaction in the lower portion. The combustion housing 31 may include a first combustion vessel 311 , an enlarged diameter part 313 , and a second combustion vessel 315 .

Referring to Figure 8, the first combustion vessel 311 is provided on the lower side of the combustion housing 31, is formed in a cylindrical shape having a predetermined diameter, through the combustion air inlet 311a formed on one side of the air supply unit ( 20) can receive the input from the heated air and fuel gas. In the first combustion vessel 311, the heated air may be supplied through the combustion air inlet 311a formed on the side, and the fuel gas may be supplied through the fuel gas inlet 331 formed through the lower side. However, as can be seen in FIGS. 7 and 8 , the fuel gas and the heated air are not directly mixed in the first combustion vessel 311 , but are separated by a fuel gas supply unit 33 to be described later, and the mixing unit (32) can be mixed with each other.

The enlarged diameter portion 313 connects the first combustion vessel 311 and the second combustion vessel 315 , is formed in the shape of an upper-gwang-lower narrow, and increases in diameter toward the upper side, and is connected to the igniter 36 .

The second combustion vessel 315 is provided on the upper side of the combustion housing 31, is formed in a cylindrical shape having a predetermined diameter with the upper side open, and is preferably coaxially aligned with the first combustion vessel and the first combustion vessel 311 ) can have a larger diameter than In the second combustion vessel 315, the fuel gas and air flowing in a turbulent flow are subjected to a combustion reaction through the igniter 36.

As shown in FIG. 8 , the mixing unit 32 is provided to mix fuel gas and air before combustion of fuel gas and air in the first combustion vessel 311 . Due to the combustion characteristics of hydrogen, which has a fast combustion rate and is explosive, incomplete combustion occurs and compounds such as NOx are generated, or the reforming unit 50 is damaged by the flame because it is difficult to control the flame. In order to make the supply of hydrogen contained in the fuel gas constant, air and fuel gas are mixed before combustion, and turbulent flow is generated so that combustion proceeds relatively constantly. The mixing unit 32 may include an air storage chamber 323 , a premixing chamber 325 , and a rim 327 .

The air storage chamber 323 is a space separated from the fuel gas supply part 33 to be described later in the first combustion vessel 311, and in the air storage chamber 323, the introduced heated air introduced from the combustion air inlet 311a is temporarily stored. After being stored as , the temporarily stored air flows into the premixing chamber 325 .

The pre-mixing chamber 325 is provided at a relatively upper side of the first combustion vessel 311 , and may be formed to surround the fuel gas distribution port 333 in the upper portion of the air storage chamber 323 . In the pre-mixing chamber 325, the fuel gas and air are mixed before combustion. The fuel gas discharged from the fuel gas supply unit 33 to be described later is mixed with air in the premixing chamber 325 to prevent backfire or sudden change of the flame.

The rim 327 is formed along the inner circumferential surface at the upper end of the first combustion vessel 311, and refracts the air flowing toward the wall of the first combustion vessel 311 together with the stirring means 34 and 35 to generate turbulence. can

The fuel gas supply unit 33 is provided to supply fuel gas, which is a mixture of natural gas and off-gas, to the combustion unit. The fuel gas supply unit may be provided in the first combustion vessel 311 to prevent direct mixing of fuel gas and air, and to mix with turbulent flow in the premixing chamber 325 . The fuel gas supply unit 33 may be coaxially aligned with the first combustion vessel 311 as a whole, and includes a fuel gas inlet 331 and a fuel gas distribution port 333 .

Referring back to FIG. 7 , the fuel gas inlet 331 passes through the lower side of the first combustion vessel 311 and is formed to extend a predetermined height from the lower side of the first combustion vessel. The air storage chamber 323 may be divided through the fuel gas inlet 331 , and fuel gas is introduced through the fuel gas inlet 331 .

The fuel gas distribution port 333 is provided above the fuel gas inlet 331 and in the premixing chamber 325 to distribute the fuel gas introduced from the fuel gas inlet 331 to the premixing chamber 325 . The fuel gas distribution port 333 may be formed to extend vertically after being enlarged from the fuel gas inlet 331 , to be bent to the center, and to be formed to be closed. A nozzle 333a is provided in the fuel gas distribution port 333 to inject fuel gas toward or above the premixing chamber 325 . In this case, the nozzle 333a may have a diameter of preferably 1.2 mm to 2 mm.

The first stirring means 34 is disposed to cover the flow path of fuel gas and air rising from the fuel gas distribution hole 333 in the pre-mixing chamber 325 as the center, and the fuel gas distribution hole 333 . and a plurality of first vanes 341 extending from the to the first combustion vessel 311 and a first separation space 343 formed between the first vanes 341 .

As can be seen from FIG. 7 , the first vane 341 is twisted at a predetermined angle to the fuel gas distribution port 333 , and the first separation space 343 between each of the first vanes 341 . ) is formed so that the mixed gas passing through the separation space can flow spirally.

The second stirring means 35 may be disposed to cover the flow path of combustion gas or fuel gas rising around a portion where combustion occurs in the second combustion vessel 315, and the second stirring means (35) may be coaxially aligned with the first stirring means (34). The second stirring means 35 is formed from a plurality of second vanes 351 extending from the fire-resistant castable 355 toward the center, a second spaced space 353 formed between each of the second vanes 353 and the flame. It includes a fire-resistant castable 355 to protect the second combustion vessel (315).

As can be seen in FIG. 7 , the second vane 351 is twisted at a predetermined angle to the fire resistant castable 355 , and the second spaced space 353 between each of the second vanes 351 . This is characterized in that the mixed gas passing through the spaced space can flow in a spiral. The fire resistant castable 355 may include a vertical portion 355a that extends vertically and is attached to the second combustion vessel 315 and an enlarged diameter portion 355b whose diameter is increased going upward.

The igniter 36 burns the mixed gas of fuel gas and air, and is provided in the enlarged diameter part 313 to ignite the fire upward.

9 to 14 , the source gas supply unit 40 supplies the source gas to the reforming unit 50 to cause a hydrogen reforming reaction to occur in the reforming unit 50 . The raw material gas may be a mixture of natural gas and water vapor, in which case the water vapor is heated to a certain extent, and preferably has a temperature of about 230 degrees Celsius. As will be described later, the temperature required for the reforming reaction to take place by the catalyst in the reforming unit 50 is about 700 degrees, so the temperature of the raw material gas needs to be raised in the process of supplying the raw material gas. The source gas supply unit 40 includes a source gas inlet 41 , a source gas heating tube, a spiral support unit 44 , a distribution header 45 , and a distribution tube 47 .

The source gas inlet 41 is provided to receive the source gas, and is preferably formed through the side surface of the upper chamber 15 so as to be connected to the outside through an opening formed in the upper housing to receive the source gas.

9 and 11 , the source gas heating tube 43 is provided to heat the source gas flowing in through the source gas inlet 41 before supplying it to the reformer 50 . The source gas heating tube 43 may be provided in the second space 155 to heat the source gas by heat exchange with the combustion gas flowing through the second space 155 . The raw material gas heating tube 43 may form a spiral shape in order to efficiently exchange heat with the combustion gas flowing through the second space 155 in the upper chamber 15 . The source gas heating tube 43 forms a double overlapping spiral shape, and an outer spiral 431 connected while communicating with the source gas inlet 41 , and the inner spiral are connected while communicating with the distribution header 45 . and an inner spiral 433 that becomes It can be made to be heated secondary.

11 to 12 , the outer spiral 431 is provided to form a spiral or coil in the second space 155 in the upper chamber 15 , and the inner spiral 433 is concentric with the outer spiral 431 . It is spaced apart from the outer spiral 431 while being ordered to form a spiral or a coil. The outer spiral 431 and the inner spiral 433 may be provided to be spaced apart from the inner surface of the upper chamber 15 . Being spaced from the inner surface includes being spaced apart from the inner surface of the upper chamber 15 , that is, from the side surface of the heat insulating layer 153 , and being spaced apart from the lower surface and/or the upper surface.

Referring to FIG. 16, which is a view showing the flow of combustion gas in the upper chamber 15, a flow path guide 435 for guiding a flow path of combustion gas is added to the outside or inside of the raw material gas heating tube 43 can be formed with The flow path guide 435 may be provided to guide the flow direction of the combustion gas flowing in the second space 155 , that is, the upper chamber 15 . The flow path guide 435 may be provided in the form of a tube or a wall, and is preferably coaxially aligned with the upper chamber 15 and may have a cylindrical shape based on the center of the upper chamber 15 . A plurality of the flow path guides 435 are formed in the upper chamber 15 in a cylindrical shape, and it is preferable to have a height smaller than the height of the second space 155 so that the combustion gas can pass therethrough. The flow path guide 435 may allow the combustion gas to flow along the spiral-shaped source gas heating tube, and the combustion gas heating tube 43 has a spiral shape so that the source gas is in the form of the combustion gas heating tube 43 In preparation for flowing in accordance with the flow path guide part 435 is formed in a cylindrical shape having a predetermined height, so that the combustion gas flows from the upper side to the lower side around the combustion gas heating tube 43 or the combustion gas flows from the lower side to the upper side to face each other It enables efficient heat transfer between combustion gas and raw material gas.

The flow path guide 435 may include a first flow path guide 435a and a second flow guide 435b. The first flow path guide 435a may be spaced apart from the plurality of second communication holes 157 and extend upwardly from the lower surface of the upper chamber. The combustion gas passing through the second communication hole 157 and flowing into the second space 155 flows from the lower side to the upper side according to the first flow path guide part 435a, and the first flow path guide part 435a and the upper chamber Heat exchange with the combustion gas heating tube is possible while spreading outward through the spaced part of the upper surface.

The second flow path guide 435b may be spaced apart from the first flow path guide 435a to extend downward from the upper surface of the upper chamber. The combustion gas flows downward by the second flow path guide 435b, and is diffused outward again through the space spaced apart between the lower end of the second flow path guide 435b and the lower surface of the upper chamber toward the combustion gas outlet. It can exchange heat with the raw material gas heating tube 43 . This flow of combustion gas can be confirmed in FIGS. 15 and 16 .

11 to 13 , the spiral support part 44 is provided to support the outer spiral 431 and the inner spiral 433 . The spiral support portion 44 supports the outer spiral and the inner spiral to be spaced apart from the inner surface of the upper chamber 15 . The spiral support unit 44 connects the outer support 441 for supporting the outer spiral, the inner support 443 for supporting the inner spiral, and the outer support 441 and the inner support 443 to fix or guide the position of the support. and a support connector 445 .

The outer support 441 and the inner support 443 may be brackets. In a preferred embodiment of the present invention, a plurality of bracket-shaped outer supporters 441 and inner supporters 443 are provided such that a plurality, more preferably four pairs, are aligned in opposite directions to support the outer spiral and the inner spiral. The shape of the bracket formed by the outer supporter 441 and the inner supporter 443 is not limited, but it is sufficient as long as it can accommodate a raw material gas heating tube having a circular cross section between both ends. The support connector connects the outer support 441 and the inner support 443 between the pair of outer support 441 and the inner support 443 , and extends from the inner surface of the upper chamber 15 to provide the outer support 441 . ) and the position of the inner support 443 can be fixed or guided.

Referring to FIG. 13 , in another embodiment of the present invention, the outer support 441 ′ and the inner support 443 ′ may be formed as walls. The outer supporter 441' and the inner supporter 443' formed as a wall may extend from the upper surface or the lower surface of the upper chamber 15, respectively, and a spaced space between the outer supporter 441' and the inner supporter 443' 446 is formed so that combustion gases can flow therebetween. In this case, heat exchange efficiency can be achieved by inducing the flow of combustion gas between the separation space 446 and each support.

Referring back to FIGS. 9 to 14 , the distribution header 45 is connected to the source gas heating tube 43 to receive the heated source gas, and distributes it to the reformer 50 . In one embodiment of the present invention, the distribution header 45 is provided in the upper center of the upper chamber 15 and is connected to the air heating tube 43 through the opening formed in the upper side of the upper chamber 15 to be heated source gas may be supplied and the source gas may be supplied to the plurality of reforming units 50 radially arranged around the distribution header. The distribution header 45 may preferably have a cylindrical shape having a predetermined diameter d3, and may be connected to a side surface thereof to communicate with a plurality of distribution pipes 47 connected to the side surface of each reforming unit 50 . The distribution header 45 may be arranged in the center on a plane to evenly distribute the source gas to each reforming unit 50 .

Referring to FIG. 14 , the distribution pipe 47 supplies the heated source gas from the distribution header 45 to each reforming unit 50 . The distribution pipe 47 has one end connected to the side surface of the distribution header 45 to communicate with the distribution header, and the other end connected to the side surface of the outer tube 51 of the reformer 50 to communicate with the outer tube 51 . provided as much as possible. The distribution pipe 47 may have elasticity so as not to be destroyed or damaged by the high-temperature raw material gas flow. In addition, the distribution pipe 47 may be formed to have a curve to accommodate expansion and contraction. The distribution pipe 47 has a predetermined diameter d4, preferably in the shape of a tube having a diameter of 10 mm or less, so that the diameter d4 of the distribution pipe 47 is smaller than the diameter d3 of the distribution header. It may be formed, and may be formed to be smaller than the diameter (d1) of the outer tube (51).

The distribution pipe 47 includes a first extension portion 471 extending approximately in a straight line from the side surface of the distribution header 45 , a bent portion 473 formed to be curved to accommodate expansion and contraction, and a modified portion 50 from the bent portion 473 . ) side, that is, includes a second extension portion 473 extending approximately in a straight line to the side of the outer tube (51).

The curved portion 473 may include a first curved portion 473a formed to be curved in one side from the first extension portion and a second curved portion 473b formed to be curved from the first curved portion to the other side. The first curved portion 473a and the second curved portion 473b may be bent so that the first extension portion 471 and the second extension portion 473 are parallel to each other. In a preferred embodiment of the present invention, the first bend 473a is bent from the first extension to the upper side and the distribution header 45 side, and the second bend 473b is from the first bend 473a to the first extension ( By bending toward the reforming part 50 in parallel to 471 , the distribution pipe 47 may be formed to have a Z-shape as a whole. When the high-temperature raw material gas flows, the length of the flexible distribution pipe can be increased by the temperature, and the expansion and contraction is accommodated by the bent portion 473 like a dotted line, so that the distribution pipe 47, the distribution header 45 And it is possible to prevent breakage or damage to the reforming unit 50 .

Furthermore, the distribution pipe 47 has a diameter d4 smaller than the diameter d3 of the distribution header to form a differential pressure so that a uniform amount of source gas can be distributed. Therefore, while the distribution header 45 supplies a uniform amount of raw material gas to the plurality of reforming units 50 from the center, for each reforming unit 50, the pressure difference between the distribution pipe 47 and the distribution header 45 is applied. The raw material gas can be uniformly supplied.

In addition, the distribution pipe 47 is formed to have a diameter d4 smaller than the diameter d1 of the outer tube 51 , so that the source gas may be uniformly supplied to the inside of the outer tube 51 on a plane surface.

15 is a view illustrating that combustion gas is discharged while flowing along the first space 117 and the second space 155 according to an embodiment of the present invention, and FIG. 16 is a view showing combustion in the upper chamber 15 It is a diagram showing the flow of gas. Combustion gas is generated in the first space 117 by combustion of external air and fuel gas in the combustion unit 30, and the lower chamber 11 is sealed except for the opening through which air and fuel gas are introduced. The combustion gas in the space 117 flows into the second space 155 in the upper chamber 15 through the first communication hole 119 and the second communication hole 157, is connected to the second space, and is connected to the upper housing ( 151) is discharged to the outside through the exhaust gas outlet formed on the side. In this process, the combustion gas discharged to the high temperature of the second space flows while surrounding the raw material gas heating tube 43, and through efficient heat exchange with the raw material gas flowing inside the raw material gas heating tube 43, approximately It can raise the temperature of raw material gas from 230 degrees to 650 to 700 degrees.

Referring to FIGS. 3 to 4 and 17 to 19 , at least a part of the reforming unit 50 is disposed in the lower chamber 11 and the upper chamber 15 , and from the combustion gas generated in the combustion unit 30 . It receives heat and performs a reforming reaction to generate hydrogen. A plurality of reforming units 50 may be provided, and may be radially disposed from the center on a plane. The reforming unit may be provided with a different number depending on the capacity. In a preferred embodiment of the present invention, three reforming units 50 may perform the hydrogen reforming reaction, but when the processing capacity is increased, 6, 8, or 10 or more reforming units 50 are radially disposed. Hydrogenation reaction can be carried out. At least a part of the reforming part 50 is provided on the upper side of the upper chamber 15 , at least part of it is located in the second space 155 in the upper chamber 15 , and at least part of the reforming part 50 is provided with the first communication hole 119 and It is disposed through the second communication hole 157 , and at least a portion is located in the first space 117 in the lower chamber 11 . The reforming unit 50 may include an outer tube 51 , an inner tube 52 , a catalyst 53 , a protective jacket 54 , a heat transfer means 55 , a flow path 56 , and a sensor 57 . .

The outer tube 51 is connected to the source gas supply unit 40 to receive the heated source gas. The outer tube 51 may extend up and down while having a constant diameter d1, which is smaller than the diameter d2 of the first communication hole 119 and the second communication hole 157, the first communication hole 119 When passing through and the second communication hole 157 , a flow path 56 is formed, and the upper hole may be blocked by corresponding to the diameter d1 of the upper hole 159 . An inlet hole 51a is formed on the side surface of the outer tube 51 and is connected to the distribution tube 47, and the diameter d4 of the distribution tube is smaller than the diameter d1 of the outer tube 51 so as to be evenly distributed into the outer tube 51. The heated source gas is supplied, and the source gas flows downward in the outer tube 51 . The outer tube 51 may be formed to extend vertically from the upper side of the upper chamber 15 to the first space 117 . The outer tube 51 is formed to be completely closed up and down, but an opening may be formed for the inflow and discharge of gas, and may communicate with the inner tube 52 accommodated therein. The upper side of the outer tube may be connected to the combustion gas supply unit and the lower side may be closed. The outer tube 51 includes an outer tube 511 , a lower cap 513 that closes the lower end of the outer tube, and an upper cap 515 that closes the upper end of the outer tube.

The outer tube 511 is a cylindrical, vertically extending tube, the inlet hole 51a is formed on the side, the lower end is closed by the lower cap 513, and the upper end is closed by the upper cap 515. , the upper cap 515 may form an opening in the center to receive through the inner tube 52 to be described later. The outer tube 511 extends from the upper side of the upper chamber 15 through the second space 155 into the first space 117 in the lower chamber 11 , and a catalyst is disposed in the first space 117 . (53) can be provided to convert the source gas into hydrogen.

The inner tube 52 is provided in the outer tube 51 , and may be coaxially aligned with the outer tube 51 . Accordingly, the diameter of the inner tube is formed to be smaller than the diameter (d1) of the outer tube (51). The lower end of the inner tube 52 is provided to be spaced apart from the lower cap 513 , so that the reformed gas reformed through the catalyst 53 may be introduced into the lower end of the inner tube 52 . The upper end of the inner tube 52 may be provided to be connected to a reformed gas discharge unit 60 to be described later to discharge the reformed gas, and may be formed to pass through an opening formed in the upper cap 515 . The inner tube 52 is formed extending vertically from the upper side of the upper chamber 15 to the first space 117 , the lower end is located above the lower end of the outer tube 51 , and the upper end of the outer tube 51 . It may be located above the top.

The catalyst 53 is provided in the reforming unit 50 to convert the raw material gas containing natural gas and water vapor into reformed gas containing hydrogen. The catalyst 53 may be provided between the outer tube 51 and the inner tube 52 . The catalyst 53 may be formed in an outer tube disposed in the first space 117 . The reforming reaction that occurs in the catalyst 53 is an endothermic reaction, and heat supply is required. 50) may be blocked. Accordingly, it is provided in the first space 117 where combustion occurs, and heat can be transferred by a heat transfer means 55, which will be described later, and the raw material gas flowing into the vicinity of the catalyst 53 is heated to about 650 to 700 degrees in advance. will move

The catalyst 53 is disposed in the first space 117 in the lower chamber 11, preferably disposed above the first space 117 to cause a reforming reaction. Referring back to FIG. 15 , when combustion gas is generated in the combustion housing 31 at the lower side (bottom firing), the combustion gas first proceeds to the upper side, and after transferring heat to the protective jacket 54 in the closed space, the lower side and flows into the combustion gas accommodating part 543 to be described later. Accordingly, heat transfer can occur smoothly from the upper side between the first space 117 and the protective jacket 54, and as the combustion gas flows downwardly while flowing into the combustion gas receiving unit 543 provided at the lower side, it is also on the lower side. heat transfer takes place. In consideration of this, the catalyst 53 extends downward from the upper end of the first space 117 and is disposed in the outer tube 51 to increase the efficiency of the hydrogen reforming reaction.

The protective jacket 54 is provided in coaxial alignment on the outside of the outer tube 51 , and extends vertically from the second communication hole 157 through the first communication hole 119 to the first space 117 . The protective jacket 54 is provided such that one end communicates with the first space 117 in the lower chamber 11 and the other end communicates with the second space 155 in the upper chamber 15 . The diameter of the protective jacket 54 may correspond to the diameter d2 of the first communication hole 119 and the second communication hole 157 and may be spaced apart from the outer tube 51 by a predetermined distance. The protective jacket 54 may extend so that the lower end of the outer tube 51 is exposed, but it is preferable to extend below the lower end of the outer tube 51 so that the lower end of the outer tube 51 is not exposed. If the protective jacket 54 is not provided, the flame directly transfers heat to the outer tube 51 . In this case, the reforming unit 50 is damaged or the reforming reaction does not occur smoothly due to the brittleness of the catalyst 53 . does not Therefore, the protective jacket 54 can protect the flame from direct contact with the outer tube 51, and transfer heat to the outer tube 51 by convection or radiation to cause the reforming reaction to occur. The protective jacket 54 includes a sleeve 541 and a combustion gas accommodating part 543 .

The sleeve 541 is provided to surround the outer side of the outer tube 51, extends vertically from the second communication hole 157, and has an open lower end, which is blocked to a certain extent by a combustion gas receiving part 543 to be described later. . The sleeve 541 is spaced apart from the outer tube 511 by a predetermined distance to form a flow path 56 therebetween, so that heat is transferred into the outer tube 51 by convective heat of the combustion gas flowing upward through the flow path 56 . While doing so, heat may be transferred to the outer tube 51 through the heat radiated from the sleeve 541 . The sleeve 541 may extend below the lower end of the outer tube. The sleeve 541 preferably extends below the upper end of the combustion housing 31 , and more preferably extends below the upper end of the second combustion vessel 315 . When heat from the combustion housing 31 is directly transferred, heat transfer to the side facing the flame and heat transfer to the side not facing the flame are unbalanced, so that heat exchange efficiency and reforming efficiency may decrease. By extending below the upper end of the second combustion vessel 315, the combustion gas may be indirectly introduced into the sleeve 541 to perform uniform heat transfer.

20 is a cross-sectional view illustrating a cross section C-C′ of FIG. 17 . Referring to FIG. 20 , the combustion gas accommodating part 543 is provided to receive combustion gas at the lower end of the sleeve 541 , and a plurality of inlet holes 543a are formed so that the combustion gas flows through the inlet holes 541 . ) can be introduced into the The plurality of inlet holes 543a may be formed while having the same angle radially from the center of the circular plane of the reforming unit 50 , that is, the combustion gas receiving unit 543 . In a preferred embodiment, eight inlet holes 543a may be formed while having an angle of 45 degrees. As the inlet holes 543a are formed radially, the combustion gas in the first space 117 is uniformly introduced along each inlet hole 543a. The combustion gas accommodating part 543 includes an accommodating cap 5431 and an accommodating wall 5433 .

The accommodating cap 5431 is the lower end of the combustion gas accommodating part 543 to close the lower surface of the combustion gas accommodating part, and the accommodating wall 5433 has an accommodating hole 543a formed on the lower surface of the combustion gas accommodating part 543 . It extends from the accommodating cap 5431 as much as possible, and the accommodating wall may also be radially formed with the same angle so that the accommodating hole 543a is formed radially while having the same angle.

Referring back to FIGS. 15 and 17 to 18 , a flow path 56 is formed between the sleeve 541 and the outer tube 51 of the protective jacket 54 , and the combustion gas flows upward through the flow path to form the first It flows from the space 117 to the second space 155 . At this time, the combustion gas is uniformly introduced into the flow path 56 , and heat is transferred from the combustion gas to the outer tube 51 through convection. On the other hand, it is the coefficient of heat transfer to the dura mater, and the dura mater heat transfer coefficient expressed as the amount of heat transfer [kcal/m ² h ℃] for unit area, unit time, and unit temperature difference is, In the case of forced convection, it is 15-40, in the case of natural convection due to the density difference created in the fluid by heating, etc., it is 5-8, and in the case of forced convection, the heat transfer efficiency is high.

In a preferred embodiment of the present invention, when the protective jacket 54 is formed to be long, the movement speed of the combustion gas in the flow path 56 is increased, so that the nature of the convection in the flow path 56 is forced convection. The closer to , the higher the heat transfer efficiency by convection. When viewed from the lower end of the outer tube 51 or the lower end of the protective jacket 54 , the sleeve 541 does not extend only at the upper end of the first space 117 , that is, within the lower chamber 11 , but rather the upper chamber. By extending to the second communication hole 157 of (15), convection with higher efficiency than the convective heat transfer with the outer tube 51 by the protective jacket 54 or sleeve 541 in the steam hydrocarbon reformer composed of a single chamber to allow heat transfer.

FIG. 21 is an enlarged view of a portion of FIG. 19 , and the following description will be made with reference to FIGS. 17 to 19 and 21 , focusing on the attachment of the heat transfer means 55 to the reforming unit 50 of the present invention. The heat transfer means 55 may be provided to increase the efficiency of hydrogen reforming by assisting in heat transfer to the catalyst 53 or raw material gas. The heat transfer means 55 may be provided to transfer heat from the combustion gas in the first space 117 to the catalyst 53 or the source gas. Alternatively, the heat transfer means 55 may be provided to transfer heat from the reformed gas rising through the inner tube 52 to the source gas in the outer tube 51 descending. The heat transfer means 55 may be provided to have the shape of a fin, and has the shape of a plate extending to one side and is attached to the protective jacket 54 or the inner tube 52 to increase the surface area or heat transfer area for heat transfer It is desirable to promote The heat transfer means 55 may include a first transfer member 551 and a second transfer member 553 .

The first transfer member 551 may be provided to transfer heat from the reformed gas including hydrogen to the source gas. The first transfer member 551 is provided between the inner tube 52 and the outer tube 51 to transfer heat from the reformed gas to the source gas, and may be formed on the outer peripheral surface of the inner tube 52 . The first delivery body 551 has a plate shape extending vertically from the outer circumferential surface of the inner tube 52, and thus does not interfere with the flow of the raw material gas going down. It may be provided to transfer heat to the raw material gas of about 700 degrees. To this end, the first carrier 551 may be provided above the catalyst 53 . A plurality of the first transmission members 551 are formed and radially disposed with respect to the center of the inner tube 52 , and each of the first transmission members 551 is extended while having the same angle from the center of the inner tube 52 . can be formed. In a preferred embodiment of the present invention, the first transmission member 551 may be formed while having an angle of 90 degrees from the center.

Referring to FIG. 21 , the second transfer member 553 may be provided to transfer heat from the combustion gas in the first space 117 to the source gas. The second transfer member 553 is provided on the outside of the protective jacket 54 or sleeve 541 to transfer heat from the combustion gas to the sleeve 541, and heat is transferred from the sleeve 541 to the outer tube 51 through radiation. can be transmitted. The second transmission member 553 is formed on the outer circumferential surface of the sleeve 541 , and preferably has a plate shape extending vertically from the outer circumferential surface of the sleeve 541 . The second delivery member 553 may be provided above the first space 117 , and may preferably be formed at a height corresponding to the upper end of the catalyst 53 . Since a lot of heat is required for the reforming reaction in the catalyst 53, and in particular, a lot of heat is required at the upper end of the catalyst where the reforming reaction occurs first, the second carrier 553 is provided to efficiently transfer heat to the upper side of the catalyst. do.

A plurality of the second transfer members 553 may be radially disposed with respect to the center of the sleeve 541 . In this case, the second transfer member 553 may be disposed with the same spacing around the sleeve 541 . Accordingly, heat from the first space 117 is transferred to the sleeve 541 by the second transfer member 553 , and heat is transferred from the sleeve 541 to the outer tube 51 by radiation. In a preferred embodiment of the present invention, eight second transmission bodies may be disposed at a 45 degree angle, but other arrangements are not excluded from the scope of the rights.

22 is a view showing the arrangement of the second transmission body 553 according to another embodiment of the present invention. Referring to FIG. 22 , the plurality of second transmission members 553 in another embodiment of the present invention may be formed to extend from the center of the sleeve 541 at different angles. In the case of the combustion gas accommodating part 543, the plurality of accommodating holes 543a are formed radially while having the same angle, so that combustion gas can be uniformly introduced into the protective jacket, but in the case of the outside of the sleeve 541, combustion Where the housing 31 faces the flame side, a lot of heat is transferred by the combustion gas, and less heat can be transferred to the part that does not face the flame. In this case, heat transfer by radiation from the sleeve 541 to the outer tube is not uniform, so that the hydrogen reforming reaction may occur non-uniformly in the catalyst 53 in the outer tube 51 . Accordingly, each second transmission body 553 is provided with a wide angle β from the center of the sleeve 541 on the side facing the combustion unit 30 or the combustion housing 31, and the combustion unit 30 ) or the combustion housing 31 is provided spaced apart so as to have a narrow angle (α) from the center of the sleeve (541) on the side. Accordingly, the second transmission body 553 provided on the side facing the flame is provided while forming a wider angle than the second transmission body 553 provided on the side not facing the flame (α<β), and does not face the flame It may be arranged such that the angle between each of the second transmission members 553 gradually decreases toward the non-removable side. In addition, the plurality of second delivery members 553 may be disposed to be symmetrical with respect to an imaginary straight line connecting the center of the sleeve 541 from the center of the combustion unit 30 or the inner space 117 .

The flow path 56 is formed by extending the protective jacket 54 or sleeve 541 while enclosing the outer tube from the outside of the outer tube 51 , and the combustion gas passes through the flow path 56 into the first space ( 117) flows upward into the second space 155 and transfers heat to the outer tube 51 through convection, and accordingly, the raw material gas is converted into reformed gas including hydrogen in the catalyst 53. As described above, as the protective jacket 54 or sleeve 541 extends vertically from the second communication hole 157 , the flow path 56 extends from the second communication hole 157 to the lower end of the outer tube 51 . formed, thereby allowing the combustion gas to flow upward at a faster rate than when the flow path is formed only in the lower chamber 11, so that efficient heat transfer is possible with a high dural heat transfer coefficient.

The sensor 57 may be provided to sense the temperature of each part in the reforming unit 50 in which the hydrogen reforming reaction is performed. In order for the reforming reaction to occur efficiently, a constant temperature must be maintained or a temperature within an appropriate range must be maintained, so that the reforming reaction can be controlled after sensing the temperature of the portion where the reforming reaction is being performed by the sensor 57 . The sensor 57 may be attached to or extended from the outer circumferential surface of the sleeve 541 of the protective jacket (57a). The sensor 57a detects the temperature of the first space 117, so that it can be checked whether heat required for the reforming reaction is supplied. The sensor 57a may be provided above, below, and below the sleeve 541 in the first space. The sensor 57 may sense the temperature of the catalyst 53 between the inner tube 52 and the outer tube 51 (57b). By sensing the temperature of the catalyst 53, it can be checked whether the reforming reaction is well performed over the entire area of the catalyst. The sensor 57b is provided on the outer circumferential surface of the inner tube 52 and may be disposed in an area where the catalyst is disposed, and is provided over the area where the inner tube 52 extends as well as the area where the catalyst is disposed, so that the reforming unit ( 50) You can also collect temperature data for each location. Furthermore, the sensor 57 may be provided on the outer peripheral surface of the inner tube to detect the temperature of the raw material gas flowing downward, or may be provided on the inner peripheral surface of the inner tube to detect the temperature of the reformed gas flowing upward. In addition, the sensor 57 extends vertically along the outer circumferential surface of the outer tube 51 and is attached to extract temperature data of the outer tube 51 . The extracted data may be used for control of the combustion unit 30 and safety management related to flame or heat for efficient hydrogen reforming.

Referring back to FIGS. 9 to 10 , the reformed gas discharge unit 60 is provided to discharge the reformed gas generated through the reaction in the reformer 50 . The reformed gas discharge unit 60 may be disposed above the upper chamber 15 to discharge the reformed gas. The reformed gas discharge unit 60 includes a reformed gas inlet 61 , an outlet pipe 63 , an outlet header 65 , and a reformed gas outlet 67 .

The reformed gas inlet 61 receives the reformed gas from the reformer 50 . The reformed gas inlet 61 is connected to the open upper end of the inner tube 52 to receive the reformed gas flowing upward.

The outlet pipe 63 supplies the reformed gas to the outlet header 65 by connecting the reformed gas inlet 61 and the outlet header 65 . The outlet pipe 63 is provided such that one end is connected to the reformed gas inlet 61 and the other end is connected to the side or upper surface of the outlet header 65 to communicate with the outlet header. The outlet pipe 63 may have elasticity so as not to be destroyed or damaged by the high-temperature reformed gas flow. In addition, the outlet pipe 63 may be formed to have a curve to accommodate expansion and contraction. The outlet pipe 63 has a predetermined diameter, and preferably has a pipe shape having a diameter of 20 mm or less. As in the case of the distribution pipe 47, the diameter of the outlet pipe 63 is the reformed gas inlet diameter. It may be formed to be smaller, and may be formed to be smaller than the diameter of the outflow header 65 .

The outlet pipe 63 includes a third extension 631 extending approximately in a straight line from the reformed gas inlet 61, a bent portion 633 formed to be curved to accommodate expansion and contraction, and an outflow header 65 from the bent portion 633. and a fourth extension 675 connected to the side surface or the upper surface.

The curved portion 633 may include a third curved portion 633a formed to be curved from the third extended portion 631 to one side and a fourth curved portion 633b formed to be curved from the third curved portion to the other side. The third curved portion 633a and the fourth curved portion 633b may be bent so that the third extended portion 631 and the fourth extended portion 635 preferably form a right angle. In a preferred embodiment of the present invention, the third curved portion 633a is curved from the third extension 631 toward the lower side and the outflow header 65 side, and the fourth curved 633b is the third curved portion from the third curved portion 633a. By bending toward the outlet header 65 to be perpendicular to the extension 631 , the outlet pipe 63 may be formed to have an S-shape as a whole. When the high-temperature reformed gas flows, the length of the stretchable outlet pipe can be increased by temperature, and the expansion and contraction is accommodated by the bent portion 633, so that the outlet pipe 63, the outflow header 65 and the reforming part are accommodated. (50) It is possible to prevent breakage or damage. Furthermore, the outlet pipe 63 is formed to have a diameter smaller than the diameter of the reformed gas inlet 61 to form a differential pressure so that a uniform amount of raw material gas can flow out.

The outflow header 65 is provided in a circular ring shape on the upper side of the upper chamber 15 , receives reformed gas from a plurality of outflow pipes 63 , and a reformed gas outlet formed at one side of the outflow header 65 . The reformed gas is discharged through (67).

Accordingly, the source gas flows into the source gas inlet 41 and is heated in the source gas heating tube 43 , and then flows through the distribution header 45 and the distribution tube 47 into the outer tube 51 , and the outside It is converted into reformed gas by the catalyst 53 while exchanging heat while flowing downward in the tube 51 . The converted reformed gas flows into the open lower end of the inner tube 52 accommodated in the outer tube 51, then flows upward and flows into the reformed gas inlet 61, and the outlet pipe 63 and the outlet header 65. and flows out through the reformed gas outlet 67.

The above detailed description is illustrative of the present invention. In addition, the above description shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications are possible within the scope of the concept of the invention disclosed herein, the scope equivalent to the written disclosure, and/or within the scope of skill or knowledge in the art. The written embodiment describes the best state for implementing the technical idea of the present invention, and various changes required in specific application fields and uses of the present invention are possible. Accordingly, the detailed description of the present invention is not intended to limit the present invention to the disclosed embodiments. Also, the appended claims should be construed to include other embodiments.

1: steam hydrocarbon reformer
10: body 11: lower chamber
13: diaphragm 15: upper chamber
20: air supply 21: air inlet
23: air heating tube 25: air outlet
30: combustion unit 31: combustion housing
32: mixing unit 33: fuel gas supply unit
34: first stirring means 35: second stirring means
40: source gas supply unit 41: source gas inlet
43: raw material gas heating tube 431: outer spiral
433: inner helix 435: flow path guide
44: support 45: distribution header
47: distribution pipe 471: first extension
473: bent portion 475: second extension
50: reformed part 51: outer tube
52: inner tube 53: catalyst
54: protective jacket 541: sleeve
543: combustion gas receiving unit 543a: inlet hole
55: heat shear means 56: Euro
57: sensor 60: reformed gas discharge unit
61: reformed gas inlet 63: outlet pipe
65: outflow header 67: reformate gas outlet

Claims (16)

A lower chamber having a first space in which combustion gas is generated through a combustion reaction of fuel gas at the center therein, a first communication hole in an upper portion, a second space in an upper side of the lower chamber, and the first communication in a lower portion An upper chamber having a second communication hole communicating with the hole, at least a portion of which is disposed in the lower chamber and the upper chamber to perform a reforming reaction, and a source gas supply unit for supplying a source gas to the reforming unit,
The combustion gas is introduced into the second space through the first communication hole and the second communication hole, and is discharged through the combustion gas outlet formed in the upper chamber,
The upper chamber is separated so as not to overlap the lower chamber up and down,
The source gas supply unit includes a source gas inlet formed on a side surface of the upper chamber to be connected to the outside, and a source gas heating that is provided so that the source gas flows therein to heat the source gas with combustion gas before the source gas is supplied to the reformer. including a tube,
The source gas heating tube has a spiral shape overlapping in the second space in the upper chamber, and includes an outer spiral and an inner spiral that are connected while communicating with each other. The method according to claim 1, wherein the upper chamber and the lower chamber are vertically separated by a diaphragm, and the diaphragm has at least one opening formed to correspond to the first communication hole and the second communication hole. Steam hydrocarbon reformer with
delete delete delete According to claim 1, wherein the source gas supply unit further comprises a distribution header for distributing the heated source gas to the reforming unit, the source gas inlet is connected to the outer spiral, the inner spiral is connected to communicate with the distribution header to flow in Steam hydrocarbon reformer, characterized in that the raw material gas is heated primarily through the outer spiral and secondarily heated through the inner spiral. According to claim 6, wherein the source gas supply unit further comprises a spiral support for supporting the outer spiral and the inner spiral, characterized in that the outer spiral and the inner spiral are provided to be spaced apart from the inner surface of the upper chamber by the spiral support. steam hydrocarbon reformer. The steam hydrocarbon reformer according to claim 7, wherein the spiral support unit includes an outer support for supporting the outer spiral and an inner support for supporting the inner spiral. The steam hydrocarbon reformer according to claim 8, wherein the outer support and the inner support are formed by walls, and a space is formed between the outer support and the inner support to induce the flow of combustion gas. The steam according to claim 1, wherein a flow path guide is provided inside the upper chamber to guide the flow of combustion gas, and the flow guide guides the flow of combustion gas along the spiral-shaped raw material gas heating tube. hydrocarbon reformer. The steam hydrocarbon reformer according to claim 10, wherein the flow path guide part is coaxially aligned with the upper chamber and has a cylindrical shape with a predetermined height so as to surround the plurality of reforming parts. 12. The method of claim 11, wherein the flow guide portion is spaced apart from the plurality of second communication holes, the first flow guide portion extending upwardly from the lower surface of the upper chamber, and the first passage guide portion spaced apart from the outside of the upper surface of the upper chamber to the lower side A steam hydrocarbon reformer comprising a second flow path guide extending to 13. The air supply unit for supplying air to the first space for a combustion reaction, a combustion unit for burning fuel gas and air to supply heat, and a reforming unit according to any one of claims 1 and 6 to 12. Steam hydrocarbon reformer, characterized in that it further comprises a reformed gas discharge unit for discharging the reformed gas generated through the reaction in. The method according to claim 13, wherein the first communication hole and the second communication hole are coaxially aligned, and the first communication hole and the second communication hole receive the reformed part through and the reformed part is disposed over the first space and the second space. ,
The reforming unit includes an outer tube connected to the source gas supply unit to receive the heated source gas, and an inner tube coaxially aligned with the outer tube in the outer tube, wherein the diameters of the first communication hole and the second communication hole are the outer tube Steam hydrocarbon reformer, characterized in that larger than the diameter of. 15. The steam hydrocarbon reformer according to claim 14, wherein the reformer further comprises a catalyst for performing a reforming reaction on the raw material gas, wherein the catalyst is formed in the outer tube disposed in the first space. The method according to claim 15, wherein the outer tube has an upper side connected to the combustion gas supply unit and a lower side is closed, and the inner tube has an open lower side and an upper side is connected to the reformed gas discharge unit to descend within the outer tube and pass through the catalyst. A steam hydrocarbon reformer, characterized in that the reformed gas rises through the inner tube and is discharged.

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