KR101641766B1 - Compact methanol refomer - Google Patents

Abstract

A compact methanol reformer using methanol as fuel for supplying hydrogen to a fuel cell is disclosed.
The compact methanol reformer according to the present invention comprises: a burner part located at a central portion; A raw material supply unit formed outside the burner unit and supplied with a raw material containing methanol and H ₂ O (1); A preheating unit for vaporizing the supplied raw material; A reforming unit formed at a lower side of the raw material supply unit to reform methanol contained in the vaporized raw material; And a methanation unit formed on the outer side of the raw material supply unit to convert carbon monoxide contained in the reformate exhaust gas into methane gas, wherein the preheating unit forms at least one of the reforming unit and the methanation unit vertically .

Description

[0001] COMPACT METHANOL REFOMER [0002]

The present invention relates to a reformer for supplying hydrogen to a fuel cell, and more particularly, to a methanol reformer for a fuel cell system using methanol as a fuel.

As fossil fuels such as coal and petroleum are gradually depleted, much research has been done to replace fossil fuels.

As part of this research, fuel cells are attracting much attention.

Hydrogen (H ₂ ) is required for driving the fuel cell, and a reformer is required to obtain such hydrogen.

A general reformer is used to convert natural gas to hydrogen, and it is mainly used in large-scale fuel cell systems such as factories and households.

However, in the case of a fuel cell system installed in a vehicle or the like, a small-sized large-sized fuel cell system is not suitable due to a spatial restriction, and accordingly, a small-sized fuel cell system is required.

The background art related to the present invention is Korean Patent Laid-Open Publication No. 10-2007-0099702 (published on October 10, 2007), which discloses a steam reforming fuel treatment apparatus comprising a methanol steam reforming catalyst, A method for generating hydrogen gas is disclosed.

An object of the present invention is to provide a compact methanol reformer for supplying hydrogen to a fuel cell system.

According to an aspect of the present invention, there is provided a compact methanol reformer comprising: a burner unit located at a central portion; A raw material supply unit formed outside the burner unit and supplied with a raw material containing methanol and H ₂ O (1); A preheating unit for vaporizing the supplied raw material; A reforming unit formed at a lower side of the raw material supply unit to reform methanol contained in the vaporized raw material; And a methanation unit formed on the outer side of the raw material supply unit to convert carbon monoxide contained in the reformate exhaust gas into methane gas, wherein the preheating unit forms at least one of the reforming unit and the methanation unit vertically .

The compact methanol reformer may further include a reforming unit and a raw material mixing unit formed outside the methanation unit for mixing the vaporized raw material and supplying the vaporized raw material to the reforming unit.

The preheating unit may be formed to penetrate the methanation unit.

Also, in the reforming section, the methanol reforming reaction by water vapor and the water gas-shift reaction may be performed simultaneously. In this case, it is preferable that the reforming unit includes a Cu-based catalyst.

The methanol reformer according to the present invention is capable of minimizing the temperature difference between the reforming portion and the methanation portion and minimizing the flow path and spacing of the reaction gas and the reforming gas. In particular, by forming the preheating portion into the reforming portion and the methanation portion, The reformer size can be reduced.

In addition, the methanol reformer of the present invention can improve the raw material mixing efficiency and minimize the use of the heat insulating material by applying the external raw material mixing portion.

In addition, the methanol reformer according to the present invention can simultaneously perform the methanol reforming by water vapor and the water gas reaction in the reforming section, thereby simplifying the reforming process and reducing the size of the reformer.

1 schematically shows a compact methanol reformer according to an embodiment of the present invention.
2 is a block diagram of the reforming process in the methanol reformer shown in FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent with reference to the embodiments and drawings described in detail below.

However, it is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. It is intended that the disclosure of the present invention be limited only by the terms of the appended claims.

Hereinafter, a compact methanol reformer according to the present invention will be described in detail with reference to the accompanying drawings.

1 schematically shows a compact methanol reformer according to an embodiment of the present invention. 2 is a block diagram of the reforming process in the compact methanol reformer shown in FIG.

1 and 2, the compact methanol reformer according to the present invention has a substantially cylindrical structure and includes a burner unit 110, a fuel supply unit 120, a preheating unit 130, a reforming unit 150, (160). In addition, the compact methanol reformer according to the present invention may further include a separate fuel mixing unit 140.

The burner unit 110 provides heat necessary for vaporization, reforming reaction, and methanation reaction of the fuel. The burner unit 110 can operate using liquid or gaseous methanol fuel.

In the present invention, the burner unit 110 is formed in the central region of the reformer, and includes a burner 111 and a burner combustion gas moving unit. More specifically, the burner unit 110 has a double pipe structure communicating from the lower side, the burner 111 is located on the upper side of the inner tube, and the burner combustion gas generated by the burner drive moves downward from the inner tube And then moves upward in the outer tube.

The fuel supply unit 120 is supplied with a raw material containing methanol to be reformed and a reactant (H ₂ O (1)) for reforming methanol.

The fuel supply unit 120 is formed outside the burner unit 110 and is supplied into the reformer through heat exchange with the burner combustion gas.

The preheating unit 130 preheats the supplied raw material and vaporizes it. In this case, the preheater 130 of the present invention is formed to pass through at least one of the reforming section 150 and the methanation section 160, and more preferably, as shown in FIG. 1, 160, respectively.

In the present invention, the preheating unit 140 is not formed on the outer side of the reforming unit 150 or the methanation unit 160 but may be formed in a shape that passes through at least one of the reforming unit 150 and the methanation unit 160 The size of the reformer can be reduced.

The reforming unit 140 is formed on the lower outer side of the raw material supply unit 120 to reform methanol contained in the vaporized raw material.

The reforming reaction can be carried out at a temperature of about 200 to 300 ° C and produces hydrogen (H ₂ ) and unavoidable CO as shown in the following formula 1.

???????? Formula 1 ???????? CH ₃ OH (g) + H ₂ O (g)? H ₂ + CO + CO ₂ + CH ₄ + H ₂ O

In the case of Formula 1, the molar number of each component was not considered in the reaction formula when a sufficiently large amount of methanol and water was added.

At this time, as shown in Equation (1), carbon monoxide (CO) is inevitably generated in addition to the desired hydrogen as a result of the reforming reaction. As a result of the reforming reaction, residual H ₂ O also exists. Thus, the reformate exhaust gas comprises H ₂ , CO, and residual H ₂ O.

In the present invention, in addition to the reforming reaction of methanol reforming by steam, the water-gas-shift reaction may be performed simultaneously in the reforming unit as shown in the following Equation 2. Water gas field In this reaction, part of carbon monoxide (CO) which is inevitably generated by the reforming reaction can be removed.

Equation 2: CO + H ₂ O? CO ₂ + H ₂

In order to perform the reaction with the reforming reaction and the aqueous gas field reaction in the reforming part, a catalyst suitable for both of the two reactions is required, and a Cu-based catalyst can be presented with such a catalyst. As the Cu-based catalyst, for example, a catalyst in which Cu is mixed in an Al ₂ O ₃ carrier may be used.

The methanation portion 160 is formed on the upper side of the raw material supply portion 120, that is, on the reforming portion 150. In the methanation unit 160, the carbon monoxide contained in the reformed gas is converted into methane gas as shown in the following Equation 3 to suppress the carbon monoxide content in the final reformed gas to the maximum. The methanation unit 160 may be a nickel-based catalyst, but is not limited thereto.

Equation 3: CO + 3H _{2 -} > CH ₄ + H ₂ O

The methanation reaction may be carried out at about 200-250 < 0 > C. This reaction temperature is not significantly different from the above-mentioned reforming reaction temperature. Therefore, the flow path and space between the reforming section 150 and the methanation section 160 can be reduced.

In addition, since this methanation reaction does not require supplying water or oxygen for CO removal, it can contribute to the compactness of the reformer.

On the other hand, the methanol compact reformer according to the present invention includes methanol and water as liquid raw materials. The reforming efficiency is the highest when the methanol and water are supplied to the reforming unit in a state where they are mixed as uniformly as possible. Accordingly, the present invention may further include a raw material mixing unit for mixing the vaporized fuel.

The raw material mixing section 140 is formed outside the reforming section 150 and the methanation section 160. Particularly, it is preferable that the raw material mixing portion 140 is formed to be spaced apart from the reforming portion 150 and the methanation portion 160. In this case, there is an advantage that it is not necessary to use a separate heat insulating material between the reforming portion and the raw material mixing portion.

The methanol reforming method in the compact methanol reformer shown in FIG. 1 is as follows.

First, the reforming unit 150 and the methanating unit 160 are heated using the heat generated from the fuel combustion in the burner unit 110 to activate the catalyst contained in the reforming unit 150 and the methanating unit 160 .

Thereafter, a raw material including methanol and water is supplied through the raw material supply unit 120. In this process, the temperature of the raw material is gradually increased.

Thereafter, the raw material supplied from the preheating unit 130 is vaporized, and the vaporized raw material is supplied to the reforming unit 150. In this process, a process in which the vaporized raw material is uniformly mixed in the raw material mixing section 140 can be further performed.

Thereafter, the raw material is supplied to the reforming unit 150 to carry out a reforming reaction, or a reforming reaction and a water gas field reaction are performed. Then, the exhaust gas from the reforming unit 150 is supplied to the methanation unit 160 to perform the methanation reaction, and the reformed gas containing hydrogen (H ₂ ) is finally discharged.

The compact methanol reformer according to the present invention has the following effects.

First, the reforming reaction and the methanation reaction having a small temperature difference are successively performed, thereby minimizing the flow path and the interval between the reforming portion and the methanation portion.

Further, when a copper-based catalyst is used, not only a reforming reaction but also a water gas field reaction can be performed simultaneously in the reforming section, thereby simplifying the reforming process.

Further, by removing CO through the methanation reaction, no additional water or air supply is required for CO removal.

Also, the mixing effect of the raw material can be enhanced through the external raw material mixing portion, and the use of the heat insulating material can be minimized.

As described above, the fuel conversion device according to the present invention can form all the elements required for fuel conversion in one cylinder, and also has a compact structure as a whole because the temperature difference between the reforming portion and the CO remover is small And is suitable for application to fuel cell systems such as construction machinery and agricultural machinery.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

110: burner part 120: raw material supply part
130: preheating part 140: raw material mixing part
150: reforming unit 160: methanation unit

Claims (5)

delete A burner portion located at a central portion;
A raw material supply unit formed outside the burner unit and supplied with a raw material containing methanol and H ₂ O (1);
A preheating unit for vaporizing the supplied raw material;
A reforming unit formed at a lower side of the raw material supply unit to reform methanol contained in the vaporized raw material; And
And a methanation unit formed on the outer side of the raw material supply unit to convert carbon monoxide contained in the reformed gas exhaust gas into methane gas,
Wherein the preheating portion is formed to penetrate through the methanation portion,
And a raw material mixing part formed outside the reforming part and the methanation part and spaced apart from the reforming part and the methanation part and mixing the vaporized raw material to supply the reformed part to the reforming part.
delete 3. The method of claim 2,
Wherein the methanol reforming reaction by water vapor and the water gas-shift reaction are simultaneously performed in the reforming section.
5. The method of claim 4,
Wherein the reforming unit includes a Cu-based catalyst.

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