KR20180123065A - Fuel gas supply device and fuel gas supply method - Google Patents

Abstract

In order to provide a technique for reforming the heavy hydrocarbon gas and supplying the fuel gas containing methane gas at a high concentration, the desulfurized heavy hydrocarbon gas is reformed by steam reforming by the reforming catalyst to methane A reforming device (10) having a gas generating part (11) for generating a methane - containing mixed gas by performing a reaction and a re - synthesizing part (12) for re - synthesizing methane from carbon monoxide and hydrogen contained in the mixed gas by a catalyst A supply path L1 for supplying heavy hydrocarbon gas to the reforming apparatus 10 through the desulfurizer 20 and a supply line L1 for supplying the mixed gas from the gas generator 11 in the re- A heat exchange unit for performing heat exchange with the heavy hydrocarbon gas before desulfurization that passes through the gas supply unit L1 and a recycle unit for returning part of the mixed gas generated by the gas generation unit 11 to the supply path L1 (L4) And a fuel gas supply passage L5 for supplying the fuel gas discharged from the re-synthesis section 12 to the combustion device (gas engine GE).

Description

Fuel gas supply device and fuel gas supply method

The present invention relates to a fuel gas supply device and a fuel gas supply method for supplying a fuel gas containing methane as a main component obtained by modifying a heavy hydrocarbon gas to a combustion device such as a gas engine or a gas turbine will be.

BACKGROUND ART Conventionally, there has been known a fuel gas supply apparatus which reforms heavy hydrocarbon gas such as propane or butane by a reforming catalyst to obtain a fuel gas containing methane as a main component and supplies the fuel gas to a combustion apparatus. In such a fuel gas supply device, a mixed gas of heavy hydrocarbon gas and water vapor is supplied to the reforming device in the heavy hydrocarbon gas supply passage, the supplied mixed gas is reformed by the reforming catalyst filled in the reforming device, (Refer to, for example, Patent Document 1).

U.S. Patent No. 7866161

Here, the generated fuel gas contains methane as a main component, but since the following reforming reaction itself is an equilibrium reaction, it is difficult to avoid a certain degree of heavy hydrocarbon gas mixing into the fuel gas. When the heavy hydrocarbon gas is mixed with the fuel gas, the gas engine tends to cause knocking, so it is desirable to minimize the amount of the heavy hydrocarbon gas to be mixed as much as possible. In addition, it is preferable to minimize the amount of hydrogen and carbon monoxide contained in the generated gas in order to stabilize the calorific value of the produced fuel gas. In addition, even in a normal combustion device such as a gas turbine, fluctuation of the fuel composition causes lift and backfire, so it can be said that it is preferable to minimize the amount of the heavy hydrocarbon gas to be mixed. For this reason, according to Patent Document 1, it is proposed to preheat the heavy hydrocarbon gas supplied to the reforming apparatus by the heat possessed by the generated fuel gas, thereby suppressing generation of hydrogen or carbon monoxide by cracking while increasing the methanation efficiency .

Modification reaction:

C ₃ H ₈ + H ₂ O → 2CH ₄ + CO + H ₂ ... ... ... (One)

_{CO + 3H 2 → CH 4 +} H 2 O ... ... ... (2)

However, in the above-described reaction (2), since the equilibrium reaction proceeds in the right direction at a temperature lower than that of the reaction (1), according to the conventional reforming apparatus, at a predetermined equilibrium temperature at which hydrogen or carbon monoxide is small and methane is increased The hydrogen content can be lowered. However, in this case, since the reaction of the decomposition reaction itself of the heavy hydrocarbon gas of (1) is also suppressed, improvement in the methanation efficiency and the like due to temperature control is also limited, and a fuel gas with a higher methane concentration Is desired.

In addition, the heavy hydrocarbon gas as the raw material gas often contains impurities such as sulfur components. If the reforming catalyst is poisoned by such an impurity, the efficiency of the reforming reaction is lowered, but the lifetime is shortened. Therefore, a technique for supplying a fuel gas having a high methane concentration, including the removal of impurities, is desired.

Accordingly, an object of the present invention is to provide a technique for reforming a heavy hydrocarbon gas to supply a fuel gas containing methane gas at a high concentration.

In order to achieve the above-mentioned object, a characteristic configuration of a fuel gas supply apparatus of the present invention is characterized in that,

A fuel gas supply device for supplying a fuel gas containing methane as a main component obtained by modifying a heavy hydrocarbon gas to a combustion device,

A desulfurizer for desulfurizing heavy hydrocarbon gas,

A gas generator for generating a methane-containing mixed gas by subjecting the desulfurized heavy hydrocarbon gas to a steam reforming with a reforming catalyst and decomposing the heavy hydrocarbon gas into methane; and a gas generator for generating carbon monoxide and hydrogen And a re-synthesis unit for re-synthesizing methane by a catalyst from the reforming unit,

The reforming apparatus is provided with a heavy hydrocarbon gas supply line for supplying heavy hydrocarbon gas through the desulfurizer,

A heat exchange unit for performing heat exchange with the mixed gas supplied from the gas generating unit and the heavy hydrocarbon gas before the desulfurization in the desulfurizing unit, the heat exchange unit communicating with the heavy hydrocarbon gas supply path,

A recycle path for returning a part of the mixed gas generated by the gas generating section to the heavy hydrocarbon gas supply path,

And a fuel gas supply passage for supplying the fuel gas discharged from the re-

.

The heavy hydrocarbon gas in the present invention refers to gaseous hydrocarbons having a larger molecular weight than methane, and includes ethane, propane, butane, and isobutane. In the case of the main component, it refers to a component having a larger content among the main effective components. It does not need to contain more than 50%, and it is not necessarily the largest component as the content. However, it is more preferable that the content of the main component is more than 50%, and when the content is not more than 50%, it is preferable that the content is the largest.

According to the above arrangement, since the reforming apparatus is provided with the gas generating section and the re-synthesis section, the reaction of decomposing and decomposing the heavy hydrocarbon gas as the raw material gas in the gas generating section is positively promoted, In the re-synthesis section, methane can be re-synthesized from carbon monoxide and hydrogen contained in the mixed gas generated based on the decomposition reaction.

Specifically, by actively promoting the decomposition of the heavy hydrocarbon gas during the above-described reforming reaction in the gas generating section, the concentration of the heavy hydrocarbon gas in the generated gas can be greatly lowered. At this time, the generated gas reaches a high temperature by the heat of reaction, and the concentration of hydrogen and carbon monoxide contained in the produced gas becomes somewhat higher. Since the hydrogen and carbon monoxide generated here are supplied to the reaction for re-synthesizing methane in the re-synthesis section, the concentration of hydrogen and carbon monoxide contained in the gas mixture is lowered and the methane gas concentration is increased. Can be obtained.

That is, the decomposition reaction of the heavy hydrocarbon (the above-mentioned reforming reaction (1)) proceeds and the hydrogen produced by the re-synthesis unit and the carbon monoxide (The above-mentioned reforming reaction (2)) to obtain more methane, each of the reaction conditions can be easily optimized, and the methane concentration can be increased more efficiently.

Here, it is preferable that the heavy hydrocarbon gas supplied to the reforming apparatus is preheated in order to perform the subsequent reaction at a high temperature. Further, the reaction in the gas generating section is performed at a higher temperature than the reaction in the re-synthesis section. In order to achieve the above object, the present invention provides a desulfurization apparatus for desulfurizing heavy hydrocarbon gas to be supplied to a gas generator, a heavy hydrocarbon gas supply line for supplying desulfurized heavy hydrocarbons to the reformer, And the heat exchanging unit for performing heat exchange between the mixed gas supplied from the reforming unit and the heavy hydrocarbon gas supplied from the heavy hydrocarbon gas supply path is provided in the desulfurizer supplied to the reforming apparatus, And the mixed gas of the re-synthesized portion is adjusted to a temperature suitable for re-synthesis by radiating heat to the heavy hydrocarbon gas. This makes it possible to easily realize a temperature condition in which the reforming reaction proceeds with good efficiency.

Further, the mixed gas supplied to the re-synthesis section through the decomposition reaction in the gas generation section has a high hydrogen concentration. On the other hand, the sulfur component contained in the heavy hydrocarbon gas is removed in the desulfurizer. Here, by providing a recycle furnace for transferring a part of the mixed gas produced in the gas generating section to the heavy hydrocarbon gas supplying furnace, the mixed gas produced in the gas generating section is supplied to the heavy hydrocarbon gas supplied to the desulfurizing device . As a result, the hydrogen gas necessary for reducing and removing the sulfur component in the desulfurizer can be procured from the reformer without being supplied from the outside. Thus, even if the desulfurizer is provided, the hydrogen gas is supplied from the reformer The present invention can be carried out with a simple configuration. Further, even if a reforming catalyst which is easy to poison the decomposition reaction or the reforming reaction performed in the reforming apparatus is used, the desulfurization apparatus can be used for a long period of time with high activity.

The fuel gas obtained by the re-synthesis unit is in a state in which the optimum reforming reaction has been completed in the state where the heat exchange is completed, and the conventional example in which the heat exchange between the fuel gas and the heavy hydrocarbon gas is performed after the reforming reaction Compared with the example of Document 1), it is possible to efficiently provide the excess heat to the preheating of the heavy hydrocarbon gas when the mixed gas is re-synthesized to be the product gas.

The fuel gas thus obtained contains methane gas of high concentration and is supplied to the combustion apparatus from the fuel gas supply.

More specifically, the above-described configuration can be realized as follows.

In other words,

Wherein the reforming device is integrally formed with the gas generating portion at the upper portion and the re-synthesizing portion at the lower portion,

Wherein the gas generator comprises an adiabatic reaction vessel for receiving a desulfurized heavy hydrocarbon gas in the desulfurizer and performing a reforming reaction by a reforming catalyst,

Wherein the recomposing portion includes a tubular reaction portion which communicates the inside of the adiabatic reaction container and the fuel gas supply passage and has a catalyst therein, and a heat exchange container formed by surrounding the tubular reaction portion, And the intermediate gas stream passing through the heavy hydrocarbon gas feed passage which is a space between the tubular reacting section and the heat exchange container performs heat exchange with the mixed gas passing through the tubular reaction section have.

According to the above-described constitution, the decomposition reaction for decomposing the heavy hydrocarbon gas into the methane by reforming the steam by the reforming catalyst is carried out in the adiabatic reaction vessel between the gas generating section and the re-synthesis section in the reforming apparatus, Hydrogen or carbon monoxide in the generated mixed gas may be re-synthesized in the re-synthesis unit to produce methane, and the concentration of hydrogen or carbon monoxide contained in the fuel gas may be lowered. At this time, the re-synthesis section includes a tubular reaction section and a heat exchange container. The re-synthesis section has a tubular reaction section and a heat exchange container. The re-synthesis section includes a gas- The reforming reaction conditions such as the composition, temperature, and pressure of the supplied heavy hydrocarbon gas, the resulting mixed gas and the discharged fuel gas can be easily made efficient, and the tubular reaction part in the re- And the composition of the mixed gas to be supplied to the recycle furnace can be made suitable for the desulfurization reaction in the desulfurizer, it is possible to reduce the amount of the mixed gas and the heavy hydrocarbons in the combustion apparatus It is possible to easily optimize the supplied fuel gas so as to contain the methane gas at a high concentration more efficiently.

The tubular reaction section communicates the inside of the adiabatic reaction vessel with the fuel gas supply path in the vertical direction and the mixed gas flowing in the tubular reaction section flows downward in the heat exchange section, The heavy hydrocarbon gas flowing in the heavy hydrocarbon gas supply path, which is a space between the reaction part and the heat exchange container, flows upward and heat exchange is performed in a state of being countercurrent.

According to the above-described configuration, heat exchange is performed in a state in which the mixed gas passing through the tubular reaction section and the heavy hydrocarbon gas are in countercurrent flow, thereby achieving heat exchange with good efficiency.

The recycle furnace may be configured such that one end thereof is connected to the lower end of the gas generating section and the other end thereof is connected to the upstream side of the reforming apparatus in the heavy hydrocarbon gas feed line.

According to the above-described structure, since the mixed gas generated in the gas generating section is conveyed to the upstream side of the reforming apparatus, after the mixing of the mixed gas and the heavy hydrocarbon gas is sufficiently performed, the mixed gas and the heavy carbonization Hydrogen gas can be supplied.

It is also possible to provide a preheating unit for preheating the heavy hydrocarbon gas before being supplied to the reforming apparatus by the exhaust gas of the combustion apparatus in the heavy hydrocarbon gas supply path.

In a combustion device, power is obtained by the obtained fuel gas, and an arrangement (exhaust heat) is generated. If the preheating portion is provided, this arrangement can be efficiently used to preheat the heavy hydrocarbon gas before being supplied to the reforming device, to perform the reforming reaction with higher reaction efficiency, and to provide the fuel Gas supply device.

The fuel gas supply method of the present invention for achieving the above-

A fuel gas supply method for supplying a fuel gas containing methane as a main component obtained by modifying a heavy hydrocarbon gas to a combustion device,

In the fuel gas supply device, a heavy hydrocarbon gas having an S / C (steam / charcoal consumption) value of not less than 0.4 and not more than 1.0 and not less than 300 ° C and not more than 450 ° C is supplied to the gas generator, A mixed gas of more than 450 DEG C and not more than 520 DEG C is obtained and a fuel gas of not less than 250 DEG C and not more than 300 DEG C is obtained in the re-synthesis section.

In the gas generating section, the S / C value is 0.4 to 1.0, and the reforming reaction (1) proceeds at 300 ° C to 450 ° C to generate heat. As a result, the obtained mixed gas contains about 10% of hydrogen in a state where it exceeds 450 DEG C and reaches 520 DEG C or less. If the S / C value is too low, the carbon becomes liable to precipitate on the basis of the thermal decomposition of the raw material gas. Therefore, the S / C value is more preferably 0.7 or more. If the S / C value is too high, the methane concentration in the reformed gas is lowered, It is preferable to be 1.0 or less. More preferably, it is 0.8 or more and 0.9 or less. Therefore, the mixed gas obtained here can be used as a desulfurization gas for sulfur component reduction of the desulfurizer, and the desulfurization reaction can be performed efficiently. Further, the obtained mixed gas can be supplied to the reaction (2) of the reforming reaction in the re-synthesis section. In the re-synthesis section, the hydrogen contained in the mixed gas is reacted with carbon monoxide or carbon dioxide, and the methane gas is re-synthesized, so that it can be converted into a high-quality fuel gas having a high methane concentration and a low hydrogen concentration.

Therefore, the heavy hydrocarbon gas can be reformed to supply fuel gas containing methane gas at a high concentration.

1 is a flow sheet of a fuel gas supply device.
2 is a flow sheet of the fuel gas supply apparatus described in another embodiment.

Hereinafter, a fuel gas supply apparatus according to an embodiment of the present invention will be described. While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention. The present invention is not limited to the following description.

[Fuel gas supply device]

As shown in Fig. 1, the fuel gas supply apparatus is an example of a combustion apparatus, in which the gas engine GE is supplied with fuel gas containing methane as a main component obtained by modifying heavy hydrocarbon gas, A re-synthesis section (12) for re-synthesizing methane from carbon monoxide and hydrogen contained in a mixed gas generated based on the decomposition reaction, And a reforming apparatus (10) provided with the reforming apparatus. The desulfurizer 20 for desulfurizing the heavy hydrocarbon gas supplied to the gas generator 11 of the reforming apparatus 10 is also provided.

The fuel gas supply device includes a reforming apparatus 10 for supplying reforming gas to the reforming apparatus 10 through a desulfurizing unit 20 and a reforming unit 12 for reforming the reformed gas A heat exchange unit for performing heat exchange with the mixed gas supplied from the generation unit 11 and the heavy hydrocarbon gas before the desulfurization in the desulfurization unit 20 that flows through the heavy hydrocarbon gas supply path L1, A recycle furnace L4 for transporting a part of the mixed gas produced in the reforming section 11 to the heavy hydrocarbon gas feed line L1 and a fuel gas And a supply path L5. The fuel gas supply line L5 is provided with a cooling unit 40 for cooling the fuel gas discharged from the re-synthesis unit 12 to remove condensed water.

[Modification device]

The reforming apparatus 10 is integrally formed in a state that the gas generating section 11 is provided on the upper part and the re-synthesizing section 12 is provided on the lower part.

The gas generating section 11 is provided with an adiabatic reaction container 11A for receiving the desulfurized heavy hydrocarbon gas in the desulfurizer 20 and performing a reforming reaction by the reforming catalyst. That is, the interior of the adiabatic reaction vessel 11A is filled with a reforming catalyst, and is controlled at a predetermined temperature and pressure. The liquefied petroleum gas (main component propane, hereinafter referred to as LPG) It is possible to generate a mixed gas containing methane as a main component.

The heavy hydrocarbon gas supply line L1 is connected to the upstream end portion 10a (upper portion) of the adiabatic reaction vessel 11A of the gas generating portion 11 and water vapor is added as described later And the desulfurized heavy hydrocarbon gas in the desulfurizer 20 is supplied from the upstream end 10a (upper portion) of the adiabatic reaction vessel 11A to the adiabatic reaction vessel 11A through the heavy hydrocarbon gas feed line L1 .

As the reforming catalyst, for example, a nickel-based or noble metal-based low temperature steam reforming catalyst can be used. Specifically, for example, palladium, silver, nickel, cobalt And a film of one kind of metal selected from the group of copper are preferably used.

A part of the mixed gas generated in the gas generating section 11 is extracted from the side in the vicinity of the downstream end 10b of the gas generating section 11 and the mixed gas And a recycle line L4 for guiding to the additive section 30 are connected. That is, the recycling furnace L4 is connected at one end to the downstream end 10b (lower end) of the gas generating section 11 and at the other end to the reforming apparatus 10 in the heavy hydrocarbon gas feed line L1, (Between the water vapor supply part 50 and the preheating part 60, which will be described later).

The mixed gas obtained in the gas generating section 11 is guided to the re-synthesizing section 12 formed in the lower part of the gas generating section 11 in the reforming apparatus 10. [

The re-synthesizing section 12 includes a plurality of tubular reacting sections 11a communicating the inside of the adiabatic reaction container 11A and the fuel gas supplying path L5 in the vertical direction and having a catalyst charging section therein, And a heat exchange container 11b formed to surround the heat exchanger 11a. Therefore, the mixed gas formed in the gas generating section 11 flows downward through the plurality of tubular reacting sections 11a from the inside of the adiabatic reaction vessel 11A, is collected at the lower end of the heat exchange vessel 11b And is discharged to the fuel gas supply path L5 through the most downstream end portion 10c formed at the lower end of the heat exchange container 11b.

In the re-synthesis section 12, a space is formed between the tubular reaction section 11a and the heat exchange container 11b. Also, spaces are formed between adjacent tubular reacting portions 11a. These spaces are configured to communicate with each other in the heat exchange container 11b. That is, these spaces are formed in the region from the substantially lower end portion to the upper end portion in the heat exchange container 11b in the state of pivoting around each tubular reaction portion 11a in the re-synthesis portion 12. [ These spaces are configured so as not to communicate with the inside of the adiabatic reaction vessel 11A.

The heat exchange vessel 11b receives the heavy hydrocarbon gas (containing steam) before the desulfurization in the desulfurizer 20 through the heavy hydrocarbon gas feed line L1 from the lower side of the heat exchange vessel 11b And flows upward from the lower end portion of the space to the upper end portion and is discharged from the side upper end portion of the heat exchange container 11b to the heavy hydrocarbon gas supply path L1 to be supplied to the desulfurization device 20. [

As a result, heat exchange is performed in a state in which a relatively high temperature mixed gas flowing downward through the tubular reaction section 11a and a relatively low-temperature heavy hydrocarbon gas flowing upward in the space are countercurrent . That is, the space functions as a heat exchange path L2. Considering the function of the heavy hydrocarbon gas supplying path L1 for supplying the heavy hydrocarbon gas to the reforming apparatus 10, the heat exchanging path L2 is part of the heavy hydrocarbon gas supplying path L1 Function.

Therefore, the heat exchanger is provided with a mixed gas passing through the tubular reacting section 11a and a heavy carbonization gas passing through the heavy hydrocarbon gas feed line L1, which is a space between the tubular reacting section 11a and the heat exchange container 11b The hydrogen gas is subjected to heat exchange. That is, the heat exchange container 11b functions as a heat exchange portion.

A nickel-based or noble metal-based low-temperature steam reforming catalyst is filled in the catalyst-packed portion of the re-synthesizing portion 12. Specifically, for example, the surface of the non-conductive porous body having micropores , Palladium, silver, nickel, cobalt, and copper.

On the upstream side of the reforming apparatus 10 in the heavy hydrocarbon gas supply line L1 is provided a preheating unit 60 for preheating the heavy hydrocarbon gas from the upstream side by the high temperature exhaust gas from the gas engine GE A mixed gas adding section 30 for adding a recycle gas as a recycle gas from the recycle furnace L4 and a mixed gas adding section 30 for adding steam to the heavy hydrocarbon gas obtained by mixing the recycle gas transferred to the recycle furnace L4 And a water vapor supply part 50 for mixing.

[Desulfurization Apparatus]

The heavy hydrocarbon gas containing water vapor discharged from the upper end side of the heat exchange path L2 in the re-synthesis section 12 of the reforming apparatus 10 can be passed through the desulfurization apparatus 20. The heavy hydrocarbon gas feed path L1 from the heat exchange path L2 to the entry into the desulfurizer 20 may be referred to as the off-flow path L3. The desulfurization apparatus 20 comprises a desulfurization reaction vessel filled with a desulfurization catalyst, and the desulfurization reactor L3 is connected to the upper part of the desulfurization apparatus 20. [ As the desulfurization catalyst, for example, a combination of a nickel-molybdenum-based or cobalt molybdenum-based catalyst and zinc oxide is preferably used which can reduce a mercaptan compound to hydrogen sulfide and adsorb and remove it. The heavy hydrocarbon gas containing water vapor via the desulfurizer 20 is introduced into the gas generator 11 through the heavy hydrocarbon gas feed line L1.

The heavy hydrocarbon gas is preheated by the high temperature exhaust gas from the gas engine GE in the preheating section 60 and the recycle gas and the steam are added The heat exchange passage L2 in the re-synthesis section 12 flows upward from the lower end side toward the upper end side. At this time, the heavy hydrocarbon gas passing through the heat exchange path L2 is received in the tubular reaction section 11a and is discharged from the upper part of the re-synthesis section 12 to the desulfurization path L3 in the preheated state. After the desulfurization in the desulfurizer 20, the gas is introduced into the gas generator 11 from the upstream end (the upstream end 10a) of the gas generator 11 of the reformer 10.

Thus, by actively promoting the decomposition of the heavy hydrocarbon gas during the reforming reaction in the gas generating section, the concentration of the heavy hydrocarbon gas in the produced gas can be greatly lowered. At this time, the produced gas reaches a high temperature (for example, more than 450 ° C and less than 520 ° C) due to the heat of reaction, and the concentration of hydrogen and carbon monoxide contained in the produced gas becomes somewhat higher.

The mixed gas flowing into the gas generating section 11 of the reforming apparatus 10 and decomposed by the heavy hydrocarbon gas is introduced into the respective tubular reaction sections 11a of the re-synthesis section 12 from the upper end side to the lower end side In the downward direction. At this time, the mixed gas flowing through the heat exchange path (L2) provides heat to the relatively low-temperature heavy hydrocarbon gas flowing through the heat exchange path (L2), and is cooled by itself. Then, the carbon monoxide and hydrogen contained in the mixed gas proceed to the re-synthesis of methane by the catalyst in the tubular reaction unit 11a. Thereafter, the re-synthesis of methane proceeds, the mixed gas becomes a fuel gas, is discharged from the re-synthesis section 12 to the fuel gas supply path L5, cooled in the cooling section 40, .

As a result, hydrogen and carbon monoxide generated in the gas generating section 11 are supplied to the reaction for re-synthesizing methane in the re-synthesizing section 12, so that the concentration of hydrogen and carbon monoxide contained in the gas mixture is lowered, The fuel gas having a high methane concentration can be obtained.

In other words, the decomposition reaction of the heavy hydrocarbon (the above-described reforming reaction (1)) proceeds and the re-synthesis section 12 performs decomposition reaction of the heavy hydrocarbons by performing the decomposition reaction actively in the gas generation section 11, (The above-described reforming reaction (2)) with hydrogen and carbon monoxide generated in the reforming reaction, and further methane is obtained. Therefore, the respective reaction conditions can be easily optimized and the methane concentration can be increased more efficiently.

Therefore, the reforming reaction conditions such as the composition, temperature, and pressure of the supplied heavy hydrocarbon gas, the produced mixed gas and the discharged fuel gas can be easily made efficient, and the tubular reaction part The mixed gas and the heavy hydrocarbon gas can be efficiently heated and stored between the heat exchange paths 11a and 11a and the composition of the mixed gas supplied to the recycle line L4 can be made suitable for the desulfurization reaction in the desulfurization device 20. [ The fuel gas supplied to the combustion device can be easily optimized so as to contain the methane gas at a high concentration more efficiently.

[Fuel gas supply method]

In the fuel gas supply device having the above-described configuration, the heavy hydrocarbon gas passed through the heat exchange path (L2) and the desulfurization furnace (L3) is supplied to the gas generating section 11 at an S / C (steam / And is supplied at 300 ° C or more and 450 ° C or less. Thus, in the gas generating section 11, the reforming reaction by the reforming catalyst proceeds, and a mixed gas of more than 450 DEG C and 520 DEG C or less can be obtained. The composition of this mixed gas is mainly composed of methane containing no heavy hydrocarbon gas and contains about 10% of hydrogen. A part of this mixed gas is guided to the recycle furnace L4 and is used for the desulfurization reaction and the remainder is re-synthesized at 250 to 300 deg. C in the re-synthesis section 12 to produce methane as a main component Gas can be obtained.

[Example]

The composition of the mixed gas obtained at the end (lower end) of the gas generating section 11 was investigated by supplying a raw material gas (LPG + H2O + H2) of 0.90 MPaG at 370 캜 to the gas generating section 11 of the reforming apparatus 10 The compositions after cooling the recycle gas and removing the condensed water (shown in parentheses in the table) were also examined. Further, the recycle gas was circulated in the re-synthesis section 12, and the composition of the fuel gas obtained at the end of the re-synthesis section 12 was examined.

As a result, the composition of each gas was as shown in Table 1.

Here, in the reforming apparatus 10, a noble metal catalyst such as nickel or ruthenium is supported on a support such as alumina to the gas generating portion 11 having an inner diameter of about 440 mm and an overall length of about 1500 mm The raw material gas is circulated at 9.5 Nm < 3 > / min. The obtained mixed gas was divided into 140 tubular reacting units filled with catalysts having the above-mentioned inner diameters of about 20 mm and an electric length of about 600 mm, and flowed into the heat exchanging unit (L2). Cooling gas (low-temperature heavy carbonization Hydrogen gas), the reaction is carried out in a state where the outlet of the re-synthesis section 12 is maintained at 278 占 폚.

[Table 1]

[0049]

Table 1 shows that the fuel gas supply apparatus can efficiently reform the heavy hydrocarbon gas such as LPG, and can easily produce the high-quality fuel gas containing almost no LPG component or hydrogen.

[0050]

[Other Embodiments]

As shown in Fig. 2, when the heat of reaction is high in the re-synthesis reaction and the heat remains in the re-synthesis section 12, a waste heat recovery type heat exchange section is provided on the downstream side (lower side) So that the outlet temperature of the re-synthesizing unit 12 of the mixed gas can be preferably maintained, and the heat utilization efficiency can be further increased. In this case, the heavy hydrocarbon gas supply line L1 is connected to the side of the lower end side of the re-synthesis unit 12, and the heat exchange path L2 is not disposed in the waste heat recovery type heat exchange unit .

[0051]

The amount of water vapor supplied from the water vapor supply part 50 is adjusted so that the supply amount is controlled in accordance with the composition of the heavy hydrocarbon gas supplied to the heavy hydrocarbon gas supply path L1 and the S / C ratio is adjusted to an appropriate value. Specifically, a calorimeter (manufactured by Ajvil), which functions as a principle for estimating the gas composition based on the thermal conductivity of the supplied gas, is used to control the amount of water vapor supplied from the water vapor supply unit 50 corresponding to the output Can be installed and configured.

[0052]

The size and shape of the fuel gas supply device are not limited to those shown in the drawings or the specific dimensions, and the catalyst to be used is not limited to the illustrated ones. Operating conditions such as the temperature and the pressure of the fuel gas supply device are also variously changed depending on the size, shape, catalyst, etc. of the fuel gas supply device. Therefore, the present invention is not limited to the above description.

[Industrial applicability]

[0053]

INDUSTRIAL APPLICABILITY The present invention can be used, for example, as a fuel gas supply device for a combustion device mounted on a ship and having various power outputs.

10: reforming device
11:
11a: tubular reaction part
11b: heat exchange container
11A: Adiabatic reaction vessel
12: Re-synthesis section (heat exchange section)
20: Desulfurization device
60: preheating part
GE: Gas engine
L1: Heavy hydrocarbon gas supply line
L2: heat exchanger
L3: Desulfurization furnace
L4: By recycling

Claims (6)

A fuel gas supply device for supplying a fuel gas containing methane as a main component obtained by reforming a heavy hydrocarbon gas to a combustion device,
A desulfurizer for desulfurizing heavy hydrocarbon gas;
A gas generator for generating a methane-containing mixed gas by subjecting the desulfurized heavy hydrocarbon gas to a steam reforming with a reforming catalyst and decomposing the heavy hydrocarbon gas into methane; and a gas generator for generating carbon monoxide and hydrogen And a re-synthesis section for re-synthesizing methane by the catalyst from the reforming section;
A heavy hydrocarbon gas supply line for supplying heavy hydrocarbon gas to the reforming apparatus through the desulfurization unit;
And a heat exchange unit for performing heat exchange between the mixed gas supplied from the gas generating unit and the heavy hydrocarbon gas before being desulfurized in the desulfurizer, through which the heavy hydrocarbon gas supply passage is communicated, ;
A recycle path for returning a part of the mixed gas generated by the gas generating section to the heavy hydrocarbon gas supply path; And
And a fuel gas supply path for supplying the fuel gas discharged from the re-
And a fuel gas supply device. The method according to claim 1,
Wherein the reforming device is integrally formed in a state that the gas generating portion is provided at the upper portion and the re-synthesizing portion is provided at the lower portion,
Wherein the gas generator comprises an adiabatic reaction vessel for receiving a desulfurized heavy hydrocarbon gas in the desulfurizer and performing a reforming reaction by a reforming catalyst,
Wherein the recomposing portion includes a tubular reaction portion which communicates the inside of the adiabatic reaction container and the fuel gas supply passage and has a catalyst therein, and a heat exchange container formed by surrounding the tubular reaction portion, Wherein the mixed gas passing through the tubular reaction section and the heavy hydrocarbon gas passing through the heavy hydrocarbon gas feed passage which is a space between the tubular reaction section and the heat exchange container are subjected to heat exchange, Gas supply. 3. The method of claim 2,
The tubular reaction section communicates the inside of the adiabatic reaction vessel with the fuel gas supply path in the up-and-down direction, and in the heat exchange section, the gas mixture flowing in the tubular reaction section flows downward, Wherein the heavy hydrocarbon gas flowing through the heavy hydrocarbon gas supply path, which is a space between the fuel cell stack and the heat exchange container, flows upwardly and performs heat exchange in a countercurrent state. 4. The method according to any one of claims 1 to 3,
Wherein the recycle furnace has one end connected to the lower end of the gas generating section and the other end connected to the upstream side of the reforming apparatus in the heavy hydrocarbon gas supply path. 5. The method according to any one of claims 1 to 4,
And a preheating unit for preheating the heavy hydrocarbon gas before being supplied to the reforming apparatus by the exhaust gas of the combustion apparatus in the heavy hydrocarbon gas supply path. A fuel gas supply method for supplying a fuel gas containing methane as a main component obtained by modifying a heavy hydrocarbon gas to a combustion device,
6. The fuel gas supply device according to any one of claims 1 to 5, wherein a heavy hydrocarbon gas having an S / C (steam / carbon consumption) value of 0.4 to 1.0 and a temperature of 300 to 450 DEG C is supplied to the gas Wherein the gas mixture is supplied to the production section to obtain a mixed gas having a temperature higher than 450 DEG C and lower than 520 DEG C in the gas generating section and a fuel gas having a temperature not less than 250 DEG C and not higher than 300 DEG C,
Fuel gas supply method.

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