KR20130071618A - Method and apparatus for synthesizing methane from syngas - Google Patents

Abstract

PURPOSE: A manufacturing method of methane from synthetic gas is provided to minimize equipment cost due to process simplification, thereby effectively manufacturing methane by an insulative reactor. CONSTITUTION: A manufacturing method of methane comprises a step of forming a mixed gas by adding steam into a synthetic gas including carbon monoxide and hydrogen as main ingredients; a step of supplying the mixed gas to an isothermal reactor; and a step of synthesizing methane by transferring gas with high methane content to insulative reactors (7-9). 10-50 vol% of steam is added based on the total volume of the synthetic gas and steam. The isothermal reactor supplies saturated water, and maintains temperature of an isothermal reactor.

Description

Method for producing methane from syngas and apparatus for methane synthesis {Method and Apparatus for Synthesizing Methane from Syngas}

The present invention synthesizes methane using a synthesis gas (CO + H 2 mixed gas) obtained through the gasification of coal or biomass or generated by-product gas, such as petrochemical industry Synthetic natural gas (Synthetic natural gas) It is about how to make and device.

Recently, the price of natural gas is rising along with rising oil prices. Accordingly, interest in clean fueling of inexpensive coal is increasing, and research on coal gasification technology is being actively conducted. Along with this, research on economic utilization of syngas obtained by coal gasification is being conducted, and commercialization is being actively promoted in the United States and China recently.

The main reaction formula and heat of reaction to make synthetic natural gas containing methane as main component are as follows.

On the other hand, in the methane synthesis reaction by the water produced in the reaction of carbon monoxide and hydrogen, a water gas shift reaction as in Scheme 3 is generated as a side reaction, and methane synthesis reaction from carbon dioxide is also generated by the carbon dioxide generated as in the reaction scheme.

In the methane synthesis reaction as described above, the synthesis yield of methane increases as the pressure increases thermodynamically, but the synthesis yield of methane decreases as the reaction temperature increases.

Ni-based catalysts are mainly used for the synthesis of methane. In this case, since strong exotherm is involved, effective extraction and control of reaction heat is a very important factor in designing the methane synthesis process. In particular, the general Ni-based catalyst temperature control is particularly important because the life of the catalyst is reduced by the sintering phenomenon above 700 ℃. In addition, since the Ni-based catalyst modified to be used at high temperature is difficult to use at 800 ° C. or higher, temperature control of the catalyst layer is very important.

Therefore, in a general process commercially used for methane synthesis, a large number of adiabatic reactors are used, and the products of the reactions from some reactors are recycled to the front end of the reactor, mixed with the reactor inlet gas, and fed to the reactor, thereby reducing CO in the reactor inlet gas. And a method of controlling the heat of reaction by lowering the H ₂ concentration.

1 is a view showing an example of a process that is conventionally applied in the commercial methane synthesis method. According to the conventional methane synthesis process as shown in FIG. 1, part of the gas discharged from the primary adiabatic reactor is recycled to the primary reactor inlet using a recycle compressor to control the reaction heat in the primary reactor, and the secondary and tertiary adiabatic reactor By sequentially passing through, the yield of methane can be increased. By maintaining the temperature below 700 ° C in the primary reactor using the recycled gas, a methane composition of about 50% can be obtained at the rear end of the primary reactor, at least 90% by going through a three-stage or four-stage adiabatic reactor. The above methane composition can be obtained.

Meanwhile, in Korean Patent Publication No. 2010-0042266, the synthesis gas is divided into a primary adiabatic reactor and a secondary adiabatic reactor, and a part of the product from the primary adiabatic reactor is recycled, mixed with the syngas, and returned to the primary reactor. A method of controlling the heat of reaction by sending is disclosed, wherein four adiabatic reactors are used to obtain products of 90% or more methane composition.

However, a method of manufacturing methane by combining a plurality of adiabatic reactors requires a lot of equipment cost for recycling high-temperature, high-pressure gas, and a plurality of adiabatic reactors may be used to obtain a desired yield of methane.

In order to overcome the disadvantages caused by the combination of a plurality of adiabatic reactors, by recovering the heat of reaction using an isothermal reactor in which a plurality of tubes are filled with a catalyst in a shell using a steam cooling device generally used for exothermic reaction Attempts have been made to reactor systems that can increase the yield of methane. As such a patent document, US patent 4294932 is mentioned.

However, it is difficult to apply to methane production process commercially because more than thousands of tubes are required to apply to a commercial scale methane synthesis process using such a reactor system. In addition, since the heat of reaction generates enormous heat in the short catalyst layer section, even if the tube is cooled to the outside using an inner diameter of about 1 inch, the tube size cannot be increased because a high temperature of 700 ° C. or higher is generated at the center of the catalyst layer. Therefore, there is a problem that the overall reactor size becomes large.

The present invention is to provide a methane synthesis method and apparatus that can minimize the cost of methane synthesis, and to suppress the enlargement of the entire reactor by simplifying the methane synthesis process.

The present invention also provides a method and apparatus for effectively producing methane through an adiabatic reactor by effectively controlling the heat of reaction on the catalyst surface.

The present invention relates to a method for synthesizing methane from syngas, and according to a first embodiment, adding steam to a syngas containing carbon monoxide and hydrogen as a main component to form a mixed gas, and mixing the gas into an isothermal reactor. And supplying a gas to the adiabatic reactor by synthesizing methane by increasing the methane content by the isothermal reactor.

According to a second embodiment of the present invention, the steam may be added in 10 to 50% by volume based on the total volume of the syngas and steam.

According to a third embodiment of the present invention, the method may further include maintaining a constant temperature of the isothermal reactor using saturated water in the mixed gas supplied to the isothermal reactor.

On the other hand, the present invention relates to a methane synthesis apparatus for synthesizing methane by reacting in the presence of a catalyst from a synthesis gas containing CO and H ₂ , according to a first embodiment, the methane synthesis apparatus is a steam to the synthesis gas A steam supply device for supplying, a mixed gas of the synthesis gas and steam is supplied, an isothermal reactor for reacting the mixed gas to generate methane, cooling water is supplied, and the cooling water is heated to form saturated water, and then saturated A cooling water supply tank for supplying water to the isothermal reactor, a condenser for supplying methane-containing gas by condensing water from the methane-containing mixed gas discharged from the isothermal reactor, and recovering heat from the methane-containing gas supplied through the condenser Heat exchanger and methane-containing gas passing through the heat exchanger and the remaining horn of syngas and steam And the gas is supplied is mixed and may include an adiabatic reactor to react in the presence of a catalyst to synthesize methane.

According to the present invention, a recirculation process is not necessary, the process can be simplified, and the heat of reaction can be effectively extracted to lower the maximum temperature of the catalyst layer. Thereby, methane can be synthesize | combined effectively.

1 is a process diagram schematically showing a process of synthesizing methane by combining a plurality of adiabatic reactors in a conventional methane synthesis process.
2 is a process diagram schematically showing an example of a methane synthesis process according to the present invention.

The present invention relates to a method for producing methane using a synthesis gas containing CO and H ₂ as a main component obtained through coal gasification, etc., which effectively controls the heat of reaction on the surface of the catalyst using an isothermal reactor and steam, It is intended to produce methane effectively through a batch of adiabatic reactors.

FIG. 2 shows a schematic diagram of a methane synthesis process of the present invention, with reference to FIG.

In the present invention, a synthesis gas containing hydrogen and carbon monoxide as main components is used for the production of methane. Such syngas may be obtained through gasification of coal or biomass, or may use syngas generated from by-product gas such as petrochemical industry. The main reaction formula and heat of reaction for making synthetic natural gas containing methane as a main component using syngas using hydrogen and carbon monoxide are as follows.

Meanwhile, in the methane synthesis reaction by water generated in the reaction of CO and H ₂ , a water gas shift reaction such as the following Equation 2 occurs as a side reaction, and the methane synthesis reaction also occurs as shown in Scheme 3 by the generated CO ₂ . .

In the methane synthesis reaction as described above, the synthesis yield of methane increases as the pressure increases thermodynamically, but the synthesis yield of methane decreases as the reaction temperature increases. Ni-based catalysts are mainly used for the synthesis of methane. In this case, since strong exotherm is involved, effective extraction and control of reaction heat is a very important factor in designing the methane synthesis process. In particular, since the Ni-based catalyst has a lifespan shortened by the sintering phenomenon at 700 ° C or higher, it is necessary to control the temperature.

Thus, in the present invention, in order to lower the heat of reaction in the catalyst layer, the steam 2 is mixed with the synthesis gas 1 as described above. The heat of reaction in the catalyst layer can be suppressed by diluting the heat of reaction by mixing steam with the synthesis gas 1.

For example, when a synthesis gas having a ratio of H ₂ / CO of 2.8 is injected at the inlet temperature of the reactor at 300 ° C, when methane is synthesized using an adiabatic reactor, the maximum temperature of the catalyst bed is increased to 923 ° C by the heat of reaction. I will go. However, it was confirmed that when the steam is supplied, for example, by mixing 30% by volume, the maximum temperature of the catalyst layer may be lowered to 809 ° C. Therefore, in the present invention, the steam is injected to extract the heat of reaction to lower the maximum temperature of the catalyst layer.

At this time, the steam (2) mixed in the synthesis gas (1) is preferably included in the range of 10% by volume to 50% by volume relative to the total volume of the mixed gas (1). When it is contained in less than 10% by volume, the dilution effect of the heat of reaction cannot be sufficiently obtained, and when it exceeds 50% by volume, the synthesis yield of methane decreases, which is not preferable.

The mixed gas of the synthesis gas 1 and steam 2 flows into the adiabatic reactor 7 and the isothermal reactor 3. The adiabatic reactor 7 is applicable to those commonly used, and is not particularly limited here. In addition, the isothermal reactor 3 may be a shell-tube type reactor, as well as an annular type reactor, and is not particularly limited.

On the other hand, the maximum temperature of the catalyst in the primary adiabatic reactor 7 can be controlled by artificially adjusting.

The mixed gas supplied to the isothermal reactor 3 undergoes methane synthesis at a low temperature. Therefore, in the isothermal reactor, the mixed gas increases the methane yield, and a methane composition of about 80% or more may be obtained.

The isothermal reactor 3 serves to maintain a constant temperature of the isothermal reactor by supplying saturated water to the outside of the catalyst layer filled with the catalyst. The saturated water is obtained by heating in the cooling water supply tank 5, and by supplying such saturated water to the isothermal reactor 3, the temperature of the isothermal reactor 3 can be kept constant. At this time, the saturated steam generated by the reaction heat is recovered to the cooling water supply tank (5) again.

On the other hand, the high pressure steam generated in the cooling water supply tank (5) can be further heated by the gas generated in the primary adiabatic reactor (7) and the heat exchanger (10) to produce the supersaturated steam (2), thereby obtained The supersaturated steam 2 can be used for a steam turbine.

The mixed gas discharged from the isothermal reactor 3 may cool the supplied mixed gas in the heat exchanger 10, and then remove moisture from the condenser 11 with the condensed water 12 to obtain a cooled mixed gas. . Thereafter, after the temperature of the gas is adjusted by the heat exchanger 10, it is supplied to the primary adiabatic reactor 7. Since the mixed gas discharged from the isothermal reactor 3 has a high methane composition, when the gas mixture is subsequently introduced into the adiabatic reactor 7, the mixed gas exhibits the same effect as the dilution effect of the previous steam and further provides an effect of suppressing the reaction heat. .

As such, the primary adiabatic reactor 7 is supplied with a mixture gas of unreacted synthesis gas 1 and steam 2 and a gas having a high methane composition mixed through the isothermal reactor 3, and supplied with the primary gas. The methane synthesis reaction is carried out in the adiabatic reactor 7 to lower the heat of reaction in the reactor, which in turn lowers the maximum temperature of the catalyst bed.

Subsequently, the gas passing through the primary adiabatic reactor (7) can be sequentially passed through the secondary adiabatic reactor (8) and the tertiary adiabatic reactor (9) to increase the yield of methane production, isothermal reactor (3) and 3 By using two adiabatic reactors 7, 8 and 9, methane 13, which is a synthetic natural gas, as a final product can be obtained at a concentration of 97% or more.

Since the methane-containing gas synthesized by passing through each of the adiabatic reactors 7, 8, and 9 contains water as a reaction by-product, each condenser 12 for condensing the methane-containing gas discharged for removing the moisture is provided. It may include. The high-purity methane 13 can be recovered by separating the condensed water from the methane gas.

1: syngas
2: steam
3: isothermal reactor
4: cooling water
5: cooling water supply tank
6: supersaturated steam
7: primary adiabatic reactor
8: secondary adiabatic reactor
9: 3rd adiabatic reactor
10: Heat exchanger
11: condenser
12: condensate
13: methane

Claims (5)

Adding steam to a synthesis gas including carbon monoxide and hydrogen as a main component to form a mixed gas;
Supplying the mixed gas to an isothermal reactor; And
Methane synthesis method comprising the step of synthesizing the methane by sending a gas having a high methane content by the isothermal reactor.
The method of claim 1, wherein the steam is methane synthesis method is added in 10 to 50% by volume relative to the total volume of the synthesis gas and steam.
The method of claim 1, wherein the isothermal reactor is methane synthesis method characterized in that to maintain a constant temperature of the isothermal reactor by supplying saturated water.
A methane synthesis apparatus for synthesizing methane by reacting in the presence of a catalyst from a synthesis gas containing carbon monoxide and hydrogen, the methane synthesis apparatus
A steam supply device for supplying steam to the synthesis gas;
An isothermal reactor in which a mixed gas of the synthesis gas and steam is supplied and the mixed gas reacts to generate methane;
Cooling water is supplied, the cooling water supply tank for heating the cooling water to form a saturated water, and then supply the saturated water to the isothermal reactor;
A condenser for condensing and removing water from the methane-containing mixed gas discharged from the isothermal reactor to supply a methane-containing gas;
A heat exchanger for recovering heat from the methane containing gas supplied through the condenser; And
Methane-containing gas passing through the heat exchanger and the remaining mixed gas of the synthesis gas and steam is mixed and supplied, the methane synthesis apparatus including an adiabatic reactor for reacting in the presence of a catalyst to synthesize methane.
The methane synthesizing apparatus according to claim 4, wherein the methane synthesizing apparatus comprises one to three adiabatic reactors.

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