KR101039929B1 - Double-jacket type reactor - Google Patents

Abstract

The present invention provides a heat supply unit including an inlet and an outlet of hot gas and a hollow heat supply pipe through which hot gas flows; A first flow pipe that forms a first flow path through which the processing gas flows between the first inlet through which the processing gas flows, the outer side of the heat supply pipe, and flows between the heat supply pipe and the first flow path A first jacket including a first outlet through which heat from the hot gas is discharged and preheated treatment gas flows out; And a second flow path formed therein with a second inflow port connected to the first outlet to communicate with the inside of the inlet, and a second flow path through which the preheated treatment gas flows into the heat supply pipe and flows into the second inlet. The present invention provides a double jacketed fluidized bed reactor having a second jacket including a second outlet through which a process gas receives heat from a high temperature gas and reacts the reacted reaction gas.

According to the double jacketed fluidized bed reactor according to the present invention, since a process gas such as methane is preheated by the hot gas in the first jacket and then heat exchanged in the second jacket, heat is recovered from the hot gas such as the combustion gas. The excellent ability to save energy can be saved, and since there is no need to provide a separate preheating device as in the prior art, the equipment construction cost is reduced as the device configuration is simplified.

Fluidized bed, reactor, reforming, steam, hydrogen

Description

Double-jacket fluidized bed reactor {Double-jacket type reactor}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double jacket type fluidized bed reactor, and more particularly, a double jacket for producing hydrogen through steam reforming of natural gas such as methane using waste heat such as combustion gas. Type fluidized bed reactor.

Hydrogen, which has recently emerged as a new renewable energy, is not secondary energy such as petroleum or coal, but secondary energy that can be obtained by converting primary energy. Such hydrogen is a clean energy that can be obtained from natural resources such as water, fossil fuel, and biomass, and has no advantage in that it does not cause environmental pollution due to a product after being used for power generation because there is no carbon component.

While hydrogen is the most common resource around us, it is difficult to obtain as an independent energy source, and if it can be produced independently, it can be an effective fuel to supply energy for power generation.

For example, as a power generation technology using hydrogen, such as a fuel cell, is gradually being realized, the development of a technology capable of producing a large amount of hydrogen is required, and researches on the manufacturing method thereof are being actively conducted.

Representative methods include steam reforming, partial oxidation, plasma reforming, and water decomposition using metal oxides.

The steam reforming method reforms by injecting and reforming source gas and water vapor such as city gas, LPG, natural gas into the reactor, and the size of the reactor is relatively slow and the reaction rate is relatively slow. Because of this, it is the most used at present.

Figure 1 is a schematic diagram showing an example of a conventional fluidized bed reactor for steam reforming natural gas using combustion gas.

Referring to the drawings, the conventional conventional fluidized bed reactor, the inlet port 10 is a natural gas such as methane and the processing gas containing the water vapor, a porous distributor 20 for filtering foreign matter, and for steam reforming reaction The reaction unit 30 receives heat from the combustion gas and an outlet 40 through which the reacted hydrogen gas flows out. On the other hand, although not shown, a catalyst layer including a plurality of catalyst particles is formed above the distributor 20.

By the way, in the fluidized bed reactor as described above, it is limited to increase the heat exchange area of the reaction unit 30 in terms of equipment construction, there is a limit to the amount of heat that can be absorbed from the hot combustion gas.

Therefore, the processing gas introduced through the inlet 10 is generally subjected to a pre-heating process through a separate preheating device (not shown) before being introduced. Accordingly, there is a problem in that the configuration of the device is complicated, and a lot of costs are required for facility construction.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides a double-jacketed fluidized bed reactor having a simplified structure and improved structure to efficiently recover heat from hot combustion gases. There is this.

The present invention provides a heat supply unit including an inlet and an outlet of hot gas and a hollow heat supply pipe through which the hot gas flows; A first flow pipe configured to form a first flow path through which the process gas flows between the first inlet through which the process gas flows, and an outer side of the heat supply pipe spaced apart from the heat supply pipe; A first jacket comprising a first outlet through which heat is transferred and the preheated treatment gas is received from the hot gas; And a second flow pipe formed therein with a second inflow port connected to the first inflow port so as to communicate with the inside, and a second flow pipe path inside which the preheated treatment gas flows into the heat supply pipe and flows into the second inflow flow. Provided is a double jacketed fluidized bed reactor having a second jacket including a second outlet through which the process gas receives heat from the hot gas and flows the reacted reaction gas while flowing in a second flow path.

Here, the second jacket may further include a porous distributor installed at the inlet side of the second flow tube path formed inside the second flow tube to allow the processing gas to pass through and not to allow foreign substances to pass therethrough. In addition, the second jacket may further include a catalyst layer having a plurality of catalyst particles on the upper side of the distributor.

In addition, the double jacketed fluidized bed reactor may be further connected to the second outlet of the second jacket, and may further include a collecting part including a cyclone for recovering the catalyst particles contained in the reaction gas.

Further, the process gas may be fuel gas and water vapor, and the reaction gas may be hydrogen and syngas. The fuel gas may be one selected from city gas, LPG, and natural gas.

According to the double jacketed fluidized bed reactor according to the present invention, since a process gas such as methane is preheated by the hot gas in the first jacket and then heat exchanged in the second jacket, heat is recovered from the hot gas such as the combustion gas. The ability to do so can save energy.

In addition, since there is no need to provide a separate preheating device for preheating the process gas as in the prior art, the configuration of the device is simplified, thereby reducing the construction cost of the facility.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the ordinary or dictionary meanings, and the inventors should properly introduce the concept of terms in order to explain their own invention in the best way. Based on the principle that the definition can be made in a simple manner, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Figure 2 is a block diagram showing a double jacketed fluidized bed reactor according to an embodiment of the present invention.

Referring to the drawings, the double jacketed fluidized bed reactor according to an embodiment of the present invention, the first and second jackets 120, 130, and heat the first and second jackets 120, 130, respectively It is provided with a heat supply unit 110 for supplying.

The heat supply unit 110 has an inlet 111 through which hot gas flows, a hollow heat supply tube 113 through which the hot gas flows, and a hot gas flowing through the heat supply tube 113 flows out. And an outlet 112 to be used. The hot gas may be a waste heat gas that can be normally discarded after performing its original function, such as combustion gas.

The first jacket 120 includes a first inlet 121 through which the processing gas flows, a first flow pipe 123 forming a first flow path 123a through which the processing gas flows, and the hot gas. It includes a first outlet (122) for receiving the heat from the preheated process gas flows out. In addition, the first flow pipe 123 surrounds the heat supply pipe 113 so as to form a first flow path 123a through which the processing gas flows. Here, the treatment gas is preferably a fuel gas and steam for steam reforming reaction, and the fuel gas may be a natural gas such as city gas, LPG, or methane (CH4).

The second jacket 130 may include a second inlet 131 connected to the first outlet 122, a second flow pipe 133 having an inner side of the second flow pipe path 133a through which the preheated treatment gas flows. In addition, the preheated process gas may receive heat from the hot gas, and includes a second outlet 132 through which the reacted reaction gas flows out.

In order to allow the preheated process gas to flow into the first jacket 120, the second inlet 131 is connected to communicate with the first outlet 122. The preheated process gas receives heat from the hot gas while flowing through the second flow pipe 133a and reacts as follows. However, here is an exemplary case of the case of methane (CH4) and steam (Steam) as the treatment gas.

CH4 + H2O = 3H2 + Syn Gas

In the second flow pipe 133a of the second jacket 130, the reaction gas flowing out through the second outlet 132 through the above reaction is synthesized with hydrogen gas and titanium monoxide (Co). Gas.

Meanwhile, in the double jacketed fluidized bed reactor of the present invention as described above, the second jacket 130 may further include a distributor 134 to filter foreign matter. The distributor 134 is installed at the inlet side of the second flow passage 133a, and is made of a porous material so that the processing gas passes but foreign substances do not pass.

In addition, the second jacket 130 may further include a catalyst layer 135 on an upper side of the distributor 134 to promote the steam reforming reaction. In addition, the catalyst layer 135 includes a plurality of catalyst particles 135a such as carbon black, and the catalyst particles 135a are introduced into the second flow pipe by the processing gas introduced through the distributor 134. Evenly scattered throughout 133a.

However, since some of the catalyst particles 135a as described above are discharged through the second outlet 132 together with the reaction gas such as hydrogen and syngas, the collecting unit 140 may be provided to recover them. The collecting unit 140 is connected to the second outlet 132 of the second jacket 130 and includes a cyclone (141) for recovering the catalyst particles (135a) contained in the reaction gas. . Here, the collector of the cyclone 141 is not significantly different from the technical configuration of the cyclone applied to the conventional dust collector, and thus detailed description thereof will be omitted.

As described above, according to the double jacketed fluidized bed reactor according to the present invention, after the treatment gas such as methane is preheated by the hot gas in the first jacket 120, heat exchange is performed again in the second jacket 130. Therefore, the ability to recover heat from hot gas such as combustion gas is excellent, and energy can be saved.

Furthermore, since there is no need to provide a separate preheating device as in the prior art, the device configuration is simplified, and thus, the construction cost of the facility can be reduced.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a configuration diagram briefly showing an example of a conventional fluidized bed reactor for steam reforming natural gas using combustion gas;

Figure 2 is a block diagram showing a double jacketed fluidized bed reactor according to an embodiment of the present invention.

<Brief description of the main parts of the drawing>

110: heat supply section 111: inlet

112: outlet 113: heat supply pipe

120: first jacket 121: first inlet

122: first outlet 123: first flow pipe

130: second jacket 131: second inlet

132: outlet 2 133: the second flow pipe

134: distributor 135: catalyst bed

140: collecting unit 141: cyclone

Claims (6)

A heat supply unit 110 including an inlet 111 and an outlet 112 of the hot gas and a hollow heat supply pipe 113 through which the hot gas flows; A first flow path 123a through which the processing gas flows between the first inlet 121 through which the processing gas flows and the outside of the heat supply pipe 113 so as to be spaced apart from each other. The first jacket 120 includes a first flow pipe 123 to be formed and a first outlet 122 through which heat is transferred from the hot gas while the first flow path 123a flows. ); And A second inlet pipe 131 connected to the first outlet 122 and a second flow pipe in which the preheated treatment gas introduced into the heat supply pipe 113 flows into the second inlet 131 so as to communicate with the inside; The second flow outlet 132 through which the reaction gas reacted by receiving heat from the hot gas while flowing the second flow pipe 133 and the second flow path 133a having the furnace 133a flowed out from the hot gas Double jacketed fluidized bed reactor having a second jacket (130) comprising. The method of claim 1, wherein the second jacket 130, The double jacketed fluidized bed reactor further includes a porous distributor 134 installed at an inlet side of the second flow pipe 133a formed inside the second flow pipe 133 to allow the processing gas to pass but not to allow foreign substances to pass therethrough. . The method of claim 2, wherein the second jacket 130, The double jacketed fluidized bed reactor further comprises a catalyst layer (135) having a plurality of catalyst particles (135a) on the upper side of the distributor (134). The method of claim 3, It is further provided with a collecting unit 140 is connected to the second outlet 132 of the second jacket 130, including a cyclone 141 for recovering the catalyst particles (135a) contained in the reaction gas Double jacketed fluidized bed reactor. The method according to any one of claims 1 to 4, The process gas is a fuel gas and water vapor, The reaction gas is a double jacketed fluidized bed reactor is hydrogen and syngas. The method according to claim 5, The fuel gas is a double jacket type fluidized bed reactor is selected from city gas, LPG, natural gas.

Images