KR100968541B1 - fuel processor of fuel cell system - Google Patents

Abstract

The present invention relates to a fuel conversion device of a fuel cell system, wherein the heat recovery layer 12 is formed outside the reformer 10, and the combustion gas discharge passage 22 is formed by the heat transfer partition 21 therein. The heat recovery layer 12, the lower portion of the reformer 10, and the triple pipe heat exchanger (30) connected to the combustion gas discharge passage (22).

In the upper space partitioned by the heat insulator 40, a two-part CO transformer 50 is installed, and a double tube heat exchanger 60 through which a reactant flows between the front reactor 51 and the rear reactor 52 is installed. .

Therefore, the efficiency of the fuel converter is improved by recovering the waste heat of the reformed gas and the combustion gas as much as possible and operating the fuel converter, and the combustion gas discharge path and the CO transformer 50 are separated so that the CO transformer 50 is separated. Excessive temperature rise is prevented.

Fuel converter, fuel converter, reformer, fuel cell fuel supply

Description

Fuel converter of fuel cell system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel conversion device for a fuel cell system, and more particularly, to an apparatus for reforming a fuel into a hydrogen-containing gas that can be used for power generation in a stack.

The fuel converter includes a reformer that generates hydrogen by reacting a hydrocarbon fuel with water vapor, and a CO converter and a CO remover that removes carbon monoxide so that the generated gas does not poison the catalyst of the stack. It is configured to include.

The reformer generates hydrogen by methane-steam reforming reaction (endothermic reaction) to discharge hydrogen-containing gas (reformed gas) (CO content 10-15%), and the CO transformer converts CO in the reformed gas into carbon dioxide ( And exothermic reaction) to generate hydrogen (CO content of 1% or less), and the CO remover removes CO to ppm units (10 ppm or less) by a selective oxidation reaction (exothermic reaction).

Fuel gas purified to the level required by the carbon monoxide in the above manner is supplied to the anode (anode) of the stack, air (oxygen) is supplied to the cathode (cathode) and the electrochemical reaction is carried out through the electrolyte membrane to generate electricity And concomitantly produce water and heat.

The generated current is converted into alternating current using an inverter as a direct current. In addition, the generated heat is thermally stored as hot water using a predetermined heat exchanger, and used for hot water supply and heating as necessary.

The fuel converter, particularly in a domestic fuel cell system, is required to be smaller and more efficient. In the conventional fuel converter, the heat required for the reforming reaction in the reformer can be obtained only from the burner (increased amount of fuel supplied to the burner). The waste heat of the combustion gas was not fully utilized.

In addition, the amount of water (H ₂ O) in the reactants had to be increased to prevent excessive rise in the temperature of the CO transformer which exothermicly reacts at the rated temperature.

Due to the above causes, the conventional fuel converter has been deteriorated in efficiency and needs to be improved.

Accordingly, the present invention has been made in accordance with the necessity as described above, and the object of the present invention is to provide a fuel conversion device for a fuel cell system with improved efficiency by enhancing waste heat recovery and preventing an excessive increase in the temperature of the CO transformer. have.

The present invention for achieving the above object,

A domed reformer having a reformed gas outlet formed at an upper apex;

A heat recovery layer surrounding an outer circumference of the reformer;

A burner installed in an inner space of the reformer;

An electrothermal partition wall disposed near the inner circumferential surface of the reformer to form a combustion gas discharge passage;

An inner tube installed outside the heat recovery layer and connected to the heat recovery layer to discharge reformed gas, an intermediate pipe connected to a lower end of the reformer, and a reactant introduced thereto, and a burner combustion gas connected to the combustion gas discharge passage Triple tube heat exchanger consisting of an outer tube is discharged;

An insulating material surrounding the heat recovery layer and partitioning an inner space into an upper space and a lower space;

A CO transformer installed in the upper space;

It includes.

The CO transformer comprises a cylindrical shear reactor and a rear stage reactor inserted therein, the inner tube of the triple tube heat exchanger is connected to the shear reactor, and a lower end of the shear reactor and the rear stage reactor is connected to the shear reactor. A modified gas outlet is formed at the top of the rear stage reactor.

The catalyst of the CO transformer is a catalyst that can be used continuously in the operating temperature range of 200 ~ 280 ℃.

On the other hand, between the shear reactor and the rear end reactor is inserted into a double tube heat exchanger consisting of the inner tube and the outer tube in close contact, the lower end of the inner tube and the outer tube are connected to each other, the reactant inlet to the upper end of the inner tube And an upper end of the outer tube is connected to the intermediate tube of the triple tube heat exchanger.

Combustion gas outlet is formed at the upper end of the outer tube of the triple tube heat exchanger.

The fluid passing through the tubes of the triple tube heat exchanger and the double tube heat exchanger is in a countercurrent relationship with the fluid passing through the tubes of the adjacent tubes.

The heat recovery layer may be filled with a heat transfer material of ceramic material in order to increase the heat transfer performance.

Likewise, the inside of the triple tube heat exchanger and the double tube heat exchanger may be filled with a heat transfer material made of ss-wool (stainless steel wool).

On the other hand, a diffusion layer is formed between the lower end of the reformer and the lower end of the intermediate tube of the triple tube heat exchanger.

When the diffusion layer is formed as above, the flame of the burner is located at the boundary between the diffusion layer and the catalyst layer in the reformer.

In addition, the catalyst layer of the reformer may be composed of a low temperature catalyst layer and a high temperature catalyst layer of the upper.

At this time, the low temperature catalyst layer is a small amount of pretreatment catalyst layer to prevent carbon precipitation, the high temperature catalyst layer may be composed of a large amount of the main reforming reaction layer.

When the reforming catalyst layer is composed of a low temperature catalyst layer and a high temperature catalyst layer as described above, a burner flame is preferably located between the low temperature catalyst layer and the high temperature catalyst layer.

On the other hand, a heat transfer device may be installed between the triple tube heat exchanger and the shear reactor of the CO transformer.

And a heat transfer device may be installed between the inner tube and the outer tube of the double tube heat exchanger.

The outermost tube in which the outer tube and the upper end are interconnected are installed on the radially outer side of the triple tube heat exchanger outer tube, and a water vaporizer is installed on the outer circumferential surface of the outermost tube.

The water vaporizer is provided with a water supply port at the bottom, a water vapor outlet is formed at the top, the water vapor outlet is connected to the middle portion of the middle tube of the triple tube heat exchanger.

Partition plates forming a plurality of layered flow paths are installed in the water evaporator, and a barrier plate is disposed across the partition plates in an up and down direction, and a moving passage is formed on each of the partition plates with respect to the barrier plate. Thus, a circulating flow path of a multilayer structure is formed.

In addition, the inside of the outermost tube in close contact with the water vaporizer has the same structure as the water vaporizer, and the burner combustion gas flowing therein and the water vapor of the water vaporizer form a countercurrent relationship.

The water vaporizer and the heat transfer material of the ss-wool material may be installed inside the outermost tube.

In addition, the perforated plate may be installed on the outer side of the moving passage on both sides of the blocking plate.

In addition, the CO remover is installed in contact with the outer peripheral surface of the intermediate tube of the triple tube heat exchanger.

The CO remover is a cylindrical device, the modified gas inlet formed at the top is connected to the modified gas outlet of the rear stage reactor, the purge gas outlet formed at the bottom is connected to the anode of the stack, the air in the previous portion of the modified gas inlet Inlets are formed.

The top and bottom attachment baffles are repeatedly installed in the CO remover along the circumferential direction to form a vertical reciprocating path.

On the other hand, the water evaporator is installed on the upper outer peripheral surface of the outermost tube, the combustion reactant preheater for preheating the air and fuel gas supplied to the burner is installed in the lower, the discharged from the anode of the stack on the inner peripheral surface of the outermost tube A stack off gas preheater is provided for preheating the gas.

The inside of the combustion reactant preheater and the stack-off gas preheater have the same structure as the water evaporator, and the inner flow thereof has a reverse flow relationship with the flow of the burner combustion gas of the outermost pipe.

The water vapor outlet of the water vaporizer may be connected to the reactant inlet of the inner tube of the double tube heat exchanger.

In addition, the water vapor outlet of the water vaporizer may be connected to the upper end of the intermediate tube.

In addition, the present invention is provided with a water preheater on the modified gas supply passage between the modified gas outlet of the CO reformer after-stage reactor and the modified gas inlet of the CO remover.

The water discharge pipe of the water preheater is connected to the water supply port of the water evaporator.

According to the present invention as described above, the amount of heat to be supplied from the burner is reduced by reabsorbing the heat of the reformed gas from the heat recovery layer surrounding the reformer and using it in the reforming reaction.

In addition, by forming a double flow path using the heat transfer partition inside the burner, the time and path for the combustion gas to stay in the internal space of the reformer are increased, thereby increasing the amount of heat recovery from the combustion gas.

Since the reactant supplied from the outside is sufficiently preheated by heat exchange with the CO remover, the CO transformer, the reforming gas, and the combustion gas, it is easy to maintain the operating temperature of the reformer and the amount of fuel consumed in the burner is reduced.

In addition, the heat of the burner combustion gas is used to heat water in the reactants to convert the water into water vapor, and preheat the combustion fuel gas, air, and the stack-off gas supplied to the burner, thereby increasing the efficiency of the burner.

In addition, by separately installing the burner combustion gas discharge path and the CO transformer as the exothermic reactor, the temperature of the CO transformer can be prevented from being excessively increased, and conventionally, the excessive amount of water is stopped to maintain the operating temperature of the CO transformer. By doing so, it is possible to maintain a low water vapor / carbon ratio.

In addition, in the case of the CO remover, a heat exchange with the reactant (fuel gas) supplied to the reformer and the water supplied to the water evaporator is cooled to prevent excessive rise in operating temperature. Therefore, it is easy to install and operate the system since there is no need to install additional equipment such as a fan and control logic for controlling its operation.

That is, the efficiency of the fuel conversion device is improved by constructing a system for recovering the heat of the reformed gas and the burner combustion gas as a whole and operating the device.

In addition, since all the devices are configured in a cylindrical shape concentric with each other can be configured a more compact and compact device.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a cross-sectional view of a fuel conversion apparatus according to an embodiment of the present invention.

The reformer 10 located in the lower inner central portion of the apparatus is reformed by the catalytic reaction while the fuel gas and water vapor supplied from the lower part are diffused upward, and the hydrogen-containing gas generated therein is easily concentrated and discharged. )

The reformed gas outlet 11 of the reformer 10 is formed at the upper apex of the reformer body, and a heat recovery layer 12 is formed surrounding the entire outer circumferential surface of the reformer.

The inner center of the reformer 10 is provided with a burner 20 for supplying heat required for the reforming reaction by receiving and burning the same kind of fuel as the reformer.

Between the burner 20 and the reformer 10, a cylindrical heat-transfer partition 21 is provided at a predetermined interval close to the inner circumferential surface of the reformer.

The heat transfer bulkhead 21 receives the radiant heat of the burner 20 flame and re-radiates through the entire body surface of the burner 20 so as to uniformly transmit heat to the entire inner circumferential surface of the reformer 10.

In addition, since the combustion gas discharge passage 22 is formed in close proximity to the inner circumferential surface of the reformer 10 by the heat transfer partition 21, the amount of contact between the high-temperature combustion gas and the inner circumferential surface of the reformer 10 increases, thereby improving the heat of the combustion gas. It can be delivered more smoothly to (10). The upper end of the heat transfer partition 21 is open for exhaust gas discharge.

Outside the heat recovery layer 12 is provided a triple tube heat exchanger (30) consisting of an inner tube (31), an intermediate tube (32) and an outer tube (33) at predetermined intervals.

The inner tube 31 of the triple tube heat exchanger 30 is connected to the heat recovery layer 12 to be a discharge passage of the reformed gas, and the intermediate tube 32 is connected to the lower end of the reformer 10 to fuel A reactant inflow passage into which a reactant such as gas and water vapor is introduced, and the outer tube 33 is connected to the combustion gas discharge passage 22 to become a discharge passage of burner combustion gas.

The outer side of the heat recovery layer 12 is provided with a cylindrical heat insulating material 40 is made of heat insulation.

The vertical portion of the heat insulator 40 blocks heat transfer between the heat recovery layer 12 and the triple tube heat exchanger 30, and the horizontal portion partitions the upper space and the lower space of the fuel converter and the space therebetween. Shut off heat transfer.

Therefore, the heat loss of the hot reformed gas discharged through the reformed gas outlet 11 and passing through the heat recovery layer 12 is minimized, so that a greater amount of heat can be absorbed into the reformer 10.

In the upper space partitioned from the lower space by the heat insulating material 40, a reforming gas generated in the reformer 10 is introduced to install a CO transformer 50 for removing CO by a CO modification reaction. The CO modification catalyst used in the CO transformer 50 is a catalyst that can be used continuously in the operating temperature range of 200 to 280 ° C. (The rated operating temperature of the CO transformer is 230 ° C.)

The CO transformer 50 includes a shear reactor 51 located at the front of the reformed gas movement path and a rear reactor 52 located at the rear thereof. The shear reactor 51 has a hollow cylindrical shape with an outer circumferential surface thereof. It is installed in contact with the inner tube 31 of the triple tube heat exchanger (30), the rear end reactor (52) is a cylindrical type is installed in the central empty space of the shear reactor (51).

The inner tube 31 of the triple tube heat exchanger 30 is connected to the upper end of the shear reactor 51, the lower end of the shear reactor 51 is connected to the lower end of the rear end reactor 52, the rear end reactor ( A modified gas discharge port 53 is formed at the upper end of 52, and a closed path is formed from the reformer 10 via the CO transformer 50.

On the other hand, between the shear reactor 51 and the rear stage reactor 52 is a double tube heat exchanger (60) consisting of an inner tube (61) and an outer tube (62).

The inner tube 61 and the outer tube 62 are in close contact with the rear stage reactor 52 and the shear reactor 51, respectively, and lower ends of the inner tube 61 and the outer tube 62 are connected to each other. .

In addition, a reactant inlet 63 is formed at an upper end of the inner tube 61, and an upper end of the outer tube 62 is connected to an upper end of the intermediate tube 32 of the triple tube heat exchanger 30.

On the other hand, the combustion gas outlet 34 is formed on the upper end of the outer tube 33 of the triple tube heat exchanger (30).

By the above configuration, all the fluids passing through the triple tube heat exchanger 30 and the double tube heat exchanger 60 form a counter flow relationship with the fluid passing through the adjacent conduit so that heat exchange between the flows is reduced. It can be made more active.

The operation of the above embodiment takes place as follows.

When fuel gas and water vapor flow into the reactant inlet 63, the rear end reactor 52 and the shear reactor of the CO transformer 50 pass through the inner tube 61 and the outer tube 62 of the double tube heat exchanger 60. The heat is absorbed from the 51 and the temperature is raised. (The reaction of the CO transformer 50 is an exothermic reaction.)

Subsequently, the reactant (= fuel gas, water vapor) flows downward along the middle tube 32 of the triple tube heat exchanger 30 and rises along the reformed gas and the outer tube 33 that rise along the inner tube 31. The heat is raised to a sufficient temperature before the heat is absorbed from the combustion gas and introduced into the reformer 10.

Therefore, since the temperature of the reformer 10 does not drop significantly due to the inflow of the reactants, the fuel consumption of the burner 20 for maintaining the operating temperature of the reformer is reduced, thereby improving the efficiency of the fuel converter.

The fuel gas and the steam introduced into the reformer 10 undergo a reforming reaction through the reforming catalyst, and are converted into a hydrogen-containing gas (= reformed gas) containing a large amount of hydrogen and discharged to the reformed gas outlet 11.

The reforming reaction is an endothermic reaction, and the amount of heat required for this is generated by fuel gas combustion of the burner 20. Radiant heat from the burner flame is transmitted to the reformer through the heat transfer partition 21, and in addition, the combustion gas flows through the combustion gas discharge passage 22 to exchange heat with the inner side of the reformer to transfer heat.

In addition, the reformed gas discharged to the reformed gas outlet 11 has a temperature of 600 ~ 700 ℃, the high temperature reformed gas is discharged through the heat recovery layer 12 surrounding the reformer 10 and the outer peripheral surface of the reformer and The heat exchanger prevents heat release from the reformer or, in particular in the lower region of the reformer, transfers heat towards the reformer to help the reformer maintain its rated operating temperature.

Therefore, the fuel amount of the burner 20 consumed for the operation of the reformer is reduced, thereby improving the efficiency of the fuel converter.

Meanwhile, in order to improve heat transfer performance from the heat recovery layer 12 to the reformer 10, a heat transfer material (ceramic material) may be filled in the heat recovery layer 12. As a result, the heat of the reformed gas is absorbed by the heat transfer material, and thus the amount of heat retained in the heat recovery layer 12 is improved, which is advantageous for heat recovery to the reformer.

The reformed gas passing through the heat recovery layer 12 is moved to the upper space of the apparatus through the inner tube 31 of the triple pipe heat exchanger 30, and the combustion gas passing through the combustion gas discharge passage 22 is It moves to the upper space of the device through the outer tube 33 of the triple tube heat exchanger (30).

At this time, the reactant is moved downward to the intermediate tube 32 between the inner tube 31 and the outer tube 33. As described above, the reformed gas and the combustion gas are reacted to the reactant having a counter flow relationship. Heat is transferred to allow the reactants to be sufficiently preheated (above 400 ° C.) prior to the reformer inlet.

The combustion gas passed through the above process is discharged through the combustion gas outlet 34, and the reformed gas is sequentially passed through the front reactor 51 and the rear stage reactor 52 of the CO transformer 50, and the CO reformed in two steps. Through the reaction, the CO content is reduced to less than 1% (preferably 0.5%). Subsequently, the denatured gas discharged from the denatured gas discharge port 53 at the top of the rear stage reactor 52 is introduced into the CO remover (described below).

On the other hand, the CO transformer 50 is divided into a shear reactor 51 and a rear reactor 52, and each of them in contact with the inner tube 61 and the outer tube 62 of the double tube heat exchanger (60) Therefore, it is heat exchanged with the reactants of the low temperature state introduced into the device through the reactant inlet (63).

Therefore, excessive increase in the temperature of the CO transformer 50 in which the exothermic reaction takes place is prevented.

Therefore, it is possible to reduce the amount of steam input for preventing excessive rise in temperature of the CO transformer 50, so that the steam / carbon ratio can be kept low, thereby improving the efficiency of the fuel converter.

Preheating of the reactants is of course made through the heat exchange action as described above.

Meanwhile, the triple tube heat exchanger 30 and the double tube heat exchanger 60 may also be filled with a heat transfer material (ss-wool material) in order to increase heat transfer performance.

The heat insulator 40 serves to prevent the heat of the reformed gas passing through the heat recovery layer 12 from being transferred to another place so that as much heat as possible can be reabsorbed by the reformer. In addition, by separating the lower space in which the reformer 10 and the burner 20 are installed and the upper space in which the CO transformer 50 is installed, it helps to prevent excessive temperature rise of the CO transformer 50.

On the other hand, the horizontal space connecting the lower end of the reformer 10 and the intermediate tube 32 of the triple tube heat exchanger 30 serves as a diffusion layer (10a), passing through the diffusion layer (10a) reactants (fuel gas) , Steam) is further mixed to improve the homogeneity of the reactant gas, which helps to activate the reforming reaction.

At this time, the flame position of the burner 20 may be disposed at the boundary between the diffusion layer 10a and the catalyst layer in the reformer 10 to further increase the temperature at the inlet of the reformer, thereby reducing the temperature gradient in the reformer to improve reforming efficiency.

On the other hand, as shown in Figure 2, the catalyst layer of the reformer 10 may be composed of a low temperature catalyst layer (10b) and a high temperature catalyst layer (10b) of the upper.

Thus, by forming a reforming catalyst layer having a different active temperature region, the lower region into which the reactant at a relatively low temperature is introduced and the upper region into which the reactant at a relatively high temperature is heated up as the reforming reaction proceeds in the lower region are optimal. By making the active reforming reaction in a state, it is possible to improve the efficiency of the reforming reaction.

At this time, the low-temperature catalyst layer 10b is used as a pretreatment catalyst layer for preventing carbon precipitation from fuel gas, and the high-temperature catalyst layer 10c is composed of a main reforming reaction layer (the amount of the high-temperature catalyst is larger than that of the low-temperature catalyst). By preventing the activity of the catalyst due to the precipitation of carbon in the main reforming reaction layer to improve the hydrogen production performance of the entire reformer. This improves the efficiency of the reformer, which improves the efficiency of the entire fuel converter.

As such, when the catalyst layer in the reformer is divided into the low temperature catalyst layer 10b and the high temperature catalyst layer 10c, a burner 20 flame is placed between the low temperature catalyst layer 10b and the high temperature catalyst layer 10c to the low temperature catalyst layer 10. Reducing the amount of heat radiation ensures that an appropriate temperature gradient is formed in the catalyst layer of the reformer.

Meanwhile, a heat transfer device 70 may be installed between the triple tube heat exchanger 30 and the shear reactor 51 of the CO transformer.

In addition, a heat transfer device 71 may be installed between the inner tube 61 and the outer tube 62 of the double tube heat exchanger 60.

The heat transfer devices 70 and 71 may be coils that generate electricity by receiving electricity.

The operation of the heat transfer devices 70 and 71 may reduce the operation start time by rapidly inducing the temperature rise of the CO transformer 50 and the reactants during the start of the operation of the fuel cell system.

The heat transfer devices 70 and 71 may be used by applying both to the fuel converter at the same time, or by using only one of them.

3 is a modified embodiment of the embodiment, the water evaporator 80 is installed outside the lower half of the triple tube heat exchanger (30).

The water evaporator 80 is discharged by evaporating the water introduced by heat exchange with the combustion gas of the burner 20, for this purpose, the outermost tube in the radially outer side of the outer tube 33 of the triple tube heat exchanger (30). 35 is provided, and the water vaporizer 80 is closely attached to the outer circumferential surface of the outermost tube 35.

The outer tube (33) and the outermost tube (35) is connected to each other the upper end so that the combustion gas rising along the outer tube (33) is lowered through the outer tube (35) to be discharged to the outside of the device. have. Accordingly, the combustion gas discharged through the outermost tube 35 and the water vapor rising through the water vaporizer 80 have opposite flow directions.

Therefore, the water flowing into the water supply port 81 formed in the lower portion of the water evaporator 80 is burned out through the outermost pipe 35 while ascending the inner space of the water evaporator 80 along a predetermined path. Receiving heat from the gas is heated and vaporized, and then the reactant supply path through the steam outlet 82 connected between the upper end of the water evaporator 80 and the middle portion of the middle tube 32 of the triple tube heat exchanger 30. Flows into the phase.

As the steam is supplied as described above, only the fuel gas is introduced into the reactant inlet 63 of the upper end of the inner tube 61 of the double tube heat exchanger 60.

On the other hand, in order to allow the water inside the water evaporator 80 to absorb more heat from the combustion gas, the inside of the water evaporator 80 has a structure as shown in FIG.

That is, partition plates 83 forming a plurality of layered flow paths are installed in the water evaporator 80, and a blocking plate 84 is installed in a state in which the partition plates 83 cross in the vertical direction. Then, the moving passage (83a) is formed on the partition plate (83) left and right repeatedly with respect to the blocking plate (84).

Therefore, the water circulated in the circumferential direction of the water evaporator 80 along the flow path of the lower layer reaches the blocking plate 84 and flows into the upper flow path through the moving passage 83a. On the opposite side of (84), it enters the upper channel through the moving passage. In this way, a multi-layered circulating flow path is formed inside the water evaporator 80 to secure a long moving path so that a greater amount of heat can be absorbed from the combustion gas passing through the outermost pipe 35. It is easily converted to water vapor is made.

At this time, the inside of the outermost pipe 35 may be formed in the same structure as the water vaporizer so that the flow of water (the phase change into water vapor while moving from the lower part of the water vaporizer to the upper part) and the flow of the combustion gas can form a more complete countercurrent relationship. Can be.

Therefore, in addition to the general flow direction, that is, the up-down direction, according to the positional relationship between the inlet and the outlet, the circumferential flow of each of the separated layers in the outermost tube 35 and the water evaporator 80 is also mutually reversed. By forming a relationship, a more active heat exchange action is achieved.

The heat evaporator 80 and the outermost tube 35 inside the heat transfer material such as ss-wool can be installed to improve the heat exchange effect.

In addition, the perforated plate 85 may be installed at both sides of the blocking plate 84 at a predetermined interval. The perforated plate 85 is installed in such a state as to cross the partition plate 83 up and down like the blocking plate 84, and a plurality of holes are formed to enable the flow of the fluid.

When the perforated plate 85 is installed, the movement passage 83a may be formed inside the perforated plate 85, that is, between the blocking plate 84 and the perforated plate 85.

The perforated plate 85 serves to prevent the backflow of the fluid past the perforated plate 85 so that the fluid in the lower flow path can be more smoothly moved to the upper flow path.

On the other hand, the combustion gas discharge path does not exist in the upper portion of the fuel conversion device by the above-described deformable structure, and the intermediate tube 32 of the triple tube heat exchanger 30 is located at the outermost side, and the outer peripheral surface of the intermediate tube 32 is In contact with the CO remover 90 is installed.

Therefore, the CO remover 90 has a function of preheating the reactant that passes through the intermediate tube 32, that is, fuel gas.

The CO remover 90 is also a cylindrical device, the modified gas inlet 91 is formed on one side of the upper side is connected to the modified gas outlet 53 formed in the rear end reactor 52 of the CO transformer 50, one side of the lower side A purge gas outlet 92 is formed at the fuel cell and connected to the fuel anode of the stack. An air inlet 93 through which air for selective oxidation is introduced is formed in the previous portion of the modified gas inlet 91.

Therefore, a state in which CO is first removed through the CO transformer 50 and a shift gas having increased hydrogen content passes through the CO remover 90 while CO satisfies a stack input condition (10 ppm or less). Is removed, the purge gas is fed to the stack and used for power generation.

As described above, by installing the water evaporator 80 on the discharge path of the burner combustion gas, the waste heat of the combustion gas of the burner can be utilized by recovering the heat of the combustion gas to generate steam for reforming reaction. The efficiency is improved.

On the other hand, the inside of the CO remover 90 is filled with a catalyst for the CO removal reaction, as shown in Figure 5, the upper and lower attachment baffle (93a) and the lower attachment baffle (93b) is repeatedly installed along the circumferential direction Thus, the modified gas introduced into the modified gas inlet 91 is discharged through the purification gas outlet 92 via the vertical reciprocating path formed by the baffles.

Thus, sufficient CO removal reaction can be achieved via a long path.

6, the water vaporizer 80 is installed on the outer circumferential surface of the outermost pipe 35 through which the combustion gas is discharged, and a combustion reactant preheater 100 is installed on the lower part of the outermost pipe 35. The inner circumferential surface of the stack off gas preheater 110 is installed.

Fuel gas and air supplied to the burner 20 are preheated to the combustion reactant preheater 100, and the stack-off gas preheater 110 is used to discharge the remaining gas that is used at the anode of the stack, that is, the stack. The off-gas is supplied and preheated, and the combustion reactant gas and the stack-off gas preheated through each preheater are supplied to the burner 20 to be burned to generate heat necessary for the reforming reaction.

On the other hand, the combustion reactant preheater 100 and the stack-off gas preheater 110 is also the same as the water evaporator 80 (partition plate 83 and blocking plate 84 and moving passage 83a of FIG. 4). Structure), so that the combustion reactant and the stack-off gas can absorb more heat from the combustion gas and be preheated sufficiently through the long moving path.

Further, by appropriately adjusting the positions of the inlet and the outlet of each preheater, the combustion reactants and the stack-off gas passing through each preheater form a countercurrent relationship with respect to the combustion gas discharged through the outermost pipe 35. Active heat exchange can be achieved.

As such, the efficiency of the fuel conversion device is improved by increasing the waste heat recovery (utilization) rate by using the combustion gas heat of the burner 20 even when preheating the combustion reactant and the stack-off gas.

Meanwhile, as illustrated in FIG. 7, the water vapor outlet 82 of the water vaporizer 80 may be connected to the reactant inlet 63 of the inner tube 61 of the double tube heat exchanger 60.

In this case, the steam can be heated by the heat transfer device 71 while passing through the double tube heat exchanger 60 together with the fuel gas, so that the steam 10 preheated to the reformer 10 can be supplied at a higher temperature. It helps to maintain the reaction temperature, thereby reducing the amount of fuel used in the burner, thereby improving the efficiency of the fuel converter.

8 is another embodiment in which the inlet position of the steam generated by the water vaporizer 80 is changed. In this case, the steam outlet 82 of the water vaporizer 80 is connected to the upper end of the intermediate tube 32. .

That is, the steam outlet 82 is connected to the reactant supply line in contact with the CO remover 90.

This prevents the phenomenon that the operating temperature of the CO transformer 50 is excessively lowered, and prevents excessive rise of the operating temperature of the CO remover 90 so that an appropriate operating temperature can be maintained.

9 is an embodiment further provided with a water preheater 120.

The water preheater 120 is installed on the modified gas supply passage connected between the modified gas outlet 53 of the CO reactor 50, the rear end reactor 52, and the modified gas inlet 91 of the CO remover 90. The water preheater 120 includes a water supply pipe and a water discharge pipe, and the water discharge pipe is connected to the water supply port 81 of the water evaporator 80.

Therefore, water at room temperature is supplied to the water preheater 120 and absorbs heat from the denatured gas while passing through the inside, and is then supplied to the water evaporator 80 to improve the vaporization efficiency of the water evaporator 80. Is improved.

In addition, since the operating temperature of the CO remover 90 can be maintained within a predetermined range even if the temperature of the denatured gas introduced into the CO remover 90 is controlled under the same conditions, for cooling the CO remover 90 that is an exothermic reactor. In addition, there is no need to install a cooling device such as a fan. In addition, the control logic for controlling the operation of the fan is also unnecessary, thus facilitating the operation of the system.

Compared to the operating performance of the fuel conversion device according to the present invention and the prior art made of the above configuration.

Prior art Invention Water vapor / carbon ratio 3.0 2.5 CO transformer temperature 200 ~ 280 ℃ 200 ~ 230 ℃ CO eliminator temperature 100 ~ 180 ℃ 100 ~ 140 ℃ Burner Combustion Gas Temperature 150 ~ 180 ℃ 60 ~ 100 ℃

As can be seen from the above and the table, the discharge temperature of the burner combustion gas dropped to 80 ° C or more. In addition, the discharge temperature of the CO remover, that is, the temperature of the purge gas discharged from the fuel converter is also reduced by more than 40 ℃. That is, the waste heat of the burner combustion gas and the gas generated by the fuel conversion device is recovered and used for the operation of the device by the amount of heat of the temperature difference, and the efficiency of the device is improved because the amount of heat supplied through the burner is not provided as much as the corresponding amount.

In addition, the water vapor / carbon ratio of the reactant supplied is reduced by 0.5, which is about 0.5, and the overall fuel converter efficiency is increased by about 5%.

1 is a cross-sectional view of a fuel conversion device according to the present invention,

2 is a state diagram of the heating device installed in the fuel converter;

3 is a state diagram of the water evaporator and the CO remover of the fuel conversion device,

4 is an internal configuration diagram of the water evaporator,

5 is an installation state of the CO remover,

6 is a burner combustion reactant preheater and a stack-off gas preheater installed state of the fuel converter;

7 is another connection state diagram of the water vapor vapor outlet;

8 is another connection state of the water vapor vapor outlet;

9 is a state pre-installed water heater of the fuel converter.

Explanation of symbols for the main parts of the drawings

10: reformer 11: reformed gas outlet

12: heat recovery layer 20: burner

21: heat transfer bulkhead 22: combustion gas discharge passage

30: triple tube heat exchanger 31: inner tube

32: intermediate tube 33: outer tube

34: combustion gas outlet 35: outermost pipe
40: insulation

50: CO transformer 51: shear reactor

52: after-stage reactor 53: modified gas outlet

60: double tube heat exchanger 61: inner tube

62: outer tube 63: reactant inlet

70,71: heating device 80: water evaporator

81: water supply port 82: water vapor outlet

83: partition plate 84: blocking plate

85: perforated plate 90: CO remover

100: combustion reactant preheater 110: stack off gas preheater

120: water preheater

Claims (30)

A domed reformer having a reformed gas outlet formed at an upper apex; A heat recovery layer surrounding an outer circumference of the reformer; A burner installed in an inner space of the reformer; An electrothermal partition wall disposed near the inner circumferential surface of the reformer to form a combustion gas discharge passage; An inner tube installed outside the heat recovery layer and connected to the heat recovery layer to discharge reformed gas, an intermediate pipe connected to a lower end of the reformer, and a reactant introduced thereto, and a burner combustion gas connected to the combustion gas discharge passage Triple tube heat exchanger consisting of an outer tube is discharged; An insulating material surrounding the heat recovery layer and partitioning an inner space into an upper space and a lower space; A CO transformer installed in the upper space; Fuel converter of the fuel cell system comprising a. The method according to claim 1, wherein the CO transformer is composed of a cylindrical shear reactor and a rear end reactor inserted therein, the inner tube of the triple tube heat exchanger is connected to the shear reactor, the lower end of the shear reactor and the rear end reactor Is connected, the fuel converter of the fuel cell system, characterized in that the modified gas outlet is formed on the upper end of the reactor. The fuel converter of claim 2, wherein the catalyst of the CO transformer is a catalyst that can be continuously used at an operating temperature of 200 to 280 ° C. 4. The double tube heat exchanger of the inner tube and the outer tube is inserted in close contact between the shear reactor and the rear stage reactor, and the lower end of the inner tube and the outer tube are connected to each other, A reactant inlet is formed, and the upper end of the outer tube is connected to the intermediate tube of the triple tube heat exchanger, the fuel conversion system of the fuel cell system. The fuel conversion device of a fuel cell system according to claim 2, wherein a combustion gas outlet is formed at an upper end of the outer tube of the triple tube heat exchanger. The fuel conversion system of claim 4, wherein the fluid passing through the tubes of the triple tube heat exchanger and the double tube heat exchanger forms a countercurrent relationship with the fluid passing through the tubes of the adjacent tube. The fuel conversion apparatus of claim 1, wherein a heat transfer material of a ceramic material is filled in the heat recovery layer to increase heat transfer performance. The fuel converter of claim 4, wherein a heat transfer material made of stainless steel wool (ss-wool) is filled in the triple tube heat exchanger and the double tube heat exchanger. The fuel converter of claim 1, wherein a diffusion layer is formed between a lower end of the reformer and a lower end of the intermediate tube of the triple tube heat exchanger. 10. The fuel conversion system according to claim 9, wherein the flame of the burner is located at the boundary between the diffusion layer and the reformer catalyst layer. 10. The fuel conversion system of claim 9, wherein the catalyst layer of the reformer comprises a lower low temperature catalyst layer and an upper high temperature catalyst layer. 12. The fuel conversion system of claim 11, wherein the low temperature catalyst layer is a small amount of pretreatment catalyst layer for preventing carbon precipitation, and the high temperature catalyst layer is composed of a large amount of main reforming reaction layer. 12. The fuel conversion device of claim 11, wherein a burner flame is positioned between the low temperature catalyst layer and the high temperature catalyst layer. The fuel converter according to claim 2, wherein a heat transfer device is installed between the triple tube heat exchanger and the shear reactor of the CO transformer. The fuel conversion device of a fuel cell system according to claim 4, wherein a heat transfer device is provided between the inner tube and the outer tube of the double tube heat exchanger. The fuel cell system as set forth in claim 1, wherein an outermost tube connected to an upper end of the outer tube and a top end thereof is installed at a radially outer side of the outer tube of the triple tube heat exchanger, and a water vaporizer is installed on an outer circumferential surface of the outermost tube. Of fuel inverter. 17. The fuel conversion system of claim 16, wherein the water evaporator has a water supply port formed at a lower end thereof, a water vapor outlet formed at an upper end thereof, and the steam outlet connected to an intermediate portion of a middle tube of a triple tube heat exchanger. Device. The method according to claim 16, wherein the partition plate forming a plurality of layered flow paths are installed inside the water evaporator, a blocking plate that traverses these partition plates in the vertical direction is provided, the left and right repeats in each partition plate around the blocking plate And a moving passage is formed to form a multi-layered circulation passage. 19. The fuel cell according to claim 18, wherein the outermost tube in close contact with the water vaporizer has the same structure as the water vaporizer, and the burner combustion gas flowing therein and the water vapor of the water vaporizer form a countercurrent relationship. The fuel converter of the system. The fuel converter of claim 16, wherein a heat transfer material of a ss-wool material is installed inside the water vaporizer and the outermost tube. 19. The fuel converter of claim 18, wherein a perforated plate is provided outside the moving passages on both sides of the blocking plate. The fuel converter of claim 16, wherein a CO remover is installed in contact with an outer circumferential surface of the intermediate tube of the triple tube heat exchanger. The method of claim 22, wherein the CO remover is a cylindrical device, the modified gas inlet formed at the top is connected to the modified gas outlet of the rear stage reactor, the purge gas outlet formed at the bottom is connected to the anode of the stack, the modified gas inlet The fuel inlet of the fuel cell system, characterized in that the air inlet is formed in the previous portion of the. 23. The fuel converter of claim 22, wherein an upper and lower mounting baffles are repeatedly installed in the CO remover along the circumferential direction to form a vertical reciprocating path. The method of claim 16, wherein the water evaporator is installed on the outer peripheral surface of the outermost tube, the combustion reactant preheater for preheating the air and fuel gas supplied to the burner is installed in the lower portion, the fuel electrode of the stack on the inner peripheral surface of the outermost tube And a stack-off gas preheater for preheating the discharged off-gas. 26. The method of claim 25, wherein the combustion reactant preheater and the stack-off gas preheater have the same structure as the water evaporator, and the internal flow thereof has a reverse flow relationship with the flow of the burner combustion gas of the outermost pipe. Fuel converter of fuel cell system. 17. The fuel conversion system of claim 16, wherein the water vapor outlet of the water vaporizer is connected to a reactant inlet of the inner tube of the double tube heat exchanger. 17. The fuel conversion system of claim 16, wherein a water vapor outlet of the water vaporizer is connected to an upper end of the intermediate tube. 24. The fuel conversion system according to claim 23, wherein a water preheater is installed on the modified gas supply passage between the modified gas outlet of the CO reformer after-stage reactor and the modified gas inlet of the CO remover. 30. The fuel conversion system of claim 29, wherein a water discharge pipe of the water preheater is connected to a water supply port of the water evaporator.

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