KR20140038007A - Fuel cell system with structure for enlarging combustion limitation of combustor - Google Patents

Abstract

Disclosed is a fuel cell system with a structure for enlarging a combustion limitation. The fuel cell system comprises the following: a fuel cell; a reformer supplying hydrogen into the fuel cell through a hydrogen supply line; a combustor supplying heat to the reformer, and installed on an exhaust gas line connected to a fuel electrode of the fuel cell; and a moisture removal unit supplied to the exhaust gas line in between the fuel cell and the combustor. The moisture removal unit includes a cooling unit for cooling exhaust gas using a heat exchanging method, and a gas-water separator separating and discharging condensed water obtained by condensing the exhaust gas using the cooling unit. [Reference numerals] (AA) Supply heat

Description

TECHNICAL FIELD [0001] The present invention relates to a fuel cell system having a flammable limit expansion structure of a combustor,

The present invention relates to a fuel cell system, and more particularly, to a fuel cell system having a flammable limit expansion structure of a combustor.

As is well known, a fuel cell is a hydrogen-oxygen fuel cell, which generates electric power through an electrochemical reaction between a fuel and an oxidant by inputting a fuel and an oxidant.

Among these fuel cells, the high-temperature type fuel cell has a high operating temperature range so that the reaction rate can be increased without expensive catalyst, and the inherent simplicity of fuel cell concept can be effectively utilized.

Generally, in a power generation system that produces electricity through a high temperature type fuel cell, that is, a fuel cell system, due to technical limitations, the fuel supplied to the stack does not react 100%, and the fuel corresponding to about 20% to 40% And is discharged to the outlet of the stack. The unburned fuel mixed with the reactant is a lean fuel containing a large amount of steam, so it is difficult to increase the energy utilization of the fuel by directly burning it.

As a method for enhancing the energy utilization of such fuel, there is a method of adding fuel to a portion where unburned fuel is discharged and burning, and a method of installing a reactor using a catalyst. However, in the former case, the efficiency of the fuel cell system is very low. In the latter case, the catalyst temperature is limited to 800 ~ 900 ^° C, .

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a fuel cell system in which the combustible limit of a combustor is extended by increasing the concentration of unburned fuel among the exhaust gas emitted from the fuel electrode outlet of the fuel cell .

Another problem to be solved by the present invention is to use a plurality of heat exchangers in the process of removing steam in the exhaust gas from the outlet of the anode and to use the heat obtained from the plurality of heat exchangers as a heat source for heating the fluid in the system, And to provide a fuel cell system having improved utility.

According to an aspect of the present invention, there is provided a fuel cell system having a flammable limit expansion structure of a combustor. The fuel cell system includes: a fuel cell; A reformer for supplying hydrogen to the fuel cell through a hydrogen supply line; A combustor installed in an exhaust gas line connected to the fuel electrode of the fuel cell and supplying heat to the reformer; And a water removal unit provided in the exhaust gas line between the fuel cell and the combustor, wherein the water removal unit includes: a cooling water step for cooling the exhaust gas by a heat exchange method; and a condensate water condensed by the cooling means, And a water separator for separating the water from the exhaust gas.

According to one embodiment, the cooling means includes a first heat exchanger for heat exchange between water and fuel supplied to the combustor and the exhaust gas, and a second heat exchanger located between the first heat exchanger and the water separator, And a second heat exchanger for performing heat exchange between the supplied air and the exhaust gas.

According to one embodiment, the condensed water separated by the water separator can be recycled so that it can be used as water supplied to the reformer together with the fuel.

According to one embodiment, a branch line is branched out from an air discharge line connected to the cathode of the fuel cell, the branch line is connected to a mixer between the water separator and the combustor, and the condensate is removed from the mixer Gas and air discharged from the air electrode are mixed and supplied to the combustor.

According to one embodiment, the air supplied to the fuel cell passes through the first heat exchanger, the exhaust-side heat exchanger of the exhaust gas, and the heat exchanger on the exit side of the air electrode of the fuel cell in turn.

According to another aspect of the present invention, there is provided a fuel cell system having a flammable limit expansion structure of a flame combustor, the fuel cell system comprising: a fuel cell; A reformer for supplying hydrogen to the fuel cell through a hydrogen supply line; A flame combustor installed on an exhaust gas line connected to the fuel electrode of the fuel cell and supplying heat to the reformer; A water removal unit provided on the exhaust gas line between the fuel cell and the flame combustor; And a branch line branched from an air discharge line connected to the air electrode of the fuel cell and connected between the water separator and the flame combustor.

At this time, the water removing unit includes a water heat exchanger, a water heat exchanger, a water heat exchanger, and a water heat exchanger, A second heat exchanger through which the exhaust gas line passes, and a water separator for separating and discharging the condensed water in the exhaust gas condensed while passing through the first heat exchanger and the second heat exchanger .

According to the present invention, it is possible to greatly expand the combustible limit of the combustor by increasing the concentration of the unburned fuel in the exhaust gas from the fuel electrode outlet of the fuel cell. By this method, the exhaust gas can be directly combusted without additional fuel supply , The use of the catalyst does not take into account the operating temperature limit due to the durability of the catalyst during combustion. Therefore, the efficiency of the fuel cell system can be improved by utilizing the thermal energy of the fuel. That is, the fuel gas outlet gas contains at least 60% water vapor and at least 30% carbon dioxide. Make conditions that allow direct combustion.

 Further, the present invention uses first and second heat exchangers together with a water separator, instead of using a condenser, in removing water from the exhaust gas. In this case, the heat of the anode outlet gas, that is, And can be used as a heat source necessary for operation of the fuel cell system. Therefore, utilization of heat is improved in terms of efficiency of the fuel cell system.

Effects according to the features of the present invention are listed as follows.

(1) Unburned fuel contained in the outlet gas of the fuel cell can be directly flame burned without additional fuel supply.

(2) High temperature heat can be recovered to the fuel cell system by condensing the anode outlet gas through a plurality of heat exchangers.

(3) The efficiency of the fuel cell system is increased by recirculating the separated condensed water through the water separator as feed water for the reformer.

The present invention can also be advantageously applied to the following applications.

(1) High-efficiency combustion by improving the fuel concentration of low-grade synthesis gas

(2) It is possible to burn low-grade gas which can not be combusted by ordinary air combustion method

(3) Recovery of waste heat through fuel concentration improvement process

1 is a view illustrating a fuel cell system according to an embodiment of the present invention,
FIG. 2 is a block diagram showing the main configuration of the fuel cell system shown in FIG. 1. FIG.

 Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided as examples for allowing a person skilled in the art to sufficiently convey the idea of the present invention. Therefore, the present invention is not limited to the embodiments described below, but may be embodied in other forms.

FIG. 1 is a block diagram illustrating a fuel cell system according to an embodiment of the present invention, and FIG. 2 is a block diagram illustrating a main configuration of the fuel cell system shown in FIG. 1. Referring to FIG.

1 and 2, a fuel cell system according to an embodiment of the present invention includes a fuel cell 2, a reformer for supplying hydrogen to the fuel cell 2 via a hydrogen supply line 101, (3), a flame combustor (4) installed on an exhaust gas line (102) connected to the fuel electrode of the fuel cell (2), and the like.

The fuel cell system according to the present embodiment also includes water and a fuel supply unit 6 that supplies water and fuel mixed with each other through the water and fuel supply line 103 to the reformer 5. The water and fuel supply unit 6 includes a mixer 66 for mixing the fuel supplied through the fuel compressor 62, the water pump 64 and the fuel compressor 62 via the water pump 64 ).

Also, the fuel cell system according to the present embodiment includes an air compressor 7, and the compressed air from the air compressor 7 is supplied to the air electrode of the fuel cell 2 through the air supply line 104.

The fuel cell system according to the present embodiment also includes a water removal unit 8 provided on the exhaust gas line 102 between the fuel cell 2 and the flame combustor 4. The water removal unit 8 includes a heat exchanger 81a and 81b for cooling the fuel electrode exhaust gas to condense water vapor in the exhaust gas and a water separator 82 for removing moisture generated by the condensation do.

The heat exchangers 81a and 81b of the water removal unit 8 include a first heat exchanger 81a and a second heat exchanger 81b which are sequentially installed toward the downstream side of the exhaust gas line 3 . The water separator 82 removes moisture in the fuel electrode exhaust gas cooled and condensed while passing through the first and second heat exchangers 81a and 81b. The second heat exchanger 81b, the flame combustor 81b, (4).

A high temperature (approximately, 800 ~ 900 ℃) from the fuel electrode of the fuel cell 2 is the reaction of the exhaust gas in the exhaust, the exhaust gas is about _{H 2 O 60%, CO 2} 32%, CO, H 2, CH 4 8 %. ≪ / RTI > Therefore, in order to increase the concentration of the fuel component, the inert gas, which occupies the largest volume, must be removed.

As described above, the water removal unit 8 does not use the condenser, but instead cools the exhaust gas in the first and second heat exchangers 81a and 81b to condense steam in the exhaust gas, And the downstream water separator 82 at the downstream side of the second heat exchangers 81a and 81b. The structure of the water removal unit 8 is not limited to the function of removing moisture, but may also be provided with heat of a proper temperature in the first and second heat exchangers 81a and 81b for a fluid for which a temperature rise in the system is required, .

The first heat exchanger 81a is installed in a section where the discharge gas line 102 and the water and the fuel supply line 103 are thermally contacted with each other and heat exchange is performed on the upstream side with respect to the second heat exchanger 81b . The exhaust gas line 102 and the water and fuel supply line 103 are exchanged between the water and the fuel and the exhaust gas while passing through the first heat exchanger 81a, And the water and the fuel are heated and their temperature rises.

The second heat exchanger 81b is installed in a region downstream of the first heat exchanger 81a where the exhaust gas line 102 and the air supply line 104 are thermally exchanged and heat exchange is performed do. The exhaust gas line 102 and the air supply line 104 are exchanged between air at room temperature and the exhaust gas while passing through the second heat exchanger 81b and the exhaust gas is secondarily cooled, And the temperature of the air rises to a temperature higher than the ambient temperature. Such an arrangement provides the advantage of omitting the additional heat source required to evaporate the water supplied with the fuel or to preheat the air.

As described above, the anode outlet gas, that is, the exhaust gas cooled through the first and second heat exchangers 81a and 81b flows into the above-described water separator 82 and flows into the gas containing condensed water and unburned fuel The water removal rate of the water separator 82 is about 80% or more, and a large amount of water vapor can be removed, and the concentration of the unfired fuel of the fuel outlet gas, that is, the exhaust gas, can be greatly increased.

The water separator 82 may be configured to separate and remove moisture contained in the steam generated in the nose drum. The separation of the water is performed by changing the direction of the steam flow, centrifugal force action, impact action, and the like. As the water separator 82, various structures such as a centrifugal water separator and an inverted water separator can be used.

The condensed water separated from the exhaust gas through the water separator 82 may be discharged out of the system or recycled since it is usable as water supplied to the reformer 3.

On the other hand, the fuel cell system according to the present embodiment includes an air discharge line 105 connected to the air pole of the fuel cell 2, and the three-way valve 9 on the air discharge line 105 connects the branch line 105a are branched from the air discharge line 105 and connected to the mixer 10 between the water separator 82 of the water removal unit 8 and the flame burner 4. [ In the mixer 10, the gas from which the condensed water has been removed, that is, the gas containing the unburned fuel, is mixed with the air (oxidant) discharged from the air electrode and supplied to the flame combustor 4, thereby directly burning.

Therefore, the fuel electrode exhaust gas can be directly combusted in the flame burner 4, and thus the advantage that the flame burner 4 can be operated at a higher temperature (1000 to 1300 ° C) than the operating temperature (850 ° C) of the existing catalyst combustor have. Further, in the operation of the flame burner 4, since no additional fuel is supplied, the efficiency of the fuel cell system can be further improved.

The water and the fuel are sufficiently heated to a high temperature suitable for being supplied to the reformer 3 while passing through the first heat exchanger 81a and passing through the heat exchanger 11 on the downstream side of the flame combustor 4 . The exhaust gas heat exchanger 12 of the exhaust gas passes through the above-described air supply line 104 and thus the temperature of the first preheated air passes through the second heat exchanger 81b of the water removal unit 8 It is heated by secondary heating. The air supply line 104 is finally supplied to the fuel cell 2 after passing through the heat exchanger 13 on the air discharge line 105.

2: Fuel cell 3: Reformer
4: combustor (flame combustor) 6: water and fuel supply unit
7: air compressor 8: water removal unit
81a, 81b: Heat exchanger of the water removal unit
82: water separator

Claims (7)

Fuel cells;
A reformer for supplying hydrogen to the fuel cell through a hydrogen supply line;
A combustor installed in an exhaust gas line connected to the fuel electrode of the fuel cell and supplying heat to the reformer; And
And a moisture removal unit provided in the exhaust gas line between the fuel cell and the combustor,
Wherein the water removal unit includes a cooling water step for cooling the exhaust gas by a heat exchange method and a water separator for separating condensed water generated by the cooling means from the exhaust gas. The cooling device according to claim 1,
A first heat exchanger in which heat exchange is performed between water and fuel supplied to the combustor and the exhaust gas;
And a second heat exchanger positioned between the first heat exchanger and the water separator and performing heat exchange between the air supplied to the fuel cell and the exhaust gas. The fuel cell system according to claim 1, wherein the condensed water separated by the water separator is recirculated so that it can be used as water supplied to the reformer together with the fuel. The fuel cell system according to claim 1, wherein a branch line is branched out from an air discharge line connected to the air electrode of the fuel cell, the branch line is connected to a mixer between the water separator and the combustor, And air discharged from the air electrode are mixed and supplied to the combustor. The fuel cell system according to claim 2, wherein the air supplied to the fuel cell passes through the first heat exchanger, the exhaust-side heat exchanger of the exhaust gas, and the heat exchanger on the exit side of the air electrode of the fuel cell in order. Fuel cells;
A reformer for supplying hydrogen to the fuel cell through a hydrogen supply line;
A flame combustor installed on an exhaust gas line connected to the fuel electrode of the fuel cell and supplying heat to the reformer;
A water removal unit provided on the exhaust gas line between the fuel cell and the flame combustor; And
And a branch line branched from an air discharge line connected to the air electrode of the fuel cell and connected between the water separator and the flame combustor. The water treatment system according to claim 6,
A water and fuel supply line for supplying water and fuel to the flame combustor, and a first heat exchanger through which the exhaust gas line passes;
A second heat exchanger positioned between the first heat exchanger and the water separator and passing through the air supply line for supplying air to the fuel cell and the discharge gas line,
And a water separator for separating and discharging condensed water in the discharged gas condensed while passing through the first heat exchanger and the second heat exchanger.

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