JPH0465064A - Method of power generation of fused carbonate fuel cell - Google Patents

Abstract

PURPOSE:To make fuel for reforming unnecessary and also make a generator of steam required for reforming and the quantity of heat therefor unnecessary by causing reforming reaction by use of sensible heat and steam of anode outlet gas. CONSTITUTION:Reforming reaction is caused by use of high temperature sensible heat of anode outlet gas and steam contained therein. and further, this reformed gas is treated by a carbon dioxide separator 12 to separatedly remove a part of carbon dioxide, and thereafter, the gas is mixed with the methane in a fuel supply line 5 through a recycle line B so that it is circulatingly supplied to the anode 3 of a fuel cell 1. Unreformed fuel is thereby perfectly reformed through circulation for many times, even if the reforming rate for once by means of the reformer 7 is low, and the then required steam and quantity of heat are obtained from the anode outlet gas itself, so that the steam generator and the quantity heat therefor become unnecessary.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a power generation method using a molten carbonate fuel cell among fuel cells used in the energy sector that directly converts the chemical energy of fuel into electrical energy. It is related to.

[Prior Art] Among the fuel cells that have been proposed to date, molten carbonate fuel cells in particular use a tile (electrolyte plate), which is made by impregnating a porous material with molten carbonate as an electrolyte, to serve as an anode (fuel It is sandwiched from both sides by an electrode) and a cathode (oxygen electrode), and by supplying fuel gas to the anode side and supplying oxidizing gas to the cathode side, a reaction occurs between the anode side and the cathode side and power generation occurs. One cell is used, and each cell is laminated in multiple layers with a separator in between.

When using natural gas or city gas as fuel in the power generation system using the molten carbonate fuel cell described above, the natural gas or city gas must be reformed and supplied as fuel gas to the anode of the fuel cell. be.

As the types of reforming of natural gas, the external reforming type and the internal reforming type are conventionally known.

As shown schematically in FIG. 2, in the conventional external reforming type, when methane (CH,) is reformed and used as the fuel gas to be supplied to the anode b of the fuel cell a, methane (CH,
CH,) is put into a reformer d together with steam S, where hydrogen (H2) obtained by an endothermic reaction and -carbon oxide (Co) are
is supplied to anode b as fuel gas and partially consumed for power generation, and the 7 node log gas discharged from 7 node b is carbon dioxide gas (CO2) generated within the fuel cell.
), in addition to water (H2O), unused methane (CH4)
, hydrogen (H2), -carbon oxide (Co), so in order to introduce it into the combustion chamber of reformer d and combust it, it is supplied along with air A to the combustion chamber of reformer d through line e and combusted. The gas containing CO2 discharged from the combustion chamber of the reformer d passes through the line f, joins the air, and is sent to the cathode C to be used in the battery reaction. It is common to do something like this.

On the other hand, as an internal reforming type, as shown in Fig. 3,
There is a system in which a mixture of methane (CH,) and steam S is supplied to a reformer d in a fuel cell a so that the amount of heat required for reforming can be obtained from the cell reaction.

[Problems to be Solved by the Invention] However, in the case of the above-mentioned external reforming type, it is necessary to supply the steam necessary for the reforming reaction, so a steam generator and heat are required, and the reforming reaction requires a large amount of heat. However, since heat is also required, there is a problem in that it is not possible to increase the fuel utilization rate. On the other hand, in the case of the internal reforming type described above, although there is no fuel consumption to supply the heat necessary for reforming, it still requires the supply of steam, and this type of battery requires a high reforming rate. Although it does not increase the fuel utilization rate, it is difficult to do so because the reforming catalyst easily deteriorates, and furthermore, there is a disadvantage that the power generation efficiency is reduced because there is unused fuel in the battery.

Therefore, the present invention provides a power generation method using a molten carbonate fuel cell that can obtain the steam necessary for reforming without using a steam generator and increase the overall fuel utilization rate. This is what I am trying to do.

[Means for Solving the Problems] In order to solve the above problems, the present invention utilizes the sensible heat and water vapor of the anode exit gas of the 7-node output log gas discharged from the anode of a molten carbonate fuel cell. Then, a part of the carbon dioxide contained in this reformed gas is separated and removed, and the remaining residue is recycled and supplied to the anode as a fuel gas, and from the reformed gas. A power generation method using a molten carbonate fuel cell is characterized in that the removed carbon dioxide gas is supplied together with air to the cathode of the fuel cell.

[Function] In addition to unused fuel, hydrogen, and carbon oxide, the anode outlet gas emitted from the anode contains carbon dioxide gas and water vapor generated within the fuel cell. Modification can be carried out using sensible heat, and furthermore,
If part of the carbon dioxide gas is separated and removed from the reformed gas and the remaining gas is recycled into batteries and used for power generation, the reformation rate will be low, but as the unreformed fuel is circulated, it will be completely reformed. be able to. Also, similarly (the utilization rate of the fuel passing through the battery is low, or it can be used completely for the power generation reaction by being recycled.

[Example] Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a system configuration diagram of a power generation device used to carry out the power generation method of the present invention, in which 1 is a tile 2 impregnated with molten carbonate sandwiched between an anode 3 and a cathode 4 from both sides. A molten carbonate fuel cell, 5 is a fuel supply line, 6 is a preheater installed in the middle of the fuel supply line 5, and 7 is a reformer installed in the anode outlet gas line 8, which is connected to a reforming chamber. The fuel in the anode outlet gas is reformed using the sensible heat of the anode outlet gas and the water vapor contained in the anode outlet gas. 9 is the reformer 7 of the anode outlet gas line 8
10 is a shift converter provided downstream from the cooler 9; 11 is a cooler provided further downstream from the shift converter 10;
2 is a carbon dioxide gas separator, and the carbon dioxide gas separator 12 includes:
- As an example, 50 wt% DEA (jetanolamine)
An absorption tower 12a that uses an aqueous solution as an absorption liquid and causes the absorption liquid to absorb carbon dioxide, a regeneration tower 12b that regenerates the absorption liquid, and an absorption liquid supply line 12c that supplies the absorption liquid to the regeneration tower 12b. The absorption liquid return line 12d returns the absorption liquid regenerated in the regeneration tower 12b to the absorption tower 12a. 13 is a carbon dioxide gas separator 12 in which part of the carbon dioxide gas is separated and removed, and residual gas (including carbon dioxide gas, methane, hydrogen, etc.) taken out from the absorption tower 12a is sent to the upstream side of the preheater 6 of the fuel supply line 5. 14 is a residual gas preheater provided in the middle of the recycling line 13; 15 is an air supply pipe connected to the lower part of the regeneration tower 12b of the carbon dioxide gas separation device 12; and 16 is the carbon dioxide gas separation device 12. An air supply line takes out the air containing carbon dioxide separated from the regeneration tower 12b and supplies it to the cathode 4 of the fuel cell 1, 17 is a heat exchanger provided in the middle of the air supply line 16, and 18 is the heat exchanger. The auxiliary combustor 19 is provided on the downstream side of the fuel cell 1 and is a cathode output log gas line in which the cathode output log gas discharged from the cathode 4 of the fuel cell 1 is cooled by the heat exchanger 17 and then released into the atmosphere. be.

Now, methane (
In the case of using methane (CH4), methane (CH4) is preheated in a preheater 6, then enters the anode 3 of the fuel cell 1 through the fuel supply inlet 5, is used for an electrochemical reaction, and then passes through the anode outlet gas fin 8. is sent to the reformer 7. The anode outlet gas discharged from the anode 3 includes unused methane (CH4), hydrogen (H2), -carbon oxide (
In addition to CO), carbon dioxide gas (CO) generated within the fuel cell 1
2) Since it contains water vapor (H2O), a reforming reaction is performed in the reformer 7 using the water vapor and its own sensible heat. The gas reformed by the reformer 7 is cooled by the cooler 9, sent to the shift converter 10, and further passed to the cooler 10.
After cooling and separating water (H2O), it is sent to the absorption tower 12a of the carbon dioxide gas separation device 12. Absorption tower 12
A part of the carbon dioxide gas in the gas sent to a is absorbed and removed by contacting the absorption liquid, and a part of the carbon dioxide gas is separated and removed to remove remaining unreacted methane, unused hydrogen, etc. The residual gas contained therein is taken out from the top of the absorption tower 12a to the recycle line 13, preheated by the preheater 14, enters the upstream side of the preheater 6 of the fuel supply line 5, and is mixed with methane supplied through the fuel supply line 5. fuel cell 1
is supplied to the anode 3 of. On the other hand, the absorption liquid that has absorbed part of the carbon dioxide gas in the absorption tower 12a is supplied to the regeneration tower 12b via the absorption liquid supply line 12c, where the carbon dioxide gas is stripped by the air supplied from the air supply pipe 15. The absorption liquid from which carbon dioxide gas has been separated is returned to the absorption tower 12a through an absorption liquid return line 12d and used for absorption of carbon dioxide gas. The air containing carbon dioxide in the regeneration tower 12b is preheated in the heat exchanger 17, and further heated in the auxiliary combustor 18 to a temperature that can be supplied to the fuel cell 1.
The cathode 4 is supplied by an air supply line 16, where oxygen and carbon dioxide gas are utilized for the electrochemical reaction. Further, the cathode log gas discharged from the cathode 4 is cooled by a heat exchanger 17 and then released to the atmosphere.

In the present invention, as described above, the reformer 7 provided in the anode outlet line 8 performs a reforming reaction using the water vapor obviously contained in the high temperature anode outlet gas, and further, This reformed gas is transferred to the carbon dioxide gas separator 12
After separating and removing a part of the carbon dioxide residue, the carbon dioxide residue is mixed with methane in the fuel supply line 5 through the recycle line 13 and circulated to the anode 3 of the fuel cell 1. Even if the reforming rate at one time is low, unreformed fuel can be completely reformed by circulating it many times, and in this case, the steam and heat necessary for reforming are contained in the anode exit gas itself. Since the fuel cell 1 is used, there is no need for a steam generator and its heat capacity.
Even if the utilization rate of the fuel passing through is low at one time, it can be completely used for the power generation reaction by being recycled, so the fuel utilization rate of the entire system can be increased.

In the above, when we conducted an experiment using a normal pressure type fuel cell 1, we found that the anode outlet gas was 1°07Kg7/
When circulating at 700°C with cdA, approximately 30% of the methane in the gas is reformed by the catalytic action of the electrode at anode 3.
Further, a reforming reaction occurred in the reformer 7, and about 40% of the remaining hydrocarbons were reformed, and the temperature decreased to 571°C. When this gas was cooled to 180°C in the cooler 9 and then supplied to the shift converter 10, about 77% of the carbon monoxide underwent a metamorphosis reaction and the gas temperature rose to 275°C. Further, this gas was cooled to 40° C. with a cooler 11 to condense and remove a portion of the moisture. This gas is absorbed into absorption tower 1
2a, 43% of the carbon dioxide gas is absorbed by the absorption liquid and removed, which is then recycled and sent to the anode 3 along with the fuel.
We were able to increase the fuel utilization rate by supplying

On the other hand, the absorption liquid that has absorbed carbon dioxide gas is sent to the regeneration tower 12b to strip the carbon dioxide gas with air, and then the air containing carbon dioxide gas is heated to 477°C by exchanging heat with the cathode output log gas in the heat exchanger 17. When the fuel was further heated in the auxiliary combustor 18 and then supplied to the cathode 4, the voltage per single cell in the fuel cell 1 at this time was 728 mV on average.

In the above experimental example, a part of the reforming reaction occurs within the fuel cell 1, but the present invention can be applied regardless of the reforming reaction within the fuel cell 1, and as a carbon dioxide gas separation device, In addition to the DEA aqueous solution, other absorption liquids such as a potassium carbonate aqueous solution are used as the absorption liquid, separation membranes are used, and PSA (Pressure Swing Adso
rber), etc. may be adopted.
It goes without saying that various other changes may be made without departing from the spirit of the present invention.

[Effects of the Invention] As described above, the power generation method using a molten carbonate fuel cell of the present invention exhibits the following excellent effects.

(:) Since the reforming reaction is carried out using the gas and water vapor of the anode outlet gas, the structure of the reformer can be simplified, eliminating the need for reforming fuel, and the water vapor necessary for reforming. This makes it possible to eliminate the need for a generator and its amount of heat.

(-) Since a part of the carbon dioxide gas in the anode outlet gas is separated and removed, and the unused fuel in the battery is recycled to the battery, the fuel utilization rate in the battery in the gas passing through the battery is low. However, the fuel utilization rate of the power generation system as a whole can be increased.

(iii) Similarly to (1) above, by circulating unreformed fuel, the fuel can be completely reformed even if the reforming rate at one time is low.

Regardless of whether it is an external reforming type or an internal reforming type,
Further, a type that uses both of them can also be applied, and the system can be configured flexibly.

[Brief explanation of drawings]

FIG. 1 is a system diagram showing an example of a power generation system used to carry out the power generation method using a molten carbonate fuel cell of the present invention, FIG. 2 is a schematic diagram of a conventional external reforming fuel cell power generation system, and FIG. The figure is a schematic diagram of a conventional internal reforming type fuel cell power generation system. 1... Molten carbonate fuel cell, 3... Anode, 4
... cathode, 5 ... fuel supply line, 7 ... reformer, 8 ... anode outlet gas line, 12 ... carbon dioxide gas separation device, 13 ... recycle line, 15.
...Air supply pipe, 16...Air supply line.

Claims (1)

[Claims] (1) The anode outlet gas discharged from the anode of the molten carbonate fuel cell is subjected to a reforming reaction using the gas and water vapor contained in the anode outlet gas, and then the carbon dioxide contained in the reformed gas is A part of the gas is separated and removed, and the remaining gas is recycled and supplied to the anode,
A power generation method using a molten carbonate fuel cell, characterized in that carbon dioxide gas removed from the reformed gas is supplied together with air to the cathode of the fuel cell.