JPH0569856U - Molten carbonate fuel cell protection device - Google Patents

Abstract

(57) [Summary] [Purpose] The objective is to improve the load change rate when the load of the molten carbonate fuel cell increases. A reformer 6 for reforming a natural gas 1 to obtain a fuel gas 10, and a fuel gas 10 obtained by the reformer 6.
And a fuel cell 8 for introducing the gas to the anode 9 side, and an outlet gas 12 from the anode 9 to the reformer 6 for combustion,
A protective device for a molten carbonate fuel cell, comprising: an oxidizing gas supply flow path 13 configured to guide the burned oxidizing gas 7 to the cathode 11 side of the fuel cell 8.
And CO ₂ concentration meter 19 which detects the CO ₂ concentration in the exhaust gas 18 of the cathode 11 the delivery side of, CO from the CO ₂ concentration meter 19
_{2 When the} concentration signal 20 becomes equal to or less than the set value 21, the load increase signal 1 of the control device 16 controlling the fuel cell 8
A load limit command device 22 for fixing 7'to the current value is provided.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a protective device for a molten carbonate fuel cell.

[0002]

[Prior Art]

FIG. 4 shows an example of a conventional molten carbonate fuel cell, in which a natural gas 1 is branched by a reforming fuel flow path 2 and a temperature raising fuel flow path 3 to form a reforming fuel 4 and a temperature raising fuel. The catalyst in the reformer 6 is heated to a temperature of approximately 800 ° C. by guiding it to the reformer 6 as the fuel 5, and guiding the temperature-increasing fuel 5 to a burner (not shown) of the reformer 6 to burn it. In addition, the reforming fuel 4 is reacted with the catalyst of the reformer 6 for reforming, and the obtained fuel gas 10 such as H ₂ or CO is guided to the anode 9 side of the fuel cell 8 or burner. The oxidizing gas 7 such as CO ₂ generated by the combustion of the fuel is guided to the cathode 11 side of the fuel cell 8 to generate power. Further, the burner of the reformer 6 is designed so that the anode output side gas 12 after being introduced into the anode 9 and reacted therewith is introduced through the oxidizing gas supply passage and burned. That is, since a large amount of H ₂ and C ₂ O that have not been used for the reaction still remain in the anode outlet side gas 12, they are burned by the burner. When the temperature of the reformer 6 reaches a predetermined temperature (approximately 800 ° C.), it is possible to sufficiently maintain the temperature of the reformer 6 only by burning the anode outlet gas 12 with a burner. Therefore, the shutoff valve 14 provided in the temperature raising fuel passage 3 is closed. Therefore, the temperature-increasing fuel 5 is supplied through the temperature-increasing fuel passage 3 almost only when the reformer 6 is started.

The fuel cell 8 controls the flow rate of the fuel gas 10 and the oxidizing gas 7 according to the load command 17 from the control device 16 which receives the output command 15 and responds to the output command 15. Electricity is being generated.

[0004]

[Problems to be solved by the device]

However, in the above-mentioned conventional device, when the load (output) of the fuel cell 8 is to be increased, if the load increase width of the load command 17 is larger than a predetermined value (especially when the load changes from low load to high load). 5, the flow rate of the reforming fuel 4 introduced into the reformer 6 is immediately increased, and the flow rate of the fuel gas 10 guided to the anode 9 is increased. The outlet gas 12 from the anode 9 is introduced into the reformer 6 through the relatively long oxidizing gas supply passage 13 and burned, and the oxidizing gas 7 generated by the combustion is introduced into the cathode 11. Therefore, there is a time delay until the flow rate of the oxidizing gas 7 increases, and as a result, the CO ₂ amount A of the oxidizing gas 7 at the inlet of the cathode 11 decreases as shown in FIG. The CO ₂ amount B at the 11th exit is reduced to zero Therefore, the fuel cell 8 is operated in an abnormal state, which causes an important problem that the safety of the fuel cell 8 is impaired.

The present invention has been made in view of the above conventional problems, and an object of the present invention is to protect a fuel cell from the problem of insufficient oxidizing gas when the load of the molten carbonate fuel cell increases.

[0006]

[Means for Solving the Problems]

The present invention relates to a reformer for reforming natural gas to obtain a fuel gas, a fuel cell for introducing the fuel gas obtained by the reformer to the anode side, and a gas for exit from the anode. A protective device for a molten carbonate fuel cell, which is provided with an oxidizing gas supply flow path that guides the burned oxidizing gas to the reformer and burns it as temperature-raising fuel, and guides the burned oxidizing gas to the cathode side of the fuel cell. there are, and CO ₂ concentration meter for detecting a CO ₂ concentration of the exhaust gas in the cathode outlet side of the fuel cell, the fuel cell when the CO ₂ concentration signal from the CO ₂ concentration meter becomes under the set value or less A protection device for molten carbonate fuel cells, which is equipped with a load limit command device that fixes the load increase signal of the controlling device to the current value, and a fuel by reforming natural gas. Reformer for obtaining gas and fuel gas obtained by the reformer A fuel cell that introduces hydrogen into the anode side, and a gas that exits from the anode is introduced into the reformer and burned as a temperature-raising fuel, and the burned oxidizing gas is introduced into the cathode side of the fuel cell. A protective device for a molten carbonate fuel cell, comprising: an oxidizing gas supply flow path; and a heat recovery device for recovering heat by introducing an oxidizing gas from the cathode, the exhaust gas on the cathode outlet side of the fuel cell. A CO ₂ concentration meter for detecting the CO ₂ concentration of the gas, and when the CO ₂ concentration signal from the CO ₂ concentration meter falls below a set value, the fuel gas and the oxidizing gas are switched to the bypass flow passages to the fuel cell. And a stop command device for stopping the operation of the fuel cell by cutting off the supply of the fuel.

[0007]

[Action]

According to the first aspect of the present invention, when the CO ₂ concentration of the oxidizing gas on the cathode output side becomes lower than the set value, the load limit command device outputs the load increase signal input from the control device to the fuel cell at that time. The CO ₂ concentration is controlled to be fixed to prevent the CO ₂ concentration from further decreasing. When the CO ₂ concentration rises, the control of the fuel cell by the load increase signal is restarted again to protect the fuel cell from the problem due to the shortage of oxidizing gas.

According to the second aspect of the invention, when the CO ₂ concentration of the oxidizing gas on the cathode outlet side becomes equal to or lower than the set value, the stop command device is activated to supply the fuel gas and the oxidizing gas supplied to the fuel cell, respectively. By switching to the bypass flow path, the supply to the fuel cell is cut off, and the operation of the fuel cell is stopped, thereby protecting the fuel cell from problems due to lack of oxidizing gas.

[0009]

【Example】

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

FIG. 1 shows an embodiment of the invention of claim 1 applied to the molten carbonate fuel cell shown in FIG. 4, and the same reference numerals as those in FIG. 4 are the same. , And detailed description is omitted.

[0011] As shown in FIG. 1, the outlet side of the cathode 11 of the fuel cell 8, the CO ₂ concentration meter 19 which detects the CO ₂ concentration in the exhaust gas 18 after the reaction at the cathode 11 is provided, further, the CO _A load limit command device 22 is provided for inputting a CO ₂ concentration signal 20 from a ₂ concentration meter 19 and a set value 21. The load limit command device 22 shows a load increase signal 17 'according to the load command 17 of the control device 16 controlling the fuel cell 8 when the CO ₂ concentration signal 20 becomes equal to or less than the set value 21 in FIG. Thus, the load limit command signal 23 fixed to the current value a is output to the control device 16.

When the control device 16 outputs the load increase signal 17 ′ to the fuel cell 8, the fuel gas 10 from the reformer 6 is increased in a short time, but the oxidizing gas 7 is supplied to the fuel cell 8. After reacting through the anode 9, it is guided to the cathode 11 via the long oxidizing gas supply flow path 13, so that there is a time delay, and therefore, the oxidizing gas 7 tends to be insufficient in the cathode 11.

At this time, the CO ₂ concentration of the oxidizing gas 7 is detected by the CO ₂ concentration meter 19. Therefore, when the detected CO ₂ concentration signal 20 falls below the set value 21, the load limit command device 22 The load limit command signal 23 is output to the control device 16 so that the load increase signal 17 ′ input to the fuel cell 8 from the control device 16 is controlled to be fixed to the value a at that time. As a result, the CO ₂ concentration is prevented from further decreasing and the amount of the oxidizing gas 7 increases with the passage of time. Therefore, if the CO ₂ concentration rises above the set value 21, the fuel consumption by the load increase signal 17 ′ is restarted. The battery 8 is controlled. As a result, the fuel cell 8 can be protected from the problem caused by the shortage of the oxidizing gas 7.

FIG. 2 shows an embodiment of the invention of claim 2, in which power is generated by the fuel cell 8 and the exhaust gas 18 on the outlet side of the cathode 11 is guided to a heat recovery device 24 such as a boiler to recover heat. The present invention is applied to an electric / heat parallel supply type fuel cell 8 configured as described above, and such an electric / heat parallel supply type fuel cell 8 is generally regarded as a relatively small device for business establishments and homes. Mainly considered. In such an electric / heat parallel supply type fuel cell 8, it is difficult to inspect and repair immediately even if something goes wrong. Therefore, when the deficiency of the oxidizing gas 7 occurs, the fuel cell It is possible to stop the operation of No. 8.

[0015] Figure 2 has been made based on this thinking, the cathode 1 1 of the outlet side of the fuel cell 8, the CO ₂ concentration meter for detecting a CO ₂ concentration of the exhaust gas 18 after the reaction at the cathode 11 Further, a stop command device 25 for inputting a CO ₂ concentration signal 20 from the CO ₂ concentration meter 19 and a set value 21 is provided. Further, a fuel gas flow path 26 for supplying the fuel gas 10 to the fuel cell 8 is provided with a fuel gas bypass flow path 28 which can bypass the anode 9 and can be switched by a switching valve 27, and the oxidizing gas supply flow The passage 13 is provided with an oxidizing gas bypass passage 30 that can bypass the cathode 11 and can be switched by the switching valve 29. When the CO ₂ concentration signal 20 becomes equal to or less than the set value 21, the stop command device 25 switches to the bypass flow passages 28 and 30, respectively, and shuts off the supply of the fuel gas 10 and the oxidizing gas 7 to the fuel cell 8. As described above, the switching command signal 31 is output to the switching valves 27 and 29, and the stop signal 32 is simultaneously output to the control device 16 and the reformer 6 to stop the supply of the natural gas 1. The operation of the reformer 6 is stopped. As a result, the operation of the fuel cell 8 is stopped (tripped).

When the load increase signal 17 ′ is commanded from the control device 16 to the fuel cell 8, the oxidizing gas 7 introduced to the cathode 11 tends to be insufficient.

At this time, since the CO ₂ concentration of the oxidizing gas 7 is detected by the CO ₂ concentration meter 19, when the CO ₂ concentration becomes lower than the set value 21, the stop command device 25 sends the switching command signal 31 to the switching valve 31. 27 and 29 to switch the oxidizing gas supply flow path 13 and the fuel gas flow path 26 to the bypass flow paths 28 and 30, respectively, whereby the fuel gas 10 and the oxidizing gas 7 are supplied to the fuel cell 8. The fuel cell 8 is shut off and the operation of the fuel cell 8 is stopped. At the same time, the stop signal 32 is output to the control device 16 and the reformer 6 to stop the operation of the reformer 6, and the fuel cell 8 is protected from the problem due to the shortage of the oxidizing gas.

It should be noted that the present invention is not limited to the above-mentioned embodiments, and it goes without saying that various modifications can be made without departing from the gist of the present invention.

[0019]

[Effects of the Invention] According to the protection device for molten carbonate fuel cells of the present invention described above, the fuel cell can be safely operated even if the problem of insufficient oxidizing gas supplied to the fuel cell at the time of load increase occurs. It can exert an excellent effect that can be protected.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of claim 1 of the present invention.

FIG. 2 is a block diagram showing an embodiment of claim 2 of the present invention.

FIG. 3 is a diagram showing the operation of FIG.

FIG. 4 is a block diagram showing an example of a conventional molten carbonate fuel cell.

FIG. 5 is a diagram showing an operation of a conventional device.

[Explanation of symbols]

1 Natural Gas 6 Reformer 7 Oxidizing Gas 8 Fuel Cell 9 Anode 10 Fuel Gas 11 Cathode 12 Anode Outlet Gas 13 Oxidizing Gas Supply Flow Path 16 Controller 17 'Load Increase Signal 18 Exhaust Gas 19 CO ₂ Concentration Meter 20 CO ₂ Concentration signal 21 Set value 22 Load limit command device 25 Stop command device 28 Fuel bypass flow passage 30 Oxidizing gas bypass flow passage a Current value

Claims (2)

[Scope of utility model registration request] 1. A reformer for reforming natural gas to obtain a fuel gas, a fuel cell for introducing the fuel gas obtained by the reformer to an anode side, and an outlet gas from the anode. A protective device for a molten carbonate fuel cell, comprising: an oxidizing gas supply flow path, which is guided to the reformer and burned as a temperature-raising fuel, and the burned oxidizing gas is guided to the cathode side of the fuel cell. there are, and CO ₂ concentration meter for detecting a CO ₂ concentration of the exhaust gas in the cathode outlet side of the fuel cell, controlling the fuel cell when the CO ₂ concentration signal from the CO ₂ concentration meter becomes less than the set value A protection device for a molten carbonate fuel cell, comprising a load limit command device for fixing a load increase signal of a control device being operated to the current value. 2. A reformer for reforming natural gas to obtain a fuel gas, a fuel cell for introducing the fuel gas obtained by the reformer to the anode side, and an outlet gas from the anode. An oxidizing gas supply flow path for guiding the reformed oxidizing gas to the reformer and burning it as a temperature raising fuel, and guiding the burned oxidizing gas to the cathode side of the fuel cell, and introducing the oxidizing gas from the cathode to recover heat. a protective apparatus for molten carbonate fuel cell comprising a heat recovery device for performing a CO ₂ concentration meter for detecting a CO ₂ concentration of the oxidizing gas in the cathode outlet side of the fuel cell, the CO ₂ concentration meter A stop command device for stopping the operation of the fuel cell by switching the fuel gas and the oxidizing gas to the bypass flow passages and cutting off the supply to the fuel cell when the CO ₂ concentration signal from Molten carbonic acid characterized by having Type fuel cell of the protection device.