JP5157489B2 - Method for determining retention of generated water in fuel cell system and method for responding to retention of generated water - Google Patents

Description

  The present invention relates to a determination method for quickly and safely determining whether or not a cause of power generation failure of a solid polymer electrolyte fuel cell is caused by retention of water generated in an oxidant gas flow path. It relates to a handling method after the determination.

  A solid polymer electrolyte fuel cell forms a thin film electrode assembly in which an ion exchange membrane of a solid polymer is sandwiched between electrodes made of a conductive porous body, and the thin film electrode assembly is sandwiched between two conductive separators. A solid polymer electrolyte fuel cell (hereinafter referred to as a cell) is formed, and a plurality of such cells are stacked to form a solid polymer electrolyte fuel cell stack (hereinafter referred to as a cell stack).

The conductive separator constituting the cell has a fuel gas flow path (anode side) and an oxidant gas flow path (cathode side) formed on both sides of the thin film electrode assembly. Hydrogen (H ₂ ) in the fuel gas supplied to the flow path passes through the electrode made of a conductive porous material and is ionized in the anode-side catalyst layer on the ion exchange membrane, so that hydrogen ions (H ⁺ ) and electrons ( e ^-) to become.
The hydrogen ions (H ⁺ ) move through the ion exchange membrane to the cathode side with the intervention of water, and the electrons (e ⁻ ) pass through the external load because the ion exchange membrane is a nonconductor. It moves to the electrode which consists of a conductive porous body.
The oxidant gas flow path on the cathode side of the cell is supplied with an oxidant gas via an oxidant gas supply line, and oxygen (0 ₂ ) in the oxidant gas and electrons (e ⁻ ) moving to the cathode side are supplied. ) And hydrogen ions (H ⁺ ) chemically react in the cathode catalyst layer on the ion exchange membrane to generate water.
And the unreacted gas which did not raise | generate a chemical reaction within a cell can be continuously discharged | emitted from a fuel gas discharge line and an oxidizing gas discharge line, respectively.

Thus, when hydrogen ions (H ⁺ ) react with oxygen (0 ₂ ) and electrons (e ⁻ ) in the oxidant gas, the electrons (e ⁻ ) are directed to the cathode side electrode via an external load. Therefore, this can be used as a direct current, and when a high-voltage direct current is taken out, the expected high voltage can be obtained by stacking a plurality of cells to form a cell stack.

  A DC-AC inverter that converts a direct current into an alternating current or a power utilization device is connected as a load on the output power line connected to the output terminal of the cell stack, and in many cases, power that passes through the DC-AC inverter The electric power company's grid power is also connected to the equipment used, and a fuel cell system that can use power simultaneously by selecting the cell stack and the grid power of the power company or by performing grid interconnection is obtained.

Since this series of chemical reactions is an exothermic reaction, the temperature of the cell stack increases with power generation. Each cell becomes hot due to the heat generated in the cell stack. Therefore, a cooling water circulation channel for extracting heat energy is arranged in the cell stack, and this cooling water circulation channel is a circulating water tank configured to be able to use heat. By operating a circulating water pump installed on the circulating water line, the inside of the cell stack is cooled and the thermal energy generated by the chemical reaction is taken out.
Therefore, a cogeneration system (hereinafter referred to as a fuel cell cogeneration system) using this cell stack brings work by electric energy to the outside by this electron transfer, and at the same time, recovers and uses heat generated by a chemical reaction as heat energy. System.

  The problem with the operation of this solid polymer electrolyte fuel cell cogeneration system is that the generated water generated in the oxidant gas flow path due to the chemical reaction described above stays in the oxidant gas flow path of the cell. It is a power generation failure trouble that occurs in Japan.

  As described above, by supplying fuel gas and oxidant gas to the anode side and cathode side catalyst layers on the ion exchange membrane of the cell stack, the cell stack generates electric energy. On the oxidant gas flow path on the cathode side, water generated by a chemical reaction is generated. Normally, the generated product water is included in the unreacted gas in the oxidant gas as water vapor, or is swept away on the oxidant gas flow path by the pressure of the gas flowing through the oxidant gas flow path. To be discharged.

  However, when the power generation output of the cell stack is large, the amount of water generated is large, and the generated water cannot be discharged by the above-described method. As a result, the generated water remains on the oxidant gas flow path. If the oxidant gas flow path is blocked due to the retention of the generated water, the oxidant gas is not supplied any further, so that no chemical reaction occurs, and eventually the power generation of the cell stops. This will cause a problem of accumulated water.

  Further, it is the humidification of the fuel gas and the oxidant gas by the fuel gas humidifier and the oxidant gas humidifier that contributes to the trouble of staying in the generated water.

The fuel gas and the oxidant gas supplied to the cell are humidified by the fuel gas humidifier and the oxidant gas humidifier arranged in the fuel gas supply line and the oxidant gas supply line. By humidifying the agent gas, ionization of hydrogen (H ₂ ) is promoted, and further, resistance when hydrogen ions (H ⁺ ) pass through the polymer ion exchange membrane is reduced. Therefore, hydrogen from the anode to the cathode is reduced. The movement of ions (H ⁺ ) is facilitated, and in addition, the chemical reaction on the cathode side is also promoted.

  For this reason, humidifying the fuel gas and oxidant gas has been established as one method for greatly increasing the power output and power generation efficiency of the cell stack. In general, a fuel gas humidifier and an oxidant gas humidifier are provided respectively.

  However, while the amount of water vapor in each gas increases, the amount of water that can be taken into the gas as water vapor at a certain pressure and temperature, that is, the amount of saturated water vapor, is determined. In the oxidant gas flow channel located on the cathode side where water is generated by chemical reaction by humidification, the ability to take the generated water generated after the chemical reaction into the unreacted gas as water vapor and discharge it outside the cell As a result, the generated water stays in the oxidant gas flow path and the trouble of the oxidant gas passage obstruction easily occurs.

In addition, in a cell stack in which a plurality of cells are stacked, since the gas flow paths of the cells exist in parallel, due to causes such as an increase in the power output of the cell stack or an increase in the amount of humidification of the fuel gas, The amount of product water that cannot be discharged at the cathode increases.
If the generated water once stays in the cathode and closes the oxidant gas flow path of a certain cell, the supply amount of the oxidant gas is temporarily reduced as a method for solving the conventional generated water retention trouble. By increasing the pressure, the internal pressure of the oxidant gas flow path is increased to push out the accumulated generated water.
When this method is used, in a cell stack in which a plurality of cells are stacked, the gas flow paths of each cell exist in parallel, so that the oxidant gas flows through the oxidant gas flow paths of other cells. Therefore, it is difficult to eliminate the accumulated product water by extrusion, and since power generation continues at this time, water continues to be generated in the cell stack, and eventually the generated water cannot be completely eliminated. There are many cases where the power generation capacity of the cell cannot be recovered.

The present invention is for solving the problem related to the retention of the generated water in the oxidant gas flow path, and the method for determining the retention of the generated water in the fuel cell system is as follows:
Solid polymer electrolyte fuel cell in which a conductive separator in which a fuel gas channel and an oxidant gas channel are formed is arranged on both sides of a thin film electrode assembly in which an ion exchange membrane is sandwiched between electrodes made of a conductive porous material A cell (hereinafter referred to as a cell) is provided, and a plurality of the cells are stacked to form a solid polymer electrolyte fuel cell stack (hereinafter referred to as a cell stack), and a hydrogen-rich fuel is provided in the fuel gas flow path of the cell stack. A fuel gas supply line for supplying gas, an oxidant gas supply line for supplying an oxidant gas containing oxygen to an oxidant gas flow path of the cell stack, and a fuel gas supply line for humidifying the fuel gas and the oxidant gas In addition, the fuel gas humidifier and the oxidant gas humidifier respectively provided in the oxidant gas supply line and the unreacted gas that has not reacted in the cell stack are discharged. A circulating water line for supplying circulating water from a circulating water tank to a cooling water circulation passage disposed in the cell stack, and the circulation water line and the cooling water circulation passage. And a circulating water pump installed on the circulating water line for forcibly circulating the circulating water, and a load including a DC-AC inverter is connected to the output power line for extracting power from the cell stack, and the cell A fuel cell system in which a cell stack cutoff relay is arranged on an output power line between a stack and a load, and a cell voltage monitoring monitor is connected to a voltage detection terminal of a cell constituting the cell stack. When the cell voltage monitor detects an abnormal cell whose voltage drops below the set value, the fuel cell system
(1) Open the cell stack cut-off relay to stop the power supply to the load,
(2) Stop the supply of fuel gas to the fuel gas supply line,
(3) The oxidant gas supply line supplies oxidant gas that has not been humidified by the oxidant gas humidifier,
(4) Circulating high temperature circulating water from the circulating water line to the cell stack,
Switching to the retained generated water removal mode operation, performing the retained generated water removal mode operation for a predetermined time, and then returning to the normal power generation operation. In the normal power generation operation after the return, the cell voltage monitoring monitor detects the voltage of the abnormal cell. The drop is monitored, and when the voltage drop of the abnormal cell is not detected, it is determined that the previous voltage drop is the retention of the generated water.

  Further, in the normal power generation operation after returning from the accumulated product water removal mode operation, the amount of humidification by the fuel gas humidifier and the oxidant gas humidifier in the fuel gas supply line and the oxidant gas supply line is reduced. In the preferred embodiment, the cell voltage monitor monitors the voltage drop of the abnormal cell by increasing the temperature of the circulating water circulating to the cooling water circulation passage in the cell stack.

  Furthermore, in the generated water retention determination method of the fuel cell system, the cell voltage monitoring monitor monitors the voltage drop of each cell during normal power generation operation after recovery, and when a voltage drop of a cell other than an abnormal cell is detected. Then, after switching to the accumulated product water removal mode operation and operating for a predetermined time, the operation returns to the normal power generation operation to determine the product water retention, and when the abnormal cell voltage drop is not detected, the normal power generation operation is continued. When the voltage drop is detected, the subsequent operation of the fuel cell system is stopped.

  A solid polymer electrolyte fuel cell has a conductive separator in which a fuel gas channel and an oxidant gas channel are formed on both sides of a thin film electrode assembly in which an ion exchange membrane is sandwiched between electrodes made of a conductive porous material. A cell is formed by arranging, and a hydrogen-rich fuel gas and an oxidant gas containing oxygen are supplied to the cell to generate power. By stacking a plurality of cells, a desired voltage can be obtained. A cell stack is configured, and a fuel cell cogeneration system is realized using the cell stack.

In this fuel cell cogeneration system, if one of the cells that make up the cell stack experiences a power generation failure during power generation operation and the cell voltage drops abnormally, a cell voltage monitoring monitor connected to the voltage detection terminal of each cell When this voltage abnormality is detected, the cell stack cut-off relay is activated to electrically cut off the load from the cell stack. At the same time, the supply of fuel gas to the cell stack is stopped, and the dry oxidant that does not go through the oxidant gas humidifier Only gas is supplied to the cell stack.
In addition, the circulating water heater that heats the circulating water that is supplied to the cooling water circulation channel that recovers the amount of heat generated in the cell stack is activated to circulate high-temperature circulating water in the cell stack, and normal power generation is performed in the cell stack. It is maintained at a high temperature like driving.
In this way, in the retained product water removal mode operation, if the supply of fuel gas is stopped and the power generation function is lost, there is no increase in product water, and if the power generation failure of the cell is due to the product water retention, the oxidant gas The generated water blocking the flow path is heated by the high-temperature circulating water, and vaporization is promoted by the dry, non-humidified oxidant gas sent to the oxidant gas flow path. It was possible to remove it with the gas out of the cell stack.
For this reason, it was possible to eliminate the retention of the produced water more reliably and more quickly than the conventional method of increasing the supply amount of the oxidant gas while continuing the power generation.

In this invention, after returning to the normal power generation operation after the end of the staying water removal mode operation, the voltage drop of the abnormal cell in the cell stack is continuously monitored by the cell voltage monitoring monitor, and the staying water removal mode operation is performed. Judgment whether or not the cause of starting was a trouble due to stay of generated water can be made by detecting the voltage of the abnormal cell by the cell voltage monitoring monitor after returning to the normal power generation operation.
And since the accumulated product water is discharged by the accumulated product water removal mode operation, if the voltage abnormality is not detected at the time of detecting the voltage of the cell that has become abnormal by the cell voltage monitoring monitor earlier, It can be judged that the cause was a trouble caused by the retention of generated water.

In addition, when the cause of starting the retained product water removal mode operation is a trouble due to product water retention, the normal humidification amount and cell stack temperature of the normal power generation operation from the stay product water removal mode operation to the previous When returning to power generation, the cell voltage monitoring monitor temporarily detects that the cell voltage value is within the normal range, but the root cause of the trouble due to accumulated water is solved while it continues to return to normal for a certain period of time. Therefore, the cause of the abnormal drop in cell voltage may not be known, and the same cell may repeatedly cause an abnormal drop in voltage.
At this time, it is determined that the cause of the abnormal drop in the cell voltage is due to a failure other than the retention of the generated water, and the cause will be found by disassembling the cell stack, but the failure part is not found, eventually, In some cases, it was estimated that this was a trouble due to product water retention and reuse was started.

In the present invention, in the normal power generation operation after returning from the retained product water removal mode operation, the humidification amount of the fuel gas and the oxidant gas by the fuel gas humidifier and the oxidant gas humidifier is reduced, and the temperature of the cooling water is adjusted. As a result, the temperature of the cell stack during power generation is increased by a certain temperature, and this temperature increase improves the discharge capacity of the generated water generated in the oxidant gas flow path of the cell stack to the outside of the cell stack, and the retention of the generated water It has become possible to make it difficult for power generation failure of the cell to occur.
By performing this measure, if the cause of the start of the previous accumulated water removal mode operation is the retention of the produced water, unless the cell stack is in a condition that the produced water is particularly likely to stay. The voltage monitoring monitor does not detect a cell voltage abnormality and can continue normal power generation as it is, so that it can be determined that the cause of the previous voltage abnormality was a trouble due to the retention of generated water.

In addition, the cause of the abnormal drop in the cell stack and the cell voltage constituting the cell stack, which has started the operation to remove the accumulated product water removal mode, is not only the trouble caused by the product water retention in the oxidant gas flow path, It is also conceivable that circulating water has entered from the circulating water flow path or circulating water manifold, or that minute pinholes have occurred in the ion exchange membrane.
As described above, the cell voltage monitoring monitor detects the voltage drop of the abnormal cell, performs the retained water removal mode operation of reducing the humidification amount to the oxidant gas and increasing the cell stack temperature, and stays in the cell stack. The cell voltage value is normal if the cause of the start of the accumulated water removal mode operation is the retention of the produced water in the oxidant gas flow path when the normal power generation operation is resumed after the water is expelled. The cell voltage monitoring monitor can continue normal operation as it is without detecting the voltage drop of the abnormal cell.
Even when the cell voltage monitoring monitor detects the cell voltage drop again, if the abnormality detection cell is different, it can be determined that the cause of the previous abnormality cell is retention of generated water in the oxidant gas flow path. In the case of a cell that has detected a voltage abnormality at the same time, the accumulated generation water removal mode operation is performed again for a predetermined time and then the normal power generation operation is restored. It will be judged whether it is due to generation of water or generated water.

When the abnormal voltage drop due to the same cell that constitutes the cell stack is detected by the cell voltage monitoring monitor after returning from the accumulated water removal mode operation to the normal power generation operation state, the cause is not only the retention trouble of the generated water. As mentioned above, the circulating water that cools the cell stack may leak and enter, or minute pinholes may be generated in the ion exchange membrane. Since oxidant gas is mixed, there is a risk of explosion, and it is extremely dangerous if measures are not taken immediately.
In the above embodiment, when the voltage monitoring monitor detects an abnormal drop in the cell voltage, the fuel gas supply valve is shut off at the same time as the cell stack shut-off relay is opened to stop the supply of hydrogen gas to the cell stack. Since the operation to stop power generation is performed,
Even if the cause of the cell abnormality discovered by the cell voltage monitoring monitor is due to breakage of the ion exchange membrane, the retained product water removal mode operation can be dealt with quickly and safely. .
When the accumulated water removal mode operation ends and the normal power generation operation is resumed, if the power generation is not possible due to the damage of the ion exchange membrane as described above, the voltage detection of the next voltage monitoring monitor is performed. Sometimes a voltage drop in the same cell is detected, so it can be determined that the cause of the trouble is not stagnation of the produced water.

In the conventional method, even if the sudden drop in cell voltage is a problem of stagnation of product water, it takes time to solve the problem, so if the cause is not stagnation of product water, further countermeasures can be taken. There is a possibility that accidents that are delayed and may be prevented in some cases cannot be prevented.
In this invention, in the normal power generation operation after the return, when the voltage drop of the abnormal cell can be detected, the cause of the voltage drop of the abnormal cell is immediately due to the stay of generated water when compared with the previous abnormal cell. In this case, it can be determined that a device failure has occurred. At this time, the cell stack cutoff relay is opened, the cell stack is disconnected from all loads including the DC-AC inverter, the fuel gas cutoff valve is closed, and the fuel cell system is immediately The power generation operation of is stopped.
For this reason, the ion exchange membrane can be operated while it is damaged, and the danger of an explosion due to a mixture of hydrogen and oxidant gas inside the cell stack can be immediately avoided and serious accidents can be prevented in advance. A highly functional system has been completed.

FIG. 1 is a configuration diagram showing a solid polymer electrolyte fuel cell (also referred to as a cell), which is a basic configuration of a solid polymer electrolyte fuel cell, and 3 is a fuel gas. A thin-film ion exchange membrane that partitions the gas and the oxidant gas, 4 is a thin-film electrode formed of a conductive porous body that sandwiches the ion-exchange membrane 3 from both sides, and 5 is disposed on the ion-exchange membrane 3 and both sides thereof. This is a thin film electrode assembly in which the thin film electrode 4 is integrated.
6 is a conductive separator for further integrating the thin film electrode assembly 5 from both sides thereof, and 7 is a fuel gas flow formed on the surface of the conductive separator 6 on the anode side of the thin film electrode assembly 5. A path 8 is an oxidant gas flow path formed on the surface of the conductive separator 6 on the cathode side of the thin film electrode assembly 5.
Reference numeral 1 denotes a cell (solid polymer electrolyte fuel cell) as a unit power generation element of a solid polymer electrolyte fuel cell constituted by a conductive separator 6 and the thin film electrode assembly 5 sandwiched between the conductive separators 6. Yes, the thin film electrode assembly 5 sandwiched between two conductive separators 6 supplies the fuel gas channel 7 with hydrogen gas as fuel gas and the oxidant gas channel 8 with air as oxidant gas. Then, the reaction is promoted by the action of the catalyst layer attached on the ion exchange membrane 3, and an electromotive force is generated between the electrodes 4 sandwiching the ion exchange membrane 3.

FIG. 2 is an exploded perspective view showing the structure of the solid polymer electrolyte fuel cell. The conductive separator 6 has the fuel gas flow path 7 formed on the lower surface and the oxidant on the upper surface. A gas flow path 8 is formed, and reference numeral 2 denotes a cell in which the conductive separator 6 having the fuel gas flow path 7 and the oxidant gas flow path 8 and the thin film electrode assembly 5 are alternately stacked. It is a stack.
Since the cell stack 2 is formed by stacking a number of cells 1 composed of the conductive separator 6 and the thin film electrode assembly 5 connected in series, a predetermined voltage can be obtained as a fuel cell.

7a is a fuel gas inlet manifold for supplying fuel gas in common to each of the fuel gas flow paths 7 through the conductive separator 6 and the thin film electrode assembly 5 when the cell stack 2 is formed. , 7b is a fuel gas outlet manifold for discharging the remaining fuel gas in common, and 8a is an oxidation for supplying the oxidant gas in common to the oxidant gas flow path 8 when the cell stack 2 is constructed. An agent gas inlet manifold 8b is an oxidant gas outlet manifold for discharging the remaining oxidant gas in common. The fuel gas inlet manifold 7a, the fuel gas outlet manifold 7b, the oxidant gas inlet manifold 8a, and the oxidant gas outlet manifold 8b are arranged so as to penetrate the plurality of cells 1 at the corners of the periphery of the cell stack 2. And the ends of the fuel gas flow path 7 and the oxidant gas flow path 8 are in communication with each other.
For this reason, the fuel gas sent to the fuel gas inlet manifold 7a is branched and sent to the fuel gas flow path 7 provided in a plurality of stages, and the unreacted fuel gas is collected in the fuel gas outlet manifold 7b. Is discharged outside. Similarly, the oxidant gas sent to the oxidant gas inlet manifold 8a is branched and sent to the oxidant gas flow path 8 provided in a plurality of stages, and the unreacted oxidant gas and the generated water that has become water vapor are oxidized. Collected in the agent gas outlet manifold 8 b and discharged out of the cell stack 2.

Reference numeral 9 denotes a cooling water circulation passage formed in place of the fuel gas passage 7 and the oxidant gas passage 8 in the laminated conductive separator 6. For example, the conductive separator 6 is disposed on the lower side. A cooling water circulation flow path 9 is formed on the surface to be replaced with the fuel gas flow path 7, and another conductive separator 6 has a cooling water circulation flow path 9 instead of the oxidant gas flow path 8 on the upper surface. The two conductive separators 6 are formed so as to form one cooling water circulation channel 9 by directly superimposing the cooling water circulation channels 9.
9a is formed through the conductive separator 6 and the thin-film electrode assembly 5 in order to circulate water for adjusting the temperature of the cell stack 2 in communication with the cooling water circulation passage 9 in the cell stack 2. A circulating water inlet manifold 9b is a circulating water outlet manifold for discharging water circulated through the cooling water circulation passage 9. The position where the circulating water inlet manifold 9a is arranged is substantially at the center of the periphery of the cell stack 2. It forms so that the several cell 1 may be penetrated in the vicinity, and the end of the inlet of the said cooling water circulation flow path 9 and the exit is each communicating.

In the fuel gas flow path 7 on the anode side of the cell stack 2, hydrogen gas (H ₂ ) in the fuel gas sent to the fuel gas flow path 7 is ionized in the anode side catalyst layer on the ion exchange membrane 3. As a result, hydrogen ions (H ⁺ ) and electrons (e ⁻ ) are formed. The hydrogen ions (H ⁺ ) pass through the ion exchange membrane 3 and move to the oxidant gas flow path 8 on the cathode side, and the electrons (e ⁻ ) Conductive separator on the oxidant gas flow path 8 side via an external load connected between the conductive separator 6 on the fuel gas flow path 7 side and the conductive separator 6 on the oxidant gas flow path 8 side Go to 6.
On the other hand, in the oxidant gas flow path 8 on the cathode side of the cell stack 2, oxygen (O ₂ ) in the air sent as the oxidant gas to the oxidant gas flow path 8 has permeated the ion exchange membrane 3. Between the hydrogen ion (H ⁺ ) and the electron (e ⁻ ) that has moved to the cathode side, a chemical reaction occurs in the cathode side catalyst layer on the ion exchange membrane 3 to generate water, and at this time, an external load An electromotive force is generated by the movement of electrons (e ⁻ ) via, and a current flows through this external load.
The chemical reaction of oxygen (O ₂ ), hydrogen ion (H ⁺ ), and electron (e ⁻ ) not only generates water but also generates an exothermic reaction. The amount of heat generated by the exothermic reaction depends on the amount of heat in the cell stack 2. The water is taken out by the water passing through the cooling water circulation path 9.

FIG. 3 is a connection diagram of components representing the supply / discharge state of the fuel gas and the oxidant gas, the circulation state of the circulating water, the extraction state of the power generation output, etc. in order to make the cell stack 2 function.
10 is a fuel gas supply line for supplying fuel gas to the fuel gas inlet manifold 7a of the cell stack 2, and 11 is a fuel gas discharge line for discharging the remaining unreacted fuel gas after reaction from the fuel gas outlet manifold 7b to the outside. , 12 is a fuel gas cutoff valve installed in the fuel gas supply line 10 to supply and stop the fuel gas, and 13 is the fuel gas supply line 10 between the fuel gas cutoff valve 12 and the fuel gas inlet manifold 7a. The fuel gas humidifier installed in the fuel gas is controlled so that the water vapor in the fuel gas is humidified by the fuel gas humidifier 13, so that a predetermined amount of fuel gas is always supplied to the cell stack 2. It has become.
14 is an oxidant gas supply line for supplying an oxidant gas to the oxidant gas inlet manifold 8a of the cell stack 2, and 15 is a discharge of the remaining unreacted oxidant gas after reaction from the oxidant gas outlet manifold 8b. An oxidant gas discharge line, 16 is an oxidant gas cutoff valve installed in the oxidant gas supply line 14 for supplying / stopping the oxidant gas, and 17 is an oxidant gas cutoff valve 16 and an oxidant gas inlet manifold 8a. The oxidant gas humidifier installed in the fuel gas supply line 14 between the oxidant gas and the water vapor in the oxidant gas is controlled to be humidified by the oxidant gas humidifier 17 so that the moisture is always kept in a predetermined amount. A certain oxidizing gas is supplied to the cell stack 2.

When the fuel gas shutoff valve 12 of the fuel gas supply line 10 is opened, the fuel gas is sent into the cell stack 2 from the fuel gas inlet manifold 7a, while the oxidant gas shutoff valve 16 of the oxidant gas supply line 14 is opened. And the oxidant gas are sent into the cell stack 2 from the oxidant gas inlet manifold 8a.
Therefore, in the cell stack 2, hydrogen gas (H ₂ ) in the fuel gas and oxygen gas (O ₂ ) in the oxidant gas react to generate water, reaction heat, and electromotive force. Electric power can be taken out and used.
The unreacted fuel gas in the fuel gas channel 7 is discharged from the fuel gas outlet manifold 7b through the fuel gas discharge line 11, while the unreacted oxidant gas in the oxidant gas channel 8 is Together with the generated water that has become water vapor, it is discharged from the oxidant gas outlet manifold 8b through the oxidant gas discharge line 15.
The reaction between hydrogen gas (H ₂ ) and oxygen gas (O ₂ ) in the cell stack 2 is promoted in a high-humidity atmosphere in the solid polymer electrolyte fuel cell. The gas humidifier 13 and the oxidant gas supply line 14 are provided with an oxidant gas humidifier 17, and the fuel gas and oxidant gas are made into a high-humidity atmosphere by the fuel gas humidifier 13 and the oxidant gas humidifier 17. Supplying into 2 is an effective means for increasing the power generation output.

Reference numeral 18 denotes an output terminal that is in conduction with the conductive separators 6 on the top and bottom surfaces constituting the cell stack 2, and the cell 1 constituting the solid polymer electrolyte type fuel cell using the thin-film ion exchange membrane 3 is provided. When the cell stack 2 of the solid polymer electrolyte fuel cell is formed by stacking, a predetermined output voltage can be obtained by the conductive separators 6 on the top and bottom surfaces of the cell stack 2. A power generation output can be taken out of the cell stack 2 using the output terminal 18 connected to the.
Reference numeral 19 denotes an output power line connected to the output terminal 18 of the cell stack 2, 20 denotes a load connected to the output power line 19, and the power generation output taken out from the cell stack 2 using the output terminal 18 is It is supplied to the load 20 via the output power line 19 and used as appropriate.

20a is a DC-AC inverter constituting the load 20, and 20b is a power utilization device constituting the load 20, and the DC-AC inverter 20a is not required when the power utilization device 20b is a system that directly uses a DC power source. .
When the power utilization device 20b is a device using a household AC power source, a direct current flows through the output power line 19, and therefore, it can be used by creating an AC 100V power source by the DC-AC inverter 20a.
Reference numeral 20c denotes a connection switch provided between the DC-AC inverter 20a and a power utilization device 20b that uses a home AC power supply, and the home switch AC is used by operating the connection switch 20c. The power utilization device 20b can receive power supply from the power system of the power company instead of supplying DC power from the cell stack 2.

21 is a circulating water line connected to the circulating water inlet manifold 9a and the circulating water outlet manifold 9b of the cell stack 2 in order to extract the amount of heat generated in the cell stack 2, 22 is a circulating water pump attached to the circulating water line 21, Reference numeral 23 denotes a circulating water tank for storing the circulating water. A heat exchanging mechanism (not shown) is attached to the circulating water tank 23, and the heat exchanging mechanism is used in the circulating water tank 23 as necessary. The amount of heat contained in the water can be used.
The circulating water tank 23 initially stores low-temperature water. When the circulating water pump 22 is operated, the water in the circulating water tank 23 flows from the circulating water line 21 to the circulating water inlet manifold 9a of the cell stack 2. , And becomes hot water when passing through the cooling water circulation passage 9 in the cell stack 2 and is returned from the circulation water outlet manifold 9b to the circulation water tank 23 via the circulation water line 21 again. For this reason, the amount of heat generated by the reaction between the hydrogen gas (H ₂ ) and the oxygen gas (O ₂ ) in the cell stack 2 can be discharged by the temperature rise of the circulating water flowing through the circulating water line 21. Makes it possible to efficiently extract the power generation output.

Among the troubles of power generation failures that occur during the use of the solid polymer electrolyte fuel cell stack 2 described above, the most serious problem is that the thin film electrode assembly 5 is destroyed and the fuel gas and the oxidant gas are directly It is a trouble that causes an oxidation reaction. Then, the occurrence of a trouble in the cell stack 2 is easily noticed because the power generation output is reduced, and the use of the cell stack 2 is stopped, disassembled, and a defective portion is found and repaired.
Further, the trouble of the cell stack 2 includes a trouble of power generation failure that occurs when the generated water stays in the oxidant gas flow path 8 of the cell 1 even when the thin film electrode assembly 5 is not destroyed. Also at this time, the use of the cell stack 2 is stopped, and when it is disassembled to search for a defective portion but is not found, it is determined that the cause is the retention of the generated water, and only the generated water is removed and the use is resumed. However, if there is no repair due to the generated water, it is preferable that the cell stack 2 can be handled without being disassembled.

In the present invention, when a trouble of power generation failure occurs, the cause is that the thin-film electrode assembly 5 is broken, the generated water stays in the oxidant gas flow path 8, or the cell stack 2 is Judging without disassembling, it proposes a method to solve the trouble of power generation failure.
In the embodiment of FIG. 2 showing the configuration of the solid polymer electrolyte fuel cell, reference numeral 24 denotes a conductive separator 6 that sandwiches the thin-film electrode assembly 5 of the cell 1 constituting the cell stack 2 and faces out of the cell stack 2. The voltage detection terminals 25 and 25 are cell voltage monitoring monitors connected between the voltage detection terminals 24. The cell voltage monitoring monitor 25 is arranged for each cell 1 and monitors the power generation output (electromotive force). The cell 1 that has caused the trouble can be identified.
Further, in the embodiment of FIG. 3 showing the connection state of each component for causing the solid polymer electrolyte fuel cell to function, 26 is connected to the cell stack 2 side of the output power line 19 connected to the output terminal 18 of the cell stack 2. The cell stack cutoff relay is attached, and the cell stack cutoff relay 26 can disconnect the load 20 including the DC-AC inverter 20a and the power utilization device 20b from the cell stack 2.
20d is a power storage device for accumulating a direct current flowing in the output power line 19 that functions as a component of the load 20 in the same manner as the DC-AC inverter 20a, and is disposed immediately after the cell stack interruption relay 26. When the DC current of the output power line 19 is cut off by the cell stack cut-off relay 26, DC power is supplied from the power storage device 20d to the DC-AC inverter 20a and the like instead of the output terminal 18 of the cell stack 2. The power utilization device 20b can continue to operate as it is.

Reference numeral 27 denotes an oxidant gas humidifier that bypasses the oxidant gas humidifier 17 and directly supplies the oxidant gas to the cell stack 2 in the oxidant gas supply line 14 that supplies the oxidant gas to the cell stack 2. A line 28 is an oxidant gas bypass valve capable of switching the path of the oxidant gas to the oxidant gas humidifier 17 and the oxidant gas humidifier bypass line 27.
Reference numeral 29 denotes a circulating water line 21 that cools the inside of the cell stack 2 to increase the circulating water temperature by being attached to the circulating water tank 23 for storing the circulating water or the circulating water line 21 on the supply side to the cell stack 2. The circulating water heater 29 is energized, and by energizing the circulating water heater 29, the circulating water for cooling the inside of the cell stack 2 can be used to bring the inside of the cell stack 2 to a high temperature, which is a completely opposite action. it can.

FIG. 4 is a block diagram for operating the solid polymer electrolyte fuel cell 1, wherein 30 is a control unit for controlling the solid polymer electrolyte fuel cell system by an internal CPU, and 31 is an operation state. An indicator, 32 is an operation unit for outputting various operation signals such as starting and stopping of the fuel cell system to the control unit 30, and 33 is for the CPU of the control unit 30 to control various control components in a predetermined procedure. These are non-volatile memories that hold programs and fixed data, and may be rewritable non-volatile memories. Reference numeral 34 denotes a volatile memory for holding data or the like temporarily required for operation when the CPU of the control unit 30 operates.
The control unit 30 operates according to the procedure of the program stored in the non-volatile memory 33 by the function of the built-in CPU. In this program, the cell voltage monitoring monitor 25 is constantly monitored. When the monitor 25 detects an abnormal cell, a program for pursuing the cause of the abnormality is activated.

FIG. 5 is a flowchart showing the operation of a program for pursuing the cause of this abnormality when this abnormal cell is detected. The operation of the present invention will be described according to this flowchart.
During the normal power generation operation mode operation, the control unit 30 operates the flowchart shown in FIG. 5 during the operation of the main program, and the control unit 30 includes each of the plurality of cells 1 constituting the cell stack 2. Since the cell voltage monitoring monitor 25 installed in the cell is connected, the control unit 30 operates step 1 (S1) to monitor the output of each cell 1 of the cell voltage monitoring monitor 25, and the voltage of the cell 1 is monitored. If no abnormality is detected, return to the main program.
When one of the plurality of cell voltage monitoring monitors 25 detects an abnormal voltage drop in step 1 (S1), the control unit 30 changes the fuel cell system from the normal power generation operation to the accumulated product water removal mode operation.
Then, the process proceeds to step 2 (S2), and it is determined whether or not the number for identifying the abnormal cell is written in the volatile memory 34. If no abnormal cell is written, the position of the abnormal cell is numbered in step 3 (S3). And is stored in the volatile memory 34.

Next, the process proceeds to step 4 (S4), and the accumulated water removal mode operation is started from the normal power generation operation. In the accumulated water removal mode operation starting from step 4 (S4), since the cell stack cutoff relay 26 is first opened to stop the power supply to the load 20, the DC current is not supplied from the cell stack 2. The power usage equipment 20b that constitutes the load 20 stops operating.
At this time, when the power storage device 20d is provided as a component of the load 20, the power storage device 20d is always charged with a part of the power supplied from the cell stack 2, so that the cell stack cutoff relay 26 is If the power is not supplied from the cell stack 2 after being opened, the power storage device 20d is immediately activated, and a direct current can subsequently flow from the power storage device 20d to the output power line 19. For this reason, the electric power utilization apparatus 20b can continue use for a certain amount of time continuously.
Further, when the connection switch 20c is installed between the DC-AC inverter 20a constituting the load and the power utilization device 20b, and the household AC power is supplied to the connection switch 20c, the cell stack is cut off. The connection switch 20c is operated in conjunction with the relay 26 being opened, and the household AC power supply can be supplied to the power utilization device 20b of the load 20 via the connection switch 20c. For this reason, even if the cell stack interruption | blocking relay 26 opens | releases, the electric power utilization apparatus 20b can continue use.

In step 5 (S5), the fuel gas shut-off valve 12 is closed to stop the supply of fuel gas to the cell stack 2. In step 6 (S6), the oxidant gas bypass valve 28 is switched. Thus, a dry oxidant gas that does not pass through the oxidant gas humidifier 17 can be supplied to the oxidant gas flow path 8 in the cell stack 2.
Furthermore, the operation of Step 7 (S7) operates the circulating water heater 29 that heats the circulating water to a high temperature in order to switch the circulating water for performing the heat radiation operation to the heating operation. By this operation, the temperature of the circulating water circulating in the cell stack 2 rises, and the temperature in the cell stack 2 is maintained at a high temperature as in the normal power generation operation.
By performing all the four operations from Step 4 (S4) to Step 7 (S7) described above, the retained water removal mode operation becomes possible, and these operations are naturally performed simultaneously. There is no need to carry out in the order of step 4 (S4) to step 7 (S7), and since the optimum order for the fuel cell system at that time is selected, the order may be appropriately changed.

In the retained water removal mode operation, the solid polymer electrolyte fuel cell stops the supply of power generation output to the load 20, stops the fuel gas, stops the humidification of the oxidant gas, and stops the high temperature to the cell stack 2 as described above. While the operation such as the supply of water is performed, the other operations continue as they are, and the chemical reaction for generating the power generation output is stopped by stopping the supply of the fuel gas, so that the generated water is not generated.
On the other hand, when the generated water stays in the oxidant gas flow path 8 of the cell stack 2, the remaining generated water vaporizes little by little in the cell stack 2 where the high temperature is maintained by the supply of high temperature water. In addition, since the oxidant gas supplied to the cell stack 2 is sent through the oxidant gas humidifier bypass line 27 as dry air that is not humidified, the vaporized product water is used as steam. It can be discharged out of the cell stack 2. Then, if the amount of retained product water decreases and a passage of dry air is formed in the oxidant gas flow path 8, the product water retained in the oxidant gas flow path 8 by the passing dry air rapidly It can be removed by drying.

A predetermined time is required for the generated water staying in the oxidant gas flow path 8 in the cell stack 2 to be removed by the above-described staying water removal mode operation, so step 8 (S8) It is confirmed whether or not the water removal mode operation has been executed for a predetermined time. If the predetermined time has not elapsed, the process returns to step 8 (S8) again to repeat the confirmation operation.
When the predetermined time has elapsed, in order to return to the normal operation return operation, the operation of the circulating water heater 29 is stopped in step 9 (S9) so that the cooling water can be supplied to the cell stack 2, and in step 10 (S10). The oxidant gas bypass valve 28 of the oxidant gas supply line 14 is returned so that the oxidant gas humidifier 17 can be operated to supply the oxidant gas to the cell stack 2, and in step 11 (S11), the fuel gas supply line 10 is supplied. The fuel gas cutoff valve 12 is opened to start supplying fuel gas to the cell stack 2, and the stack cutoff relay 26 is switched in step 12 (S12) to start supplying the power generation output from the cell stack 2 to the load 20. By this series of operations, the solid polymer electrolyte fuel cell starts normal power generation operation.
In the normal operation return operation, the operations from step 9 (S9) to step 12 (S12) are performed almost at the same time, as in the case of the start of the accumulated water removal mode operation. There is no particular problem.
As described above, the operation of the retained water removal mode is terminated by the operation from step 9 (S9) to step 12 (S12), and the operation state of the cell stack 2 is returned to the normal operation. Therefore, step 13 (S13) To return to the main program.

As described above, although the power generation operation of the solid polymer electrolyte fuel cell is temporarily stopped for a short time during the operation of the retained water removal mode, one of the plurality of cell voltage monitoring monitors 25 of the cell 1 has an abnormal voltage drop. When the cause of the generation is due to the retention of the generated water in the oxidant gas flow path 8, it is possible to quickly eliminate the retention of the generated water. It is no longer necessary to determine the cause.
Even after returning to the normal power generation operation, the output of the cell voltage monitoring monitor 25 is constantly monitored by repeating the operation of step 1 (S1) in the flowchart of FIG. 5 in the middle of the main program. When the abnormality of the voltage of the cell 1 is not detected, it can be determined that the cause of the abnormal cell is the generated water staying in the oxidant gas flow path 8, and the normal power generation operation can be continued as it is.
Even after returning to the normal power generation operation, the output of the cell voltage monitoring monitor 25 is monitored during the main program, and it is determined that the cause of the abnormal cell is the generated water staying in the oxidant gas flow path 8. For this purpose, it is necessary that a state where no abnormality in the voltage of the cell 1 is detected be continued for a predetermined time.
For this reason, the operation of step 1 (S1) for monitoring the output of the cell voltage monitoring monitor 25 during the operation of the main program is performed without counting the voltage abnormality, and an abnormal cell is detected when a specific number of counts are completed. As a result, it is determined that the generated water is retained, and the abnormal cell number stored in the volatile memory 34 is cleared.

On the other hand, when the operation of step 1 (S1) in the flowchart of FIG. 5 is repeated in the middle of the main program after returning to the normal power generation operation, one of the cell voltage monitoring monitors 25 generates an abnormal voltage drop. There is a time to let you.
At this time, the process proceeds to step 2 (S2) to determine whether or not the abnormal cell number has already been written in the volatile memory 34. If there is already an abnormal cell number written, step 14 (S14). Then, it is determined whether the number of the abnormal cell already written in the volatile memory 34 matches the number of the newly found abnormal cell.
Then, when the newly found abnormal cell number is the same as the stored abnormal cell number, it is determined that the cause of the abnormal voltage drop is not due to the retention of the generated water but the component failure, Proceeding to step 15 (S15), the control unit 30 stops the operation of the solid polymer electrolyte fuel cell, warns the user if necessary, and disassembles the cell stack 2 for the first time for this abnormality. The cause of the failure will be determined.

If the newly found abnormal cell is different from the abnormal cell stored in the volatile memory 34 in the determination of the coincidence of the stored abnormal cell performed in the above-mentioned step 14 (S14), the accumulated water is removed. About the abnormal cell which caused the mode operation, it is determined that the abnormality has already been eliminated by the retained water removal mode operation and the normal operation is continued.
However, for the newly detected abnormal cell, the cause of the abnormal state is unknown, and in order to pursue this cause, the process goes to step 3 (S3) and the volatile memory 34 becomes abnormal. Store the number of the selected cell. Thereafter, the process proceeds to step 4 (S4), where the normal power generation operation so far is changed to the staying water removal mode operation for a predetermined time, and it is determined whether or not the cause of the abnormal cell is the staying of the generated water.

When the abnormal cell number is stored in the volatile memory 34 as described above and the normal power generation operation is resumed, if the cell 1 constituting the cell stack 2 is out of order, the normal operation is resumed. The cell voltage monitoring monitor 25 detects an abnormal cell over time, and in this case, in step 14 (S14), the abnormal cell number stored in the volatile memory 34 is compared with the newly found abnormal cell number. If this is the case, it can be seen that they match, so that the operation can be stopped in step 15 (S15) to prevent the occurrence of a major trouble.
Further, when a minor trouble has occurred in the cell 1, the cell voltage monitoring monitor 25 may detect an abnormality after a certain amount of time has elapsed. Even in such a case, if the generated water does not stay in the oxidant gas flow path 8, a failure of the cell 1 can be found although it takes time.
However, under conditions where product water is likely to stay, abnormalities caused by the retention of product water may be detected in other cells 1 before abnormalities due to minor troubles are detected. Even if the detected cause is minor but the trouble requires repair, the number of the abnormal cell is different, so it is determined that the cause of the abnormality is due to stagnation of the generated water, and normal power generation operation may continue as it is There is.

In addition, when the cause that the cell voltage monitoring monitor 25 detects abnormality is retention of generated water, an abnormal cell that is frequently caused by retention of generated water may be detected depending on operating conditions. Sometimes, even if the cause is retention of generated water, it is impossible to avoid the possibility that the abnormal cell found this time and the previous abnormal cell become the same abnormal cell in the comparison operation in step 14 (S14).
For this reason, it is determined that the cause of the abnormal cell is a failure of the cell 1, the process proceeds to step 15 (S 15), the operation of the cell stack 2 is stopped, and even when the cell stack 2 is caused by the retention of the generated water. Will be broken down to find the fault location.

  The present invention proposes that the cause of occurrence of an abnormal cell can be reliably determined so that the operation can be stopped only when the cell 1 fails, and the normal generation operation is returned from the accumulated water removal mode operation. At times, before performing the operation from step 9 (S9) to step 12 (S12), or while performing the operation, or after performing the operation, the normal power generation operation after the return is made to coincide with the first operation condition. Rather, it is characterized by the addition of a step for changing the operating conditions.

That is, as shown in the flowchart of the normal power generation operation return of FIG. 6 in which the operating conditions are changed, step 9a (S9a) reduces the amount of heat taken out from the heat exchange mechanism provided in the circulating water tank 23, for example. In this operation, the temperature of the circulating water circulating to the cooling water circulation passage 9 in the cell stack 2 can be increased by the added operation.
Further, the operation of Step 10a (S10a) for changing the oxidant gas to low humidity and Step 11a (S11a) for changing the fuel gas to low humidity are added. In this step, the fuel in the fuel gas supply line 10 is added. This can be realized by the operation of reducing the humidification amount of the oxidant gas humidifier 17 in the gas humidifier 13 and the oxidant gas supply line 14.

  In general, the reason why the amount of water vapor contained in the oxidant gas and the fuel gas is increased by the fuel gas humidifier 13 and the oxidant gas humidifier 17 is to promote a chemical reaction that generates power in a humid state. When the amount of generated water is large, retention of the generated water occurs in the cell stack 2. For this reason, if the cause of the cell abnormality is retention of generated water, the humidification of the fuel gas humidifier 13 in the fuel gas supply line 10 and the humidification of the oxidant gas humidifier 17 in the oxidant gas supply line 14 in the added step described above. Even if the amount is reduced, since the high humidity atmosphere is maintained in the cell stack 2, the function of water vapor for promoting the chemical reaction to generate electricity is not impaired, and the generated water is water vapor because the amount of humidification is small. It becomes easy to discharge | emit outside in the form of, and abnormality of the cell 1 resulting from retention of produced water becomes difficult to generate | occur | produce.

Further, the chemical reaction generated in the cell stack 2 is an exothermic reaction, and the temperature of the cell stack 2 rises, but this amount of heat is exhausted to the outside by circulating water circulating in the cell stack 2. In the above added step, if the temperature of the circulating water circulating in the cell stack 2 rises, the amount of heat extracted from the cell stack 2 decreases, so the temperature inside the cell stack 2 becomes high and is generated by a chemical reaction. The generated water is easily discharged to the outside in the form of water vapor, and the abnormality of the cell 1 due to the retention of the generated water is less likely to occur.
For this reason, even if an abnormal cell due to the retention of the generated water can be detected, the generation of the generated water is suppressed after returning to the normal power generation operation, and the same cell 1 becomes an abnormal cell in succession twice. When this occurs, it is possible to reliably determine that the cell 1 is out of order without causing the product water to stay.

1 is a cross-sectional view of a main part of a solid polymer electrolyte fuel cell according to the present invention. The disassembled perspective view which shows the structure of the solid polymer electrolyte type fuel cell using the fuel battery cell shown in FIG. The connection diagram of each component to the solid polymer electrolyte fuel cell stack of this invention. The block diagram which shows the control apparatus of the solid polymer electrolyte fuel cell of this invention. It is a flowchart which shows operation | movement of the solid polymer electrolyte type fuel cell stack of this invention. It is a flowchart which shows the principal part of the other Example of the flowchart shown in FIG.

Explanation of symbols

1 Solid polymer electrolyte fuel cell (cell)
2 Solid polymer electrolyte fuel cell stack (cell stack)
3 Ion exchange membrane 4 Electrode 5 Thin film electrode assembly 6 Conductive separator 7 Fuel gas flow path (anode side)
8 Oxidant gas flow path (cathode side)
9 Cooling water circulation channel 10 Fuel gas supply line 11 Fuel gas discharge line 13 Fuel gas humidifier 14 Oxidant gas supply line 15 Oxidant gas discharge line 17 Oxidant gas humidifier 19 Output power line 20 Load 20a DC-AC inverter 21 Circulating water line 22 Circulating water pump 23 Circulating water tank 25 Cell voltage monitoring monitor 26 Cell stack cutoff relay 27 Oxidant gas humidifier bypass line 28 Oxidant gas bypass valve 29 Circulating water heater

Claims (3)

Solid polymer electrolyte fuel cell in which a conductive separator in which a fuel gas channel and an oxidant gas channel are formed is arranged on both sides of a thin film electrode assembly in which an ion exchange membrane is sandwiched between electrodes made of a conductive porous material A cell (hereinafter referred to as a cell),
A plurality of these cells are stacked to form a solid polymer electrolyte fuel cell stack (hereinafter referred to as a cell stack)
A fuel gas supply line for supplying a hydrogen-rich fuel gas to the fuel gas flow path of the cell stack; an oxidant gas supply line for supplying an oxidant gas containing oxygen to an oxidant gas flow path of the cell stack; and a fuel gas. In addition, the fuel gas humidifier and the oxidant gas humidifier installed in the fuel gas supply line and the oxidant gas supply line, respectively, to humidify the oxidant gas, and the unreacted gas that did not react in the cell stack are discharged. A fuel gas discharge line and an oxidant gas discharge line,
Installed on the circulating water line for supplying the circulating water from the circulating water tank to the cooling water circulation channel arranged in the cell stack, and on the circulating water line for forcibly circulating the circulating water to the circulating water line and the cooling water circulation channel And a circulating water pump
A fuel cell system in which a load including a DC-AC inverter is connected to an output power line for extracting power from the cell stack, and a cell stack cutoff relay is disposed on the output power line between the cell stack. And
A cell voltage monitoring monitor is connected to the voltage detection terminals of the cells constituting the cell stack,
When the cell voltage monitoring monitor detects an abnormal cell whose voltage drops below the set value, the fuel cell system
(1) Open the cell stack cut-off relay to stop the power supply to the load,
(2) Stop the supply of fuel gas to the fuel gas supply line,
(3) The oxidant gas supply line supplies oxidant gas that has not been humidified by the oxidant gas humidifier,
(4) Circulating high temperature circulating water from the circulating water line to the cell stack,
Switch to the accumulated water removal mode operation,
After performing the stagnant product water removal mode operation for a predetermined time, return to normal power generation operation,
In normal power generation operation after recovery, the cell voltage monitoring monitor monitors the voltage drop of the abnormal cell, and when the voltage drop of the abnormal cell is not detected, it is determined that the previous voltage drop is retention of generated water. A method for determining retention of generated water in a fuel cell system. In normal power generation operation after returning from the accumulated product water removal mode operation,
The temperature of the circulating water that reduces the amount of humidification by the fuel gas humidifier and the oxidant gas humidifier in the fuel gas supply line and the oxidant gas supply line and circulates to the cooling water circulation passage in the cell stack The method of claim 1, wherein the cell voltage monitor monitors the voltage drop of the abnormal cell. In the generated water retention determination method of the fuel cell system according to claim 1 or 2, the cell voltage monitoring monitor monitors a voltage drop of each cell in a normal power generation operation after returning,
When detecting a voltage drop in a cell other than an abnormal cell, switch to the accumulated product water removal mode operation and operate for a predetermined time, and then return to normal power generation operation to make a product water retention determination.
When no abnormal cell voltage drop is detected, normal power generation operation is continued.
A method of responding to retention of generated water in a fuel cell system, wherein operation of the subsequent fuel cell system is stopped when a voltage drop in an abnormal cell is detected.

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