JP2013211221A - Fuel cell system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fuel cell system that returns liquid fuel cross-leaking from an anode to a cathode, to a fuel circulation passage while preventing cost increase.SOLUTION: In a gas-liquid separation tank 27, liquid is separated from air that is to be emitted to an air exhaust passage 26. The gas-liquid separation tank 27 is connected to a fuel circulation passage 8 through a recirculation passage 29. In the recirculation passage 29, a gas-liquid separation tank valve 30 is interposed. In the air exhaust passage 26, an air back pressure regulating valve 28 is interposed downstream of the gas-liquid separation tank 27 in an air flow direction. The air back pressure regulating valve 28 regulates pressure in the air exhaust passage 26. When the liquid separated in the gas-liquid separation tank 27 is returned to the fuel circulation passage 8, the air back pressure regulating valve 28 is controlled so as to be opened narrowly. Thus, pressures in the air exhaust passage 26 and in the gas-liquid separation tank 27 are increased. After the pressure increase, the gas-liquid separation tank valve 30 is opened.

Description

  The present invention relates to a fuel cell system.

  As a fuel cell system, one that supplies liquid fuel such as hydrazine to a fuel cell is known.

  The fuel cell has a structure in which an anode (fuel electrode) and a cathode (oxygen electrode) are arranged to face each other with an electrolyte membrane interposed therebetween. A fuel circulation path is connected to the anode. That is, one end of the fuel circulation path is connected to the fuel supply port of the anode, and the other end is connected to the fuel discharge port of the anode. Liquid fuel is supplied to the anode from the fuel circulation path, and the liquid fuel that has passed through the anode is discharged to the fuel circulation path. On the other hand, air is supplied to the cathode.

At the anode, nitrogen gas (N ₂ ), water (H ₂ O) and electrons (e ⁻ ) are generated. The electrons move to the cathode via an external circuit (not shown). Nitrogen gas and water are discharged into the fuel circuit together with unreacted liquid fuel. On the other hand, an anion (OH ⁻ ) is generated at the cathode. The anion passes through the electrolyte membrane and moves to the anode. As a result, an electromotive force is generated between the anode and the cathode due to a power generation reaction (electrochemical reaction).

JP 2011-216341 A

  In such a fuel cell system, a so-called cross leak (crossover) occurs in which liquid fuel moves together with water from the anode through the electrolyte membrane and moves to the cathode.

  If the cross leaked liquid fuel can be returned to the fuel circulation path, waste of the liquid fuel due to the cross leak can be suppressed. However, if a pump is provided to return the cross-leaked liquid fuel to the fuel circulation path, the cost and system size increase.

  An object of the present invention is to provide a fuel cell system capable of returning liquid fuel that has cross-leaked from the anode to the cathode to the fuel circulation path while suppressing an increase in cost.

  In order to achieve the above object, a fuel cell system according to the present invention includes a fuel cell having an anode and a cathode arranged opposite to each other with an electrolyte membrane interposed therebetween, and a fuel circulation path through which liquid fuel circulates via the anode. An air supply means for supplying air to the cathode, a discharge path for discharging gas from the cathode, a back pressure adjusting valve for adjusting the pressure in the discharge path, and the back pressure in the discharge path A gas-liquid separator that is interposed upstream of the regulating valve in the gas flow direction and separates the gas discharged from the cathode and the liquid contained in the gas, and the liquid separated by the gas-liquid separator In a state where the on-off valve is closed by controlling the back pressure adjusting valve and the on-off valve, the recirculation path for returning the fuel to the fuel circulation path, the on-off valve interposed in the recirculation path, Opening of the back pressure adjustment valve By reducing, after the pressure in the gas-liquid separator is increased, and a valve control means for opening the closing valve.

  The fuel cell has a structure in which an anode and a cathode are arranged to face each other with an electrolyte membrane interposed therebetween. The anode is supplied with liquid fuel that circulates in the fuel circulation path. Air is supplied to the cathode. Thereby, in the fuel cell, a power generation reaction occurs, and an electromotive force is generated by the power generation reaction.

  Water is produced at the anode as a product of the power generation reaction. Most of the water and unreacted liquid fuel is discharged from the anode to the fuel circulation path, and a part of the water passes through the electrolyte membrane from the anode and cross leaks to the cathode. Therefore, the gas discharged from the cathode to the discharge path includes a liquid. The gas containing the liquid flows into the gas-liquid separator, and the liquid is separated from the gas in the gas-liquid separator.

  The gas-liquid separator is connected to the fuel circulation path via the recirculation path. Thereby, the liquid separated by the gas-liquid separator can be returned to the fuel circulation path through the recirculation path. An open / close valve is interposed in the recirculation path. Further, a back pressure adjusting valve for adjusting the pressure in the discharge path is interposed in the discharge path downstream of the gas-liquid separator in the gas flow direction.

  When the liquid separated by the gas-liquid separator is returned to the fuel circulation path, the back pressure adjusting valve is controlled before the opening / closing valve is opened, and the opening of the back pressure adjusting valve is reduced. Thereby, the pressure in a discharge channel and a gas-liquid separator increases. Then, after the pressure rises, the on-off valve is opened. When the on-off valve is opened, the liquid in the gas-liquid separator is sent out to the recirculation path due to the pressure in the gas-liquid separator. Therefore, no pump or the like is required to return the liquid in the gas-liquid separator to the fuel circulation path.

  Therefore, it is possible to return the cross-leaked liquid fuel to the fuel circulation path while suppressing an increase in cost.

  According to the present invention, it is possible to return the cross-leaked liquid fuel to the fuel circulation path while suppressing an increase in cost.

FIG. 1 is a configuration diagram of a fuel cell system according to an embodiment of the present invention. FIG. 2 is a block diagram showing an electrical configuration of the fuel cell system. FIG. 3 is a flowchart showing the flow of the liquid amount management control. FIG. 4 is a flowchart showing the flow of liquid recovery control. FIG. 5A is a diagram schematically showing a change in the amount of liquid in the gas-liquid separation tank, and shows a state in which the amount of liquid in the gas-liquid separation tank is smaller than the recovery threshold value. FIG. 5B is a diagram schematically showing a change in the amount of liquid in the gas-liquid separation tank, and shows a state in which the amount of liquid in the gas-liquid separation tank has reached the recovery threshold value. FIG. 5C is a diagram schematically showing a change in the liquid amount in the gas-liquid separation tank, and shows a state in which the liquid in the gas-liquid separation tank is sent to the fuel circulation path. FIG. 6 is a flowchart showing the flow of the liquid amount reduction control.

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

  FIG. 1 is a configuration diagram of a fuel cell system according to an embodiment of the present invention.

The fuel cell system 1 is a fuel cell system using liquid fuel, and is mounted as a drive source in, for example, an automobile. The liquid fuel is, for example, hydrazine hydrate (N ₂ H ₄ .H ₂ O).

The fuel cell system 1 includes a fuel cell 2. The fuel cell 2 includes a plurality of cells having a structure in which an anode (fuel electrode) 3 and a cathode (oxygen electrode) 4 are arranged to face each other with an electrolyte membrane 5 interposed therebetween. The plurality of cells are stacked with a separator interposed between the cells to form a cell stack. The electrolyte membrane 5 is, for example, a solid polymer membrane having a property of allowing anions (OH ⁻ ) to pass therethrough.

  A fuel flow path is formed in the anode 3. The fuel flow path is connected to the fuel inlet 6 and the fuel outlet 7. For example, the fuel flow path is bent in a twisted manner between the fuel inlet 6 and the fuel outlet 7.

  One end of a fuel circulation path 8 is connected to the fuel inlet 6. The other end of the fuel circulation path 8 is connected to the fuel outlet 7.

  A fuel inlet valve 9 and a fuel outlet valve 10 are interposed at one end and the other end of the fuel circulation path 8, respectively. The fuel inlet valve 9 and the fuel outlet valve 10 are, for example, electromagnetic valves.

  A fuel circulation pump 11 is interposed between the fuel inlet valve 9 and the fuel outlet valve 10 in the fuel circulation path 8.

  When the fuel circulation pump 11 is driven in a state where the fuel inlet valve 9 and the fuel outlet valve 10 are opened, the liquid containing liquid fuel flows in the direction from the fuel outlet 7 toward the fuel inlet 6 through the fuel circulation path 8. The liquid flowing through the fuel circulation path 8 flows into the fuel flow path of the anode 3 from the fuel inlet 6. The liquid flowing into the fuel flow path flows through the fuel flow path and is discharged from the fuel outlet 7 to the fuel circulation path 8. In this way, the liquid containing the liquid fuel circulates through the fuel flow path and the fuel circulation path 8.

  A fuel sub-tank 12 is interposed in a portion of the fuel circulation path 8 between the fuel outlet valve 10 and the fuel circulation pump 11. The liquid circulating in the fuel circulation path 8 is temporarily stored in the fuel sub tank 12. The fuel sub-tank 12 is provided with a fuel sub-tank liquid amount sensor 13 for detecting the amount of liquid (liquid amount) stored in the fuel sub-tank 12.

  A fuel tank 15 is connected to the fuel sub tank 12 through a fuel supply pipe 14. Liquid fuel is stored in the fuel tank 15. A fuel supply pump 16 is interposed in the middle of the fuel supply pipe 12. When the fuel supply pump 16 is driven, liquid fuel is supplied from the fuel tank 15 through the fuel supply pipe 14 to the fuel sub tank 12.

Further, a gas-liquid separator 17 is interposed in a portion of the fuel circulation path 8 between the fuel outlet valve 10 and the fuel sub tank 12. The gas-liquid separator 11 separates a gas contained in the liquid (for example, N ₂ gas generated during power generation when hydrazine is used as fuel) from the liquid flowing through the fuel circulation path 8 to obtain a liquid Only to return to the fuel circulation path 8.

  A purge pipe 18 is connected to the gas-liquid separator 17. The tip of the purge pipe 18 is connected to an exhaust treatment device 19. A purge valve 20 is interposed in the middle of the purge pipe 18. The purge valve 20 is composed of, for example, an electromagnetic valve. When the purge valve 20 is opened, the gas in the gas-liquid separator 17 is sent to the exhaust processor 19 through the purge pipe 18. The gas sent to the exhaust treatment device 19 is released to the atmosphere after removing harmful components.

  An air flow path is formed in the cathode 4. The air flow path is connected to the air inlet 21 and the air outlet 22, and is bent in a twisted manner between the air inlet 21 and the air outlet 22, for example.

  An air supply path 23 is connected to the air inlet 21.

  An air compressor 24 is interposed in the middle of the air supply path 23.

  An air inlet valve 25 is interposed in a portion of the air supply path 23 between the air compressor 24 and the air inlet 21. The air inlet valve 25 is composed of, for example, an electromagnetic valve.

  An air discharge path 26 is connected to the air outlet 22. The front end of the air discharge path 26 is connected to the exhaust treatment device 19.

  A gas-liquid separation tank 27 and an air back pressure adjustment valve 28 are interposed in the middle of the air discharge path 26.

  When the air compressor 24 is driven in a state where the air inlet valve 25 and the air back pressure adjustment valve 28 are opened, air (atmosphere) is taken into the air supply path 23 through the air cleaner. The air taken into the air supply path 23 flows into the air flow path of the cathode 4 from the air inlet 21. The air flowing into the air flow path flows through the air flow path and is discharged from the air outlet 22 to the air discharge path 26.

  In the fuel cell system 1, so-called cross leak occurs in which water and liquid fuel move from the anode 3 through the electrolyte membrane 5 to the cathode 4. Therefore, the air discharged to the air discharge path 26 includes a liquid containing liquid fuel and water that cross leaks from the anode 3 to the cathode 4. Therefore, a gas / liquid separation tank 27 is interposed in the air discharge path 26. In the gas-liquid separation tank 27, the liquid is separated from the air flowing from the air discharge path 26, and only the air is returned from the gas-liquid separation tank 27 to the air discharge path 26. The air returned to the air discharge path 26 is sent to the exhaust treatment device 19 to remove harmful components and then released to the atmosphere.

  The gas-liquid separation tank 27 stores liquid separated from air. One end of a recirculation path 29 is connected to the bottom of the gas-liquid separation tank 27. The other end of the recirculation path 29 is connected to a gas-liquid separator 17 interposed in the fuel circulation path 8. A gas-liquid separation tank valve 30 is interposed in the middle of the recirculation path 29. The gas-liquid separation tank valve 30 is composed of, for example, an electromagnetic valve.

  The gas-liquid separation tank 27 is provided with a gas-liquid separation tank liquid amount sensor 31 for detecting the amount of liquid (liquid amount) stored in the gas-liquid separation tank 27.

  Further, an air outlet pressure sensor 32 for detecting the pressure in the air discharge path 26 is provided in the vicinity of the air outlet 22 in the air discharge path 26 and on the upstream side of the air-liquid separation tank 27 in the air flow direction. It is connected.

  The fuel cell system 1 includes a cooling water circulation path 33, and the fuel cell 2 is cooled by the cooling water circulating in the cooling water circulation path 33. A water pump 34 for circulating the cooling water to the cooling water circulation path 33 is interposed in the middle of the cooling water circulation path 33. Further, a radiator 36 for cooling the cooling water by air blown from the radiator fan 35 is interposed in the middle of the cooling water circulation path 33. Furthermore, a three-way valve 37 is interposed between the water pump 34 and the radiator 36 in the cooling water circulation path 33. The remaining one port of the three-way valve 37 is connected to a branch pipe 38 that branches from a portion of the coolant circulation path 33 between the coolant outlet of the fuel cell 2 and the radiator 36.

  FIG. 2 is a block diagram showing an electrical configuration of the fuel cell system.

  The fuel cell system 1 includes an FC-ECU (electronic control unit) 41 having a configuration including a CPU and a memory.

  The FC-ECU 41 receives detection signals from the fuel sub tank fluid level sensor 13, the gas / liquid separation tank fluid level sensor 31, and the air outlet pressure sensor 32.

  The FC-ECU 41 controls each part of the fuel cell system 1 on the basis of detection signals from the fuel sub-tank liquid amount sensor 13, the gas-liquid separation tank liquid amount sensor 31, and the air outlet pressure sensor 32 in accordance with a program stored in the memory. . That is, the FC-ECU 41 controls driving of the fuel circulation pump 11, the fuel supply pump 16, the air compressor 24, the water pump 34, and the radiator fan 35. The FC-ECU 41 controls the opening and closing of the fuel inlet valve 9, the fuel outlet valve 10, the purge valve 20, the air inlet valve 25, and the gas-liquid separation tank valve 30. Further, the FC-ECU 41 controls the opening degree of the air back pressure adjustment valve 28.

  In normal power generation control, the fuel inlet valve 9 and the fuel outlet valve 10 are opened, the fuel circulation pump 11 is driven, and the liquid fuel is supplied to the fuel flow path of the anode 3. On the other hand, the air compressor 24 is driven, the air inlet valve 25 is opened, the opening degree of the air back pressure adjusting valve 28 is adjusted, and air is supplied to the air flow path of the cathode 4.

  Thereby, in the fuel cell 2, an electrochemical reaction occurs, and an electromotive force is generated by the electrochemical reaction.

Specifically, the reaction represented by the reaction formula (1) occurs at the anode 3, and nitrogen gas (N ₂ ), water (H ₂ O), and electrons (e ⁻ ) are generated. The electrons move to the cathode 4 via an external circuit (not shown). Nitrogen gas and water are discharged together with unreacted liquid fuel from the fuel flow path to the fuel circulation path 8 through the fuel discharge port 10. On the other hand, at the cathode, the reaction represented by the reaction formula (2) occurs, and an anion (OH ⁻ ) is generated. The anion passes through the electrolyte membrane 5 and moves to the anode 3.

NH ₂ NH ₂ + 4OH ⁻ → N ₂ + 4H ₂ O + 4e ⁻ (1)

O ₂ + 2H ₂ O + 4e ⁻ → 4OH ⁻ (2)

  As a result, an electromotive force is generated between the anode 3 and the cathode 4 due to a power generation reaction (electrochemical reaction).

  The fuel supply pump 16 is driven when it becomes necessary to replenish the fuel circulation path 8 with liquid fuel.

  The purge valve 20 is normally open.

  FIG. 3 is a flowchart showing the flow of the liquid amount management control.

  While the normal power generation control is being executed, the liquid amount management control shown in FIG. 3 is executed by the FC-ECU 41 in parallel with the power generation control. By executing the liquid amount management control, the liquid amount in the fuel sub-tank 12 is held within an appropriate range, and as a result, the liquid amount on the fuel circulation path 8 is held in the appropriate range.

  In the liquid amount management control, first, the detection signal of the fuel sub tank liquid amount sensor 13 is referred to. For example, a fuel sub-tank liquid amount sensor 13 is configured to convert the amount of float provided in the fuel sub-tank 12 into a resistance value by a potentiometer and output the resistance value. Based on the detection signal of the fuel subtank liquid amount sensor 13, the liquid amount (position of the liquid level) in the fuel subtank 12 is detected. Whether or not the amount of liquid in the fuel sub-tank 12 is within a predetermined appropriate range, that is, whether the liquid amount is within a range that is larger than a predetermined proper range lower limit value Pmin and smaller than a predetermined proper range upper limit value Pmax. It is determined whether or not (step S1).

  The water and liquid fuel that cross leaked from the anode 3 to the cathode 4 are discharged to the air discharge path 26 together with the air flowing through the air flow path of the cathode 4. The amount of water and liquid fuel discharged to the air discharge path 26, particularly the amount of water discharged by steam to the air discharge path 26 (discharged steam amount) is near the air outlet 22 in the air discharge path 26. The smaller the pressure (air back pressure), the greater. Therefore, the amount of steam discharged from the cathode 4 to the air discharge path 26 can be adjusted by adjusting the air back pressure. The air back pressure can be adjusted by controlling the air back pressure adjusting valve 28.

  Therefore, when the amount of liquid in the fuel sub-tank 12 is outside the predetermined appropriate range (NO in step S1), the air back pressure adjustment valve 28 is controlled (step S2).

  Specifically, when the amount of liquid in the fuel sub-tank 12 is equal to or less than the appropriate range lower limit value Pmin, the opening of the air back pressure adjustment valve 28 is set to a predetermined opening that is smaller than the opening in normal power generation control. Be changed. As a result, the air back pressure increases, and the amount of steam discharged from the cathode 4 to the air discharge path 26 decreases. Then, along with the power generation reaction, water is generated at the anode 3, and the water is discharged to the fuel circulation path 8, thereby increasing the amount of liquid in the fuel sub tank 12.

  On the other hand, when the amount of liquid in the fuel sub-tank 12 is not less than the appropriate range upper limit value Pmax, the opening degree of the air back pressure adjustment valve 28 is changed to a predetermined opening degree that is larger than the opening degree in normal power generation control. . Thereby, air back pressure falls and the amount of vapor | steam discharged | emitted from the cathode 4 to the air discharge path 26 increases. As a result, the amount of water and liquid fuel that cross leaks from the anode 3 to the cathode 4 increases, and the amount of liquid in the fuel sub-tank 12 decreases.

  Thereafter, whether or not the amount of liquid in the fuel sub-tank 12 is within a predetermined target range, that is, within a range that is larger than a predetermined target range lower limit value Tmin and smaller than a predetermined target range upper limit value Tmax. It is determined whether or not (step S3). The target range is set within an appropriate range. That is, the target range lower limit value Tmin is larger than the appropriate range lower limit value Pmin (Tmin> Pmin), and the target range upper limit value Tmax is smaller than the appropriate range upper limit value Pmax (Tmax> Pmax).

  Until the amount of liquid in the fuel sub-tank 12 falls within the target range (NO in step S3), the control of the air back pressure adjustment valve 28 is continued (step S2).

  When the amount of liquid in the fuel sub-tank 12 falls within the target range (YES in step S3), the control of the air back pressure adjustment valve 28 is terminated, and the opening degree of the air back pressure adjustment valve 28 is the opening degree in normal power generation control. Then, the liquid amount management control is terminated.

  If the liquid amount in the fuel sub-tank 12 is within the appropriate range at the start of the liquid amount management control (YES in step S1), the liquid amount management control is immediately terminated.

  FIG. 4 is a flowchart showing the flow of liquid recovery control. 5A, 5B, and 5C are diagrams schematically showing changes in the amount of liquid in the gas-liquid separation tank.

  While normal power generation control is being executed, the liquid recovery control shown in FIG. 4 is executed by the FC-ECU 41 in parallel with the power generation control. This liquid recovery control is a control for recovering the liquid stored in the gas-liquid separation tank 27 to the fuel circulation path 8 through the recirculation path 29.

  As shown in FIG. 5A, the liquid contained in the air flowing into the gas-liquid separation tank 27 from the air discharge path 26 is captured by the porous metal body 51 provided in the gas-liquid separation tank 27 to be gas-liquid. It is stored at the bottom of the separation tank 27. Until the amount of liquid in the gas-liquid separation tank 27 reaches a certain value, the water level of the liquid does not rise to the float position of the gas-liquid separation tank liquid amount sensor 31, and the detection of the gas-liquid separation tank liquid amount sensor 31. The signal is off. At this time, the gas-liquid separation tank valve 30 is closed.

  When the amount of liquid in the gas-liquid separation tank 27 exceeds a predetermined recovery threshold, the water level of the liquid rises to the float position of the gas-liquid separation tank liquid amount sensor 31 as shown in FIG. The detection signal of the separation tank liquid amount sensor 31 is turned on.

  When the detection signal of the gas-liquid separation tank liquid amount sensor 31 is turned on (YES in step S11), the air back pressure adjustment valve 28 is controlled, and the opening degree of the air back pressure adjustment valve 28 is the opening degree in normal power generation control. Is changed to a predetermined opening smaller than (step S12). At this time, the gas-liquid separation tank valve 30 remains closed. Therefore, when the control of the air back pressure adjustment valve 28 is started, the internal pressure upstream of the air back pressure adjustment valve 28 in the air discharge path 26 in the air flow direction including the inside of the gas-liquid separation tank 27 increases. .

  Thereafter, it is checked whether or not the pressure detected by the air outlet pressure sensor 32, that is, the pressure (air back pressure) in the vicinity of the air outlet 22 in the air discharge path 26 has risen above a predetermined pressure (step S13). .

  Control of the air back pressure adjustment valve 28 is continued while the gas-liquid separation tank valve 30 is closed until the air back pressure rises above a predetermined pressure.

  When the air back pressure rises above a predetermined pressure (YES in step S13), the gas-liquid separation tank valve 30 is opened (step S14). Thereby, as shown in FIG. 5C, the liquid in the gas-liquid separation tank 27 is pushed out to the recirculation path 29 by the air back pressure. Then, the liquid flows into the gas-liquid separator 17 interposed in the fuel circulation path 8 through the recirculation path 29.

  When a predetermined time has elapsed since the gas-liquid separation tank valve 30 was opened (YES in step S15), the gas-liquid separation tank valve 30 is closed (step S16).

  Then, the control of the air back pressure adjustment valve 28 is finished (step S17), the opening degree of the air back pressure adjustment valve 28 is returned to the opening degree in the normal power generation control, and the liquid recovery control is finished.

  Even if the amount of liquid in the gas-liquid separation tank 27 has not reached the recovery threshold (NO in step S11), the liquid stored in the gas-liquid separation tank 27 is recovered in the fuel circulation path 8. When a certain period of time has elapsed since the operation (steps S12 to S17) was executed last time (YES in step S18), the operation of collecting the liquid stored in the gas-liquid separation tank 27 in the fuel circulation path 8 is executed. (Steps S12 to S18). Thereby, even if the gas-liquid separation tank liquid amount sensor 31 is out of order, the liquid stored in the gas-liquid separation tank 27 can be collected in the fuel circulation path 8 at regular time intervals. It is possible to prevent the liquid from being excessively accumulated in 27.

  FIG. 6 is a flowchart showing the flow of the liquid amount reduction control.

  Even if the liquid amount management control shown in FIG. 3 is executed, the liquid amount reduction shown in FIG. 6 is performed in order to reduce the liquid amount in the fuel sub tank 12 when the liquid amount in the fuel sub tank 12 continues to increase. Control is executed in a fail-safe manner.

  After the amount of liquid in the fuel subtank 12 detected by the fuel subtank liquid amount sensor 13 rises to the appropriate range upper limit value Pmax or more and the liquid amount management control shown in FIG. 3 is started (step S21), the fuel subtank 12 When the amount of the liquid continues to increase and the liquid amount increases to a certain value greater than the appropriate range upper limit value Pmax (YES in step S22), temperature control for temporarily increasing the temperature of the fuel cell 2 is performed. (Step S23).

  In this temperature control, for example, the water pump 34 and the radiator fan 35 are stopped. Thereby, the circulation of the cooling water in the cooling water circulation path 33 is stopped, and the cooling of the fuel cell 2 is stopped. On the other hand, the temperature of the fuel cell 2 rises by continuing the power generation of the fuel cell 2. When the temperature of the fuel cell 2 rises, the electrolyte membrane 5 expands thermally, and the holes formed in the electrolyte membrane 5 expand. Therefore, the amount of water and liquid fuel that permeate the electrolyte membrane 5 from the anode 3 and cross leak to the cathode 4 increases. As a result, the amount of liquid on the fuel circulation path 8 decreases, and the amount of liquid in the fuel sub tank 12 decreases.

  When the amount of liquid in the fuel sub-tank 12 falls below a certain value (YES in step S24), the temperature control is terminated (the driving of the water pump 34 and the radiator fan 35 is resumed), and the liquid amount reduction control is terminated. The

  As described above, the fuel cell 2 has a structure in which the anode 3 and the cathode 4 are disposed to face each other with the electrolyte membrane 5 interposed therebetween. The anode 3 is supplied with liquid fuel that circulates through the fuel circulation path 8. Air is supplied to the cathode 4. Thereby, in the fuel cell 2, a power generation reaction occurs, and an electromotive force is generated by the power generation reaction.

  Water is generated at the anode 3 as a product of the power generation reaction. Most of the water and unreacted liquid fuel are discharged from the anode 3 to the fuel circulation path 8, and a part of the water passes through the electrolyte membrane 5 from the anode 3 and cross leaks to the cathode. Therefore, the liquid discharged from the cathode 4 to the air discharge path 26 contains liquid. The air containing the liquid flows into the gas-liquid separation tank 27, and the liquid is separated from the air in the gas-liquid separation tank 27.

  The gas-liquid separation tank 27 is connected to the fuel circulation path 8 via the recirculation path 29. Thereby, the liquid separated in the gas-liquid separation tank 27 can be returned to the fuel circulation path 8 through the recirculation path 29. A gas-liquid separation tank valve 30 is interposed in the recirculation path 29. In addition, an air back pressure adjustment valve 28 for adjusting the pressure in the air discharge path 26 is interposed in the air discharge path 26 on the downstream side of the gas-liquid separation tank 27 in the air flow direction.

  When the liquid separated in the gas-liquid separation tank 27 is returned to the fuel circulation path 8, the air back pressure adjustment valve 28 is controlled before the gas-liquid separation tank valve 30 is opened, and the air back pressure adjustment valve is controlled. The opening degree of 28 is made small. Thereby, the pressure in the air discharge path 26 and the gas-liquid separation tank 27 increases. Then, after the pressure rises, the gas-liquid separation tank valve 30 is opened. When the gas-liquid separation tank valve 30 is opened, the liquid in the gas-liquid separation tank 27 is sent to the recirculation path 29 due to the pressure in the gas-liquid separation tank 27. Therefore, no pump or the like is required to return the liquid in the gas-liquid separation tank 27 to the fuel circulation path 8.

  Therefore, it is possible to return the cross-leaked liquid fuel and water to the fuel circulation path 8 while suppressing an increase in cost.

  As mentioned above, although one Embodiment of this invention was described, this invention can also be implemented with another form.

  For example, in the above-described embodiment, the case where the amount of steam discharged from the cathode 4 is adjusted by adjusting the air back pressure is taken as an example. However, the amount of vapor discharged from the cathode 4 varies not only with the air back pressure but also with the temperature of the fuel cell 2 and the flow rate of air supplied to the air flow path of the cathode 4. Specifically, the higher the temperature of the fuel cell 2, the greater the amount of vapor discharged from the cathode 4. Further, as the flow rate of air supplied to the air flow path of the cathode 4 increases, the amount of vapor discharged from the cathode 4 increases.

  Therefore, in addition to the control of the air back pressure adjustment valve 28, the water pump 34 and the radiator fan 35 for cooling the fuel cell 2 may be controlled to adjust the temperature of the fuel cell 2. In addition to the control of the air back pressure adjustment valve 28, the air compressor 24 may be controlled to adjust the flow rate of air supplied to the air flow path of the cathode 4. Furthermore, in addition to the control of the air back pressure adjustment valve 28, both the control of the water pump 34 and the radiator fan 35 and the control of the air compressor 24 may be performed. As a result, the amount of steam discharged from the cathode 4 can be adjusted more finely, and the amount of liquid on the fuel circulation path 8 can be managed better.

  Even if the air back pressure is changed, the power generation output of the fuel cell system 1 as a whole does not substantially change. When the air back pressure increases, the power generation efficiency in the fuel cell 2 increases. On the other hand, the power consumption of the air compressor 24 increases. When the air back pressure decreases, the power consumption of the air compressor 24 decreases. Because it goes down. Therefore, the adjustment of the amount of steam discharged from the cathode 4 by adjusting the air back pressure is excellent in that the influence on the power generation output of the fuel cell system 1 is small.

  Further, in order to detect the amount of liquid in the fuel sub-tank 12, a configuration provided with a fuel sub-tank liquid amount sensor 13 including a potentiometer is taken up. However, the amount of liquid on the fuel circulation path 8 including the inside of the fuel sub-tank 12 may be calculated by, for example, a method proposed in Japanese Patent Application Laid-Open No. 2011-216341.

That is, in the method according to the proposal, power generation in the fuel cell 2 is performed with the fuel circulation path 8 closed from the outside. Then, the amount of current generated from the fuel cell 2 at a certain time is calculated, and based on the amount of current, the fuel consumption that is the amount of liquid fuel consumed at the certain time, the N ₂ gas generated at the anode 3 at the certain time. And the amount of produced water, which is the amount of water produced at the anode 3 in a certain time, is calculated. Based on these, the void volume in the fuel circulation path 8 (including the anode 3 and the gas-liquid separator 17) at the end of the fixed time is calculated, and the calculated void volume is calculated from the total volume in the fuel circulation path 8. By subtracting the volume, the amount of liquid in the fuel circulation path 8 is calculated.

  Further, in the temperature control for temporarily raising the temperature of the fuel cell 2, the water pump 34 and the radiator fan 35 are stopped while the power generation of the fuel cell 2 is continued. As an alternative control, in order to temporarily raise the temperature of the fuel cell 2, the three-way valve 37 is switched without stopping the water pump 34 while the power generation of the fuel cell 2 is continued, and the fuel cell 2 The cooling water discharged from the cooling water outlet is passed through the branch pipe 38 so that the cooling water may be sent again to the fuel cell 2 without passing through the radiator 36.

  In addition, various design changes can be made to the above-described configuration within the scope of the matters described in the claims.

DESCRIPTION OF SYMBOLS 1 Fuel cell system 2 Fuel cell 3 Anode 4 Cathode 5 Electrolyte membrane 8 Fuel circulation path 23 Air supply path (air supply means)
24 Air compressor (air supply means)
26 Air discharge path (discharge path)
27 Gas-liquid separation tank (gas-liquid separator)
28 Air back pressure adjustment valve (back pressure adjustment valve)
29 Recirculation path 30 Gas-liquid separation tank valve (open / close valve)
41 FC-ECU (valve control means)

Claims (1)

A fuel cell having an anode and a cathode disposed opposite to each other with an electrolyte membrane interposed therebetween;
A fuel circulation path through which liquid fuel circulates via the anode;
Air supply means for supplying air to the cathode;
A discharge path for discharging gas from the cathode;
A back pressure adjusting valve for adjusting the pressure in the discharge passage;
A gas-liquid separator that is interposed upstream of the back pressure regulating valve in the exhaust passage in the gas flow direction and separates the gas discharged from the cathode and the liquid contained in the gas;
A recirculation path for returning the liquid separated by the gas-liquid separator to the fuel circulation path;
An on-off valve interposed in the recirculation path;
After controlling the back pressure adjusting valve and the on-off valve and closing the on-off valve, reducing the opening of the back pressure adjusting valve and increasing the pressure in the gas-liquid separator, And a valve control means for opening the on-off valve.

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