JP2019075254A - Fuel cell system - Google Patents

Abstract

To perform abnormality determination accurately with simple configuration, in a fuel cell system where water is sprayed to a heat exchanger for cooling fuel cells.SOLUTION: A fuel cell system includes a fuel cell 10 where hydrogen and oxygen are reacted electrochemically, and water is generated by the electrochemical reaction, water storage parts 31, 35 for storing water collected from the fuel cell 10, a heat exchanger 22 performing heat exchange of a heat exchange medium received heat from the fuel cell 10 and the fresh air, and ejecting heat generated in the fuel cell 10 to the outside of the system, a spray part 39 for spraying water in the water storage parts to the heat exchanger 22 for cooling the heat exchanger 22 by using the latent heat of vaporization, and an abnormality determination part 50 for determining abnormality related to water spray from the spray part 39. The abnormality determination part 50 performs abnormality determination on the basis of the difference of the theoretical heat release of the heat exchanger 22 when water is not sprayed to the heat exchanger 22, and the actually measured heat release of the heat exchanger 22 when water is sprayed to the heat exchanger 22.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a fuel cell system for dispersing water in a heat exchanger for cooling a fuel cell.

  Patent Document 1 proposes that the generated water of a fuel cell mounted in a vehicle be collected and stored in a tank, and the stored water be dispersed to a radiator to improve the cooling capacity of the radiator. Further, Patent Document 2 proposes that in the cooling system of the fuel cell system, the abnormality of the cooling system circuit is determined from the power consumption of the cooling water pump. Therefore, in the configuration of Patent Document 1, it is conceivable to apply the abnormality determination of Patent Document 2.

JP 2002-343396 A JP, 2009-170378, A

  However, as described in Patent Document 2, in the case where the abnormality determination is performed by the power consumption of the pump, a current sensor or a voltage sensor is required to detect the power consumption of the pump.

  Moreover, in the structure which spreads water to a radiator like patent document 1, abnormality generation | occurrence | production by clogging of a dispersion | distribution nozzle is assumed. Clogging of the spray nozzle increases the pressure loss of water supplied to the spray nozzle and decreases the flow rate, but the change in the power consumption of the pump accompanying this is small, and the absolute value of the power consumption of the pump is also small Therefore, it is difficult to perform abnormality determination with high accuracy.

  SUMMARY OF THE INVENTION In view of the above-described point, the present invention has an object of performing abnormality determination with high accuracy with a simple configuration in a fuel cell system for dispersing water in a heat exchanger for cooling a fuel cell.

  In order to achieve the above object, in the invention according to claim 1, a fuel cell (10) which electrochemically reacts hydrogen and oxygen to generate water along with the electrochemical reaction, and water recovered from the fuel cell A water storage section (31, 35) for storing the heat, heat exchange between the heat exchange medium which receives heat from the fuel cell and the outside air, and the heat exchanger (22) for releasing the heat generated by the fuel cell to the outside of the system; In order to cool the heat exchanger by utilizing the latent heat of evaporation of water, a spraying section (39) which sprays water in the water storage section to the heat exchanger, and an abnormality determining section which determines an abnormality related to the spraying of water from the spraying section (50), and the abnormality determination unit is a theoretical heat release amount which is a theoretical value of the heat release amount of the heat exchanger in the case where the water is not spread in the heat exchanger, and when the water is dispersed in the heat exchanger Based on the difference between the measured heat release amount, which is the measured value of the heat release amount of the heat exchanger, And performing constant.

  According to the present invention, the abnormality determination regarding the dispersion of water to the heat exchanger is performed based on the theoretical heat release amount and the actually measured heat release amount of the heat exchanger, so that a simple configuration can be achieved without adding a new configuration. Abnormality determination can be performed.

  In addition, the heat release amount of the heat exchanger is larger in absolute value than the power consumption amount of the pump. Therefore, when an abnormality occurs in which the amount of water sprayed to the heat exchanger runs short, the change in the heat release amount of the heat exchanger becomes larger than the change in the amount of power of the pump. Therefore, the abnormality determination can be performed with high accuracy by performing the abnormality determination on the dispersion of the water to the heat exchanger based on the heat release amount of the heat exchanger.

  In addition, the code | symbol in the parenthesis of each said component shows the correspondence with the specific means as described in embodiment mentioned later.

It is a conceptual diagram which shows the whole structure of the fuel cell system of 1st Embodiment. It is a conceptual diagram which shows the cooling system of the fuel cell system of 1st Embodiment. It is a block diagram showing a control system of a fuel cell system of a 1st embodiment. It is a flowchart which shows abnormality determination control of the fuel cell system of 1st Embodiment. It is a flowchart which shows abnormality determination control of the fuel cell system of 2nd Embodiment.

First Embodiment
Hereinafter, a first embodiment of the present invention will be described based on FIGS. 1 to 4. FIG. 1 is an entire configuration view showing a fuel cell system according to the first embodiment. This fuel cell system is applied to a so-called fuel cell vehicle, which is a type of electric vehicle, and supplies power to an electric load such as a vehicle travel electric motor.

  As shown in FIG. 1, the fuel cell system includes a fuel cell (FC stack) 10 that generates electric power by using an electrochemical reaction of hydrogen and oxygen. The fuel cell 10 is configured to supply power to an electric device such as an inverter (not shown). The inverter converts direct current supplied from the fuel cell 10 into alternating current and supplies it to a traveling motor (load) to drive the motor.

  In the first embodiment, a solid polymer electrolyte fuel cell is used as the fuel cell 10, and a plurality of cells as basic units are stacked. Each cell has a configuration in which an electrolyte membrane is sandwiched between a pair of electrodes.

  The fuel cell 10 is supplied with hydrogen via the hydrogen supply passage 11 and oxygen is supplied via the air supply passage 12. In the fuel cell 10, the following electrochemical reaction of hydrogen and oxygen occurs to generate electric energy.

(Negative ^{_{electrode) H 2 → 2H + + 2e}} -
(Positive _{^{side) 2H + + 1 / 2O 2}} + 2e - → H 2 O
For this electrochemical reaction, the electrolyte membrane in the fuel cell 10 needs to be in a wet state containing water. For this reason, hydrogen and air supplied to the fuel cell 10 are humidified, and the humidified gas is supplied to the fuel cell 10 to humidify the electrolyte in the fuel cell 10. The humidification of hydrogen and air supplied to the fuel cell 10 can be performed by a humidifier or the like not shown.

  Unreacted oxygen which has not been used for the electrochemical reaction is discharged from the fuel cell 10 as exhaust gas through the exhaust passage 13. Further, in the fuel cell 10, generated water is generated by an electrochemical reaction, and this moisture is discharged from the fuel cell 10 through the exhaust passage 13 in a state of being contained in the exhaust gas.

  During power generation, the fuel cell 10 generates heat due to the above-mentioned electrochemical reaction. The fuel cell 10 needs to be maintained at a constant temperature (for example, about 80 ° C.) during operation for power generation efficiency. In addition, since the electrolyte membrane inside the fuel cell 10 is broken due to high temperature if the predetermined allowable upper limit temperature is exceeded, it is necessary to keep the fuel cell 10 at the allowable temperature or less.

  As shown in FIG. 2, the fuel cell system includes a cooling water passage 20 that circulates and supplies cooling water to the fuel cell 10. The cooling water passage 20 is provided with a cooling water pump 21 for circulating the cooling water.

  A radiator 22 is provided in the cooling water passage 20. The radiator 22 is a heat exchanger that exchanges heat between the cooling water that has been heated to a high temperature by the fuel cell 10 and the outside air blown by the fan 22 a and releases the heat generated by the fuel cell 10 out of the system. The rotation of the fan 22a is controlled by the control unit 50 described later.

  A sub radiator 23 is provided in parallel with the radiator 22 in the cooling water passage 20. The sub radiator 23 is a heat exchanger that exchanges heat between cooling water and the atmosphere, and is used supplementally when the cooling capacity is insufficient with only the radiator 22 such as when the fuel cell 2 is under high load.

  The coolant passage 20 is provided with a bypass passage 24 for bypassing the radiator 22. The bypass passage 24 is provided in parallel with the radiator 22.

  A cooling water control valve 25 is provided at a branch portion of the cooling water passage 20 and the bypass passage 24. The coolant control valve 25 can adjust the ratio of the coolant flow rate flowing to the radiator 22 to the coolant flow rate flowing to the bypass passage 24 by adjusting the valve opening degree.

  At the outlet side of the fuel cell 10 in the cooling water passage 20, a first water temperature sensor 26 for detecting the temperature of the cooling water flowing out of the fuel cell 10 is provided. The temperature of the coolant flowing out of the fuel cell 10 (that is, the outlet temperature of the fuel cell 10) can also be referred to as the temperature of the coolant that flows into the radiator 22 (that is, the inlet temperature of the radiator 22).

  At the outlet side of the radiator 22 in the cooling water passage 20, a second water temperature sensor 27 for detecting the temperature of the cooling water flowing out of the radiator 22 is provided. The temperature of the coolant flowing out of the radiator 22 (that is, the outlet temperature of the radiator 22) can also be referred to as the temperature of the coolant flowing into the fuel cell 10 (that is, the inlet temperature of the fuel cell 10).

  Returning to FIG. 1, a gas-liquid separator 30 is provided in the exhaust passage 13 through which the exhaust gas of the fuel cell 10 passes. The gas-liquid separator 30 constitutes a water recovery unit that recovers the water produced by the fuel cell 10 contained in the exhaust gas.

  Below the gas-liquid separator 30, a first tank 31 is provided. The gas-liquid separator 30 is provided with a communication passage 30 a for supplying the water of the gas-liquid separator 30 to the first tank 31. The end of the communication passage 30 a is located inside the first tank 31.

  The generated water of the fuel cell 10 recovered by the gas-liquid separator 30 is stored in the first tank 31. The first tank 31 needs to be provided vertically below the gas-liquid separator 30, and it is difficult to increase the installation space. Therefore, a small tank is used as the first tank 31.

  The first tank 31 is provided with a lower limit liquid level sensor 31a that detects whether the water level of stored water is lower than the lower limit value. In addition, the first tank 31 is provided with a discharge passage 31 b for discharging excess water and air inside. The discharge passage 31 b is provided in the upper part of the first tank 31. When the water level of the first tank 31 exceeds the upper limit value, the water of the first tank 31 is discharged to the outside through the discharge passage 31 b.

  The stored water of the first tank 31 can be supplied to the second tank 35 via the intertank passage 32. An intertank pump 33 is provided in the intertank passage 32 for supplying the storage water of the first tank 31 to the second tank 35. On the downstream side of the intertank pump 33 in the intertank passage 32, a check valve 34 is provided to prevent the backflow of water.

  The water supplied from the first tank 31 is stored in the second tank 35. The second tank 35 has a volume larger than that of the first tank 31. In the present embodiment, the first tank 31 is positioned as a sub tank, and the second tank 35 is positioned as a main tank.

  The second tank 35 is provided with an upper limit liquid level sensor 35 a that detects whether the water level of stored water exceeds the upper limit value. In addition, the second tank 35 is provided with an external communication portion 35 b. The external communication portion 35 b is used for the purpose of discharging excess air from the inside of the second tank 35 and for the purpose of supplying water to the second tank 35 from the outside.

  The storage water of the second tank 35 is supplied to the spray unit 39 via the spray passage 36. The spraying unit 39 is a water using unit that uses tank storage water for the purpose of spraying water on the surface of the radiator 22.

  The spraying passage 36 is provided with a spraying pump 37 for supplying the storage water of the second tank 35 to the spraying portion 39. On the downstream side of the spray pump 37 in the spray passage 36, a check valve 38 is provided to prevent backflow of water.

  The spray pump 37 can adjust the flow rate of water supplied to the spray unit 39. The flow rate adjustment by the distribution pump 37 can be performed, for example, by voltage control or duty ratio control.

  The spray unit 39 is provided at the tip of the spray passage 33. The scattering portion 39 is disposed in the vicinity of the upper portion of the radiator 22 on the windward side (i.e., the vehicle front side) of the radiator 22.

  The spreader 39 communicates with the housing having an internal space into which water can flow, and the inside and the outside of the housing, and has a plurality of communication holes (for example, spray nozzles) capable of dispersing water. The communication hole of the scattering portion 39 is opposed to the radiator 22, and water can be dispersed from the communication hole of the scattering portion 39 to the surface of the radiator 22.

  By spraying the radiator 22 with water, the water evaporates on the surface of the radiator 22. The cooling capacity of the radiator 22 can be improved by utilizing the latent heat of evaporation of water.

  The spraying of water by the spraying unit 39 is performed when the calorific value of the fuel cell 10 increases as the amount of power generation of the fuel cell 10 increases, and the coolant temperature rises. That is, the spreading of the water by the spreading unit 39 is performed when the cooling capacity of the radiator 22 needs to be improved.

  For example, when the outlet temperature of the fuel cell 10 reaches a predetermined allowable upper limit temperature, water can be sprayed by the spraying unit 39. The allowable upper limit temperature may be determined based on the heat resistant temperature (for example, about 110 ° C.) of the electrolyte membrane of the fuel cell 10, and is a value that can be arbitrarily set.

  As shown in FIG. 3, a control unit 50 is provided in the fuel cell system. The control unit 50 is a control unit that controls the operation of each control target device that constitutes the fuel cell system. The control unit 50 is configured of a known microcomputer including a CPU, a ROM, a RAM, and the like, and peripheral circuits thereof.

  Various information is input to the control unit 50 from the water temperature sensors 26, 27, the liquid level sensors 31a, 35a, the outside air temperature sensor 51, the vehicle speed sensor 52, and the like. The outside air temperature sensor 51 is a sensor that detects the outside air temperature, and the vehicle speed sensor 52 is a sensor that detects the speed of the fuel cell vehicle.

  Control signals are output from the control unit 50 to control target devices such as the cooling water pump 21, the radiator fan 22a, the cooling water control valve 25, the intertank pump 33, and the distribution pump 37. The control unit 50 can control the operation of each control target device based on the control program stored in the ROM.

  Further, to the control unit 50, the rotation number of the cooling water pump 21, the rotation number of the radiator fan 22a, and the valve opening degree of the cooling water control valve 25 are input.

  When the control unit 50 according to the present embodiment applies water to the radiator 22 from the application unit 39, the control unit 50 performs an abnormality determination as to whether an abnormality relating to the application of water has occurred. An abnormality relating to the water distribution occurs because the required amount of water is not distributed to the radiator 22 from the distribution unit 39, that is, the amount of water to be dispersed to the radiator 22 is insufficient.

  It is assumed that an abnormality relating to the water distribution is caused by a failure of the distribution passage 36, the distribution pump 37, the distribution unit 39, and the like. As problems with these devices, for example, clogging of the spray unit 39, failure of the spray pump 37, water leakage in the spray passage 36, and the like can be considered.

  When the required amount of water is not dispersed to the radiator 22, the amount of water evaporated on the surface of the radiator 22 decreases, and the effect of increasing the heat release amount of the radiator 22 due to the latent heat of evaporation of water decreases. Therefore, in the present embodiment, the control unit 50 performs an abnormality determination as to whether or not an abnormality relating to water dispersion has occurred based on the heat release amount of the radiator 22.

  In the present embodiment, when the value obtained by subtracting the theoretical heat release amount from the actually measured heat release amount of the radiator 22 is less than a predetermined value, it is determined that an abnormality related to the water dispersion has occurred.

  The theoretical heat release amount is a theoretical value of the heat release amount of the radiator 22 when the water is not dispersed to the radiator 22. The theoretical heat release amount of the radiator 22 can be obtained based on the temperature and flow rate of the cooling water flowing into the radiator 22 and the temperature and air flow rate of the outside air passing through the radiator 22.

  The flow rate of the cooling water can be obtained based on the rotational speed of the cooling water pump 21 and the valve opening degree of the cooling water control valve 25. The air volume of the outside air can be acquired based on the vehicle speed and the number of rotations of the radiator fan 22a.

  The actually measured heat radiation amount is a measured value of the heat radiation amount of the radiator 22 when water is dispersed to the radiator 22. The actually measured heat radiation amount of the radiator 22 can be calculated from the difference between the inlet temperature and the outlet temperature of the radiator 22, the flow rate of the cooling water, the specific heat of the cooling water, and the like.

  The predetermined value in the present embodiment is an abnormality determination reference value serving as a reference for abnormality determination using the heat release amount, and may be set in advance based on the heat release amount of the radiator 22 which is increased by spraying water on the radiator 22. . The predetermined value can be set based on the amount of water sprayed to the radiator 22, the proportion of the sprayed water that evaporates on the surface of the radiator 22, the latent heat of evaporation of water, and the like. The spread amount of water can be obtained based on the flow rate of water supplied to the spreader 39, the nozzle diameter of the spreader 39, and the like. The flow rate of water supplied to the spray unit 39 can be acquired based on the number of rotations of the spray pump 37 when water is supplied to the spray unit 39.

  Next, abnormality determination control for determining an abnormality relating to the dispersion of water to the radiator 22 will be described based on the flowchart of FIG. 4. The abnormality determination control shown in FIG. 4 is a part of the main routine executed by the control unit 50, and is repeatedly executed in a predetermined cycle.

  First, it is determined whether the water is being sprayed from the spraying unit 39 to the radiator 22 (S10). As a result, if it is determined that the radiator 22 is not sprayed with water (S10: NO), the abnormality determination process is ended.

  On the other hand, when it is determined that the water is sprayed to the radiator 22 (S10: YES), the outside air temperature, the vehicle speed, the number of rotations of the cooling water pump 21, the number of rotations of the radiator fan 22a, the inlet of the radiator 22 Various information such as the temperature, the outlet temperature of the radiator 22, the valve opening degree of the cooling water control valve 25 and the like are acquired (S11).

  The flow rate of the cooling water can be obtained based on the rotational speed of the cooling water pump 21 and the valve opening degree of the cooling water control valve 25. The flow rate of the outside air can be acquired based on the vehicle speed and the rotational speed of the radiator fan 22a.

  Next, based on the various information acquired in S11, the theoretical heat release amount of the radiator 22 is obtained (S12), and the actual heat release amount of the radiator 22 is obtained (S13).

  Next, it is determined whether the difference between the heat release amount obtained by subtracting the theoretical heat release amount from the actually measured heat release amount of the radiator 22 exceeds a predetermined value (S14). As a result, when it is determined that the difference in the heat release amount exceeds the predetermined value (S14: YES), it is determined that no abnormality relating to the dispersion of water to the radiator 22 has occurred (S15).

  On the other hand, when it is determined that the difference in the heat release amount does not exceed the predetermined value (S14: NO), it is determined that an abnormality relating to the dispersion of water to the radiator 22 has occurred (S16).

  According to the present embodiment described above, the abnormality determination regarding the dispersion of water to the radiator 22 is performed based on the theoretical heat release amount of the radiator 22 and the actually measured heat release amount. As a result, it is possible to perform the abnormality determination on the dispersion of water to the radiator 22 without adding a new configuration.

  Further, the heat release amount of the radiator 22 is larger in absolute value than the power consumption amount of the distribution pump 37. Therefore, when an abnormality occurs in which the amount of water sprayed to the radiator 22 is insufficient, the change in the amount of heat released from the radiator 22 is larger than the change in the amount of power of the spray pump 37. Therefore, the abnormality determination can be performed with high accuracy by performing the abnormality determination on the dispersion of the water to the radiator 22 based on the heat release amount of the radiator 22.

Second Embodiment
Next, a second embodiment of the present invention will be described. The second embodiment differs from the first embodiment in the contents of the abnormality determination control. Descriptions of parts similar to those of the first embodiment are omitted, and only different parts are described.

  When water distribution to the radiator 22 is started, the heat dissipation capacity of the radiator 22 is improved by the latent heat of evaporation of water, and the outlet temperature of the radiator 22 is lowered. For this reason, when water distribution to the radiator 22 is started, the difference between the inlet temperature and the outlet temperature of the radiator 22 (hereinafter referred to as "the radiator inlet / outlet temperature difference") becomes larger than before the water is distributed to the radiator 22. .

  Therefore, in the second embodiment, the control unit 50 controls the water to the radiator 22 based on the temperature difference between the radiator inlet and outlet before the water is dispersed to the radiator 22 and the radiator inlet and outlet temperature during the water distribution to the radiator 22. Anomaly determination regarding the dispersion of In the second embodiment, when the value obtained by subtracting the radiator inlet / outlet temperature difference during water distribution to the radiator 22 from the radiator inlet / outlet temperature difference before water distribution to the radiator 22 is lower than a predetermined value, It is determined that an abnormality has occurred.

  The predetermined value in the second embodiment is an abnormality determination reference value serving as a reference for abnormality determination using the radiator inlet / outlet temperature difference, and is previously determined based on the outlet temperature of the radiator 22 which is lowered by spraying water on the radiator 22. It should be set.

  As shown in FIG. 5, in the abnormality determination control of the second embodiment, it is determined whether the outlet temperature of the fuel cell 10 exceeds the allowable upper limit temperature (S20). As a result, when it is determined that the outlet temperature of the fuel cell 10 does not exceed the allowable upper limit temperature (S20: NO), the abnormality determination control is ended.

  On the other hand, when it is determined that the outlet temperature of the fuel cell 10 is higher than the allowable upper limit temperature (S20: YES), the inlet temperature and the outlet temperature of the radiator 22 are acquired, and the radiator before water is dispersed to the radiator 22 An entrance / exit temperature difference is acquired (S21).

  Next, spraying of water from the spraying unit 39 to the radiator 22 is started (S22). Then, the inlet temperature and the outlet temperature of the radiator 22 are acquired, and the radiator inlet / outlet temperature difference during the distribution of water to the radiator 22 is acquired (S23).

  Next, it is determined whether a subtraction value obtained by subtracting the radiator inlet / outlet temperature difference before water distribution to the radiator 22 from the radiator inlet / outlet temperature difference during water distribution to the radiator 22 exceeds a predetermined value (S24). As a result, when it is determined that the subtraction value exceeds the predetermined value (S24: YES), it is determined that no abnormality relating to the dispersion of water to the radiator 22 has occurred (S25). On the other hand, when it is determined that the subtraction value does not exceed the predetermined value (S24: NO), it is determined that an abnormality relating to the dispersion of water to the radiator 22 has occurred (S26).

  According to the second embodiment described above, based on the inlet / outlet temperature of the radiator 22 before and after the water is dispersed, the abnormality determination regarding the dispersion of water to the radiator 22 is performed. As a result, it is possible to perform the abnormality determination on the dispersion of water to the radiator 22 without adding a new configuration.

  Further, the temperature of the cooling water flowing through the radiator 22 has a larger absolute value than the amount of power consumption of the distribution pump 37. Therefore, when an abnormality occurs in which the amount of water sprayed to the radiator 22 is insufficient, the change in the radiator inlet / outlet temperature becomes larger than the change in the amount of power of the spray pump 37. Therefore, the abnormality determination can be performed with high accuracy by performing the abnormality determination on the dispersion of the water to the radiator 22 based on the inlet / outlet temperature of the radiator 22.

  In addition, when the radiator 22 is degraded, the heat radiation performance of the radiator 22 may be reduced. Even in such a case, the abnormality determination can be performed with high accuracy by performing the abnormality determination on the dispersion of water to the radiator 22 based on the inlet / outlet temperature of the radiator 22.

  Further, in the second embodiment, if conditions other than the water spray change before and during the water spray, the accuracy of the abnormality determination may be affected. The conditions other than water distribution are conditions that affect the coolant temperature such as the outside air temperature, the vehicle speed, the rotation speed of the cooling water pump 21, the rotation speed of the fan radiator 22a, and the opening degree of the cooling water control valve 25.

  For this reason, after S21 is performed in the above-mentioned abnormality determination control, it is desirable to execute S23 in as short a time as possible after the radiator outlet temperature is lowered by the water dispersion. As a result, it is possible to avoid that the conditions other than the water dispersion change as much as possible, and it is possible to suppress the decrease in the accuracy of the abnormality determination.

  If the conditions other than the water distribution change before the water distribution and during the water distribution, the radiator inlet / outlet temperature difference may be corrected based on the changes in these conditions.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and can be variously modified as follows without departing from the spirit of the present invention. In addition, the means disclosed in each of the above embodiments may be combined as appropriate in the feasible range.

  (1) In the configuration of each of the above embodiments, the power consumption of the spray pump 37 is detected, and when it is determined that an abnormality related to the spray of water to the radiator 22 has occurred, the spray pump 37 The cause of the abnormality may be classified based on the power consumption. By configuring the control unit 50 to receive the drive voltage value and the drive current value of the spray pump 37, the control unit 50 can acquire the power consumption of the spray pump 37.

  For example, when clogging of the spray unit 39 occurs, the power consumption of the spray pump 37 increases. When a water leak occurs in the spray passage 36, the power consumption of the spray pump 37 is reduced. For this reason, if it is determined that an abnormality relating to the dispersion of water to the radiator 22 is occurring, if the power consumption of the distribution pump 37 exceeds the reference value to determine clogging, the distribution unit 39 It can be determined that an abnormality attributable to the clogging of the In addition, when it is determined that an abnormality relating to the dispersion of water to the radiator 22 is occurring, if the power consumption of the distribution pump 37 is below the reference value to determine the water leak, the water of the cooling water It can be determined that an abnormality caused by a leak has occurred.

  (2) In the above embodiments, the example in which the two tanks 31 and 35 are provided as the water storage unit for storing the generated water of the fuel cell 10 has been described. However, the invention is not limited thereto. .

10 fuel cell 22 radiator (heat exchanger)
30 gas-liquid separator 31 first tank (water storage section)
35 2nd tank (water storage part)
37 Scattering pump 39 Scattering unit 50 Control unit (abnormality judging unit)

Claims (4)

A fuel cell (10) which electrochemically reacts hydrogen and oxygen to generate water in accordance with the electrochemical reaction;
Water storage sections (31, 35) for storing water recovered from the fuel cell;
A heat exchanger (22) which exchanges heat between a heat exchange medium which receives heat from the fuel cell and the outside air, and releases the heat generated by the fuel cell to the outside of the system;
A sparging section (39) for sparging the water in the water storage section to the heat exchanger in order to cool the heat exchanger using the latent heat of evaporation of water;
And an abnormality determination unit (50) that determines an abnormality relating to water dispersion from the dispersion unit,
The abnormality determination unit is a theoretical heat release amount which is a theoretical value of the heat release amount of the heat exchanger when the water is not sprayed to the heat exchanger, and the heat exchange when water is dispersed to the heat exchanger The fuel cell system which determines the said abnormality based on the difference with the measurement heat release which is a measurement value of the heat release of a fuel cell.   The abnormality determination unit acquires the theoretical heat release amount based on the temperature and the flow rate of the heat exchange medium flowing into the heat exchanger, and the temperature and the flow rate of the outside air passing through the heat exchanger. The fuel cell system described.   3. The apparatus according to claim 1, wherein the abnormality determination unit acquires the actual heat release amount based on the temperature of the heat exchange medium flowing into the heat exchanger and the temperature of the heat exchange medium flowing out of the heat exchanger. The fuel cell system described. A fuel cell (10) which electrochemically reacts hydrogen and oxygen to generate water in accordance with the electrochemical reaction;
Water storage sections (31, 35) for storing water recovered from the fuel cell;
A heat exchanger (22) which exchanges heat between a heat exchange medium which receives heat from the fuel cell and the outside air, and releases the heat generated by the fuel cell to the outside of the system;
An inlet temperature detection unit (26) that detects an inlet temperature that is a temperature of the heat exchange medium flowing into the heat exchanger;
An outlet temperature detection unit (27) that detects an outlet temperature that is a temperature of the heat exchange medium flowing out of the heat exchanger;
A spraying unit (39) for spraying the water in the water storage unit to the fuel cell to cool the heat exchanger using the latent heat of evaporation of water;
And an abnormality determination unit (50) that determines an abnormality relating to water dispersion from the dispersion unit,
The abnormality determination unit, the heat exchanger may be a difference between the inlet temperature and the outlet temperature before the water is sprayed to the heat exchanger, and the inlet when water is sprayed to the heat exchanger. The fuel cell system which performs the determination of the said abnormality based on the difference of a temperature and the said exit temperature.

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