JP5194827B2 - Fuel cell system - Google Patents

Description

  The present invention relates to a fuel cell system.

  Conventionally, a fuel cell system includes a cooling system for keeping the internal temperature of the fuel cell constant. The cooling system includes a refrigerant pump, a radiator, piping for circulating the refrigerant, and a temperature sensor that measures the refrigerant temperature near the inlet and outlet of the fuel cell. The refrigerant temperature at the fuel cell outlet is regarded as the internal temperature of the fuel cell, and the refrigerant pump and the radiator fan are controlled based on the refrigerant temperature at the fuel cell outlet to keep the internal temperature of the fuel cell constant. Yes.

  However, for example, when the refrigerant pump fails and the refrigerant is not supplied to the fuel cell, the internal temperature of the fuel cell rises, but the refrigerant temperature at the fuel cell outlet does not rise. That is, the refrigerant temperature at the fuel cell outlet may not represent the internal temperature of the fuel cell. For this reason, an increase in the temperature of the fuel cell cannot be detected, and the fuel cell may fail due to a high temperature.

  To solve this problem, it is conceivable to directly measure the temperature of the fuel cell. However, it is difficult to embed a temperature sensor in each single cell of the fuel cell stack, and there is a problem that costs are increased. Therefore, a technique for determining an abnormality of the cooling system such as a failure of the refrigerant pump based on the refrigerant flow rate and the refrigerant pressure has been proposed (see, for example, Patent Document 1).

JP 2002-184435 A JP-A-10-092452 JP 2005-122959 A

  However, as described above, when a flow meter for measuring the refrigerant flow rate and a pressure gauge for measuring the refrigerant pressure are added, there is a problem that costs increase. Therefore, the present invention has been made in view of such a problem, and an object thereof is to provide another technique for determining an abnormality of a cooling system.

SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples. One aspect of the present invention is a fuel cell system, a cooling system having a refrigerant pump for circulating refrigerant inside the fuel cell; a power consumption detector that detects power consumption of the refrigerant pump; and the refrigerant pump A power consumption estimation unit that estimates power consumption of the refrigerant pump based on the rotation speed of the refrigerant and pressure loss of the refrigerant; a detected value of power consumption of the refrigerant pump detected by the power consumption detection unit; And a determination unit that determines abnormality of the cooling system without using the pressure value of the refrigerant based on the estimated value of power consumption of the refrigerant pump estimated by the power consumption estimation unit. For example, in a fuel cell system, when there is an abnormality in the cooling system in which a pipe is crushed, if the cavitation occurs due to the crushing of the pipe and the flow rate of the refrigerant decreases, the refrigerant pump runs idle, and the power consumption in the refrigerant pump is Smaller than when the flow rate is normal. With such a configuration, it is possible to easily determine the abnormality of the cooling system when there is a significant difference between the measured value and the estimated value of the power consumption of the refrigerant pump. In addition, the present invention can be realized as the following forms.

Application Example 1 A fuel cell system,
A cooling system having a refrigerant pump for circulating the refrigerant inside the fuel cell;
A power consumption detector for detecting power consumption of the refrigerant pump;
A power consumption estimation unit that estimates power consumption of the refrigerant pump based on the number of rotations of the refrigerant pump and pressure loss of the refrigerant;
Based on the detected value of the power consumption of the refrigerant pump detected by the power consumption detection unit and the estimated value of the power consumption of the refrigerant pump estimated by the power consumption estimation unit, the abnormality of the cooling system A determination unit for determining
A fuel cell system comprising:

  For example, when there is an abnormality in the cooling system that the pipe is crushed and the cavitation occurs due to the crushed pipe and the flow rate of the refrigerant decreases, the refrigerant pump runs idle and the power consumption in the refrigerant pump is normal. Becomes smaller than Therefore, according to the fuel cell system of Application Example 1, when the measured value and the estimated value of the power consumption of the refrigerant pump are compared and there is a significant difference, it is possible to easily determine the abnormality of the cooling system. .

  The actual power consumption of the refrigerant pump may be calculated from, for example, the current and voltage of a battery that supplies electric power to the refrigerant pump, or may be measured by a power meter or the like.

[Application Example 2] In the fuel cell system according to Application Example 1,
The cooling system is
A cooling pipe for passing a radiator for cooling the refrigerant;
Uncooled piping that does not allow the refrigerant to pass through the radiator;
A first pipe for distributing the refrigerant discharged from the fuel cell to the cooling pipe and the non-cooling pipe;
A second pipe that joins the refrigerant flowing through the cooling pipe and the refrigerant flowing through the non-cooling pipe to supply the fuel cell;
An adjustment valve for determining distribution of the refrigerant to the cooling pipe and the non-cooling pipe;
With
The power consumption estimation unit is
The fuel cell system, wherein the power consumption is estimated from a temperature of the refrigerant, a rotation speed of the refrigerant pump, and a valve opening degree of the adjustment valve.

  The refrigerant temperature, the number of revolutions of the refrigerant pump, and the valve opening of the adjusting valve are usually measured when managing the temperature and flow rate of the refrigerant. This is preferable because it is not necessary to add a new device to determine

[Application Example 3] In the fuel cell system according to Application Example 1 or 2,
The determination unit
An abnormality in the cooling system is determined based on a difference between the detected value and the estimated value.

  If it does in this way, abnormality of a cooling system can be judged easily from the detected value and estimated value of the power consumption in a refrigerant pump. Further, it is possible to easily determine an abnormality in the cooling system in which the detected value is larger than the estimated value and an abnormality in the cooling system in which the detected value is smaller than the estimated value. For example, when the flow rate of cooling water is large, the detected value is larger than the estimated value. When the power consumption of the refrigerant increases, the fuel consumption deteriorates. Thus, by easily knowing the abnormality of the cooling system, the deterioration of the fuel consumption can be suppressed at an early stage.

Application Example 4 In the fuel cell system according to any one of Application Examples 1 to 3,
The determination unit
The fuel cell system, wherein when the estimated value is larger than the detected value and the difference is not less than a predetermined value, it is determined that the cooling system is abnormal.

  If it does in this way, it can be judged easily that the flow rate of a refrigerant is insufficient, and it can control that a fuel cell fails by high temperature.

  The present invention can be realized in various forms, for example, in the form of a fuel cell system, a vehicle equipped with the fuel cell system, and the like.

A. First embodiment:
A1. Example configuration:
FIG. 1 is an explanatory diagram showing the configuration of a fuel cell system 1000 as a first embodiment of the present invention. In this embodiment, the fuel cell system 1000 is mounted on a vehicle. The fuel cell system 1000 of the present embodiment includes a fuel cell stack 100, a hydrogen supply / discharge system 200 that supplies / discharges hydrogen as a fuel gas, an air supply / discharge system 300 that supplies / discharges air as an oxidant gas, and a fuel A cooling system 400 that cools the battery stack 100 and an ECU (Electronic Control Unit) 500 that controls the fuel cell system 1000 are mainly provided.

  The fuel cell stack 100 is a polymer electrolyte fuel cell that is relatively small and excellent in power generation efficiency, and pure hydrogen as a fuel gas and oxygen in the air as an oxidant gas cause an electrochemical reaction at each electrode. Thus, an electromotive force is obtained. The fuel cell stack 100 has a stack structure in which a plurality of single cells (not shown) are stacked with separators (not shown) interposed, and the number of stacked layers depends on the output required for the fuel cell stack 100. Can be set arbitrarily.

  In the hydrogen supply / discharge system 200, hydrogen is supplied from a hydrogen tank (not shown) in which high-pressure hydrogen is stored to the anode of the fuel cell stack 100 via the pipe 202, and after being used for an electrochemical reaction at the anode, The anode exhaust gas is discharged into the atmosphere via the pipe 204. A circulation pipe 206 is provided branching from the pipe 204, and a valve 208 is provided in the pipe 204. When the valve 208 is closed, the anode exhaust gas is returned to the pipe 202 via the circulation pipe 206, and hydrogen in the anode exhaust gas is reused. When the valve 208 is opened, the anode exhaust gas is discharged into the atmosphere via the pipe 204.

  In the air supply / discharge system 300, compressed air compressed by a compressor (not shown) is supplied to the cathode of the fuel cell stack 100 via the pipe 302. After being used for the electrochemical reaction at the cathode, the cathode exhaust gas is released into the atmosphere via the pipe 304.

  The cooling system 400 includes a water pump 410, a motor 412, an inverter 414, a battery 418, a supply pipe 402, a discharge pipe 404, a cooling pipe 406, a radiator 422, an uncooled pipe 408, and an adjustment valve 420. And an inlet temperature sensor 426 and an outlet temperature sensor 428 are mainly provided. The cooling water flows through the supply pipe 402 by the water pump 410, circulates in the fuel cell stack 100 and cools the fuel cell stack 100, and then passes through the discharge pipe 404, the non-cooling pipe 408, and the cooling pipe 406, (Which will be described in detail later) and supplied to the fuel cell stack 100 again. The water pump 410 in this embodiment corresponds to the refrigerant pump in the claims, and the cooling water corresponds to the refrigerant in the claims. Further, the supply pipe 402 in this embodiment corresponds to the second pipe in the claims, and the discharge pipe 404 corresponds to the first pipe in the claims.

  The water pump 410 is a pump for circulating the cooling water through the piping 402, 404, 406, 408 of the cooling system 400 and a cooling water flow path (not shown) in the fuel cell stack 100. The water pump 410 is an electric water pump and is driven by receiving power from the battery 418. The ECU 500 described later determines the number of rotations of the water pump 410 based on the detection value of the outlet temperature sensor 428 and controls the inverter 414 to control the rotation speed and torque of the motor 412, thereby controlling the water pump 410. The number of revolutions is controlled. The water pump 410 includes a rotation detector (not shown) inside, and while the water pump 410 is being driven, the rotation number of the water pump 410 is measured by the rotation detector and transmitted to the ECU 500.

  The adjustment valve 420 is an electric rotary valve, and the ECU 500 described later determines the valve opening degree of the adjustment valve 420 based on the detection value of the outlet temperature sensor 428 and controls the adjustment valve 420. The adjustment valve 420 can adjust the valve opening between 0% and 100%. When the valve opening is 0%, the non-cooling pipe 408 and the supply pipe 402 are opened 100%, the non-cooling pipe 408 and the supply pipe 402 are connected, and the cooling pipe 406 and the supply pipe 402 are blocked. . At this time, the cooling water after circulating through the fuel cell stack 100 is supplied to the fuel cell stack 100 again through the discharge pipe 404, the non-cooling pipe 408, and the supply pipe 402. Since the cooling water does not pass through the radiator 422, the temperature drop of the cooling water is suppressed.

  On the other hand, when the valve opening degree is 100%, the cooling pipe 406 and the supply pipe 402 are opened 100%, the cooling pipe 406 and the supply pipe 402 are connected, and the non-cooling pipe 408 and the supply pipe 402 are blocked. At this time, the cooling water after circulating through the fuel cell stack 100 is supplied again to the fuel cell stack 100 through the discharge pipe 404, the cooling pipe 406, and the supply pipe 402. The cooling water is cooled when it flows through the radiator 422 provided in the cooling pipe 406. The operation and stop of the fan 424 are controlled by the ECU 500 based on the detected value of the outlet temperature sensor 428.

  When the valve opening is between 0 and 100%, the opening of the cooling pipe 406 and the non-cooling pipe 408 are adjusted, and the cooling water flows through both the cooling pipe 406 and the non-cooling pipe 408. The temperature of the cooling water supplied to the fuel cell stack 100 is set to the target temperature.

  For example, when the internal temperature of the fuel cell stack 100 is low, such as when the fuel cell stack 100 is started up, the ECU 500 adjusts the valve opening of the adjustment valve 420 to 0% so that the cooling water passes through the cooling pipe 406. Instead, it passes through the uncooled piping 408. Then, since the heated cooling water (hot water) is supplied to the fuel cell stack 100, the fuel cell stack 100 is warmed.

  On the other hand, when the internal temperature of the fuel cell stack 100 is high, the ECU 500 adjusts the valve opening degree of the adjustment valve 420 to 100% so that the cooling water does not pass through the non-cooling pipe 408 but passes through the cooling pipe 406. Like that. Then, the cooling water heated by absorbing the heat of the fuel cell stack 100 is cooled by the radiator 422, and the cooled cooling water is supplied to the fuel cell stack 100, so that the fuel cell stack 100 is cooled. The

  Further, depending on the outlet temperature of the cooling water, the ECU 500 adjusts the valve opening of the adjustment valve 420 to 0 to 100% so that the cooling water flows through both the cooling pipe 406 and the non-cooling pipe 408. Then, the temperature of the cooling water supplied to the fuel cell stack 100 is set to the target temperature.

  The ECU 500 mainly includes an input / output port 510, a CPU 520, and a memory 530. In the memory 530, a map 532 and a flow rate abnormality determination program 534 are recorded in advance. The map 532 is detected by the coolant temperature by the inlet temperature sensor 426, the number of rotations of the water pump 410 detected by the rotation detector (not shown) provided in the water pump 410, and the position detector (not shown) provided by the adjustment valve 420. The relationship between a valve opening degree and the power consumption in the water pump 410 is shown. The map 532 is created in advance by measuring the power consumption in the water pump 410 according to the cooling water temperature, the rotation speed of the water pump 410, and the valve opening. The power consumption in the water pump 410 can be obtained by measuring the current and voltage supplied from the battery 418 to the inverter 414.

  The CPU 520 functions as a determination unit, a power consumption estimation unit, and a power consumption detection unit in the claims by executing a flow rate abnormality determination program 534 recorded in the memory 530. The CPU 520 refers to the map 532 stored in the memory 530 based on the cooling water inlet temperature, the rotation speed of the water pump 410, and the valve opening degree of the adjustment valve 420 acquired through the input / output port 510. Then, the power consumption of the water pump 410 is estimated, and an abnormality in the flow rate of the cooling water is determined as will be described later.

  As described above, the input / output port 510 includes the rotation speed signal from the water pump 410, the voltage from the battery 418, the current signal, the opening signal from the adjustment valve 420, the temperature signal from the inlet temperature sensor 426, and the outlet temperature sensor 428. The temperature signal is received, and the control signal of the inverter 414 and the control signal of the adjustment valve 420 are output. Further, when the CPU 520 determines that the cooling water flow rate is abnormal, it outputs an instruction to turn on the cooling water warning lamp 600 to notify the abnormality of the cooling system. The cooling water warning lamp 600 is displayed on, for example, an instrument panel provided in front of the vehicle.

  The ECU 500 is included in, for example, a PCU (Power Control Unit) (not shown) that controls the fuel cell system 1000 and a secondary battery (not shown).

A2. About power consumption in water pump:
Prior to describing the operation of determining abnormality of the cooling system in the present embodiment, the power consumption in the water pump 410 will be described. The number of rotations of the water pump 410 is determined and controlled by the ECU 500 based on the detection value of the outlet temperature sensor 428 as described above. The valve opening of the adjustment valve 420 is determined based on the detection value of the outlet temperature sensor 428, and the inlet temperature of the cooling water is determined by the valve opening of the adjustment valve 420.

  The viscosity of the cooling water varies depending on the temperature of the cooling water. When the temperature of the cooling water is low, the viscosity of the cooling water increases. As the viscosity of the cooling water increases, the pressure loss of the cooling water in the pipe increases. Further, the pressure loss of the cooling water varies depending on the opening of the adjustment valve 420. The power consumption of the water pump 410 is obtained by (cooling water flow rate) × (pressure increase in the water pump 410). When there is no abnormality in the cooling water system, the flow rate of the cooling water changes according to the rotation speed of the water pump 410. Therefore, if there is no abnormality in the cooling water system, for example, the rotation speed of the water pump 410 is uniquely determined based on the outlet temperature of the cooling water (indicating the internal temperature of the fuel cell stack 100). When the number is constant (that is, the flow rate of the cooling water is constant), if the viscosity of the cooling water increases or the pressure loss of the cooling water increases due to the opening of the adjustment valve 420, the pressure increase in the water pump 410 increases. Therefore, the power consumption in the water pump 410 increases. Therefore, a predetermined relationship is established among the coolant inlet temperature, the pump rotation speed, the valve opening degree, and the power consumption in the water pump 410.

  Therefore, if the relationship between the cooling water inlet temperature, the pump rotation speed, the valve opening, and the power consumption in the water pump 410 is checked in advance and stored in the memory 530 as a map, the cooling water inlet temperature, The power consumption in the water pump 410 can be estimated from the pump speed and the valve opening. On the other hand, the actual power consumption (pump actual power) in the water pump 410 can be obtained from the current and voltage supplied from the battery 418 to the inverter 414.

  For example, when one of the piping of the cooling system 400 is crushed and bubbles are generated in the cooling water (hereinafter also referred to as cavitation), the cooling water hardly flows, so the water pump 410 is idle. If the cooling water does not flow, the fuel cell stack 100 cannot be sufficiently cooled, and the temperature of the fuel cell stack 100 rises. However, since the cooling water does not flow, the temperature rise is not reflected in the outlet temperature of the cooling water. Therefore, the outlet temperature of the cooling water is almost the same as the temperature before cavitation occurs, and the rotation speed of the water pump 410 is almost the same as before the cavitation occurs.

  Further, since the valve opening of the adjustment valve 420 is adjusted based on the outlet temperature of the cooling water, as described above, if the outlet temperature of the cooling water is almost the same as before the cavitation occurs, the valve opening is not cavitation. Same as before. Further, since the cooling water does not flow, the cooling water stays in the pipe, and the inlet temperature of the cooling water is the same as before the cavitation occurs. Then, the value of the estimated power obtained by estimating the power consumption in the water pump 410 from the map is the same as before cavitation occurs.

  On the other hand, after cavitation occurs, as described above, the cooling water hardly flows and the water pump 410 idles. As described above, since the power consumption of the water pump 410 is obtained by (cooling water flow rate) × (pressure increase in the water pump 410), the actual power consumption (pump actual power) in the water pump 410 is reduced when the cooling water flow rate decreases. Power) is smaller than the estimated power.

  Further, when the water pump 410 fails, the pump may not rotate, or the cooling water may not be sent out even though the water pump 410 rotates at a predetermined rotation speed. For example, when the water pump 410 is rotating at a predetermined number of revolutions, the cooling water is not sent out and the flow rate of the cooling water is small, as in the case where the cavitation occurs. Since the cooling water temperature and the valve opening are the same as before the water pump 410 fails, the estimated pump power is the same as before the water pump 410 fails. On the other hand, the actual pump power is smaller than the estimated pump power because the flow rate of the cooling water decreases as described above.

  As described above, when an abnormality occurs in the cooling system such as the piping, the water pump 410, the adjustment valve 420, etc., and the flow rate of the cooling water decreases, the actual power consumed in the water pump 410 becomes smaller than the estimated power.

A3. Example operation:
FIG. 2 is a flowchart showing a flow of determining an abnormality of the cooling system in the fuel cell system 1000. In this embodiment, an abnormality in the flow rate of the cooling water is determined as an abnormality in the cooling system. This routine is repeatedly executed at predetermined intervals while the fuel cell system 1000 is activated. First, the CPU 520 receives the cooling water temperature from the outlet temperature sensor 428, the pump rotation speed from the water pump 410, the valve opening from the adjustment valve 420, and the current supplied from the battery 418 to the inverter 414 via the input / output port 510. , Also referred to as “supply current”) and voltage (hereinafter also referred to as “supply voltage”), respectively (step S102). The CPU 520 estimates the pump power consumption with reference to the map 532 stored in the memory 530 based on the acquired cooling water temperature, pump rotation speed, and valve opening (step S104). Hereinafter, the estimated pump power consumption is referred to as pump estimated power. CPU 520 calculates actual power consumption of water pump 410 (hereinafter also referred to as “pump actual power”) from the acquired supply current and supply voltage (step S105).

  Subsequently, CPU 520 determines whether or not a value obtained by subtracting pump actual power from pump estimated power is equal to or greater than a predetermined value (step S106). If the value is equal to or greater than the predetermined value (Yes in step S106), CPU 520 determines that the cooling water flow rate is abnormal (step S108). If the value is less than the predetermined value (No in step S106), it is determined that the flow rate of the cooling water is normal. If the CPU 520 determines in step S108 that the cooling water flow rate is abnormal, the CPU 520 turns on the cooling water warning lamp 600 via the input / output port 510 and ends this routine.

A4. Effects of the embodiment:
In the fuel cell system 1000 of the present embodiment, the actual pump power is compared with the estimated pump power estimated from the rotation speed of the water pump 410, the valve opening of the adjustment valve 420, and the coolant temperature by the inlet temperature sensor 426. By doing so, the abnormality of the cooling water amount is determined. As described above, in this embodiment, an abnormality in the cooling water amount is determined as an abnormality in the cooling system. That is, a failure of the cooling system can be easily found by comparing the actual pump power and the estimated pump power. Therefore, it is possible to suppress the failure of the fuel cell stack 100 due to an increase in the internal temperature of the fuel cell stack 100 due to the cooling water not flowing.

  Further, in the fuel cell system 1000 of the present embodiment, an outlet temperature sensor 428, a rotation detector provided in the water pump 410, a position detector provided in the adjustment valve 420, and the like conventionally provided in the fuel cell system 1000 are used. Since the power consumption in the water pump 410 is estimated from the detected value, an abnormality in the flow rate can be determined without adding a new device such as a flow meter for measuring the flow rate of the cooling water. Therefore, an increase in cost can be suppressed.

  In addition, for example, when the internal temperature of the fuel cell stack 100 is directly measured, it is necessary to provide a temperature sensor for each single cell, which is expensive. However, according to the fuel cell system 1000 of the present embodiment, the existing By using this detector, it is possible to prevent a failure due to an increase in the internal temperature of the fuel cell stack 100 by determining an abnormality in the flow rate of the cooling water, so the temperature of the single cell of the fuel cell stack 100 is directly measured. Compared with the case where it does, cost increase can be suppressed.

B. Second embodiment:
The fuel cell system of the second embodiment is different in the flow rate abnormality determination program executed by the CPU 520, but the other configuration is the same as that of the first embodiment, so that the cooling system of the second embodiment is the same. The description of the configuration is omitted, and the operation of the embodiment will be described below. In addition, about the same structure, it demonstrates using the same code | symbol as 1st Example.

B1. Example operation:
FIG. 3 is a flowchart showing a flow for determining an abnormality of the cooling system in the fuel cell system 1000. Also in the present embodiment, as in the first embodiment, an abnormality in the flow rate of the cooling water is determined as an abnormality in the cooling system. First, as in the first embodiment, the CPU 520 acquires the coolant temperature, the pump speed, the valve opening, the supply current, and the supply voltage via the input / output port 510 (step U102). Subsequently, the CPU 520 determines whether or not the acquired cooling water temperature is 0 ° C. or less (step U104). When the cooling water temperature is 0 ° C. or lower, the CPU 520 ends this routine. On the other hand, when the cooling water temperature is higher than 0 ° C., the CPU 520 stores it in the memory 530 based on the acquired cooling water temperature, pump rotation speed, and valve opening degree, as in the first embodiment. The pump power consumption is estimated with reference to the map 532 (step U106). Further, CPU 520 calculates pump actual power from the acquired supply current and supply voltage (step U107).

  Subsequently, CPU 520 determines whether or not a value obtained by subtracting pump actual power from pump estimated power is equal to or greater than a predetermined value (step U107). If the value is equal to or greater than the predetermined value (Yes in step U108), CPU 520 determines that the coolant flow rate is abnormal (step U110). If the value is less than the predetermined value (No in step U112), it is determined that the flow rate of the cooling water is normal. If the CPU 520 determines in step S108 that the cooling water flow rate is abnormal, the CPU 520 turns on the cooling water warning lamp 600 via the input / output port 510 and ends this routine.

B2. Effects of the embodiment:
In the fuel cell system according to the present embodiment, unlike the first embodiment, when the coolant temperature is 0 ° C. or lower, the determination of the flow rate abnormality is not performed, and this routine ends. As described above, when the temperature of the cooling water is lowered, the viscosity is increased, but when the temperature of the cooling water is 0 ° C. or lower, the viscosity is rapidly increased. Therefore, for example, if a slight error occurs in the detection of the temperature of the cooling water, there is a high possibility that the estimated power values are greatly different. Further, when the cooling water temperature is 0 ° C. or lower, it is considered that the internal temperature of the fuel cell stack 100 is unlikely to increase because the environmental temperature is low. Therefore, when the cooling water temperature is 0 ° C. or less, the fuel cell stack 100 is less likely to fail due to the high temperature. Therefore, when the cooling water temperature is 0 ° C. or lower, the flow rate abnormality is not determined, and even if this routine is terminated, the flow rate is the same as in the first embodiment when the cooling water temperature is higher than 0 ° C. By determining the abnormality, the same effect as in the first embodiment can be obtained.

C. Variations:
The present invention is not limited to the above-described examples and embodiments, and can be implemented in various modes without departing from the gist thereof. For example, the following modifications are possible.

  (1) In the above embodiment, the power consumption in the water pump 410 is estimated from the cooling water temperature, the pump rotation speed, and the valve opening, but instead of the valve opening, You may make it estimate the power consumption in the water pump 410 using the pressure difference of an exit. Even in this case, since it is possible to determine an abnormality in the flow rate of the cooling water, it is understood that an abnormality has occurred in the cooling system.

  (2) In the above-described embodiment, the abnormality in the coolant flow rate is determined based on whether or not the value obtained by subtracting the pump actual power from the pump estimated power is larger than the predetermined value. An abnormality in the flow rate may be determined based on whether or not the difference (absolute value) from the actual pump power is greater than a predetermined value. For example, if the pipe is crushed and the cavitation is not occurring, the cooling water flows, but the pressure loss increases, so that the actual pump power may be larger than the estimated pump power. Even in such a case, the abnormality of the cooling system can be determined.

  (3) In the above embodiment, when it is determined that the flow rate is abnormal, the cooling water warning lamp 600 is turned on. However, the cooling system abnormality may be notified by other methods. For example, a display panel (used in a navigation system or the like) included in the vehicle may be displayed as “abnormality of cooling system” or the like, or may be notified by voice. Moreover, you may combine them.

  (4) In the above embodiment, the case where the fuel cell system 1000 is mounted on a vehicle has been described as an example. However, for example, in a stationary fuel cell system, a cooling system abnormality is similarly determined. be able to.

  (5) Although the polymer electrolyte fuel cell is used in the fuel cell system 1000 of the above embodiment, various fuel cells such as a phosphoric acid fuel cell, a molten carbonate fuel cell, and a solid oxide fuel cell are used. Can be used.

  (6) In the fuel cell system 1000 of the above embodiment, the power consumption in the water pump 410 is obtained from the current and voltage supplied to the inverter 414. The power consumption in the water pump 410 is obtained using a power meter or the like. May be measured.

It is explanatory drawing which shows the structure of the fuel cell system 1000 as a 1st Example of this invention. 5 is a flowchart showing a flow for determining an abnormality of a cooling system in the fuel cell system 1000. 5 is a flowchart showing a flow for determining an abnormality of a cooling system in the fuel cell system 1000.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Fuel cell stack 200 ... Hydrogen supply / discharge system 202, 204 ... Pipe 206 ... Circulation pipe 208 ... Valve 300 ... Air supply / discharge system 302, 304 ... Pipe 400 ... Cooling system 402 ... Supply pipe 404 ... Discharge pipe 406 ... Cooling pipe 408: Uncooled piping 410: Water pump 412 ... Motor 414 ... Inverter 418 ... Battery 420 ... Adjustment valve 422 ... Radiator 424 ... Fan 426 ... Inlet temperature sensor 428 ... Outlet temperature sensor 500 ... ECU
510 ... I / O port 520 ... CPU
530 ... Memory 532 ... Map 534 ... Flow rate abnormality determination program 600 ... Cooling water warning lamp 1000 ... Fuel cell system

Claims (4)

A fuel cell system,
A cooling system having a refrigerant pump for circulating the refrigerant inside the fuel cell;
A power consumption detector for detecting power consumption of the refrigerant pump;
A power consumption estimation unit that estimates power consumption of the refrigerant pump based on the number of rotations of the refrigerant pump and pressure loss of the refrigerant;
Based on the detected value of the power consumption of the refrigerant pump detected by the power consumption detector and the estimated value of the power consumption of the refrigerant pump estimated by the power consumption estimation unit, the pressure value of the refrigerant Without using a determination unit for determining abnormality of the cooling system,
A fuel cell system comprising: The fuel cell system according to claim 1, wherein
The cooling system is
A cooling pipe for passing a radiator for cooling the refrigerant;
Uncooled piping that does not allow the refrigerant to pass through the radiator;
A first pipe for distributing the refrigerant discharged from the fuel cell to the cooling pipe and the non-cooling pipe;
A second pipe that joins the refrigerant flowing through the cooling pipe and the refrigerant flowing through the non-cooling pipe to supply the fuel cell;
An adjustment valve for determining distribution of the refrigerant to the cooling pipe and the non-cooling pipe;
With
The power consumption estimation unit is
The fuel cell system, wherein the power consumption is estimated from a temperature of the refrigerant, a rotation speed of the refrigerant pump, and a valve opening degree of the adjustment valve. The fuel cell system according to claim 1 or 2,
The determination unit
An abnormality in the cooling system is determined based on a difference between the detected value and the estimated value. The fuel cell system according to any one of claims 1 to 3,
The determination unit
The fuel cell system, wherein when the estimated value is larger than the detected value and the difference is not less than a predetermined value, it is determined that the cooling system is abnormal.

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