JP2013114909A - Fuel cell power supply system, and method of controlling the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve efficiency of charge and operation of a fuel cell in a fuel cell power supply system using a secondary battery for external power supply and using the fuel cell for charging the secondary battery, and to enhance durability of the system.SOLUTION: This fuel cell power supply system includes a secondary battery for supplying electricity to an external load, a fuel cell for charging the secondary battery, a hydrogen storage alloy vessel for supplying hydrogen to the fuel cell, a secondary battery voltage measuring part for measuring the voltage of the secondary battery, a fuel cell output measuring part for measuring the output of the fuel cell, and a control part for controlling operation of the fuel cell. The control part receives the measurement results of the secondary battery voltage measuring part and the fuel cell output measuring part, starts the fuel cell if the voltage of the secondary battery is determined to be less than a prescribed voltage, and stops the operation of the fuel cell if the output of the fuel cell is determined to be lower than a prescribed output during the charging operation of the fuel cell, the fuel cell thereby generates power at high efficiency (FC efficiency), and the secondary battery can be charged while reducing a charge loss to the secondary battery.

Description

  The present invention relates to a fuel cell power supply system that supplies electricity to an external load while charging a secondary battery with the output of the fuel cell, and a control method thereof.

A fuel cell power source using a secondary battery and a fuel cell has been proposed as a power supply system used for a power source or an emergency power source in a place where a commercial power source is not reachable.
For example, a power supply device has been proposed in which electricity is supplied from a secondary battery to an external load and the fuel cell is used as a power source for charging (see, for example, Patent Document 1). This power supply device is mounted on an automobile or the like, and uses hydrogen gas or the like obtained by reforming methanol as a raw material for a fuel cell.
In addition, when the battery is charged from the fuel cell, the power supply device controls operation at 30 to 90% of the battery capacity, so that it always generates power with the maximum power generation efficiency to convert the fuel of the fuel cell into electric energy. Is possible.
In addition, a portable fuel cell power source for outdoor use has been proposed in which a secondary battery is used as a buffer as an outdoor power source without a commercial power source, and electricity is supplied from the fuel cell to an external load (Non-Patent Documents 1 and 2). The secondary battery responds to an instantaneous high current that occurs when the load is started.

JP 2004-253189 A

"Abstracts of the 51st Battery Discussion Meeting", Department of Molecular Materials Engineering, Faculty of Engineering, Mie University, 2010, p338 “Fuel Cell Summer Issue vol.10”, Fuel Cell Development Information Center, 2010, p110-114

However, among the above-described conventional techniques, in the former apparatus that charges a battery from a fuel cell, charging loss increases when the battery capacity is 80% or more.
Further, the power supply device obtains the capacity of the battery (secondary battery) by the remaining capacity detection device, and starts and stops the fuel cell. As a specific method for detecting the remaining capacity, the charging current of the battery (secondary battery) is detected, and the fuel cell is stopped when the charging flow rate value is ½ or less of the normal value. However, when charging the power supply system while supplying electricity to the load, it is difficult to accurately check the battery capacity. In general, as a means for detecting the battery (secondary battery) capacity, there is a method of measuring the open-circuit voltage by stopping charging and discharging for several tens of minutes or measuring the current if it is constant charge or discharge. . However, this method cannot accurately measure the battery (secondary battery) capacity when the external load varies.

Of the above-mentioned conventional technologies, the latter outdoor fuel cell power supply is such that the battery (secondary battery) has only a buffer role, and the load output is basically equal to the fuel cell power generation output or When the load output is small, the operation is performed with low power generation efficiency. That is, when the load is small, there is a problem that the power consumption for control is greatly influenced by the system efficiency.
Hydrogen used as fuel for the fuel cell is supplied from a hydrogen storage alloy container (MH canister). To meet the high output of the fuel cell, the MH canister size is increased and the endotherm is released. Therefore, it is necessary to heat the container uniformly. In general, exhaust heat from a fuel cell is used as a heat source for MH. However, when the MH canister is large, it is difficult to uniformly transmit the exhaust heat of the fuel cell, and it is not easy to increase the power generation output.

  As for the durability of the fuel cell, only the evaluation of the single cell is generally reported, and the durability of the system is not publicly disclosed. In the fuel cell power supply system corresponding to the load fluctuation, about 5,000 hours is considered to be the limit, and there is a problem for those operating continuously for several years.

  The present invention has been made in the context of the above circumstances, and can operate a fuel cell with high efficiency against an external load having a load fluctuation, and can improve the durability of a system including the fuel cell. It is an object of the present invention to provide a battery power supply system and a control method thereof.

That is, the first aspect of the fuel cell power supply system of the present invention is:
A secondary battery for supplying electricity to an external load;
A fuel cell for charging the secondary battery;
A hydrogen storage alloy container for supplying hydrogen to the fuel cell;
A secondary battery voltage measuring unit for measuring a voltage of the secondary battery;
A fuel cell output measuring unit for measuring the output of the fuel cell;
A control unit for controlling the operation of the fuel cell,
The control unit receives measurement results of the secondary battery voltage measurement unit and the fuel cell output measurement unit, and determines that the voltage of the secondary battery is lower than a predetermined voltage according to the measurement result of the secondary battery voltage measurement unit. Then, the fuel cell is activated, and the operation of the fuel cell is stopped when it is determined that the output of the fuel cell is lower than a predetermined output according to the measurement result of the fuel cell output measuring unit during the charging when the fuel cell is operated. It is characterized by that.

According to the present invention, electricity is supplied from the secondary battery to the external load, and the charging operation of the fuel cell can be controlled by the voltage of the secondary battery and the output of the fuel cell. On the other hand, charging and operation of the fuel cell can be performed with high efficiency.
The control unit can be configured mainly with a CPU and a program for operating the CPU. In addition, an electric circuit using a relay or the like can be used.
In addition, as the secondary battery, a battery whose battery capacity is matched with the load output capacity can be used. The type of the secondary battery is not particularly limited as the present invention, and a lead battery, a Ni-hydrogen battery, a Li ion battery, or the like can be used.
Moreover, the fuel cell power supply system of the present invention is excellent in portability, and can be suitably used for a power supply or an emergency power supply in a place where a commercial power supply is not reachable.

  In the fuel cell power supply system according to the second aspect of the present invention, in the first aspect of the present invention, the control unit performs operation control of the fuel cell by adjusting a hydrogen supply amount from the hydrogen storage alloy container. And

  According to the present invention, the operation control of the fuel cell can be performed by increasing / decreasing the hydrogen flow rate from the hydrogen storage alloy container, ON / OFF of the hydrogen supply, or the like.

  In the fuel cell power supply system according to the third aspect of the present invention, in the first or second aspect of the present invention, the predetermined output is obtained when the battery capacity reaches 80% of the rated battery capacity when the secondary battery is charged. The output of the fuel cell is determined in advance.

  According to the present invention, it is possible to stop charging at a rated battery capacity of 80% or more where the charging efficiency is reduced, and to increase the charging efficiency as a whole. The predetermined output can be determined by the initial charging characteristics of the secondary battery.

  In the fuel cell power supply system of the fourth aspect of the present invention, in any one of the first to third aspects of the present invention, the predetermined output is predetermined as 40% of the rated output of the fuel cell. A fuel cell power supply system.

  According to the present invention, it is possible to control the operation of the fuel cell by setting threshold values suitable for the charging efficiency and the fuel cell efficiency.

  The fuel cell power supply system according to a fifth aspect of the present invention is characterized in that, in any of the first to fourth aspects of the present invention, the predetermined voltage is determined in advance as a rated voltage of the secondary battery. To do.

The fuel cell power supply system according to a sixth aspect of the present invention is the fuel cell power supply system according to any one of the first to fifth aspects, wherein the hydrogen storage alloy container is portable and contains a hydrogen storage alloy capable of releasing hydrogen at room temperature. The maximum hydrogen storage amount of the hydrogen storage alloy contained in the hydrogen storage alloy container is 1 m ³ or less,
The fuel cell is of a solid polymer type and has a rated output of 500 W or less.

According to the present invention, the fuel cell power supply system is made portable and can be easily used as a power supply in the field. If the maximum hydrogen storage amount of the hydrogen storage alloy exceeds 1 m ³ , it is necessary to increase the size of the hydrogen storage alloy container, which is inferior in portability. In addition, when the fuel cell exceeds 500 W at the rated output, the size of the hydrogen storage alloy container to be supplied to the fuel cell inevitably increases, and the portability is inferior. In addition, since the fuel cell uses a low output device, the system is simple and the cost can be reduced.

  A fuel cell power supply system according to a seventh aspect of the present invention includes a drive power source for driving the system according to any one of the first to sixth aspects of the present invention, and the drive power source is stopped by the fuel cell. In the meantime, the mode is characterized in that the mode is shifted to a save mode in which the drive target is limited.

  According to the present invention, the amount of power used in the fuel cell power supply system can be reduced while charging is stopped.

  The fuel cell power supply system according to an eighth aspect of the present invention is characterized in that, in the seventh aspect of the present invention, the drive power supply includes the secondary battery.

  According to the present invention, the secondary battery can be used as all or part of the drive power supply.

  In the fuel cell power supply system of the ninth aspect of the present invention, in the seventh or eighth aspect of the present invention, in the save mode, the drive of the secondary battery voltage measurement unit and the measurement result of the secondary battery voltage measurement unit are used. Accordingly, only a part of the controller that drives the fuel cell is actuated.

  According to the present invention, it is possible to use only the electric power necessary for controlling the fuel cell.

A control method for a fuel cell power supply system according to a tenth aspect of the present invention is a method for controlling a fuel cell power supply system that supplies electricity from the secondary battery to an external load while charging the secondary battery with the fuel cell,
When determining that the voltage of the secondary battery is lower than a predetermined voltage, when starting the fuel cell and determining that the output of the fuel cell is lower than a predetermined output during the charging when the fuel cell is operated, The operation of the fuel cell is stopped.

  According to the present invention, the system can be controlled so as to perform efficient charging and operation of the fuel cell.

As described above, according to the present invention, the fuel cell is always generated with high efficiency (FC efficiency), and can be charged with a small charge loss to the secondary battery.
Further, by using the secondary battery, it is possible to cope with a power load having a capacity larger than that of the fuel cell output.
By controlling the fuel cell according to the voltage of the secondary battery and the output of the fuel cell that can be accurately grasped, durability of the fuel cell and the entire system is reduced by suppressing the operation time without continuously operating the fuel cell. Can be improved.

It is a control block diagram of the fuel cell power supply system of one embodiment of the present invention. Similarly, it is a flowchart which shows the procedure of a control method. Similarly, it is a graph which shows the characteristic of the lead battery which is a secondary battery. Similarly, it is a graph which shows the relationship between the battery capacity at the time of charge, and the output of a fuel cell. Similarly, it is a figure explaining the overcharge at the time of charge with respect to a secondary battery. Similarly, it is a graph which shows the relationship between a fuel cell output and FC efficiency. Similarly, it is a graph which shows the evaluation test result of a fuel cell power supply system. Similarly, it is a graph which shows the time change of the battery capacity and system efficiency by simulation.

  A fuel cell power supply system according to an embodiment of the present invention will be described below with reference to the accompanying drawings.

The following terms are defined below.
-FC efficiency (fuel cell efficiency): The efficiency of a single FC unit, and the ratio of FC output obtained to the amount of supplied hydrogen.
-System efficiency: The ratio of the system output obtained with respect to the amount of supplied hydrogen in terms of overall system efficiency.
(Calculation formula: output Wh / (hydrogen amount NL × 2.9944) × 100)
Charging loss: The ratio of the amount of power required for charging and the amount of power obtained by discharging in the secondary battery.
-Operation rate: Ratio of fuel cell operation time to system operation (power supply to load) time.

The fuel cell power supply system 1 includes a secondary battery 2 made of a lead battery or the like, and the secondary battery 2 has a performance that matches the external load capacity. The rated capacity of the secondary battery 2 is, for example, 80 Ah or less in consideration of portability.
The output of the secondary battery 2 is supplied to an external load directly or via a DC / DC converter, a DC / AC converter, a power supply controller, etc. (not shown). A secondary battery voltmeter 10 that measures an output voltage is connected to the secondary battery 2, and the measurement result of the secondary battery voltmeter 10 is transmitted to the control unit 7. The secondary battery voltmeter 10 corresponds to a secondary battery voltage measurement unit of the present invention.

The secondary battery 2 is connected to the output side of a polymer electrolyte fuel cell 3. In consideration of portability, the fuel cell 3 has a rated output of 500 W or less, for example. A fuel cell ammeter 12 that measures the output current of the fuel cell 3 is interposed on the output side of the fuel cell 3. The measurement result of the fuel cell ammeter 12 is transmitted to the control unit 7. Further, a fuel cell voltmeter 11 for measuring the output voltage of the fuel cell 3 is connected to the fuel cell 3, and the measurement result of the fuel cell voltmeter 11 is transmitted to the control unit 7. The fuel cell voltmeter 11 and the fuel voltage ammeter 12 function together as a fuel cell output measuring unit of the present invention.
The secondary battery 2 and the fuel cell 3 may be directly connected, or may be connected via a DC / DC converter, a DC / AC converter, a charging controller, etc. (not shown).

A portable hydrogen storage alloy container 4 is connected to the fuel cell 3 via a hydrogen supply pipe 5, and hydrogen as a raw material can be supplied to the fuel cell 3. Note that the portable type means that it is not fixed and can be moved as a member in the fuel cell power supply system.
The hydrogen storage alloy container 4 stores a hydrogen storage alloy (not shown) capable of releasing hydrogen at room temperature, and the maximum hydrogen storage amount in the hydrogen storage alloy container 4 is 1 m ³ or less. As the hydrogen storage alloy, an AB ₅ alloy, an AB ₂ alloy, or the like can be used. The hydrogen storage alloy container 4 can use the exhaust heat of the fuel cell 3 as a drive source for hydrogen release of the hydrogen storage alloy. However, the hydrogen storage alloy container 4 does not use the exhaust heat or the fuel cell is stopped to exhaust the heat. Even when it cannot be used, hydrogen can be released from the hydrogen storage alloy at room temperature. For example, as a temperature at which hydrogen can be released, 15 ° C. can be exemplified.
An electromagnetic valve 6 is interposed in the hydrogen supply pipe 5 so that the flow rate of hydrogen passing through the hydrogen supply pipe 5 can be adjusted and the supply of hydrogen can be shut off. A control signal is transmitted from the control unit 7 to the electromagnetic valve 6 to adjust the opening degree.

The control unit 7 mainly includes a CPU and a program for operating the CPU. The control unit 7 includes a storage unit 70 that stores operation parameters for controlling the operation of the fuel cell 3. In the storage unit 70, a predetermined voltage of the secondary battery 2 serving as a threshold value when starting the fuel cell 3 is stored as data, and further, the fuel cell 3 serving as a threshold value when stopping the operating fuel cell 3 is stored. A predetermined output is stored as data.
The control unit 7 controls the start and stop of the fuel cell 3 as described above, adjusts the opening of the electromagnetic valve 6 according to the output of the fuel cell 3, and controls the amount of hydrogen supplied to the fuel cell 3. It can be adjusted to an appropriate amount.

The secondary battery 2 is connected to the control unit 7 so as to drive the control unit 7 and further drive the electromagnetic valve 6 and a controller (not shown). Therefore, the secondary battery 2 acts as a drive power source of the present invention. In addition, as this invention, it has the drive power supply 8 with the secondary battery 2, or separately from a secondary battery, and you may perform the said drive.
In addition, the control unit 7 has a CPU or operation area for a save mode, receives the measurement result of the secondary battery voltmeter 10, reads the data in the storage unit 70, and compares the measurement result with the read data. The save mode power supply line that supplies power to the operation of driving the electromagnetic valve 6 based on the comparison result and the power supply line to other parts of the control unit 7 are independent. The selection of the power supply line can be executed by the control unit 7 operating in the save mode. In the save mode, the secondary battery 2 (or the secondary battery 2 and / or the drive power supply 8 is provided only in the power supply line for the save mode. ) Is supplied, and the power supply to other power supply lines can be cut off.

  Below, the control procedure in the fuel cell power supply system 1 is demonstrated based on the flowchart of FIG. Control is automatically executed by the control unit 7. In the control method of the present invention, it is also possible to manually control the fuel cell 3 based on the following procedure, and at that time, data reading from the storage unit 70 is not indispensable.

At the start of operation of the fuel cell power supply system 1, the control unit 7 is operated in a save mode that restricts power supply from the secondary battery 2. Or it works in the normal mode instead of the save mode.
First, the control 2 procedure for monitoring the output voltage of the secondary battery 2 and issuing a start signal is executed.
That is, the control unit 7 receives the measurement result of the secondary battery voltmeter 10 and reads predetermined voltage data related to the secondary battery 2 from the storage unit 70. In this example, the predetermined voltage is a rated voltage. The measurement result and the read data are compared to determine whether the secondary battery voltage is less than the rated voltage (step s1). In this example, when the secondary battery voltage falls below the rated voltage by 3% in consideration of errors and the like, it is determined that the voltage is less than the rated voltage. If the measured voltage is equal to or higher than the rated voltage, the save mode is maintained in the save mode, and if not the save mode, the save mode is entered, and the determination in step s1 is repeated (step s2).

In step s1, if the measured voltage is less than the rated voltage, the control 1 procedure for controlling the fuel cell is executed. In this example, if the measured voltage is not 3% lower than the rated voltage, it is determined that the measured voltage is higher than the rated voltage. In the control 1, first, the save mode is canceled (step s3).
In the above description, when determining whether the voltage is higher than the rated voltage or lower than the rated voltage, the determination is made based on whether the voltage is 3% lower than the rated voltage. ) Is appropriately determined, and the determination can be performed based on this threshold value.

After step s3, the fuel cell 3 is activated (step s4). When the fuel cell 3 is activated, if it has a controller for charging, the fuel cell 3 is activated as a fuel cell system including the controller.
After starting the fuel cell 3, the secondary battery 2 is charged (step s5).

In charging the secondary battery 2, the power generation output of the fuel cell 3 is calculated by the control unit 7 based on the measurement results of the fuel cell voltmeter 11 and the fuel cell ammeter 12. In the secondary battery 2, the charging current decreases as the charging progresses, and the power generation output of the fuel cell 3 decreases accordingly.
At the same time, predetermined output data relating to the fuel cell 3 is read from the storage unit 70 and compared with the output calculated above. In this example, the predetermined output is set at 40% of the rated output of the fuel cell.
If the power generation output is greater than or equal to the predetermined output, the process returns to step s5 to continue charging.
When the power generation output is less than the predetermined output, the fuel cell 3 or the fuel cell system is stopped (step s7), the control 1 is exited and the control 2 is returned to the step s1, and the voltage of the secondary battery 2 is monitored. If the voltage of the secondary battery 2 is equal to or higher than the rated voltage, the mode is shifted to the save mode (step s2), and the power consumption in the fuel cell power supply system 1 is minimized.

  By repeating the above procedure, the operation control of the fuel cell 3 can be appropriately performed to perform efficient charging and efficient fuel cell operation, and the operating efficiency of the fuel cell 3 is also improved.

Examples of the present invention will be described below.
FIG. 3 shows the result of measuring the open-circuit voltage due to the progress of discharge after charging a lead battery having a capacity of 20 Ah and a rated voltage of 12V. By this test, the relationship between the open circuit voltage and the battery capacity was grasped.
Deep cycle lead batteries can generally be used at a lower limit of about 30%. The open circuit voltage at that time substantially matches the rated voltage of the lead battery as shown in FIG. From this, the start of the fuel cell may be controlled to start when the battery voltage falls below the rated voltage. The start-up criteria are the same even when the secondary battery is not a lead battery.

In addition, the relationship between the FC output and the battery capacity when a lead battery having a capacity of 20 Ah was charged with a 50 W rated fuel cell was grasped (see FIG. 4). As the charging progresses (battery capacity increases), the fuel cell output decreases. When the output of the fuel cell reaches 20 W (40% of the rated output), the battery capacity becomes approximately 80%. Therefore, when the output of the fuel cell falls below a predetermined value, here 40% of the rated output, the battery capacity becomes 80% or more, and the charging efficiency decreases. For this reason, when the output of the fuel cell falls below a predetermined value, the efficiency of the system can be improved by stopping the fuel cell.
When the secondary batteries have different capacities, the fuel cell output decreases as the secondary battery capacity decreases, and the fuel cell output increases as the secondary battery capacity increases. The output of the fuel cell varies depending on the discharge state of the secondary battery. That is, the rated output of the fuel cell varies depending on the combination of the fuel cell and the secondary battery. The fuel cell needs to have an output corresponding to the capacity of the secondary battery. Under such conditions, as shown in FIG. 4, regardless of the capacity of the secondary battery, at the time of charging, the secondary battery capacity is about 80% when the ratio to the rated output of the fuel cell is 40%. It has become. Therefore, in the operation control of the fuel cell, it is desirable in terms of charging efficiency that the operation of the fuel cell is controlled when the output of the fuel cell falls below 40% during charging.
In general, when a secondary battery is charged, as shown in FIG. 5, the battery is charged with a capacity 1.2 to 1.6 times the battery capacity. Further, the capacity that can be used with respect to the battery capacity charged in the secondary battery causes a charging loss of about 15%. This charge loss increases as the battery capacity approaches full (100%). For this reason, the secondary voltage capacity is controlled to be charged from the fuel cell at 80% or less.

Furthermore, as a characteristic investigation of a single fuel cell, the relationship between the output and FC efficiency in a fuel cell rated at 50 W was grasped (see FIG. 6). The FC efficiency is remarkably improved when the output of the fuel cell is 20 W or more (40% or more of the rated output).
From these test results, when charging the battery (secondary battery) from the fuel cell, the fuel cell is operated at 40% or more of the rated output in order to charge the battery with high fuel cell efficiency (FC efficiency). It is preferable to control in such a manner.

FIG. 7 shows the results of an evaluation test when a fuel cell power supply system is operated according to the control procedure shown in FIG. 2 using a lead battery having a capacity of 20 Ah, a rated voltage of 12 V, and a fuel cell having a rating of 50 W.
The output load was kept constant at 5 W, and a fuel cell power supply rated at 50 W was operated at an operation rate of 33%.
Stable output and system efficiency were obtained.

  Moreover, the simulation result by the same conditions is shown in FIG. As a result of the simulation, the battery capacity was operated in the range of 50 to 70%, and the system efficiency showed a good agreement with about 31%.

Furthermore, the system efficiency and the fuel cell operation rate with respect to the load output by simulation were evaluated. The results are shown in Table 1.
Even if the load falls to 1/5 (10 W) or less of the rating of the fuel cell, the system efficiency does not decrease. The operating rate of the fuel cell can be greatly reduced according to the output, and the durability is improved. In addition, it is possible to cope with a load exceeding the output of the fuel cell by selecting the secondary battery.

DESCRIPTION OF SYMBOLS 1 Fuel cell power supply system 2 Secondary battery 3 Fuel cell 4 Hydrogen storage alloy container 5 Hydrogen supply pipe

Claims (10)

A secondary battery for supplying electricity to an external load;
A fuel cell for charging the secondary battery;
A hydrogen storage alloy container for supplying hydrogen to the fuel cell;
A secondary battery voltage measuring unit for measuring a voltage of the secondary battery;
A fuel cell output measuring unit for measuring the output of the fuel cell;
A control unit for controlling the operation of the fuel cell,
The control unit receives measurement results of the secondary battery voltage measurement unit and the fuel cell output measurement unit, and determines that the voltage of the secondary battery is lower than a predetermined voltage according to the measurement result of the secondary battery voltage measurement unit. Then, the fuel cell is activated, and the operation of the fuel cell is stopped when it is determined that the output of the fuel cell is lower than a predetermined output according to the measurement result of the fuel cell output measuring unit during the charging when the fuel cell is operated. A fuel cell power supply system.   2. The fuel cell power supply system according to claim 1, wherein the control unit performs operation control of the fuel cell by adjusting a hydrogen supply amount from the hydrogen storage alloy container.   3. The fuel cell output according to claim 1, wherein the predetermined output is determined in advance as an output of the fuel cell when the battery capacity reaches 80% of the rated battery capacity when the secondary battery is charged. 4. Fuel cell power system.   The fuel cell power supply system according to any one of claims 1 to 3, wherein the predetermined output is determined in advance as 40% of the rated output of the fuel cell.   The fuel cell power supply system according to any one of claims 1 to 4, wherein the predetermined voltage is determined in advance as a rated voltage of the secondary battery. The hydrogen storage alloy container is portable and contains a hydrogen storage alloy capable of releasing hydrogen at room temperature. The maximum hydrogen storage amount of the hydrogen storage alloy stored in the hydrogen storage alloy container is 1 m ³ or less. There,
The fuel cell power supply system according to any one of claims 1 to 5, wherein the fuel cell is of a solid polymer type and has a rated output of 500 W or less.   A drive power source for driving the system is provided, and the drive power source shifts to a save mode in which a drive target is limited while the fuel cell is stopped. The fuel cell power supply system described in 1.   8. The fuel cell power supply system according to claim 7, wherein the drive power supply includes the secondary battery.   In the save mode, only the drive of the control unit that performs the operation of starting the fuel cell according to the drive of the secondary battery voltage measurement unit and the measurement result of the secondary battery voltage measurement unit is targeted. The fuel cell power supply system according to claim 7 or 8, characterized in that: A method of controlling a fuel cell power supply system that supplies electricity from the secondary battery to an external load while charging the secondary battery with the fuel cell,
When determining that the voltage of the secondary battery is lower than a predetermined voltage, when starting the fuel cell and determining that the output of the fuel cell is lower than a predetermined output during the charging when the fuel cell is operated, A control method for a fuel cell power supply system, wherein the operation of the fuel cell is stopped.

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