JP2023113490A - fuel cell system - Google Patents

Abstract

To implement response performance improvement of power generation output and downsizing of a fuel cell system.SOLUTION: A fuel cell system 1 comprises: a fuel cell stack 10 for generating electricity using hydrogen and oxygen; and an air passage 31 connected to the fuel cell stack 10. The air passage 31 has a compressed air introduction port 32 to which house air or air for control is introduced. On the air passage 31 is provided a pressure reduction valve 33 between the compressed air introduction port 32 and the fuel cell stack 10.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to fuel cell systems.

A fuel cell system is known as a system for directly converting chemical energy of fuel gas into electricity. The fuel cell in this fuel cell system can electrochemically react hydrogen, which is the fuel, and oxygen, which is the oxidant, to extract electrical energy with high power generation efficiency. A fuel cell requires air at a flow rate corresponding to the required power generation output. To introduce air into the fuel cell, the fuel cell system is equipped, for example, with a blower.

JP 2013-242964 A

Here, there is a demand for improved responsiveness of the power generation output of the fuel cell system to the required power generation output. In addition, miniaturization of the fuel cell system is required.

SUMMARY OF THE INVENTION The present invention has been made in consideration of such points, and aims to improve the responsiveness of the power generation output of a fuel cell system and to reduce the size of the fuel cell system.

A fuel cell system according to the present invention comprises:
a fuel cell stack that uses hydrogen and oxygen to generate electricity;
an air flow path connected to the fuel cell stack;
with
The air flow path has a compressed air inlet into which internal air or control air is introduced,
A pressure reducing valve is provided on the air flow path between the compressed air inlet and the fuel cell stack.

Alternatively, the fuel cell system according to the present invention is
a plurality of fuel cell stacks that generate electricity using hydrogen and oxygen;
an air distribution channel that distributes air to the plurality of fuel cell stacks;
with
The air distribution channel has a compressed air inlet into which the in-house air or control air is introduced,
A pressure reducing valve is provided on the air distribution channel between the compressed air inlet and the plurality of fuel cell stacks.

According to the present invention, it is possible to improve the responsiveness of the power generation output of the fuel cell system and reduce the size of the fuel cell system.

FIG. 1 is a block diagram showing the configuration of a fuel cell system according to one embodiment of the invention. FIG. 2 is a block diagram showing the configuration of a modified example of the fuel cell system shown in FIG. FIG. 3 is a block diagram showing the configuration of another modification of the fuel cell system shown in FIG. FIG. 4 is a block diagram showing the configuration of still another modification of the fuel cell system shown in FIG.

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a fuel cell system 1 according to one embodiment of the invention.

A fuel cell system 1 shown in FIG. 1 includes a fuel cell stack 10 , a hydrogen supply system 20 and an oxygen supply system 30 . Connected to the fuel cell stack 10 are a power supply device 2 for extracting current from the fuel cell stack 10 and a control device 70 for calculating an output command value and sending it to the power supply device 2 . The input section 3 is connected to the control device 70 . A required power generation amount required for the fuel cell system 1 is input to the control device 70 via the input unit 3 . The control device 70 calculates an output command value based on the requested power generation amount input from the input unit 3 . Also, the control device 70 controls each part of the fuel cell system 1 based on the output command value and other information.

The fuel cell stack 10 uses hydrogen and oxygen to generate electricity. The fuel cell stack 10 has an anode electrode (fuel electrode) 11 and a cathode electrode 12 . Hydrogen is supplied to the anode electrode 11 as a fuel gas. Air is supplied to the cathode electrode 12 . The fuel cell stack 10 reacts hydrogen with oxygen in the air to produce water, which reaction produces electricity. This electricity is output from the fuel cell stack 10 as direct current.

A hydrogen supply system 20 supplies hydrogen to the anode electrode 11 . Air is supplied to the cathode electrode 12 by an oxygen supply system 30 . The rest of the hydrogen supplied to the anode electrode 11 is discharged from the fuel cell stack 10 as anode exhaust. Also, the rest of the air supplied to the cathode electrode 12 is discharged from the fuel cell stack 10 as cathode exhaust. In the illustrated example, the anode exhaust is resupplied to the anode electrode 11 and the cathode exhaust is discharged outside the fuel cell system 1 .

The hydrogen supply system 20 includes a hydrogen supply source 21 such as a hydrogen storage tank and a hydrogen channel 22 . The hydrogen channel 22 connects the hydrogen supply source 21 and the fuel cell stack 10 . Hydrogen from the hydrogen supply source 21 is thereby supplied to the fuel cell stack 10 via the hydrogen flow path 22 . A blower may be provided on the hydrogen flow path 22 , and hydrogen from the hydrogen supply source 21 may be sent to the anode electrode 11 using the blower. The hydrogen supply source 21 may be inside the fuel cell system 1 or outside.

The oxygen supply system 30 includes an air flow path 31 and a pressure reducing valve 33 and a filter device 60 provided on the air flow path 31 . The air flow path 31 connects the in-house air supply device 40 outside the fuel cell system 1 and the fuel cell stack 10 . As a result, air from the in-house air supply device 40 is supplied to the fuel cell stack 10 via the air flow path 31 . More specifically, air flow path 31 has compressed air inlet 32 . The compressed air inlet 32 is connected to a local air supply device 40 . In-house air from an in-house air supply device 40 is introduced into the compressed air inlet 32 . Note that the compressed air inlet 32 may be connected to a control air supply device instead of the in-house air supply device 40 . In this case, control air is introduced into the compressed air inlet 32 from the control air supply device.

The in-house air supply device 40 and the control air supply device may be known devices for supplying in-house air or control air (also called factory air or instrument air). In addition, the in-house air supply device 40 and the control air supply device may be devices already installed in a plant or the like where the fuel cell system 1 is arranged, and are used for purposes other than supplying compressed air to the fuel cell system 1. can be For example, compressed air (house air, control air, factory air, instrument air) from the in-house air supply device 40 or the control air supply device may be used as driving air for various machines, or may be used as air for driving various machines. It may also be used as cleaning air for cleaning equipment inside. Applications of the compressed air from the in-house air supply device 40 and the control air supply device are not limited to those described above.

In the illustrated example, a domestic air supply pressure gauge 51 is connected to the domestic air supply device 40 . The indoor air supply pressure gauge 51 measures the pressure of the compressed air supplied from the indoor air supply device 40 to the air flow path 31 . The in-house air supply pressure gauge 51 can be connected to the control device 70 in the fuel cell system 1 and can send information on the measured compressed air pressure to the control device 70 .

The pressure reducing valve 33 is arranged between the compressed air inlet 32 and the fuel cell stack 10 on the air flow path 31 . The pressure reducing valve 33 reduces the pressure of the compressed air supplied from the in-house air supply device 40 or the control air supply device. Here, the pressure of the compressed air supplied from the in-house air supply device 40 or the control air supply device is generally about 800 kPa to 4.5 MPa. On the other hand, a preferable pressure for the air supplied to the fuel cell stack 10 is, for example, about 2 kPa to 20 kPa. Thus, the pressure of the compressed air supplied from the in-house air supply device 40 or the control air supply device is much higher than the preferable pressure of the air supplied to the fuel cell stack 10 . Therefore, in the fuel cell system 1 , the compressed air supplied from the in-house air supply device 40 or the control air supply device is decompressed using the pressure reducing valve 33 and then supplied to the fuel cell stack 10 . The pressure reducing valve 33 reduces the pressure of the compressed air supplied from the in-house air supply device 40 or the control air supply device to about 20 kPa to 30 kPa, for example.

The filter device 60 removes moisture and impurities from the air introduced into the fuel cell system 1 from the in-house air supply device 40 or the control air supply device. In the illustrated example, the filter device 60 is arranged on the air flow path 31 between the compressed air inlet 32 and the pressure reducing valve 33 .

Thus, in the fuel cell system 1 shown in FIG. 1, the oxygen supply system 30 does not include an air supply device such as a blower, and air is supplied from the existing device 40 at the location where the fuel cell system 1 is used. Thereby, the fuel cell system 1 can be miniaturized. In general, the indoor air supply device 40 and the control air supply device constantly generate the indoor air and the control air. Therefore, air can be immediately supplied to the fuel cell stack 10 by connecting the compressed air inlet 32 of the fuel cell system 1 to the in-house air supply device 40 or the control air supply device. This contributes to improving the responsiveness of the power generation output of the fuel cell system 1 . In addition, when the oxygen supply system 30 of the fuel cell system 1 includes a blower and the blower is used to supply air to the fuel cell stack 10, the time from when the blower is started until the air volume of the blower reaches a desired air volume is Sufficient air cannot be supplied to the fuel cell stack 10 during this period. This is a factor that hinders improvement in the responsiveness of the power generation output of the fuel cell system 1 .

In the illustrated example, the oxygen supply system 30 further includes a buffer tank 34 , a flow control valve 35 , and a buffer tank internal pressure gauge 50 . The buffer tank 34 is provided between the pressure reducing valve 33 and the fuel cell stack 10 on the air flow path 31 and stores the air pressure-reduced by the pressure reducing valve 33 . A buffer tank internal pressure gauge 50 is connected to the buffer tank 34 . A buffer tank internal pressure gauge 50 measures the pressure within the buffer tank 34 . The flow control valve 35 is provided between the buffer tank 34 and the fuel cell stack 10 on the air flow path 31 . A flow control valve 35 regulates the flow rate of air from the buffer tank 34 to the fuel cell stack 10 . The flow control valve 35 adjusts the flow rate of the air according to the output command value input to the power supply device 2 and the battery current measured by the power supply device 2 . The flow control valve 35 receives a control signal from the control device 70, for example, and controls the flow rate of the air.

The air decompressed by the decompression valve 33 is stored in the buffer tank 34, and the flow rate of the air from the buffer tank 34 to the fuel cell stack 10 is adjusted by the flow control valve 35, so that the fuel cell stack 10 is maintained at the desired pressure. of air can be stably supplied at a desired flow rate.

In the illustrated example, the oxygen supply system 30 further has an auxiliary compressor 36 , an auxiliary air flow path 37 and a flow control valve 38 . The auxiliary compressor 36 may be a known compressor, and can generate compressed air of about 20 kPa to 30 kPa by compressing outside air, for example. The auxiliary air flow path 37 connects the auxiliary compressor 36 and the buffer tank 34 and introduces the compressed air from the auxiliary compressor 36 into the buffer tank 34 . The auxiliary compressor 36 is activated upon receiving a control signal from the control device 70, for example. A flow rate control valve 38 regulates the flow rate of air from the auxiliary compressor 36 to the buffer tank 34 . The flow control valve 38 adjusts the flow rate of the air according to the battery current measured by the power supply device 2 . The flow control valve 38 receives a control signal from the control device 70, for example, and controls the flow rate of the air.

Compressed air can be introduced from the auxiliary compressor 36 to the buffer tank 34, so that even if for some reason a sufficient amount of compressed air cannot be obtained from the in-house air supply device 40 or the control air supply device, the buffer tank 34 can be filled with a sufficient amount of compressed air. Therefore, the fuel cell stack 10 can be more stably supplied with air at a desired pressure and at a desired flow rate.

Next, the action of the fuel cell system 1 shown in FIG. 1 will be described. First, the compressed air inlet 32 of the fuel cell system 1 is connected to the local air supply device 40, and the supply of air from the local air supply device 40 to the buffer tank 34 is started. At this time, air from which moisture and impurities have been removed by the filter device 60 is supplied to the buffer tank 34 . Further, when the required power generation amount required for the fuel cell stack 10 is input from the input unit 3 to the control device 70 , the control device 70 calculates an output command value based on the required power generation amount, hand over. As a result, the supply of hydrogen from the hydrogen supply system 20 and the supply of air from the oxygen supply system 30 to the fuel cell stack 10 are started, and the fuel cell system 1 starts power generation.

While the fuel cell system 1 is generating power, the control device 70 acquires information about the pressure inside the buffer tank 34 from the buffer tank pressure gauge 50 . If the pressure is less than the predetermined pressure, the controller 70 inputs a control signal to the auxiliary compressor 36 to start the auxiliary compressor 36 .

Also, while the fuel cell system 1 is generating power, the control device 70 adjusts the opening degree of the flow control valve 35 based on the output command value input to the power supply device 2 .

As described above, the power generation output corresponding to the output command value determined by the control device 70 is obtained from the fuel cell stack 10 .

The output command value is calculated as follows. First, the control device 70 performs a predetermined calculation on the requested power generation amount input from the input unit 3 . When the calculation result is equal to or less than the predetermined upper limit value and equal to or more than the predetermined lower limit value, the control device 70 passes the calculation result to the power supply device 2 as an output command value. On the other hand, when the calculation result is larger than the predetermined upper limit value, the control device 70 passes the predetermined upper limit value to the power supply device 2 as an output command value. Further, when the calculation result is smaller than the predetermined lower limit value, the control device 70 passes the predetermined lower limit value to the power supply device 2 as an output command value. When the indoor air supply device 40 and the auxiliary compressor 36 are not operating normally, the control device 70 sets the output command value to 0, as will be described later.

The upper limit value used for calculating the output command value is determined as follows. Normally, the upper limit value is set to the same value as the rated power output of the fuel cell stack 10 . However, if the pressure in the buffer tank 34 obtained from the buffer tank pressure gauge 50 during power generation by the fuel cell system 1 is lower than the predetermined pressure, the flow rate from the buffer tank 31 to the fuel cell stack 10 is lower than normal. of air can be supplied, the fuel cell stack 10 cannot generate power at its rated power output. Therefore, the control device 70 obtains a new upper limit value corresponding to the pressure measured by the buffer tank internal pressure gauge 50, and uses this new upper limit value to determine the output command value. Here, the new upper limit is a value lower than the rated power output. For example, the new upper limit is the maximum power output that the fuel cell stack 10 can output even if the pressure in the buffer tank 31 is the pressure measured above. The new upper limit value is obtained by performing a predetermined calculation on the pressure measured by the buffer tank internal pressure gauge 50 . This predetermined calculation is performed by the upper limit value calculator 71 of the control device 70 .

When the new upper limit value is set, a new output command value is input from the control device 70 to the power supply device 2, and the fuel cell stack 10 generates power based on this new output command value. Since the new output command value is determined using a new upper limit value that is lower than the normal upper limit value, the maximum flow rate of air required for power generation by the fuel cell stack 10 is reduced. In this way, when the pressure in the buffer tank 34 is lowered, the upper limit of the output setting value input to the power supply device 2 is lowered, so that the fuel cell stack 10 from the buffer tank 34 (in other words, the in-house air supply is reduced). Even if the flow rate of air supplied from the device 40 or the auxiliary compressor 36 to the buffer tank 34 decreases, the fuel cell system 1 can continue to generate power. Note that when the amount of air supplied to the fuel cell stack 10 decreases and the amount of air consumed by the fuel cell stack 10 becomes greater than the amount of air, the fuel cell system 1 cannot continue power generation. protection is suspended.

Further, while the fuel cell system 1 is generating power, the control device 70 acquires information about the pressure of the compressed air supplied to the fuel cell system 1 by the local air supply device 40 from the local air supply pressure gauge 51 . Thereby, the control device 70 determines whether or not the indoor air supply device 40 is operating normally. Specifically, when the pressure measured by the indoor air supply pressure gauge 51 is extremely low, the control device 70 determines that the indoor air supply device 40 is not operating normally. Further, while the fuel cell system 1 is generating power, the control device 70 determines whether or not the auxiliary compressor 36 is operating normally. For example, if controller 70 does not receive an operation signal from auxiliary compressor 36, it determines that auxiliary compressor 36 has failed and stopped. If the in-house air supply device 40 is not operating normally and the auxiliary compressor 36 is stopped, air cannot be supplied to the fuel cell stack 10 . In this case, the control device 70 determines the output command value to be 0 and transfers it to the power supply device 2 . As a result, the operation of the fuel cell system 1 can be safely stopped.

It should be noted that whether or not the in-house air supply device 40 and the auxiliary compressor 36 are operating normally may be determined based on the pressure inside the buffer tank 34 obtained from the pressure gauge 50 inside the buffer tank. Specifically, when the pressure measured by the buffer tank internal pressure gauge 50 continues to be extremely low for a predetermined period of time, the control device 70 prevents both the in-house air supply device 40 and the auxiliary compressor 36 from operating normally. You can judge that it is not.

As described above, the fuel cell system 1 according to the present embodiment includes the fuel cell stack 10 that generates electricity using hydrogen and oxygen, and the air flow path 31 connected to the fuel cell stack 10. there is The air flow path 31 has a compressed air inlet 32 through which room air or control air is introduced. A pressure reducing valve 33 is provided on the air flow path 31 between the compressed air inlet 32 and the fuel cell stack 10 . According to such a fuel cell system 1, the size of the fuel cell system 1 can be reduced compared to the case where the fuel cell system 1 includes an air supply device such as a blower. Also, the responsiveness of the power generation output of the fuel cell system 1 can be improved.

In addition, in the fuel cell system 1 according to the present embodiment, a buffer tank 34 that stores air decompressed by the pressure reducing valve 33 is provided on the air flow path 31 between the pressure reducing valve 33 and the fuel cell stack 10; and a flow control valve 35 that controls the flow rate of air from the buffer tank 34 to the fuel cell stack 10 . According to such a fuel cell system 1, it is possible to stably supply the fuel cell stack 10 with air at a desired pressure and at a desired flow rate.

Moreover, the fuel cell system 1 according to the present embodiment further includes an auxiliary compressor 36 that introduces compressed air into the buffer tank 34 . According to the fuel cell system 1 as described above, even if a sufficient amount of compressed air cannot be obtained from the in-house air supply device 40 or the control air supply device for some reason, the buffer tank 34 can be supplied with a sufficient amount of compressed air. can be filled with Therefore, the fuel cell stack 10 can be more stably supplied with air at a desired pressure and at a desired flow rate.

Further, the fuel cell system 1 according to the present embodiment calculates an output command value equal to or lower than the predetermined upper limit value based on the required power generation amount required of the fuel cell stack 10 and the predetermined upper limit value, and the fuel cell stack 10 A control device 70 for generating power according to the output command value and a pressure gauge 50 for measuring the pressure in the buffer tank 34 are further provided. When the pressure in the buffer tank 34 measured by the pressure gauge 50 is lower than the predetermined pressure, the control device 70 lowers the predetermined upper limit value to calculate a new output command value, and outputs the new output command value to the fuel cell stack 10 . Power is generated with the power generation output according to the output command value. In this case, even if the flow rate of the air supplied from the buffer tank 34 to the fuel cell stack 10 (in other words, from the in-house air supply device 40 or the auxiliary compressor 36 to the buffer tank 34) decreases, the fuel cell system 1 will operate to generate power. can be continued.

Further, the fuel cell system 1 according to the present embodiment includes a pressure gauge 50 for measuring the pressure in the buffer tank 34, an auxiliary compressor 36, and an auxiliary compressor for introducing the air compressed by the auxiliary compressor 36 into the buffer tank 34. and an air flow path 37 for air flow. Auxiliary compressor 36 is activated when the pressure in buffer tank 34, as measured by pressure gauge 50, is lower than a predetermined pressure. Compressed air can be introduced from the auxiliary compressor 36 to the buffer tank 34, so that even if for some reason a sufficient amount of compressed air cannot be obtained from the in-house air supply device 40 or the control air supply device, the buffer tank 34 can be filled with a sufficient amount of compressed air. Therefore, the fuel cell stack 10 can be more stably supplied with air at a desired pressure and at a desired flow rate.

Further, the fuel cell system 1 according to the present embodiment calculates an output command value based on the required power generation amount required for the fuel cell stack 10, and outputs power to the fuel cell stack 10 according to the output command value. A control device 70 for generating power and a pressure gauge 50 for measuring the pressure in the buffer tank 34 are further provided. The control device 70 stops the fuel cell system 1 when the pressure in the buffer tank 34 measured by the pressure gauge 50 remains lower than a predetermined pressure for a predetermined period of time. If the pressure in the buffer tank 34 measured by the pressure gauge 50 continues to be lower than the predetermined pressure for a predetermined period of time, the in-house air supply device 40 is not operating normally and the auxiliary compressor 36 is out of order. Therefore, air cannot be supplied to the fuel cell stack 10 . In this case, by stopping the fuel cell system 1 by the control device 70, the operation of the fuel cell system 1 can be safely stopped.

Next, a modification of the fuel cell system according to this embodiment will be described with reference to FIG. The fuel cell system 1 of the modified example shown in FIG. The difference is that the oxygen supply system 30 includes a check valve 61 for the purpose of preventing backflow of air to the equipment 40 . Other configurations are substantially the same as those of the fuel cell system 1 shown in FIG. In the modification shown in FIG. 2, the same reference numerals are assigned to the same parts as in the embodiment shown in FIG. 1, and detailed description thereof will be omitted.

With the fuel cell system 1 shown in FIG. 2 as well, the same effects as those of the fuel cell system 1 shown in FIG. 1 can be obtained.

Next, another modification of the fuel cell system according to this embodiment will be described with reference to FIG. The modified fuel cell system 100 shown in FIG. 3 is different in that it includes a plurality of fuel cell stacks 10A and 10B. Further, the modified fuel cell system 100 shown in FIG. 3 is different in that its oxygen supply system 300 includes an air distribution channel 310 that distributes air to the plurality of fuel cell stacks 10A and 10B. Further, the modified fuel cell system 100 shown in FIG. 3 is different in that its hydrogen supply system 200 includes a hydrogen supply source 21 and a plurality of hydrogen flow paths 22A and 22B. Other configurations are substantially the same as those of the fuel cell system 1 shown in FIG. In the modification shown in FIG. 3, the same reference numerals are assigned to the same parts as in the embodiment shown in FIG. 1, and detailed description thereof will be omitted.

As shown in FIG. 3, the modified fuel cell system 100 includes a first fuel cell stack 10A, a second fuel cell stack 10B, a hydrogen supply system 200, and an oxygen supply system 300. Power supply devices 2A and 2B are connected to the respective fuel cell stacks 10A and 10B for extracting current from the fuel cell stacks 10A and 10B. Each power supply device 2A, 2B is connected to a control device 70 .

A required power generation amount required for the fuel cell system 100 is input to the control device 70 via the input unit 3 . Control device 70 calculates output command values for fuel cell stacks 10A and 10B based on the required power generation amount input from input unit 3 . The control device 70 controls each part of the fuel cell system 100 in the same manner as the control device 70 of the fuel cell system 1 shown in FIG.

The first fuel cell stack 10A and the second fuel cell stack 10B are configured similarly to the fuel cell stack 10 shown in FIG. The hydrogen supply system 200 supplies hydrogen to the anode electrode 11 of the first fuel cell stack 10A and the anode electrode 11 of the second fuel cell stack 10B. The hydrogen supply system 200 includes a hydrogen supply source 21 and hydrogen flow paths 22A and 22B. The first hydrogen flow path 22A connects the hydrogen supply source 21 and the first fuel cell stack 10A. Thereby, hydrogen from the hydrogen supply source 21 is supplied to the first fuel cell stack 10A through the first hydrogen flow path 22A. The second hydrogen flow path 22B connects the hydrogen supply source 21 and the second fuel cell stack 10B. As a result, hydrogen from the hydrogen supply source 21 is supplied to the second fuel cell stack 10B via the second hydrogen channel 22B.

The oxygen supply system 300 supplies air to the cathode electrode 12 of the first fuel cell stack 10A and the cathode electrode 12 of the second fuel cell stack 10B. In the example shown in FIG. 3, the oxygen supply system 300 includes an air distribution channel 310 that distributes air to the first fuel cell stack 10A and the second fuel cell stack 10B, and a pressure reducing valve provided on the air distribution channel 310. 33 and The air distribution channel 310 connects the in-house air supply device 40 or the control air supply device outside the fuel cell system 100 and the plurality of fuel cell stacks 10A and 10B. Air from the in-house air supply device 40 or the control air supply device is thereby supplied to the plurality of fuel cell stacks 10A and 10B via the air distribution flow path 310 . More specifically, the air distribution channel 310 has a main channel 311 and a first branch channel 312 and a second branch channel 313 connected to the downstream end of the main channel 311 . A compressed air inlet 32 connected to the in-house air supply device 40 or the control air supply device is provided at the upstream end of the main flow path 311 . The downstream ends of the first branched channel 312 and the second branched channel 313 are connected to the first fuel cell stack 10A and the second fuel cell stack 10B, respectively.

The pressure reducing valve 33 is arranged on the air distribution channel 310 between the compressed air inlet 32 and the fuel cell stacks 10A and 10B. In the illustrated example, the pressure reducing valve 33 is arranged on the main flow path 311 . The pressure reducing valve 33 reduces the pressure of the compressed air supplied from the in-house air supply device 40 or the control air supply device.

In the fuel cell system 100 shown in FIG. 3, the oxygen supply system 300 also does not include an air supply device such as a blower. Therefore, the fuel cell system 100 can be downsized. Further, since air is supplied from the in-house air supply device 40 and the control air supply device, the responsiveness of the power generation output of the fuel cell system 100 can be improved.

In the illustrated example, the oxygen supply system 300 further includes a buffer tank 34 and flow control valves 35A and 35B. The buffer tank 34 is provided between the pressure reducing valve 33 and the fuel cell stacks 10A and 10B on the air distribution flow path 310 and stores the air pressure-reduced by the pressure reducing valve 33 . In the illustrated example, the buffer tank 34 is arranged on the main flow path 311 . Flow control valves 35A and 35B are provided on air distribution channel 310 between buffer tank 34 and fuel cell stacks 10A and 10B. In the illustrated example, the oxygen supply system 300 includes a first flow control valve 35A and a second flow control valve 35B. The first flow control valve 35A and the second flow control valve 35B are provided on the first branch channel 312 and the second branch channel 313, respectively. The first flow rate control valve 35A and the second flow rate control valve 35B respectively control the flow rate of air from the buffer tank 34 to the first fuel cell stack 10A and the second fuel cell stack 10B. The flow control valves 35A, 35B control the flow rate of the air according to output command values input to the power supply devices 2A, 2B of the corresponding fuel cell stacks 10A, 10B, power supply devices 2A, 2B of the corresponding fuel cell stacks 10A, 10B, Adjust according to the battery current measured at 2B. The flow rate control valves 35A and 35B, for example, receive control signals from the control device 70 and control the flow rate of the air.

The air decompressed by the decompression valve 33 is stored in the buffer tank 34, and the flow rate of the air from the buffer tank 34 to the fuel cell stacks 10A and 10B is adjusted by the flow control valves 35A and 35B. Air of a desired pressure can be stably supplied to 10A and 10B at a desired flow rate. In the example shown in FIG. 3, the oxygen supply system 300 has the same number of the flow control valves 35A and 35B as the number of the branch channels 312 and 313, but it is not limited to this. For example, oxygenation system 300 may have only one flow control valve 35 . In this case, the flow control valve 35 may be provided on the main flow path 311 downstream of the buffer tank 34 (between the buffer tank 34 and the branch flow paths 312 and 313). In this case also, the flow control valve 35 can control the flow rate of air from the buffer tank 34 to each of the fuel cell stacks 10A and 10B.

Further, in the illustrated example, the oxygen supply system 300 further includes an auxiliary compressor 36 , an auxiliary air flow path 37 and a flow control valve 38 .

Although the fuel cell system 100 includes two fuel cell stacks 10A and 10B in the example shown in FIG. 3, the present invention is not limited to this. Fuel cell system 100 may include three or more fuel cell stacks 10 . In this case, the air distribution channel 310 of the fuel cell system 100 may have the same number of branch channels as the fuel cell stack 10, and each branch channel may be provided with a flow control valve 35 . Moreover, in the example shown in FIG. 3 , the fuel cell system 100 may have a plurality of hydrogen supply systems 20 . In this case, one hydrogen supply system 20 may be provided for each fuel cell stack 10 .

Further, as shown in FIG. 4, the buffer tank 34, the auxiliary compressor 36 and the flow control valve 38 may be provided upstream of the pressure reducing valve 33. FIG. In this case, the oxygen supply system 300 may include a check valve 61 as shown in FIG.

Next, operation of the fuel cell system 100 shown in FIG. 3 will be described. First, the compressed air inlet 32 of the fuel cell system 100 is connected to the local air supply device 40 , and the supply of air from the local air supply device 40 to the buffer tank 34 is started. At this time, air from which moisture and impurities have been removed by the filter device 60 is supplied to the buffer tank 34 . Further, when the required power generation amount required for the fuel cell system 100 is input from the input unit 3 to the control device 70 , the control device 70 calculates an output command value based on the required power generation amount, hand over. As a result, the supply of hydrogen from the hydrogen supply system 200 and the supply of air from the oxygen supply system 300 to the fuel cell stacks 10A and 10B are started, and the fuel cell system 100 starts power generation.

While the fuel cell system 100 is generating power, the control device 70 acquires information about the pressure inside the buffer tank 34 from the buffer tank pressure gauge 50 . If the pressure is less than the predetermined value, the control device 70 inputs a control signal to the auxiliary compressor 36 to start the auxiliary compressor 36 .

Further, while the fuel cell system 100 is generating power, the control device 70 adjusts the opening degree of the flow control valve 35A based on the output command value input to the power supply device 2A, and based on the output command value input to the power source device 2B. Adjust the opening of the flow control valve 35B.

As described above, a power generation output corresponding to the output command value determined by the control device 70 is obtained from each of the fuel cell stacks 10A and 10B.

The output command value is calculated as follows. First, when the required power generation amount is input from the input unit 3, the controller 70 calculates the required power generation amount required for each fuel cell stack 10A, 10B in consideration of the rated power generation output of each fuel cell stack 10A, 10B. Ask for Next, the control device 70 performs a predetermined calculation on the required power generation amount required of the first fuel cell stack 10A. When the calculation result is equal to or less than the predetermined upper limit value and equal to or more than the predetermined lower limit value, the control device 70 passes the calculation result to the power supply device 2A as an output command value. On the other hand, when the calculation result is larger than the predetermined upper limit value, the control device 70 passes the predetermined upper limit value to the power supply device 2A as an output command value. Further, when the calculation result is smaller than the predetermined lower limit value, the control device 70 passes the predetermined lower limit value to the power supply device 2A as an output command value. Similarly, the control device 70 performs a predetermined calculation on the required power generation amount required of the second fuel cell stack 10B. When the calculation result is equal to or less than the predetermined upper limit value and equal to or more than the predetermined lower limit value, the control device 70 passes the calculation result to the power supply device 2B as an output command value. On the other hand, when the calculation result is larger than the predetermined upper limit value, the control device 70 passes the predetermined upper limit value to the power supply device 2B as an output command value. Further, when the calculation result is smaller than the predetermined lower limit value, the control device 70 passes the predetermined lower limit value to the power supply device 2B as an output command value. When the indoor air supply device 40 and the auxiliary compressor 36 are not operating normally, the control device 70 sets the output command value to 0, as will be described later.

The upper limit value used for calculating the output command value is determined as follows. Normally, the upper limit value used to calculate the output command value input to the power supply device 2A is set to the same value as the rated power generation output of the first fuel cell stack 10A. Also, the upper limit value used for calculating the output command value input to the power supply device 2B is set to the same value as the rated power generation output of the second fuel cell stack 10B. However, if the pressure in the buffer tank 34 obtained from the buffer tank pressure gauge 50 during power generation by the fuel cell system 100 is lower than the predetermined pressure, the pressure from the buffer tank 31 to the fuel cell stacks 10A and 10B will be higher than normal. Since only a small flow rate of air can be supplied, the fuel cell stacks 10A and 10B cannot generate power at their rated power output. Therefore, the control device 70 obtains a new upper limit value corresponding to the pressure measured by the buffer tank internal pressure gauge 50 for each of the fuel cell stacks 10A and 10B, and uses this new upper limit value to , 2B are determined. Here, the new upper limit value input to the power supply device 2A is a value lower than the rated power generation output of the first fuel cell stack 10A. Also, the new upper limit value input to the power supply device 2B is a value lower than the rated power generation output of the second fuel cell stack 10B. For example, the new upper limit value is the maximum power output that each fuel cell stack 10A, 10B can output even if the pressure in the buffer tank 31 is the pressure measured above. The new upper limit value is obtained by performing a predetermined calculation on the pressure measured by the buffer tank internal pressure gauge 50 . This predetermined calculation is performed by the upper limit value calculator 71 of the control device 70 .

When a new upper limit value is set, a new output command value is input from the control device 70 to the power supply devices 2A and 2B, and power generation is performed in the fuel cell stacks 10A and 10B based on this new output command value. Since the new output command value is determined using a new upper limit value that is lower than the normal upper limit value, the maximum flow rate of air required for power generation by fuel cell stacks 10A and 10B is reduced. In this way, when the pressure in the buffer tank 34 decreases, the upper limit of the output setting value input to the power supply device 2 is lowered, so that the fuel cell stacks 10A and 10B from the buffer tank 34 (in other words, internal Even if the flow rate of air supplied from the air supply device 40 or the auxiliary compressor 36 to the buffer tank 34 decreases, the fuel cell system 100 can continue power generation operation.

Further, while the fuel cell system 100 is generating power, the control device 70 acquires information on the pressure of the compressed air supplied to the fuel cell system 100 by the local air supply device 40 from the local air supply pressure gauge 51 . Thereby, the control device 70 determines whether or not the indoor air supply device 40 is operating normally. Specifically, when the pressure measured by the indoor air supply pressure gauge 51 is extremely low, the control device 70 determines that the indoor air supply device 40 is not operating normally. Further, while the fuel cell system 100 is generating power, the control device 70 determines whether or not the auxiliary compressor 36 is operating normally. For example, if controller 70 does not receive an operation signal from auxiliary compressor 36, it determines that auxiliary compressor 36 has failed and stopped. If the in-house air supply device 40 is not operating normally and the auxiliary compressor 36 is stopped, air cannot be supplied to the fuel cell stacks 10A and 10B. In this case, control device 70 determines that the output command value to be input to power supply devices 2A and 2B is 0, and passes it to power supply devices 2A and 2B. As a result, the operation of the fuel cell system 100 can be safely stopped.

It should be noted that whether or not the in-house air supply device 40 and the auxiliary compressor 36 are operating normally may be determined based on the pressure inside the buffer tank 34 obtained from the pressure gauge 50 inside the buffer tank. Specifically, when the pressure measured by the buffer tank internal pressure gauge 50 remains extremely low, the control device 70 determines that neither the in-house air supply device 40 nor the auxiliary compressor 36 is operating normally. You can judge.

As described above, the fuel cell system 100 according to the modification includes a plurality of fuel cell stacks 10A and 10B that generate electricity using hydrogen and oxygen, and an air distribution system that distributes air to the plurality of fuel cell stacks 10A and 10B. and a channel 310 . The air distribution channel 310 has a compressed air inlet 32 into which house air or control air is introduced. A pressure reducing valve 33 is provided on the air distribution channel 310 between the compressed air inlet 32 and the plurality of fuel cell stacks 10A and 10B. With such a fuel cell system 100 as well, the fuel cell system 100 can be made smaller than when the fuel cell system 100 includes an air supply device such as a blower. Also, the responsiveness of the power generation output of the fuel cell system 100 can be improved.

Further, in the fuel cell system 100 according to the modified example, a buffer capable of containing the air pressure-reduced by the pressure-reducing valve 33 is provided on the air distribution channel 310 between the pressure-reducing valve 33 and the plurality of fuel cell stacks 10A and 10B. A tank 34 and flow control valves 35A and 35B for controlling the flow rate of air from the buffer tank 34 to the fuel cell stacks 10A and 10B are provided. According to such a fuel cell system 100, it is possible to stably supply air at a desired pressure at a desired flow rate to each of the fuel cell stacks 10A and 10B.

Moreover, the fuel cell system 100 according to the modification further includes an auxiliary compressor 36 that introduces compressed air into the buffer tank 34 . According to the fuel cell system 100 as described above, even if a sufficient amount of compressed air cannot be obtained from the in-house air supply device 40 or the control air supply device for some reason, the buffer tank 34 can be supplied with a sufficient amount of compressed air. can be filled with Therefore, air at a desired pressure can be more stably supplied to each of the fuel cell stacks 10A and 10B at a desired flow rate.

The above-described embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof. Moreover, it is of course possible to partially appropriately combine the above-described embodiments and their modifications within the scope of the present invention.

1, 100: fuel cell system, 2: power supply device, 3: input unit, 10, 10A, 10B: fuel cell stack, 11: anode electrode, 12: cathode electrode, 20, 20A, 20B: hydrogen supply system, 21: Hydrogen supply source 22: Hydrogen flow path 30, 300: Oxygen supply system 31: Air flow path 32: Compressed air inlet 33: Pressure reducing valve 34: Buffer tank 35, 35A, 35B: Flow control valve , 36: Auxiliary compressor, 37: Auxiliary air flow path, 38: Flow control valve, 40: Station air supply device, 50: Buffer tank internal pressure gauge, 51: Station air supply pressure gauge, 60: Filter device, 61 : check valve, 70: control device, 71: upper limit calculation unit, 310: air distribution channel, 311: main channel, 312: first branch channel, 313: second branch channel

Claims (9)

a fuel cell stack that uses hydrogen and oxygen to generate electricity;
an air flow path connected to the fuel cell stack;
with
The air flow path has a compressed air inlet into which internal air or control air is introduced,
A fuel cell system, wherein a pressure reducing valve is provided on the air flow path between the compressed air inlet and the fuel cell stack. On the air flow path, between the pressure reducing valve and the fuel cell stack, a buffer tank for containing air pressure-reduced by the pressure reducing valve and for adjusting the flow rate of the air from the buffer tank to the fuel cell stack. 2. The fuel cell system according to claim 1, further comprising a flow control valve that controls the flow rate of the fuel cell. 3. The fuel cell system according to claim 2, further comprising an auxiliary compressor for introducing compressed air into said buffer tank. a plurality of fuel cell stacks that generate electricity using hydrogen and oxygen;
an air distribution channel that distributes air to the plurality of fuel cell stacks;
with
The air distribution channel has a compressed air inlet into which the in-house air or control air is introduced,
A fuel cell system, wherein a pressure reducing valve is provided between the compressed air inlet and the plurality of fuel cell stacks on the air distribution channel. Between the pressure reducing valve and the plurality of fuel cell stacks, a buffer tank capable of containing air pressure-reduced by the pressure reducing valve and air from the buffer tank to each fuel cell stack are provided on the air distribution flow path. 5. The fuel cell system according to claim 4, further comprising a flow rate control valve that regulates the flow rate of . 6. The fuel cell system according to claim 5, further comprising an auxiliary compressor for introducing compressed air into said buffer tank. An output command value equal to or lower than the predetermined upper limit value is calculated based on the required power generation amount required for the fuel cell stack and a predetermined upper limit value, and the fuel cell stack is caused to generate power according to the output command value. a controller;
a pressure gauge for measuring the pressure in the buffer tank;
further comprising
When the pressure in the buffer tank measured by the pressure gauge is lower than a predetermined pressure, the control device lowers the upper limit value to calculate a new output command value, and outputs the new output to the fuel cell stack. 7. The fuel cell system according to claim 2, 3, 5, or 6, which generates power according to a command value. a pressure gauge for measuring the pressure in the buffer tank;
an auxiliary compressor;
an auxiliary air flow path for introducing the air compressed by the auxiliary compressor into the buffer tank;
further comprising
8. The fuel cell system according to claim 2, 3, 5, 6, or 7, wherein said auxiliary compressor is activated when the pressure in said buffer tank measured by said pressure gauge is lower than a predetermined pressure. a control device that calculates an output command value based on the required power generation amount required for the fuel cell stack, and causes the fuel cell stack to generate power according to the output command value;
a pressure gauge for measuring the pressure in the buffer tank;
further comprising
7. The control device stops the fuel cell system when the pressure in the buffer tank measured by the pressure gauge continues to be lower than a predetermined pressure for a predetermined time. , 7 or 8.