JP2020095800A - Control unit, control method and fuel cell power generation system - Google Patents

Abstract

To provide control unit, a control method and a fuel cell power generation system, capable of suppressing a decrease in hydrogen gas utilization rate.SOLUTION: A control unit according to the present embodiment is used for controlling the degassing flow rate of a degassing pipe that is branched from a hydrogen recycling pipe where anode off gas of a fuel cell is recycled to be mixed with raw fuel for reuse. The control unit includes an acquisition section acquiring information on the degassing flow rate, and a control section performing a control to adjust the degassing flow rate depending on a change in the degassing flow rate, on the basis of the information.SELECTED DRAWING: Figure 1

Description

The present invention relates to a control device, a control method, and a fuel cell power generation system.

A fuel cell system generally uses a hydrogen-containing gas supplied to a fuel electrode in a fuel cell and an oxygen-containing gas supplied to an oxidizer electrode in the fuel cell to generate electricity. The unreacted hydrogen is contained in the anode off gas discharged from the fuel electrode during power generation. Therefore, the anode off gas may be supplied again to the fuel cell and used for power generation.

When the anode off gas is circulated, the concentration of impurities such as nitrogen contained in the anode off gas increases with the passage of time, and the voltage of the fuel cell decreases. Therefore, a degassing pipe is connected to a hydrogen recycle pipe for circulating the anode off-gas, and a discharge valve of the exhaust degassing pipe is opened as necessary to discharge nitrogen and the like together with part of the anode off-gas. As a result, the concentration of impurities in the anode off gas reused for power generation is reduced. However, the opening time of the discharge valve may be set longer so that the concentration of nitrogen or the like is sufficiently reduced. In such a case, a larger amount of hydrogen is discharged, which may reduce the utilization rate of hydrogen gas.

JP, 2005-93232, A

The problem to be solved by the present invention is to provide a control device, a control method, and a fuel cell power generation system for a fuel cell power generation system capable of suppressing a decrease in utilization rate of hydrogen gas.

The control device according to the present embodiment is a control device that recirculates anode off-gas of a fuel cell and controls a degassing flow rate of a degassing pipe branched from a hydrogen recycle pipe mixed with a raw fuel for reuse. An acquisition unit that acquires information regarding the air flow rate, and a control unit that performs control that adjusts the degassing flow rate according to the change in the degassing flow rate based on the information.

According to the present invention, it is possible to suppress a decrease in utilization rate of hydrogen gas.

The block diagram explaining the composition of the fuel cell power generation system concerning this embodiment. The block diagram which shows the structure of a control apparatus. FIG. 4 is a graph showing an example of a table stored in a storage unit. The flowchart which shows an example of the control operation of a control apparatus. The block diagram which shows the structure of the control apparatus which concerns on 2nd Embodiment. The figure which shows the relationship between hydrogen concentration and pressure. The flowchart which shows an example of the control operation of the control apparatus which concerns on 2nd Embodiment. The block diagram which shows the structure of the control apparatus which concerns on 3rd Embodiment. The figure which shows the relationship between hydrogen concentration and pressure after the degassing shutoff valve was opened. The flowchart which shows an example of the control operation of the control apparatus which concerns on 3rd Embodiment.

Hereinafter, a control device, a control method, and a fuel cell power generation system according to embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are examples of the embodiments of the present invention, and the present invention is not construed as being limited to these embodiments. Further, in the drawings referred to in this embodiment, the same portions or portions having similar functions are denoted by the same reference numerals or similar reference numerals, and repeated description thereof may be omitted. In addition, the dimensional ratios in the drawings may be different from the actual ratios for convenience of description, or a part of the configuration may be omitted from the drawings.

(First embodiment)
FIG. 1 is a block diagram illustrating a configuration of a fuel cell power generation system 1 according to the first embodiment. As shown in FIG. 1, the fuel cell system 1 according to the present embodiment is a system capable of reusing the anode off gas discharged from the fuel electrode of the fuel cell during power generation. The fuel cell system 1 includes a hydrogen gas supply pipe 2, an oxygen gas supply pipe 4, a hydrogen recycle pipe 6, a degassing pipe 8, a fuel cell 100, a hydrogen gas supply device 102, a blower 104, and a fuel cutoff. The valve 106, the adjusting valve 108, the fuel flow meter 110, the first pressure loss portion 112, the degassing shutoff valve 114, the second pressure loss portion 116, the pressure gauge 118, the thermometer 120, and the control device 200. It is configured with. Here, the utilization rate of hydrogen gas means a rate at which hydrogen supplied from the hydrogen gas supply device 102 is used for power generation of the fuel cell 100.

The hydrogen gas supply pipe 2 is a supply pipe connected between the inlet portion J1 of the fuel electrode passage 100a of the fuel cell 100 and the hydrogen gas supply device 102. As a result, the hydrogen gas supply pipe 2 supplies the hydrogen-containing gas supplied from the hydrogen gas supply device 102 to the fuel electrode channel 100a in the fuel cell 100.

The oxygen gas supply pipe 4 is a supply pipe connected to the inlet of the oxidant electrode flow channel 100b in the fuel cell 100. As a result, the oxygen gas supply pipe 4 supplies the oxygen-containing gas to the oxidant electrode channel 100b of the fuel cell 100.

The hydrogen recycle pipe 6 is a recirculation pipe connected between the outlet J2 of the fuel electrode channel 100a in the fuel cell 100 and the confluence J3 of the hydrogen gas supply pipe 2. The hydrogen recycle pipe 6 circulates the anode off-gas discharged from the fuel electrode flow channel 100a via the confluence J3 of the hydrogen gas supply pipe 2.

The deaeration pipe 8 is a pipe branched from a branch J4 provided between the air blower 104 and the confluence J3 in the hydrogen recycle pipe 6, and discharges a part of the anode off gas.

The fuel cell 100 has a fuel electrode flow channel 100a for supplying a hydrogen-containing gas to a fuel electrode (anode) and an oxidant flow channel 100b for supplying an oxygen-containing gas to an oxidant electrode (cathode). Electric power is generated using the hydrogen-containing gas supplied to the electrode and the oxygen-containing gas supplied to the oxidant electrode. The oxygen-containing gas is, for example, the atmosphere. Here, the anode off gas is a gas discharged from the fuel electrode channel 100a during power generation of the fuel cell 100, and contains unreacted hydrogen gas. Nitrogen N ₂ in the oxygen-containing gas supplied to the oxidizer electrode is mixed in the anode off gas. Therefore, the nitrogen concentration of the anode off gas (hydrogen H ₂ +nitrogen N ₂ ) in the circulation increases with time, and conversely, the hydrogen concentration in the anode off gas decreases.

The fuel cell 100 is configured by stacking a plurality of fuel cells. The fuel cell 100 utilizes the electrochemical reaction represented by (Chemical Formula 1) to extract electric energy from the electrodes.

(Chemical formula 1)
Fuel electrode reaction: H ₂ →2H ⁺ +2e ⁻
Oxidant electrode reaction: (1/2)O ₂ +2H ⁺ +2e ⁻ →H ₂ O

The hydrogen gas supply device 102 supplies the hydrogen-containing gas from the upstream side of the fuel electrode passage 100a of the fuel cell 100 via the hydrogen gas supply pipe 2. Further, as the hydrogen gas supply device 102, a hydrogen cylinder or the like may be used. The fuel source pressure, which is the source pressure of the hydrogen-containing gas supplied from the hydrogen gas supply device 102, is maintained at a constant value.

The blower unit 104 is, for example, a diaphragm pump, a roots pump, or a scroll pump, and is provided in the hydrogen recycle pipe 6 upstream of the confluence J3 of the hydrogen gas supply pipe 2. The blower unit 104 sucks the anode off gas from the downstream side of the fuel electrode and discharges it to the downstream side of the blower unit 104 of the recycled gas flow channel 6.

The fuel cutoff valve 106 opens and closes the hydrogen gas supply pipe 2. Hydrogen is supplied from the hydrogen gas supply device 102 to the hydrogen gas supply pipe 2 when the fuel cutoff valve 106 is opened. On the other hand, when the fuel cutoff valve 106 is closed, the hydrogen supply from the hydrogen gas supply device 102 to the hydrogen gas supply pipe 2 is cut off.

The adjustment valve 108 adjusts the hydrogen supply amount from the hydrogen gas supply device 102 to the hydrogen gas supply pipe 2 by the opening degree of the valve when the fuel cutoff valve 106 is opened. The hydrogen gas supply pipe 2 according to the present embodiment is provided with the fuel cutoff valve 106 and the adjustment valve 108, but the invention is not limited to this. For example, only the fuel cutoff valve 106 is provided, and the fuel cutoff valve 106 is provided. A predetermined amount of hydrogen, which is the raw fuel, may be supplied to the hydrogen recycle pipe 6 by controlling the opening and closing of. Further, while the raw fuel is being supplied, the power generation output or current value of the fuel cell 100 is maintained at a predetermined value or higher.

The fuel flow meter 110 measures the flow rate of hydrogen flowing through the hydrogen gas supply pipe 2.

The first pressure loss portion 112 is, for example, a flow rate orifice, and is arranged between the joining portion J3 of the hydrogen gas supply pipe 2 and the hydrogen recycle pipe 6 and the branch portion J4 of the hydrogen recycle pipe 6 and the degassing pipe 8. For example, if the flow rate of the anode off-gas in the hydrogen recycle pipe 6 is constant and the fuel source pressure in the hydrogen gas supply pipe 2 is constant, if nitrogen in the anode off-gas in the hydrogen recycle pipe 6 rises, the balance is increased. , The delta pressure at the flow orifice increases. As a result, the pressure on the upstream side of the flow rate orifice, that is, the pressure in the region including the branch J4 increases.

The degassing shutoff valve 114 opens and closes the degassing pipe 8 that discharges a part of the anode off gas. When the degassing shutoff valve 114 is closed, the degassing pipe 8 is shut off. As a result, degassing from the hydrogen recycle pipe 6 is blocked. On the other hand, when the degassing shutoff valve 114 is open, degassing from the hydrogen recycle pipe 6 is performed.
The second pressure loss portion 116 is, for example, a degassing flow rate orifice, and is arranged between the branch portion J4 of the degassing pipe 8 and the degassing shutoff valve 114.

The pressure gauge 118 is provided between the blower 104 of the hydrogen recycle pipe 6 and the branch J4. Thereby, the pressure gauge 118 measures the pressure in the hydrogen recycle pipe 6 on the upstream side of the branch J4.

The thermometer 120 is provided between the air blower 104 of the hydrogen recycle pipe 6 and the branch J4. Thereby, the thermometer 120 measures the temperature in the hydrogen recycle pipe 6 on the upstream side of the branch J4.

FIG. 2 is a block diagram showing the configuration of the control device 200. As shown in FIG. 2, the control device 200 controls the entire fuel cell power generation system 1. The control device 200 is configured to include a processor, and realizes various functions by reading out a necessary program from the storage unit 202 and executing it. That is, the control device 200 is configured to include the storage unit 202, the acquisition unit 204, the degassing flow rate calculation unit 206, and the control unit 208.

The storage unit 202 is realized by, for example, a RAM (Random Access Memory), a semiconductor memory device such as a flash memory, a hard disk, an optical disk, or the like. The storage unit 202 stores a table showing the relationship between the degassing flow rate discharged from the degassing pipe 8 and the hydrogen concentration in the hydrogen recycle pipe 6. The storage unit 202 also stores a table showing the relationship between the flow rate of hydrogen flowing in the hydrogen gas supply pipe 2 and the hydrogen concentration in the hydrogen recycle pipe 6.

FIG. 3 is a graph showing an example of a table stored in the storage unit 202. It is a graph which shows the relationship between a degassing flow rate and hydrogen concentration. The vertical axis represents the degassing flow rate, and the horizontal axis represents the hydrogen concentration. Here, a case is shown in which a predetermined amount of hydrogen, which is raw fuel, is supplied to the hydrogen recycle pipe 6 by fixing the opening degree of the adjustment valve 108. That is, when the degassing shutoff valve 114 is opened and the degassing of the anode off gas is started, the degassing flow rate gradually increases. This is because the nitrogen concentration in the anode off gas decreases and the density of the anode off gas gradually decreases, so that the flow rate increases.

The acquisition unit 204 acquires a value related to the degassing flow rate degassed from the degassing pipe 8. For example, the acquisition unit 204 measures the first flow rate measured by the fuel flow meter 110 when the degassing shutoff valve 114 is shut off, and the first flow rate measured by the fuel flowmeter 110 when the degassing shutoff valve 114 is open. Get the second flow rate. The acquisition unit 204 also acquires the pressure measured by the pressure gauge 118 and the temperature measured by the thermometer 120.

The degassing flow rate calculation unit 206 calculates the degassing flow rate based on the flow rate measured by the fuel flow meter 110. For example, the degassing flow rate calculation unit 206 calculates the difference between the second flow rate and the first flow rate acquired by the acquisition unit 204 as the degassing flow rate.

During power generation of the fuel cell 100, the control unit 208 supplies the hydrogen recycle pipe 6 with a predetermined amount of hydrogen, which is the raw fuel, by opening the fuel cutoff valve 106 and fixing the opening degree of the valve of the adjusting valve 108. .. That is, the fuel source pressure, which is the source pressure of the hydrogen-containing gas supplied from the hydrogen gas supply device 102, is maintained at a constant value. On the other hand, the fuel cutoff valve 106 is closed to stop the power generation of the fuel cell 100.

Further, the control unit 208 controls the opening/closing of the degassing shutoff valve 114 when the fuel cell 100 is generating power. This controls the hydrogen concentration in the anode off gas. More specifically, the control for opening the degassing shutoff valve 114 is performed when a predetermined time has passed since the degassing shutoff valve 114 was closed. Thereby, as described above, when the degassing of the anode off gas is started, the degassing flow rate gradually increases.

The control unit 208 performs control for adjusting the degassing flow rate degassed from the degassing pipe 8 according to the change in the value related to the degassing flow rate acquired by the acquisition unit 204. That is, when the degassing flow rate of the predetermined amount of raw fuel (H ₂ ) supplied to the fuel cell 100 reaches the predetermined value, the control unit 208 controls the degassing from the degassing pipe 8.

More specifically, the control unit 208 controls the degassing from the degassing pipe 8 when the difference value calculated by the degassing flow rate calculating unit 206, that is, the degassing flow rate reaches a predetermined first threshold value. .. The first threshold value is set based on a target hydrogen concentration value using a table stored in the storage unit 202. As a result, when the hydrogen concentration reaches the predetermined value, the degassing from the degassing pipe 8 is controlled so that the hydrogen concentration can be reduced to a predetermined value or less. Further, since this control can be performed only by the measurement value of the fuel flow meter 110, the fuel cell power generation system 1 can be simplified.

In addition, the second flow rate measured when the degassing shutoff valve 114 is in the open state has a relationship that is the sum of the first flow rate measured in the closed state and the degassing flow rate. Since the first flow rate is a fixed value, the control unit 208 may control the degassing from the degassing tube 8 when the flow rate of the raw fuel in the hydrogen gas supply pipe 2 reaches a predetermined second threshold value. Good. The second threshold value is set based on a target hydrogen concentration value using a table stored in the storage unit 202. As a result, when the hydrogen concentration reaches the predetermined value, the degassing from the degassing pipe 8 is controlled so that the hydrogen concentration can be reduced to a predetermined value or less. In this case, the calculation process can be omitted, and the control process can be further simplified.

Furthermore, as shown in FIG. 3, the change in the increase amount of the degassing flow rate with respect to the hydrogen concentration has a constant characteristic. Therefore, the control unit 208 may perform control to continue degassing from the degassing pipe 8 until the rate of change of the degassing flow rate becomes equal to or higher than a predetermined value. That is, the control unit 208 may perform control to close the degassing shutoff valve 114 when the rate of change of the degassing flow rate, for example, the time differential value of the degassing flow rate becomes equal to or greater than a predetermined value. In this case, it is possible to reduce the influence of fluctuations in the fuel source pressure supplied to the hydrogen gas supply pipe 2.

Here, the word processor is, for example, a CPU (Central Processing Unit), a GPU (Graphics Processing Unit), or an application-specific integrated circuit (ASIC), a programmable logic device (eg, simple programmable logic device). (Simple Programmable Logic Device: SPLD), a complex programmable logic device (Complex Programmable Logic Device: CPLD), and a field programmable gate array (Field Programmable Gate Array: memory 202, etc.). Instead of storing the program, the program may be directly incorporated in the circuit of the processor, and each configuration in the control device 200 may be realized by an electronic circuit.

The above is the description of the configuration of the fuel cell system 1 according to the present embodiment. Next, an example of the control operation of the control device 200 will be described. FIG. 4 is a flowchart showing an example of the control operation of the control device 200. Here, the first flow rate measured by the fuel flow meter 110 in the state where the degassing shutoff valve 114 is shut off is already acquired, and the control from the time point when the degassing shutoff valve 114 is opened to start degassing An example will be described.

First, the acquisition unit 204 acquires the second flow rate measured by the fuel flow meter 110 with the degassing shutoff valve 114 open (step S100).

Next, the degassing flow rate calculation unit 206 calculates the degassing flow rate based on the second flow rate measured by the fuel flow meter 110 (step S102). That is, the degassing flow rate calculation unit 206 calculates the difference between the second flow rate and the first flow rate acquired by the acquisition unit 204 as the degassing flow rate.

Next, the control unit 208 determines whether the degassing flow rate is greater than or equal to a predetermined value (step S104). When the degassing flow rate is less than the predetermined value (No in step S104), the control unit 208 repeats the processing from step S100.

On the other hand, when the degassing flow rate is equal to or higher than the predetermined value (Yes in step S104), the control unit 208 shuts off the degassing shutoff valve 114 (step S106) and ends the entire process.

As described above, according to the present embodiment, the control unit 208 closes the degassing shutoff valve 114 when the degassing flow rate becomes equal to or higher than the predetermined value. Since the hydrogen concentration and the amount of increase in the degassing flow rate with respect to the hydrogen concentration have a fixed relationship, it is possible to block degassing from the degassing pipe 8 when the hydrogen concentration reaches a predetermined value. As a result, reduction in hydrogen utilization efficiency is suppressed while the voltage of the fuel cell 100 is maintained at a predetermined value or higher.

(Second embodiment)
The fuel cell system 1 according to the second embodiment has a function of correcting the control value of the control unit 208 according to at least one of the pressure and the temperature in the hydrogen recycle pipe 6, and thus the first embodiment The fuel cell power generation system 1 according to the present invention is different. The different points will be described below.

FIG. 5 is a block diagram showing the configuration of the control device 200 according to the second embodiment. The control device 200 according to the present embodiment differs from the control device 200 according to the first embodiment in that it further includes a hydrogen concentration calculation unit 210, a correction calculation unit 212, and a closing time adjustment unit 214.

The hydrogen concentration calculation unit 210 converts the value of the degassing flow rate calculated by the degassing flow amount calculation unit 206 into a hydrogen concentration based on the conversion table stored in the storage unit 202.

The correction calculator 212 calculates the hydrogen concentration calculator 210 based on at least one of the pressure measured by the pressure gauge 118 acquired by the acquisition unit 204 and the temperature measured by the thermometer 120 when the degassing shutoff valve 114 is closed. The hydrogen concentration calculated by is corrected. As a result, it is possible to reduce the influence of temperature and pressure fluctuations in the hydrogen recycle pipe 6 before the degassing shutoff valve 114 is opened. The pressure fluctuation here is mainly due to the fluctuation of the wind power of the air blowing unit 104.

FIG. 6 is a diagram showing a relationship between the hydrogen concentration 604 and the pressure 606 in the hydrogen recycle pipe 6 after the degassing shutoff valve 114 is opened. An instruction line 600 indicates the open/close state of the degassing shutoff valve 114. That is, the period 602 indicates the period in which the degassing shutoff valve 114 is in the closed state. The horizontal axis represents time, and the vertical axis represents hydrogen concentration and pressure.

As shown in FIG. 6, the hydrogen concentration 604 in the hydrogen recycle pipe 6 decreases as the closed state of the degassing shutoff valve 114 increases. On the other hand, the pressure 606 in the hydrogen recycle pipe 6 increases as the closing period for closing the degassing shutoff valve 114 becomes longer. As can be seen from this, as the closing period of the degassing shutoff valve 114 becomes shorter, the decrease of the hydrogen concentration 604 in the hydrogen recycle pipe 6 is suppressed.

The closing time adjustment unit 214 stores, in the storage unit 202, the deaeration time during which the deaeration flow rate becomes a predetermined value or more after the deaeration shutoff valve 114 is opened. The deaeration time is the time until the hydrogen concentration in the hydrogen recycle pipe 6 reaches a predetermined value.

The control unit 208 further shortens the closing period for closing the degassing shutoff valve 114 as the degassing time becomes longer. As shown in FIG. 6, a decrease in the hydrogen concentration in the hydrogen recycle pipe 6 is suppressed as the closing period becomes shorter. In this way, by controlling the closing period in which the degassing shutoff valve 114 is closed so that the degassing time becomes a constant value, it is possible to prevent the hydrogen concentration in the hydrogen recycle pipe 6 from falling below a predetermined value. ..

The above is the description of the configuration of the fuel cell system 1 according to the present embodiment. Next, an example of the control operation of the control device 200 will be described. FIG. 7 is a flowchart showing an example of the control operation of the control device 200 according to the second embodiment.

First, the acquisition unit 204 acquires the first flow rate measured by the fuel flow meter 110 when the degassing shutoff valve 114 is closed, the pressure measured by the pressure gauge 118, and the temperature measured by the thermometer 120. (Step S200).

Next, the control unit 208 opens the degassing shutoff valve 114 (step S202). Subsequently, the acquisition unit 204 acquires the second flow rate measured by the fuel flow meter 110 when the degassing shutoff valve 114 is open (step S204).

Next, the degassing flow rate calculation unit 206 calculates the degassing flow rate based on the first flow rate and the second flow rate measured by the fuel flow meter 110 (step S206). Subsequently, the hydrogen concentration calculation unit 210 converts the value into the hydrogen concentration based on the value of the degassing flow rate calculated by the degassing flow amount calculation unit 206 (step S208).

Next, the correction calculator 212 corrects the hydrogen concentration calculated by the hydrogen concentration calculator 210 based on the pressure measured by the pressure gauge 118 and the temperature measured by the thermometer 120 (step S210).

Next, the control unit 208 determines whether or not the hydrogen concentration is equal to or higher than a predetermined value (step S212). When the hydrogen concentration is equal to or higher than the predetermined value (YES in step S212), the control unit 208 repeats the processing from step S204.

On the other hand, when the hydrogen concentration is less than the predetermined value (NO in step S212), the control unit 208 shuts off the degassing shutoff valve 114 (step S214) and ends the entire process.

As described above, according to the present embodiment, the hydrogen concentration calculated by the degassing flow rate calculation unit 206 based on the degassing flow rate is corrected by using at least one of the pressure and temperature in the hydrogen recycle pipe 6 and the correction calculation unit 212. Decided to correct. Then, the control unit 208 decides to close the degassing shutoff valve 114 when the corrected hydrogen concentration becomes less than the predetermined value. This makes it possible to control the hydrogen concentration in the hydrogen recycle pipe 6 while reducing the influence of the pressure and temperature fluctuations in the hydrogen recycle pipe 6 when the degassing shutoff valve 114 is closed.

(Third Embodiment)
The fuel cell system 1 according to the third embodiment differs from the fuel cell power generation system 1 according to the second embodiment in that the pressure in the hydrogen recycle pipe 6 controls the open period of the degassing shutoff valve 114. The different points will be described below.

FIG. 8 is a block diagram showing the configuration of the control device 200 according to the third embodiment. The control device 200 according to the present embodiment is different from the control device 200 according to the second embodiment in that the control device 200 further includes the hydrogen concentration conversion unit 216.

FIG. 9 is a diagram showing a relationship between the hydrogen concentration 904 and the pressure 906 in the hydrogen recycle pipe 6 after the degassing shutoff valve 114 is opened. An instruction line 900 indicates the open/close state of the degassing shutoff valve 114. That is, the period 902 shows the period in which the fuel cutoff valve 106 is in the open state. The horizontal axis represents time, and the vertical axis represents hydrogen concentration and pressure.

As shown in FIG. 9, the hydrogen concentration 904 in the hydrogen recycle pipe 6 increases as the open time of the degassing shutoff valve 114 increases. On the other hand, the pressure 906 in the hydrogen recycle pipe 6 decreases as the open state time increases. As can be seen from this, it is possible to obtain the hydrogen concentration 904 in the hydrogen recycle pipe 6 based on the pressure 906 in the hydrogen recycle pipe 6.

The storage unit 202 stores a conversion table for converting the pressure 906 in the hydrogen recycle pipe 6 into the hydrogen concentration 904 in the hydrogen recycle pipe 6, which is generated based on the characteristics shown in FIG. 9, for example. That is, the conversion table is a table for converting so that the value of the hydrogen concentration 904 increases as the value of the pressure 906 decreases.

The hydrogen concentration conversion unit 216 converts the pressure in the hydrogen recycle pipe 6 acquired by the acquisition unit 204 into a hydrogen concentration based on the conversion table stored in the storage unit 202. The control unit 208 controls the open state time of the degassing shutoff valve 114 based on the hydrogen concentration converted by the hydrogen concentration converting unit 216.

Further, the control unit 208 may perform control to shut off degassing from the degassing pipe 8 when the rate of change of the pressure 906 in the hydrogen recycle pipe 6 becomes equal to or lower than a predetermined value. Alternatively, the control unit 208 may control the degassing from the degassing pipe 8 when the pressure 906 in the hydrogen recycle pipe 6 becomes equal to or lower than a predetermined value.

The above is the description of the configuration of the fuel cell system 1 according to the present embodiment. Next, an example of the control operation of the control device 200 will be described. FIG. 10 is a flowchart showing an example of the control operation of the control device 200 according to the third embodiment. Here, an example of control from the time when degassing is started by opening the degassing shutoff valve 114 will be described.

First, the acquisition unit 204 acquires the pressure measured by the pressure gauge 118 (step S1002).

Next, the hydrogen concentration conversion unit 216 converts the pressure measured by the pressure gauge 118 into hydrogen concentration (step S1004).

Next, the control unit 208 determines whether or not the hydrogen concentration is equal to or higher than a predetermined value (step S1006). When the hydrogen concentration is equal to or higher than the predetermined value (YES in step S1006), the control unit 208 repeats the processing from step S1002.

On the other hand, when the hydrogen concentration is less than the predetermined value (NO in step S1006), the control unit 208 closes the degassing shutoff valve 114 (step S210) and ends the entire process.

As described above, according to the present embodiment, the hydrogen concentration conversion unit 216 converts the pressure inside the hydrogen recycle pipe 6 into hydrogen concentration. Then, the control unit 208 determines to close the degassing shutoff valve 114 when the corrected hydrogen concentration becomes less than the predetermined value. As a result, it is possible to prevent excessive degassing of hydrogen from the degassing pipe 8 and interruption of degassing when the hydrogen concentration is low.
Although some embodiments of the present invention have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modified examples are included in the scope and the gist of the invention, and are also included in the invention described in the claims and the equivalent scope thereof.

1: Fuel cell power generation system, 2: Hydrogen gas supply pipe, 6: Hydrogen recycle pipe, 8: Degassing pipe, 100: Fuel cell, 200: Control device, 204: Acquisition unit, 208: Control unit.

Claims (14)

A control device for controlling the degassing flow rate of a degassing pipe branched from a hydrogen recycle pipe for recirculating the anode off-gas of the fuel cell and mixing with the raw fuel for reuse.
An acquisition unit for acquiring information on the degassing flow rate,
A control unit that controls the degassing flow rate according to the change of the degassing flow rate based on the information;
And a control device. A threshold value of the degassing flow rate corresponding to a predetermined hydrogen concentration in the hydrogen recycle pipe is set,
The control device according to claim 1, wherein the control unit starts degassing from the degassing pipe and, when the degassing flow rate reaches the threshold value, performs control to shut off degassing from the degassing pipe. .. The fuel cell is supplied with the raw fuel through a hydrogen gas supply pipe,
The acquisition unit has a first flow rate in the hydrogen gas supply pipe in a state where degassing from the degassing pipe is blocked, and the hydrogen gas supply in a state where degassing from the degassing pipe is continued. Has acquired the second flow rate in the pipe,
The control device according to claim 1, wherein the control unit performs control to shut off degassing from the degassing pipe when a flow rate difference between the first flow rate and the second flow rate reaches a predetermined value. The fuel cell is supplied with the raw fuel through a hydrogen gas supply pipe,
The acquisition unit acquires the flow rate in the hydrogen gas supply pipe in a state where degassing from the degassing pipe is continuing,
The control device according to claim 1, wherein the control unit performs control to shut off deaeration from the deaeration pipe when the flow rate reaches a predetermined value. The control device according to claim 1, wherein the control unit performs control to shut off degassing from the degassing pipe when the rate of change of the degassing flow rate reaches a predetermined value. The controller according to any one of claims 1 to 5, wherein the controller adjusts the degassing flow rate also based on the pressure in the hydrogen recycle pipe. The control device according to any one of claims 1 to 6, wherein the control unit adjusts the degassing flow rate also based on the temperature in the hydrogen recycle pipe. Further comprising a storage unit that stores a degassing time from the start of degassing from the degassing pipe until the degassing is interrupted,
The said control part is a control apparatus as described in any one of Claim 1 thru|or 7 which controls the start time which starts deaeration after the deaeration of the said deaeration pipe|tube was interrupted based on the said deaeration time. The control device according to claim 8, wherein the control unit performs control to further shorten the start time as the degassing time increases. The acquisition unit acquires the degassing pressure in the hydrogen recycle pipe in a state where degassing from the degassing pipe is continuing,
The control device according to any one of claims 1 to 9, wherein the control unit performs control to shut off degassing from the degassing pipe when the degassing pressure reaches a predetermined level. The acquisition unit acquires the degassing pressure in the hydrogen recycle pipe in a state where degassing from the degassing pipe is continuing,
The said control part is a control apparatus as described in any one of Claims 1 thru|or 9 which performs the control which interrupts|blocks the deaeration from the said deaeration pipe, when the change speed of the said deaeration pressure becomes below a predetermined value constant. The control device according to claim 1, wherein a power generation output or a current value of the fuel cell is maintained at a predetermined value or more while the raw fuel is being supplied. A method of controlling a fuel cell power generation system for controlling the degassing flow rate of a degassing pipe branched from a hydrogen recycle pipe for recirculating anode off-gas of a fuel cell and reusing it by mixing with raw fuel,
An acquisition step of acquiring information about the degassing flow rate,
Based on the information, a control step of shutting off deaeration from the deaeration pipe according to the change in the deaeration flow rate,
And a control method. A fuel cell,
A hydrogen recycle pipe for recirculating the anode off gas of the fuel cell, mixing it with the raw fuel for reuse.
A degassing pipe branched from the hydrogen recycle pipe,
A fuel cell system comprising: a control device for controlling the degassing flow rate from the degassing pipe,
The control device is
An acquisition unit for acquiring information on the degassing flow rate,
A control unit that controls the degassing flow rate according to the change of the degassing flow rate based on the information;
A fuel cell system having:

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