KR20230129800A - Method and system for sequentially controlling fuel cell - Google Patents

Abstract

The fuel cell sequential control method of the present invention is a sequential control method of a fuel cell sequential control system that sequentially controls a plurality of fuel cells, including the steps of operating some of the plurality of fuel cells and maintaining the others in a stopped state and preset conditions. If this is satisfied, it includes stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state.

Description

Fuel cell sequential control method and system {METHOD AND SYSTEM FOR SEQUENTIALLY CONTROLLING FUEL CELL}

The present invention relates to a fuel cell sequential control method and system for sequentially controlling a plurality of fuel cells.

Power plants such as ships can use hydrogen fuel cell systems for propulsion. A hydrogen fuel cell system refers to a system that separates hydrogen ions from hydrogen and combines them with oxygen in the air to generate electricity and provides power based on this.

Generally, a power plant may be equipped with a plurality of hydrogen fuel cell systems. There are cases where the output of the hydrogen fuel cell system must be maximized in response to the required load power of the power plant.

Meanwhile, while the hydrogen fuel cell system is maximizing its output, malfunctions and durability may vary, which may result in performance degradation.

Accordingly, there is a need for technology that can efficiently supply fuel to power plants by stably maintaining the output from the entire hydrogen fuel cell system.

The technical problem to be solved by the present invention relates to a fuel cell sequential control method and system for sequentially controlling a plurality of fuel cells to supply fuel to a power plant and maintain stable output.

The fuel cell sequential control method according to an embodiment of the present invention is a sequential control method of a fuel cell sequential control system that sequentially controls a plurality of fuel cells, in which some of the plurality of fuel cells are operated and the others are kept in a stopped state. ordering step; and stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state when a preset condition is satisfied.

In addition, when a preset condition according to an embodiment of the present invention is satisfied, the step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state includes the operation of at least some of the operating fuel cells. If the time exceeds a preset critical operation time, stopping at least part of the operation and operating at least part of the fuel cells in the stopped state.

In addition, when the operation time of at least some of the operating fuel cells according to an embodiment of the present invention exceeds a preset critical operation time, the step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state , measuring the operating time of each operating fuel cell, determining whether the operating time exceeds a preset critical operating time, and stopping at least some of the fuel cells if the operating time exceeds the preset critical operating time. It includes the step of operating the same number of fuel cells as at least some of the stopped fuel cells among the fuel cells in the stopped state.

In addition, when a preset condition according to an embodiment of the present invention is satisfied, the step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state includes the accumulation of at least some of the operating fuel cells. If the output power exceeds a preset reference cumulative output power, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state.

In addition, when the accumulated output power of at least some of the operating fuel cells according to an embodiment of the present invention exceeds a preset reference cumulative output power, at least some of the operating fuel cells are stopped and at least some of the fuel cells in the stopped state are operated. The steps include measuring the output power of each operating fuel cell, calculating the cumulative output power of each operating fuel cell based on the output power, and determining whether the cumulative output power exceeds the preset cumulative output power. A step of stopping at least some of the fuel cells when the accumulated output power exceeds a preset accumulated output power, and operating the same number of fuel cells as at least some of the stopped fuel cells among the fuel cells in the stopped state. Includes.

In addition, when a preset condition according to an embodiment of the present invention is satisfied, the step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state includes generating electricity from at least some of the operating fuel cells. If the amount of moisture exceeds a preset critical moisture amount, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state.

In addition, when the amount of moisture generated in at least some of the operating fuel cells according to an embodiment of the present invention exceeds a preset critical moisture amount, the step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state , measuring the amount of moisture generated in each operating fuel cell, determining whether the moisture amount exceeds a preset critical moisture amount, stopping at least some of the fuel cells if the moisture amount exceeds the preset critical moisture amount, and It includes operating the same number of fuel cells as at least some of the stopped fuel cells among the stopped fuel cells.

In addition, when a preset condition according to an embodiment of the present invention is satisfied, the step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state includes the membrane electrode provided in the operating fuel cell. When the fatigue level of at least some of the assemblies reaches a preset critical fatigue level, the method includes stopping at least some of the operating parts and operating at least some of the fuel cells in the stopped state.

In addition, when the fatigue of at least some of the membrane electrode assemblies provided in the operating fuel cell according to an embodiment of the present invention reaches a preset threshold fatigue, at least some of the operating fuel cells are stopped and one of the fuel cells in the stopped state is stopped. The step of operating at least part of the operation includes measuring the fatigue of the membrane electrode assembly provided in each operating fuel cell, determining whether the fatigue exceeds a preset critical fatigue, and determining whether the fatigue exceeds the preset critical fatigue. In this case, it includes stopping at least some of the fuel cells and operating the same number of fuel cells as at least some of the stopped fuel cells among the fuel cells in the stopped state.

In addition, the fuel cell sequential control system according to an embodiment of the present invention is a fuel cell sequential control system including a plurality of fuel cells, and is connected to each of the plurality of fuel cells to monitor the operating status of the plurality of fuel cells. A plurality of unit control units that measure and control the operation of a plurality of fuel cells, operate some of the plurality of fuel cells and keep the others in a stopped state, and stop at least some of the operating fuel cells when preset conditions are met. It includes a group control unit that outputs a control signal to a plurality of unit control units to operate at least some of the fuel cells in the state.

In addition, the group control unit according to an embodiment of the present invention, when the operation time of at least some of the operating fuel cells exceeds a preset critical operation time, stops at least some of the operating fuel cells and operates the fuel cells in the stopped state. A control signal is output to operate the same number of fuel cells as at least some of the stopped fuel cells.

In addition, the group control unit according to an embodiment of the present invention, when the accumulated output power of at least some of the operating fuel cells exceeds the preset accumulated output power, stops at least some of the operating fuel cells and fuels the stopped fuel cells. A control signal is output to operate the same number of fuel cells as at least some of the stopped fuel cells among the cells.

In addition, the group control unit according to an embodiment of the present invention, when the amount of moisture generated in at least some of the operating fuel cells exceeds a preset critical moisture amount, stops at least some of the operating fuel cells and operates the fuel cells in the stopped state. A control signal is output to operate the same number of fuel cells as at least some of the stopped fuel cells.

In addition, the group control unit according to an embodiment of the present invention stops and stops at least some of the operating fuel cells when the fatigue of at least some of the membrane electrode assemblies provided in the operating fuel cells reaches a preset critical fatigue. A control signal is output to operate the same number of fuel cells as at least some of the fuel cells in the stopped state.

The fuel cell sequential control method and system according to the present invention can sequentially control a plurality of fuel cells to maintain stable output and stabilize the performance of the fuel cell system.

1 is a diagram for explaining a fuel cell sequential control system, a fuel cell system, and an external device according to an embodiment of the present invention.
Figure 2 is a diagram for explaining a fuel cell sequential control method using a fuel cell sequential control system according to an embodiment of the present invention.
Figure 3 is a flowchart illustrating a fuel cell sequential control method according to an embodiment of the present invention.
Figure 4 is a flowchart explaining a fuel cell sequential control method based on operation time according to an embodiment of the present invention.
Figure 5 is a flowchart illustrating a fuel cell sequential control method based on accumulated output power according to an embodiment of the present invention.
Figure 6 is a flowchart explaining a fuel cell sequential control method based on moisture content according to an embodiment of the present invention.
Figure 7 is a flowchart explaining a fuel cell sequential control method based on fatigue according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, various embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention, parts that are not relevant to the description are omitted, and identical or similar components are assigned the same reference numerals throughout the specification. Therefore, the reference signs described above can be used in other drawings as well.

In addition, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, so the present invention is not necessarily limited to what is shown. In order to clearly represent multiple layers and regions in the drawing, the thickness may be exaggerated.

Additionally, the expression “same” in the description may mean “substantially the same.” In other words, it may be identical to the extent that a person with ordinary knowledge can understand that it is the same. Other expressions may also be expressions where “substantially” is omitted.

Additionally, when a part in the description 'includes' a certain component, this does not mean excluding other components, but may include other components, unless specifically stated to the contrary. As used herein, '~unit' refers to a unit that processes at least one function or operation, and may mean, for example, software, FPGA, or hardware components. The functions provided in '~ part' may be performed separately by multiple components, or may be integrated with other additional components. '~ part' in this specification is not necessarily limited to software or hardware, and may be configured to be in an addressable storage medium, or may be configured to reproduce one or more processors. Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a diagram for explaining a fuel cell sequential control system, a fuel cell system, and an external device according to an embodiment of the present invention.

The fuel cell sequential control system 1 according to an embodiment of the present invention may include a group control unit 10 and a plurality of unit control units 11.

The fuel cell sequential control system 1 of FIG. 1 is assumed to include n unit control units 11 (where n is a natural number), which is the same number as the plurality of fuel cells 12 to be described below. Each of the unit control units 11 will be referred to as the first to nth unit control units 11.

The fuel cell system 2 may include a plurality of fuel cells 12. The fuel cell system 2 in FIG. 1 may include n fuel cells 12. Each of the n fuel cells 12 will be referred to as the first to nth fuel cells 12.

The first to nth unit control units 11 may be connected to the group control unit 10. The first to nth unit control units 11 may be connected to the first to nth fuel cells 12, respectively.

Specifically, the first unit control unit 11 may be connected to the first fuel cell 12. The nth unit control unit 11 may be connected to the nth fuel cell 12.

The first to nth unit control units 11 can measure the operating states of the first to nth fuel cells 12. That is, the first unit control unit 11 can measure the operating state of the first fuel cell 12. The nth unit control unit 11 can measure the operating state of the nth fuel cell 12.

Specifically, the first to nth unit control units 11 can measure the operation time of the first to nth fuel cells 12. The first to nth unit control units 11 may provide an operation time measurement signal containing data on the operation times of the first to nth fuel cells 12 to the group control unit 10.

Alternatively, the first to nth unit control units 11 may measure the output power of the first to nth fuel cells 12. The first to nth unit control units 11 may provide an output power measurement signal containing data on the output power of the first to nth fuel cells 12 to the group control unit 10.

Alternatively, the first to nth unit control units 11 may measure the amount of moisture generated in the first to nth fuel cells 12. The first to nth unit control units 11 may provide a moisture quantity measurement signal containing data on the moisture amount of the first to nth fuel cells 12 to the group control unit 10.

Alternatively, the first to nth unit control units 11 may measure the fatigue of the membrane electrode assembly (MEA) provided in the first to nth fuel cells 12. The first to nth unit control units 11 may provide a fatigue measurement signal containing data on the fatigue of the membrane electrode assembly provided in the first to nth fuel cells 12 to the group control unit 10.

The first to nth unit control units 11 may receive control signals for sequentially controlling the first to nth fuel cells 12 from the group control unit 10. The first to nth unit control units 11 may sequentially control the first to nth fuel cells 12 based on control signals provided from the group control unit 10.

For example, the first unit control unit 11 may control the first fuel cell 12 based on a control signal provided from the group control unit 10. The nth unit control unit 11 may control the nth fuel cell 12 based on a control signal provided from the group control unit 10.

Specifically, the first unit control unit 11 may operate the first fuel cell 12 based on the operation control signal (osg, see FIG. 2) provided from the group control unit 10. The first unit control unit 11 may stop the operation of the first fuel cell 12 based on the stop control signal (ssg, see FIG. 2) provided from the group control unit 10.

The first unit control unit 11 may maintain the first fuel cell 12 in an operating state based on the operation control signal osg provided from the group control unit 10. The first unit control unit 11 may maintain the first fuel cell 12 in a stopped state based on the stop control signal ssg provided from the group control unit 10.

That is, the first to nth unit control units 11 operate at least some of the first to nth fuel cells 12 based on the operation control signal (osg) or stop control signal (ssg) provided from the group control unit 10. It can be kept in motion, motionless, motion, or motionless.

The group control unit 10 sends control signals for sequentially controlling the first to nth fuel cells 12 in response to the required load power (for example, 500 Kw) of the external device 3 to the first to nth unit control units. It can be provided in (11).

Specifically, the group control unit 10 sends an operation control signal (osg) for operating some of the first to nth fuel cells 12 or maintaining them in an operating state to one of the first to nth unit control units 11. It can be provided to some.

The group control unit 10 provides the rest of the first to nth unit control units 11 with a stop control signal (ssg) for stopping the rest of the first to nth fuel cells 12 or maintaining them in a stopped state. can do.

For example, the fuel cell system 2 includes first to tenth fuel cells 12, the required load power of the external device 3 is 500 kW, and each of the first to tenth fuel cells 12 When the rated capacity is 62.5Kw, the group control unit 10 sends an operation control signal (osg) to operate eight fuel cells among the first to tenth fuel cells 12 or to maintain them in an operating state. It can be provided to eight unit control units 11 connected to the battery.

The group control unit 10 sends a stop control signal (ssg) to stop the remaining two fuel cells of the first to tenth fuel cells 12, excluding the eight fuel cells, or to maintain them in a stopped state. It can be provided to the unit control unit 11 connected to the battery.

That is, the group control unit 10 transmits an operation control signal (osg) for operating eight fuel cells 12 among the first to tenth fuel cells 12 to eight unit control units (OSG) connected to the eight fuel cells 12. 11), the eight fuel cells 12 connected to the eight unit control units 11 can be controlled to provide 500 Kw of power to the external device 3.

The group control unit 10 can use the operation time measurement signal provided from the first to nth unit control units 11 to determine whether a preset condition is satisfied. The group control unit 10 can use the output power measurement signal provided from the first to nth unit control units 11 to determine whether a preset condition is satisfied.

The group control unit 10 can use the moisture quantity measurement signal provided from the first to nth unit control units 11 to determine whether a preset condition is satisfied. The group control unit 10 may use the fatigue measurement signal provided from the first to nth unit control units 11 to determine whether a preset condition is satisfied.

Specifically, the group control unit 10 may determine whether the operation time of the fuel cell 12 operating based on the operation time measurement signal exceeds a preset critical operation time. The critical operation time according to one embodiment of the present invention can be set in various ways.

When the group control unit 10 determines that the operation time of at least a portion of the operating fuel cells 12 exceeds a preset critical operation time, the group control unit 10 generates a stop control signal to stop at least a portion of the operating fuel cells 12. ssg) can be provided to at least some of the unit control units 11 connected to at least some of the fuel cells 12.

In addition, the group control unit 10 may provide an operation control signal (osg) for operating at least some of the stopped fuel cells 12 to at least some of the unit control units 11 connected to at least some of the fuel cells 12. You can.

At this time, among the operating fuel cells 12, the number of at least some fuel cells 12 that are stopped by the stop control signal (ssg) provided by the group control unit 10 and the group control unit ( The number of at least some fuel cells 12 operated by the operation control signal osg provided by 10) is the same.

For example, when it is determined that the operation time of the first fuel cell 12 exceeds the preset critical operation time, the group control unit 10 provides a stop control signal (ssg) to the first unit control unit 11. can do. The first unit control unit 11 can stop the first fuel cell 12 and maintain it in a stopped state based on the stop control signal ssg.

Additionally, the group control unit 10 may provide an operation control signal (osg) to the ninth unit control unit 11. The ninth unit control unit 11 can operate the stopped ninth fuel cell 12 based on the operation control signal osg and maintain it in an operating state.

That is, the second fuel cell 12 can operate at the same time that the first fuel cell 12 is stopped.

Alternatively, when it is determined that the operation time of the first fuel cell 12 and the second fuel cell 12 exceeds the preset critical operation time, the group control unit 10 operates the first unit control unit 11 and the second fuel cell 12. A stop control signal (ssg) can be provided to the unit control unit 11. The first unit control unit 11 can stop the first fuel cell 12 and maintain it in a stopped state based on the stop control signal ssg. The second unit control unit 11 can stop the second fuel cell 12 based on the stop control signal ssg and maintain it in a stopped state.

Additionally, the group control unit 10 may provide an operation control signal (osg) to the ninth unit control unit 11. The ninth unit control unit 11 can operate the stopped ninth fuel cell 12 based on the operation control signal osg. The group control unit 10 may provide an operation control signal (osg) to the tenth unit control unit 11. The tenth unit control unit 11 can operate the stopped tenth fuel cell 12 based on the operation control signal (osg).

That is, the ninth to tenth fuel cells 12 can operate at the same time that the first to second fuel cells 12 are stopped.

As described above, the group control unit 10 may determine that at least some of the fuel cells 12 exceed the critical operation time based on the operation time measured for each of the operating fuel cells 12. The group control unit 10 may provide a control signal to stop at least some of the fuel cells 12.

The group control unit 10 may provide a control signal to operate the same number of fuel cells as at least some of the fuel cells 12 that have been stopped by exceeding the critical operation time among the stopped fuel cells 12.

Through the above process, the durability and deterioration of the fuel cell system 2 can be prevented by first stopping one or more fuel cells 12 that have operated beyond the critical operation time among the operating fuel cells 12. Additionally, the total output of the fuel cell system 2 can be maintained constant by operating the same number of fuel cells 12 as the stopped fuel cells 12 among the stopped fuel cells 12 .

The group control unit 10 may determine whether the accumulated output power of the fuel cell 12 operating based on the output power measurement signal exceeds a preset reference cumulative output power. The reference cumulative output power according to an embodiment of the present invention can be set in various ways.

When the group control unit 10 determines that the cumulative output power of at least a portion of the operating fuel cells 12 exceeds a preset reference cumulative output power, the group control unit 10 performs stop control to stop at least a portion of the operating fuel cells 12. The signal ssg may be provided to at least some of the unit control units 11 connected to at least some of the fuel cells 12.

In addition, the group control unit 10 may provide an operation control signal (osg) for operating at least some of the stopped fuel cells 12 to at least some of the unit control units 11 connected to at least some of the fuel cells 12. You can.

At this time, among the operating fuel cells 12, the number of at least some fuel cells 12 that are stopped by the stop control signal (ssg) provided by the group control unit 10 and the group control unit ( The number of at least some fuel cells 12 operated by the operation control signal osg provided by 10) is the same.

For example, when it is determined that the accumulated output power of the first fuel cell 12 exceeds the preset reference cumulative output power, the group control unit 10 sends a stop control signal (ssg) to the first unit control unit 11. can be provided. The first unit control unit 11 can stop the first fuel cell 12 and maintain it in a stopped state based on the stop control signal ssg.

Additionally, the group control unit 10 may provide an operation control signal (osg) to the ninth unit control unit 11. The ninth unit control unit 11 can operate the stopped ninth fuel cell 12 based on the operation control signal osg.

Alternatively, when it is determined that the cumulative output power of the first fuel cell 12 and the second fuel cell 12 exceeds the preset reference cumulative output power, the group control unit 10 operates the first unit control unit 11 and A stop control signal (ssg) can be provided to the second unit control unit 11. The first unit control unit 11 can stop the first fuel cell 12 and maintain it in a stopped state based on the stop control signal ssg. The second unit control unit 11 can stop the second fuel cell 12 based on the stop control signal ssg and maintain it in a stopped state.

Additionally, the group control unit 10 may provide an operation control signal (osg) to the ninth unit control unit 11. The ninth unit control unit 11 can operate the stopped ninth fuel cell 12 based on the operation control signal osg. The group control unit 10 may provide an operation control signal (osg) to the tenth unit control unit 11. The tenth unit control unit 11 can operate the stopped tenth fuel cell 12 based on the operation control signal (osg).

That is, as described above, the group control unit 10 may determine that at least some of the fuel cells 12 exceed the reference cumulative output power based on the cumulative output power measured from each of the operating fuel cells 12.

The group control unit 10 may provide a control signal to stop at least some of the fuel cells 12. The group control unit 10 may provide a control signal to operate the same number of fuel cells as at least some of the stopped fuel cells 12 that exceed the reference cumulative output power among the stopped fuel cells 12 .

Through the above process, the durability and deterioration of the fuel cell system 2 can be prevented by first stopping at least some of the fuel cells 12 that have operated in excess of the standard cumulative output power among the operating fuel cells 12. Additionally, the total output of the fuel cell system 2 can be maintained constant by operating the same number of fuel cells 12 as the stopped fuel cells 12 among the stopped fuel cells 12 .

When the group control unit 10 determines that the amount of moisture generated in the fuel cell 12 operating based on the moisture amount measurement signal exceeds a preset critical moisture amount, the group control unit 10 stops at least a portion of the operating fuel cell 12. The control signal ssg may be provided to at least some of the unit control units 11 connected to at least some of the fuel cells 12.

In addition, the group control unit 10 may provide an operation control signal (osg) for operating at least some of the stopped fuel cells 12 to at least some of the unit control units 11 connected to at least some of the fuel cells 12. You can.

At this time, among the operating fuel cells 12, the number of at least some fuel cells 12 that are stopped by the stop control signal (ssg) provided by the group control unit 10 and the group control unit ( The number of at least some fuel cells 12 operated by the operation control signal osg provided by 10) is the same.

For example, when it is determined that the amount of moisture generated in the first fuel cell 12 exceeds the preset critical moisture amount, the group control unit 10 provides a stop control signal (ssg) to the first unit control unit 11. can do. The first unit control unit 11 can stop the first fuel cell 12 and maintain it in a stopped state based on the stop control signal ssg.

Additionally, the group control unit 10 may provide an operation control signal (osg) to the ninth unit control unit 11. The ninth unit control unit 11 can operate the stopped ninth fuel cell 12 based on the operation control signal osg.

Alternatively, when it is determined that the amount of moisture generated in the first fuel cell 12 and the second fuel cell 12 exceeds the preset critical moisture amount, the group control unit 10 controls the first unit control unit 11 and the second fuel cell 12. A stop control signal (ssg) can be provided to the unit control unit 11. The first unit control unit 11 can stop the first fuel cell 12 and maintain it in a stopped state based on the stop control signal ssg. The second unit control unit 11 can stop the second fuel cell 12 based on the stop control signal ssg and maintain it in a stopped state.

Additionally, the group control unit 10 may provide an operation control signal (osg) to the ninth unit control unit 11. The ninth unit control unit 11 can operate the stopped ninth fuel cell 12 based on the operation control signal osg and maintain it in an operating state. The group control unit 10 may provide an operation control signal (osg) to the tenth unit control unit 11. The tenth unit control unit 11 can operate the stopped tenth fuel cell 12 based on the operation control signal osg and maintain it in an operating state.

That is, as described above, the group control unit 10 can determine which one or more fuel cells 12 exceed the critical moisture amount based on the amount of moisture generated in each operating fuel cell 12. The group control unit 10 may provide a control signal to stop one or more fuel cells 12. The group control unit 10 may provide a control signal to operate the same number of fuel cells as at least one fuel cell 12 that has been stopped due to exceeding the critical moisture content among the stopped fuel cells 12 .

Through the above process, the durability and deterioration of the fuel cell system 2 can be prevented by first stopping one or more fuel cells 12 that have operated in excess of the critical moisture content among the operating fuel cells 12. Additionally, the total output of the fuel cell system 2 can be maintained constant by operating the same number of fuel cells 12 as the stopped fuel cells 12 among the stopped fuel cells 12 .

When the group control unit 10 determines that the fatigue of the membrane electrode assembly provided in the operating fuel cell 12 exceeds the preset threshold fatigue based on the fatigue measurement signal, it controls at least a portion of the operating fuel cell 12. A stop control signal (ssg) for stopping can be provided to at least some of the unit control units 11 connected to at least some of the fuel cells 12.

At this time, among the operating fuel cells 12, the number of at least some fuel cells 12 that are stopped by the stop control signal (ssg) provided by the group control unit 10 and the group control unit ( The number of at least some fuel cells 12 operated by the operation control signal osg provided by 10) is the same.

For example, when it is determined that the fatigue of the membrane electrode assembly provided in the first fuel cell 12 exceeds the preset threshold fatigue, the group control unit 10 sends a stop control signal to the first unit control unit 11 ( ssg) can be provided. The first unit control unit 11 can stop the first fuel cell 12 and maintain it in a stopped state based on the stop control signal ssg.

Additionally, the group control unit 10 may provide an operation control signal (osg) to the ninth unit control unit 11. The ninth unit control unit 11 can operate the stopped ninth fuel cell 12 based on the operation control signal osg.

Alternatively, when it is determined that the fatigue of the membrane electrode assembly provided in the first fuel cell 12 and the second fuel cell 12 exceeds the preset critical fatigue, the group control unit 10 operates the first unit control unit 11 ) and a stop control signal (ssg) can be provided to the second unit control unit 11. The first unit control unit 110 can stop the first fuel cell 12 and maintain it in a stopped state based on the stop control signal ssg. The second unit control unit 11 can stop the first fuel cell 12 based on the stop control signal ssg. Thus, the second fuel cell 12 can be stopped and maintained in a stopped state.

Additionally, the group control unit 10 may provide an operation control signal (osg) to the ninth unit control unit 11. The ninth unit control unit 11 can operate the stopped ninth fuel cell 12 based on the operation control signal osg. The group control unit 10 may provide an operation control signal (osg) to the tenth unit control unit 11. The tenth unit control unit 11 can operate the stopped tenth fuel cell 12 based on the operation control signal (osg).

That is, as described above, the group control unit 10 can determine that at least some of the fuel cells 12 exceed the critical fatigue level based on the fatigue measured in the membrane electrode assembly provided in each of the operating fuel cells 12. there is.

The group control unit 10 may provide a control signal to stop at least some of the fuel cells 12. The group control unit 10 may provide a control signal to operate the same number of fuel cells as at least some of the fuel cells 12 that are stopped due to exceeding the threshold fatigue among the stopped fuel cells 12.

Through the above process, the durability and deterioration of the fuel cell system 2 can be prevented by first stopping at least some of the fuel cells 12 that have operated beyond the critical fatigue level among the operating fuel cells 12. Additionally, the total output of the fuel cell system 2 can be maintained constant by operating the same number of fuel cells 12 as the stopped fuel cells 12 among the stopped fuel cells 12 .

The fuel cell 12 may be a hydrogen fuel cell and can generate electricity by separating hydrogen ions from hydrogen and combining them with oxygen in the air. Based on the electricity generated by the fuel cell 12, power can be used as fuel for an external device 3 or a ship. Each fuel cell 12 may have a rated capacity of 62.5Kw, but the present invention is not limited thereto.

The external device 3 may be a power device that uses the power provided by the fuel cell 12 as fuel, such as a ship.

Referring to FIG. 1 according to an embodiment of the present invention, the first to nth fuel cells 12 are shown to be disposed outside the external device 3 and provide power to the external device 3, but are limited to this. It doesn't work. The first to nth fuel cells 12 according to an embodiment of the present invention may be provided inside the external device 3.

Figure 2 is a diagram for explaining a fuel cell sequential control method using a fuel cell sequential control system according to an embodiment of the present invention.

The group control unit 10 provides a control signal to the first to nth unit control units 11 so that the first to nth fuel cells 12 can provide power corresponding to the required load power of the external device 3. can do.

Hereinafter, in FIG. 2, it is assumed that n is 10, the required power of the external device 3 is 500 kW, and the rated capacity of each fuel cell 12 is 62.5 kW.

The group control unit 10 can control eight fuel cells 12 among the first to tenth fuel cells 12 to provide power corresponding to the required load power of the external device 3. Hereinafter, the description will be made on the assumption that the first to eighth fuel cells 12 operate to provide power corresponding to the required load power of the external device 3.

The group control unit 10 may provide an operation control signal (osg) for operating the first to eighth unit control units 11 to the first to eighth unit control units 11. The group control unit 10 may provide a stop control signal (ssg) to the ninth to tenth unit control units 11 to stop the ninth to tenth unit control units 11.

The first to eighth unit control units 11 may operate the first to eighth fuel cells 12 (OP) based on the operation control signal osg provided from the group control unit 10. The first to eighth fuel cells 12 can provide power generated by separating hydrogen ions from hydrogen and combining them with oxygen in the air to the external device 3.

That is, the first to eighth fuel cells 12 can provide 500 Kw of power to the external device 3, corresponding to the required load power of the external device 3.

The ninth to tenth unit control units 11 may stop the ninth to tenth fuel cells 12 (ST) based on the stop control signal ssg provided from the group control unit 10.

The first to eighth unit control units 11 can measure the operation time of each of the first to eighth fuel cells 12. The first to eighth unit control units 11 may provide an operation time measurement signal containing data on the operation time of each of the first to eighth fuel cells 12 to the group control unit 10.

The group control unit 10 determines the operation time of at least some of the first to eighth fuel cells 12 operating based on the operation time measurement signal provided from the first to eighth unit control units 11 to a preset critical operation time. You can determine whether it is exceeded.

Hereinafter, the description will be made assuming that the operation time of the first fuel cell 12 in FIG. 1 exceeds a preset critical operation time.

The group control unit 10 may provide a stop control signal (ssg) for stopping the operating first fuel cell 12 to the first unit control unit 11 connected to the first fuel cell 12. The first unit control unit 11 may stop the first fuel cell 12 based on the stop control signal ssg provided from the group control unit 10.

The group control unit 10 may provide an operation control signal (osg) for operating any one of the stopped 9th to 10th fuel cells 12 to any one of the 9th to 10th unit control units 11. . Any one of the ninth to tenth unit control units 11 may operate any one of the ninth to tenth fuel cells 12 based on the operation control signal osg provided from the group control unit 10.

As in the above-described process, the fuel cell sequential control system 1 of the present invention can provide the required load power required for the external device 3. Additionally, by measuring the operating time of the plurality of operating fuel cells 12, the fuel cell 12 that has been operating the longest can be stopped. In addition, the required load power provided to the external device 3 can be kept constant by operating the same number of fuel cells 12 as the number of stopped fuel cells 12 among the stopped fuel cells 12. The performance of the battery system 2 can be stabilized.

The first to eighth unit control units 11 can measure the output power of each of the first to eighth fuel cells 12. The first to eighth unit control units 11 may provide an output power measurement signal including data on the output power of each of the first to eighth fuel cells 12 to the group control unit 10.

The group control unit 10 may calculate the cumulative output power of each of the first to eighth fuel cells 12 operating based on the output power measurement signal provided from the first to eighth unit control units 11. Based on the cumulative output power of each of the first to eighth fuel cells 12, the group control unit 10 determines that the cumulative output power of at least some of the first to eighth fuel cells 12 exceeds the preset reference cumulative output power. You can decide whether to do it or not.

Hereinafter, the description will be made on the assumption that the cumulative output power of the first fuel cell 12 in FIG. 1 operates in excess of the preset reference cumulative output power.

The group control unit 10 may provide a stop control signal (ssg) for stopping the operating first fuel cell 12 to the first unit control unit 11 connected to the first fuel cell 12. The first unit control unit 11 may stop the first fuel cell 12 based on the stop control signal ssg provided from the group control unit 10.

The group control unit 10 may provide an operation control signal (osg) for operating any one of the stopped 9th to 10th fuel cells 12 to any one of the 9th to 10th unit control units 11. . Any one of the ninth to tenth unit control units 11 may operate any one of the ninth to tenth fuel cells 12 based on the operation control signal osg provided from the group control unit 10.

As in the above-described process, the fuel cell sequential control system 1 of the present invention can provide the required load power required for the external device 3. Additionally, by measuring the operating time of the plurality of operating fuel cells 12, the fuel cell 12 that has been operating the longest can be stopped. In addition, the required load power provided to the external device 3 can be kept constant by operating the same number of fuel cells 12 as the number of stopped fuel cells 12 among the stopped fuel cells 12. The performance of the battery system 2 can be stabilized.

The first to eighth unit control units 11 can measure the amount of moisture generated in each of the first to eighth fuel cells 12. The first to eighth unit control units 11 may provide a moisture quantity measurement signal including data on the amount of moisture generated in each of the first to eighth fuel cells 12 to the group control unit 10.

The group control unit 10 determines that the amount of moisture generated in at least some of the first to eighth fuel cells 12 operating based on the moisture amount measurement signal provided from the first to eighth unit control units 11 exceeds the preset critical moisture amount. You can decide whether to do it or not.

Hereinafter, the description will be made assuming that the amount of moisture generated in the first and second fuel cells 12 exceeds a preset critical moisture amount.

The group control unit 10 sends a stop control signal (ssg) for stopping the operating first and second fuel cells 12 to the first and second unit control units 11 connected to the first and second fuel cells 12. ) can be provided. The first and second unit control units 11 may stop the first to second fuel cells 12 based on the stop control signal ssg provided from the group control unit 10.

The group control unit 10 may provide an operation control signal (osg) for operating the stopped ninth and tenth fuel cells 12 to the ninth and tenth unit control units 11. The 9th and 10th unit control units 11 can operate the 9th and 10th fuel cells 12 based on the operation control signal (osg) provided from the group control unit 10.

As in the above-described process, the fuel cell sequential control system 1 of the present invention can provide the required load power required for the external device 3. In addition, the fuel cells 12 can be stopped by measuring the amount of moisture generated in the plurality of operating fuel cells 12. In addition, the required load power provided to the external device 3 can be kept constant by operating the same number of fuel cells 12 as the number of stopped fuel cells 12 among the stopped fuel cells 12. The performance of the battery system 2 can be stabilized.

The first to eighth unit control units 11 can measure the fatigue of the membrane electrode assemblies provided in the first to eighth fuel cells 12. The first to eighth unit control units 11 may provide a fatigue measurement signal containing data on the fatigue of each membrane electrode assembly provided in the first to eighth fuel cells 12 to the group control unit 10. .

The group control unit 10 determines that the fatigue of at least some of the membrane electrode assemblies provided in the first to eighth fuel cells 12 that operate based on the fatigue measurement signal provided from the first to eighth unit control units 11 is preset. It can be determined whether the critical fatigue road is exceeded.

The group control unit 10 sends a stop control signal (ssg) for stopping the operating first and second fuel cells 12 to the first and second unit control units 11 connected to the first and second fuel cells 12. ) can be provided. The first and second unit control units 11 may stop the first and second fuel cells 12 based on the stop control signal ssg provided from the group control unit 10.

The group control unit 10 may provide an operation control signal (osg) for operating the stopped ninth and tenth fuel cells 12 to the ninth and tenth unit control units 11. The 9th and 10th unit control units 11 can operate the 9th and 10th fuel cells 12 based on the operation control signal (osg) provided from the group control unit 10.

As described above, the fuel cell sequential control system 1 of the present invention can provide the required load power required for the external device 3. In addition, by measuring the fatigue of the membrane electrode assembly provided in the plurality of operating fuel cells 12, the fuel cell 12 that has been operating the longest can be stopped. In addition, the required load power provided to the external device 3 can be kept constant by operating the same number of fuel cells 12 as the number of stopped fuel cells 12 among the stopped fuel cells 12. The performance of the battery system 12 can be stabilized.

Figure 3 is a flowchart illustrating a fuel cell sequential control method according to an embodiment of the present invention.

In step S10, the group control unit may provide a control signal to operate some of the plurality of fuel cells and stop the others.

Specifically, the group control unit 10 may provide a control signal to the unit control unit 11 so that the fuel cell 12 can provide power corresponding to the required load power of the external device 3.

For example, the group control unit 10 provides an operation control signal (osg) to some of the first to nth unit control units 11 so as to provide power corresponding to the required load power of the external device 3. A stop control signal (ssg) can be provided to the rest.

In step S11, the group control unit may determine whether preset conditions are satisfied.

Specifically, the group control unit 10 may determine whether preset conditions are satisfied based on the operation time measurement signal, output power measurement signal, water content measurement signal, and fatigue measurement signal provided from the unit control unit 11.

At this time, if it is determined that the preset conditions are not satisfied, the group control unit 10 may continue to provide the operation control signal (osg) to the unit control unit 11 connected to the operating fuel cell 12. The unit control unit 11 can maintain the fuel cell 12 in an operating state based on the operation control signal osg provided from the group control unit 10.

Additionally, the group control unit 10 can continuously provide a stop control signal (ssg) to the unit control unit 11 connected to the stopped fuel cell 12. The unit control unit 11 can maintain the stopped fuel cell 12 in a stopped state based on the stop control signal ssg provided from the group control unit 10.

If the preset condition is satisfied in step S12, the group control unit may stop at least some of the operating fuel cells and provide a control signal to operate at least some of the stopped fuel cells.

Specifically, when it is determined that the preset conditions are satisfied, the group control unit 10 sends a stop control signal (ssg) to stop the fuel cells 12 that satisfy the preset conditions. It can be provided to the unit control unit (11) connected to (12).

The unit control unit 11 may stop the fuel cell 12 that satisfies preset conditions based on the stop control signal ssg.

In addition, the group control unit 10 may provide an operation control signal (osg) for operating at least some of the stopped fuel cells 12 to the unit control unit 11 connected to at least some of the stopped fuel cells 12. there is.

The unit control unit 11 may operate at least some of the stationary fuel cells 12 based on the operation control signal osg.

Figure 4 is a flowchart explaining a fuel cell sequential control method based on operation time according to an embodiment of the present invention.

In step S1100, the first to nth unit control units 11 may measure the operating time of each operating fuel cell.

Specifically, some of the first to nth unit control units 11 may measure the operating time of some of the first to nth fuel cells 12. Some of the first to nth unit control units 11 may provide the group control unit 10 with an operation time measurement signal containing data on the operation time of some of the first to nth fuel cells 12. there is.

In step S1101, the group control unit may determine whether the operation time exceeds a preset critical operation time.

Specifically, the group control unit 10 may determine whether the operation time of at least some of the operating fuel cells 12 exceeds a preset critical operation time based on the operation time measurement signal provided from the unit control unit 11.

In step S1102, the group control unit may provide a control signal to stop at least some of the operating fuel cells.

Specifically, when it is determined that the preset conditions are satisfied, the group control unit 10 sends a stop control signal (ssg) to stop the fuel cells 12 that satisfy the preset conditions. It can be provided to the unit control unit (11) connected to (12).

The unit control unit 11 may stop the fuel cell 12 that satisfies preset conditions based on the stop control signal ssg.

In step S1103, the group control unit may provide a control signal to operate the same number of fuel cells as at least some of the stopped fuel cells among the stopped fuel cells.

Specifically, the group control unit 10 provides an operation control signal (osg) for operating at least some of the stopped fuel cells 12 to the unit control unit 11 connected to at least some of the stopped fuel cells 12. You can. The unit control unit 11 may operate at least some of the stopped fuel cells 12 based on the operation control signal osg.

Figure 5 is a flowchart illustrating a fuel cell sequential control method based on accumulated output power according to an embodiment of the present invention.

In step S1110, the output power of each operating fuel cell can be measured.

Specifically, some of the first to nth unit control units 11 may measure the output power of at least a portion of the first to nth fuel cells 12 operating. Some of the first to nth unit control units 11 may provide the group control unit 10 with an output power measurement signal containing data on the output power of at least some of the first to nth fuel cells 12 operating. You can.

In step S1111, the group control unit may calculate the cumulative output power of each operating fuel cell.

Specifically, the group control unit 10 calculates the cumulative output power of at least some of the first to nth fuel cells 12 operating based on the output power measurement signal provided from some of the first to nth unit control units 11. can be calculated.

In step S1112, the group control unit may determine whether the accumulated output power exceeds a preset reference accumulated output power.

Specifically, the group control unit 10 may determine whether the cumulative output power of at least some of the first to nth fuel cells 12 operating exceeds a preset reference cumulative output power based on the calculated cumulative output power. .

In step S1113, the group control unit may provide a control signal to stop at least some of the operating fuel cells.

Specifically, when it is determined that the preset conditions are satisfied, the group control unit 10 sends a stop control signal (ssg) to stop the fuel cells 12 that satisfy the preset conditions. It can be provided to the unit control unit (11) connected to (12).

The unit control unit 11 may stop the fuel cell 12 that satisfies preset conditions based on the stop control signal ssg.

In step S1114, the group control unit may operate the same number of fuel cells as at least some of the stopped fuel cells among the stopped fuel cells.

Specifically, the group control unit 10 provides an operation control signal (osg) for operating at least some of the stopped fuel cells 12 to the unit control unit 11 connected to at least some of the stopped fuel cells 12. You can.

The unit control unit 11 may operate at least some of the stopped fuel cells 12 based on the operation control signal osg.

Figure 6 is a flowchart explaining a fuel cell sequential control method based on moisture content according to an embodiment of the present invention.

In step S1120, the amount of moisture generated in each operating fuel cell can be measured.

Specifically, some of the first to nth unit control units 11 may measure the amount of moisture generated in at least a portion of the first to nth fuel cells 12 that are operating. Some of the first to nth unit control units 11 may provide the group control unit 10 with a moisture quantity measurement signal containing data on the amount of moisture generated in at least some of the first to nth fuel cells 12 operating. You can.

In step S1121, the group control unit may determine whether the moisture amount exceeds a preset critical moisture amount.

Specifically, the group control unit 10 determines that the amount of moisture generated in at least some of the first to nth fuel cells 12 operating based on the moisture amount measurement signal provided from the unit control unit 11 exceeds the preset critical moisture amount. You can decide whether to do it or not.

In step S1122, the group control unit may provide a control signal to stop at least some of the operating fuel cells.

Specifically, when it is determined that the preset conditions are satisfied, the group control unit 10 sends a stop control signal (ssg) to stop the fuel cells 12 that satisfy the preset conditions. It can be provided to the unit control unit (11) connected to (12).

The unit control unit 11 may stop the fuel cell 12 that satisfies preset conditions based on the stop control signal ssg.

In step S1123, the group control unit may provide a control signal to operate the same number of fuel cells as at least some of the stopped fuel cells among the stopped fuel cells.

Specifically, the group control unit 10 provides an operation control signal (osg) for operating at least some of the stopped fuel cells 12 to the unit control unit 11 connected to at least some of the stopped fuel cells 12. You can.

The unit control unit 11 may operate at least some of the stopped fuel cells 12 based on the operation control signal osg.

Figure 7 is a flowchart explaining a fuel cell sequential control method based on fatigue according to an embodiment of the present invention.

In step S1130, the fatigue of the membrane electrode assembly provided in each operating fuel cell is measured.

Specifically, some of the first to nth unit control units 11 may measure the fatigue of the membrane electrode assembly provided in at least some of the first to nth fuel cells 12 that are operating. Some of the first to n-th unit control units 11 send a fatigue measurement signal containing data about the fatigue of the membrane electrode assembly provided in at least a part of the first to n-th fuel cells 12 operating to the group control unit 10. ) can be provided.

In step S1131, the group control unit may determine whether the fatigue level exceeds a preset threshold fatigue level.

Specifically, the group control unit 10 determines in advance the fatigue level of at least some of the membrane electrode assemblies provided in at least some of the operating first to nth fuel cells 12 based on the fatigue measurement signal provided from the unit control unit 11. It can be determined whether the set critical fatigue level is exceeded.

In step S1132, the group control unit may provide a control signal to stop at least some of the operating fuel cells.

Specifically, when it is determined that the preset conditions are satisfied, the group control unit 10 sends a stop control signal (ssg) to stop the fuel cells 12 that satisfy the preset conditions. It can be provided to the unit control unit (11) connected to (12).

The unit control unit 11 may stop the fuel cell 12 that satisfies preset conditions based on the stop control signal ssg.

In step S1133, the group control unit may provide a control signal to operate the same number of fuel cells as at least some of the stopped fuel cells among the stopped fuel cells.

Specifically, the group control unit 10 provides an operation control signal (osg) for operating at least some of the stopped fuel cells 12 to the unit control unit 11 connected to at least some of the stopped fuel cells 12. You can.

The unit control unit 11 may operate at least some of the stopped fuel cells 12 based on the operation control signal osg.

The embodiments described above may be implemented with hardware components, software components, and/or a combination of hardware components and software components. For example, the devices, methods, and components described in the embodiments may include, for example, a processor, a controller, an Arithmetic Logic Unit (ALU), a Digital Signal Processor, a microcomputer, and a Field Programmable Gate (FPGA). It may be implemented using one or more general-purpose computers or special-purpose computers, such as an array, PLU (Programmable Logic Unit), microprocessor, or any other device that can execute and respond to instructions.

The processing device may execute an operating system and one or more software applications that run on the operating system. Additionally, a processing device may access, store, manipulate, process, and generate data in response to the execution of software. For ease of understanding, a single processing device may be described as being used; however, those skilled in the art will understand that a processing device may include multiple processing elements and/or multiple types of processing elements. You will understand that it can be included.

For example, a processing device may include a plurality of processors or one processor and one controller. Additionally, other processing configurations, such as parallel processors, are also possible. Software may include a computer program, code, instructions, or a combination of one or more of these, and may configure a processing unit to operate as desired, or to process independently or collectively. You can command the device.

Software and/or data may be used on any type of machine, component, physical device, virtual equipment, computer storage medium or device to be interpreted by or to provide instructions or data to a processing device. It can be embodied in . Software may be distributed over networked computer systems and stored or executed in a distributed manner. Software and data may be stored on one or more computer-readable recording media.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer-readable medium. Computer-readable media may include program instructions, data files, data structures, etc., singly or in combination. Program instructions recorded on the medium may be specially designed and configured for the embodiment or may be known and available to those skilled in the art of computer software.

Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CDROMs and DVDs, and ROM, RAM, and flash memory. Includes hardware devices specifically configured to store and execute program instructions, such as: Examples of program instructions include machine language code, such as that produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter, etc. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

The drawings and detailed description of the invention described so far are merely illustrative of the present invention, and are used only for the purpose of explaining the present invention, and are not used to limit the meaning or scope of the present invention described in the claims. That is not the case. Therefore, those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the appended claims.

1: Fuel cell sequential control system
2: Fuel cell system
3: External device
10: Group control unit
11: Unit control unit
12: Fuel cell

Claims (15)

In the sequential control method of a fuel cell sequential control system that sequentially controls a plurality of fuel cells,
operating some of the plurality of fuel cells and maintaining the others in a stopped state; and
When a preset condition is satisfied, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state,
Fuel cell sequential control method. According to claim 1,
The step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state when the preset condition is satisfied, includes:
When the operation time of at least some of the operating fuel cells exceeds a preset critical operation time, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state,
Fuel cell sequential control method. According to clause 2,
When the operation time of at least some of the operating fuel cells exceeds a preset critical operation time, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state, comprising:
measuring the operating time of each of the operating fuel cells;
determining whether the operation time exceeds the preset threshold operation time;
stopping at least some of the fuel cells when the operation time exceeds the preset critical operation time; and
Comprising the step of operating the same number of fuel cells as the at least some of the stopped fuel cells among the fuel cells in the stopped state,
Fuel cell sequential control method. According to claim 1,
The step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state when the preset condition is satisfied, includes:
When the accumulated output power of at least some of the operating fuel cells exceeds a preset reference cumulative output power, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state,
Fuel cell sequential control method. According to clause 4,
When the cumulative output power of at least some of the operating fuel cells exceeds a preset cumulative output power, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state includes:
measuring output power of each operating fuel cell;
calculating the cumulative output power of each of the operating fuel cells based on the output power;
determining whether the accumulated output power exceeds the preset reference accumulated output power;
stopping at least some of the fuel cells when the accumulated output power exceeds the preset accumulated output power; and
Comprising the step of operating the same number of fuel cells as the at least some of the stopped fuel cells among the fuel cells in the stopped state,
Fuel cell sequential control method. According to claim 1,
The step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state when the preset condition is satisfied, includes:
When the amount of moisture generated in at least some of the operating fuel cells exceeds a preset critical moisture amount, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state,
Fuel cell sequential control method. According to clause 6,
When the amount of moisture generated in at least some of the operating fuel cells exceeds a preset critical moisture amount, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state, comprising:
measuring the amount of moisture generated in each of the operating fuel cells;
determining whether the moisture amount exceeds the preset critical moisture amount;
stopping at least some of the fuel cells when the moisture amount exceeds the preset critical moisture amount; and
Comprising the step of operating the same number of fuel cells as the at least some of the stopped fuel cells among the fuel cells in the stopped state,
Fuel cell sequential control method. According to claim 1,
The step of stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state when the preset condition is satisfied, includes:
When the fatigue of at least some of the membrane electrode assemblies provided in the operating fuel cell reaches a preset threshold fatigue, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state.
Fuel cell sequential control method. According to clause 8,
When the fatigue of at least some of the membrane electrode assemblies provided in the operating fuel cell reaches a preset threshold fatigue, stopping at least some of the operating fuel cells and operating at least some of the fuel cells in the stopped state includes: ,
Measuring the fatigue of the membrane electrode assembly provided in each operating fuel cell;
determining whether the fatigue level exceeds the preset threshold fatigue level;
stopping at least some of the fuel cells when the fatigue degree exceeds the preset threshold fatigue degree; and
Comprising the step of operating the same number of fuel cells as the at least some of the stopped fuel cells among the fuel cells in the stopped state,
Fuel cell sequential control method. In a fuel cell sequential control system including a plurality of fuel cells,
a plurality of unit control units connected to each of the plurality of fuel cells to measure an operating state of the plurality of fuel cells and control the operation of the plurality of fuel cells; and
A control signal to operate some of the plurality of fuel cells and maintain the others in a stopped state, and to stop at least some of the operating fuel cells and operate at least some of the fuel cells in the stopped state when a preset condition is satisfied. Including a group control unit that outputs to the plurality of unit control units,
Sequential control system for fuel cells. According to claim 10,
The group control unit,
When the operating time of at least some of the operating fuel cells exceeds a preset critical operating time,
Stopping at least some of the operating fuel cells and outputting the control signal to operate the same number of fuel cells as the at least some of the stopped fuel cells among the fuel cells in the stopped state,
Sequential control system for fuel cells. According to claim 10,
The group control unit,
When the cumulative output power of at least some of the operating fuel cells exceeds the preset cumulative output power,
Stopping at least some of the operating fuel cells and outputting the control signal to operate the same number of fuel cells as the at least some of the stopped fuel cells among the fuel cells in the stopped state,
Sequential control system for fuel cells. According to claim 10,
The group control unit,
When the amount of moisture generated in at least some of the operating fuel cells exceeds a preset critical moisture amount,
Stopping at least some of the operating fuel cells and outputting the control signal to operate the same number of fuel cells as the at least some of the stopped fuel cells among the fuel cells in the stopped state,
Sequential control system for fuel cells. According to claim 10,
The group control unit,
When the fatigue of at least some of the membrane electrode assemblies provided in the operating fuel cell reaches a preset critical fatigue,
Stopping at least some of the operating fuel cells and outputting the control signal to operate the same number of fuel cells as the at least some of the stopped fuel cells among the fuel cells in the stopped state,
Sequential control system for fuel cells. A computer-readable recording medium on which a program for executing the fuel cell sequential control method according to claim 1 is recorded.

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