JP2022171698A - Hydrogen flow controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hydrogen flow rate control device capable of controlling the flow rate of hydrogen gas to an appropriate amount and stopping the supply of hydrogen gas when an abnormality is detected.

SOLUTION: A hydrogen flow rate control device includes: a hydrogen gas supply path; flow rate detection means for detecting the flow rate of the hydrogen gas in the hydrogen gas supply path; flow rate adjusting means installed in the hydrogen gas supply path and capable of regulating the flow rate of hydrogen gas; an on-off valve installed in the hydrogen gas supply path and capable of closing the supply of hydrogen gas; and control means for controlling both the flow rate of the hydrogen gas by the flow rate adjusting means and the opening and closing of the on-off valve.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2023,JPO&INPIT

Description

The present invention relates to a hydrogen flow control device for supplying hydrogen gas safely and without waste.

In recent years, the development of fuel cells, power generation systems, and the like utilizing hydrogen gas is progressing. For example, hydrogen gas is supplied from a gas cylinder or the like filled with hydrogen gas to a fuel cell or an engine to generate power. In such a case, it is required to supply an appropriate amount of hydrogen gas according to the power demand. Moreover, when an abnormality or the like occurs in a fuel cell or power generation system, an excessive supply of hydrogen gas may lead to an accident, so it is required to reliably stop the supply of hydrogen in an emergency.

SUMMARY OF THE INVENTION An object of the present invention is to provide a hydrogen flow rate control device capable of controlling the flow rate of hydrogen gas to an appropriate amount and stopping the supply of hydrogen gas when an abnormality is detected.

The above object can be achieved by the following.

[1] A hydrogen gas supply path, a flow rate detection means for detecting the flow rate of hydrogen gas in the hydrogen gas supply path, a flow rate adjustment means installed in the hydrogen gas supply path and capable of adjusting the flow rate of hydrogen gas, and hydrogen gas A hydrogen flow rate control device comprising an on-off valve installed in a supply path and capable of closing the supply of hydrogen gas, and a control means for adjusting the flow rate of hydrogen gas by a flow rate adjusting means and controlling the opening and closing of the on-off valve.

[2] The hydrogen flow rate control device according to [1] above, further comprising timer means, wherein the control means controls the flow rate adjusting means so as to adjust the flow rate of the hydrogen gas according to time.

[3] When generating power using hydrogen at a hydrogen gas supply destination that receives hydrogen gas from a hydrogen gas supply channel, the control means adjusts the flow rate of hydrogen gas according to the amount of power generated. The hydrogen flow control device according to the above [1] or [2], which controls the flow rate adjusting means so as to

[4] When the control means receives a warning signal from a hydrogen gas supply destination that receives hydrogen gas supply from the hydrogen gas supply channel, the on-off valve is controlled to close the supply of hydrogen gas, the above [1 ] to [3] any hydrogen flow rate control device.

According to the hydrogen flow rate control device of the present invention, it is possible to control the flow rate of hydrogen gas to an appropriate amount and to stop the supply of hydrogen gas when an abnormality is detected.

1 is a block diagram showing an example of the configuration of a hydrogen flow rate control system according to the present invention; FIG. It is a figure showing an example of sectional drawing seen from the side direction of the hydrogen flow control device concerning the present invention. FIG. 4 is a diagram showing an example of a flow chart of a hydrogen gas flow rate control process according to the present invention. FIG. 4 is a diagram showing an example of a flow chart of a hydrogen gas flow rate control process according to the present invention. 1 is a block diagram showing an example of the configuration of a power generation system according to the present invention; FIG.

Embodiments of the present invention will be described below with reference to the drawings, but the present invention is not limited to the drawings and embodiments.

The hydrogen flow control device will be described below. The hydrogen flow control device controls a hydrogen gas flow meter and an on-off valve, and can supply hydrogen gas at an appropriate pressure to a hydrogen gas supply destination such as a fuel cell or an engine. FIG. 1 is a diagram showing an example of a hydrogen flow rate control device according to an embodiment of the present invention. A hydrogen flow control device 1 comprises a hydrogen gas supply line 2 , a control section 3 , a hydrogen gas flow meter 4 and an on-off valve 5 .

Hydrogen gas is supplied to hydrogen gas supply paths 2a-2c from cards 6a-6c having a plurality of hydrogen gas cylinders. Hydrogen gas flowmeters 4a to 4c and on-off valves 5a to 5c are provided in the hydrogen gas supply paths 2a to 2c, respectively. It is preferable that the hydrogen gas flow meter 4 is installed on the side of the cardle, which is the supply source of the hydrogen gas, rather than the on-off valve 5 , and the on-off valve 5 is installed on the side of the hydrogen gas supply destination 7 .

The hydrogen gas that has passed through the hydrogen gas flowmeters 4a to 4c and the on-off valves 5a to 5c is supplied to the hydrogen gas supply destinations 7a to 7c, respectively. The hydrogen gas supply destination 7 is not particularly limited as long as it is a facility that uses hydrogen gas. Also, the hydrogen gas supply destination 7 may be for a different application instead of the same application. For example, the hydrogen gas supply destination 7a may be a fuel cell, and the hydrogen gas supply destinations 7b and 7c may be power generation systems.

In FIG. 1, one on-off valve 5 is provided corresponding to one hydrogen gas supply path 2, but for example, the hydrogen gas supply paths 2a and 2b are connected to the hydrogen gas flowmeters 4a and 4b. , and one on-off valve 5 may be installed at the end.

The control unit 3 includes a CPU, RAM, HDD, communication interface, and the like. The control unit 3 executes a stored predetermined program to control the hydrogen gas flow meter 4 and the on-off valve 5 . The control unit 3 is connected to the hydrogen gas flowmeter 4 and the on-off valve 5 by wire or wireless communication via a communication interface, and controls the hydrogen gas flowmeter 4 and the on-off valve 5 while exchanging information with each other. I do. Also, the control unit 3 has an internal timer for measuring time. RAM is the work area of the CPU. The HDD is a storage area for saving programs and data. Also, the control unit 3 can be manually operated by a control panel.

The control unit 3 can adjust the flow rate of hydrogen gas in the hydrogen gas supply paths 2a to 2c by controlling the hydrogen gas flowmeters 4a to 4c, respectively. For example, the controller 3 adjusts the flow rate of hydrogen gas according to the time measured by the internal timer. For example, in a predetermined time period such as midnight, the flow rate of hydrogen gas can be kept lower than in other time periods, so that the supply amount of hydrogen gas can be reduced. In this case, the upper limit of the flow rate of hydrogen gas is set to a predetermined value for each time period. In this case, the flow rate can be set differently for each hydrogen gas supply path 2 . For example, the hydrogen gas flow meter 4a sets the flow rate of hydrogen gas to be different between 8:00 to 19:59 and 20:00 to 7:59 the next day, and the hydrogen gas flow meter 4b , from 7:00 to 21:59 and from 22:00 to 6:59 the next day, different flow rates of hydrogen gas can be set.

It is also possible to adjust the flow rate of hydrogen gas on a seasonal basis. For example, in seasons when electricity usage is high (for example, summer), the amount of hydrogen gas supplied to the fuel cell and engine is increased, and in seasons when electricity usage is low, the amount of hydrogen gas supplied is decreased. You can control such as

In this way, by adjusting the supply amount of hydrogen gas according to the time zone and the season, it is possible to prevent hydrogen gas from being consumed more than necessary.

The control unit 3 adjusts the flow rate of the hydrogen gas according to the usage amount of the generated power when generating power using hydrogen at the hydrogen gas supply destination that receives the hydrogen gas supply from the hydrogen gas supply channel. is also possible. For example, when a power generation system including a hydrogen flow control device according to the present invention is introduced into business facilities such as factories and hospitals, hydrogen gas can be adjusted.

In this case, the control unit 3 is connected to the business equipment by communication, and receives the information on the power consumption per unit time in real time or at predetermined time intervals. If the amount of electric power used in the business facility per unit time is small, the hydrogen gas flow meter 4 is controlled so that the amount of hydrogen gas supplied is correspondingly reduced, and if the amount of electric power per unit time increases , the hydrogen gas flowmeter 4 is controlled so that the supply amount of hydrogen gas increases accordingly.

The control unit 3 can control the hydrogen gas flowmeters 4 separately. , the hydrogen gas flowmeters 4a and 4b can be controlled so that the flow rate of the hydrogen gas in the hydrogen gas supply path 2c is also different.

In this way, by adjusting the supply amount of hydrogen gas according to the amount of hydrogen gas used at the hydrogen gas supply destination 7, it is possible to prevent hydrogen gas from being consumed more than necessary.

When receiving a warning signal from the hydrogen gas supply destination 7, the control unit 3 can also control the on-off valve 5 to close the supply of hydrogen gas. For example, when an abnormality occurs in a fuel cell or the like, a warning signal is transmitted from the fuel cell to the control unit 3 . When the control unit 3 receives the warning signal, the on-off valve 5 is controlled to be closed, thereby stopping the supply of hydrogen gas to the fuel cell and avoiding danger.

In addition, for example, when hydrogen is used in a generator using an engine, it is assumed that an abnormality has occurred when the temperature or rotation speed of the engine is outside a predetermined range, and power generation equipped with an engine and a generator It is also possible to configure such that a warning signal is sent from the system to the controller 3 . When the control unit 3 receives the warning signal, the on-off valve 5 is controlled to be closed, thereby stopping the supply of hydrogen gas to the engine.

The controller 3 can individually control the on-off valves 5a to 5c. For example, when a warning signal is issued from the hydrogen gas supply destination 7a, only the on-off valve 5a installed in the hydrogen gas supply passage 2a corresponding to the hydrogen gas supply destination 7a can be closed.

Further, the control unit 3 can also perform control to close the on-off valve 5 during maintenance of the hydrogen gas supply destination 7 or during replacement of the hydrogen gas cylinder. In this case, the on-off valve 5 is controlled to be closed by operating the control panel connected to the control unit 3 .

Further, when the hydrogen gas cylinder of the cardle 6 becomes empty, the hydrogen gas flow meter 4 detects that the supply amount (pressure) of the hydrogen gas has become low, and notifies the control unit 3 of this fact. When notified that the supply amount of hydrogen gas has become low, the control unit 3 closes the on-off valve 5 to stop the supply of hydrogen gas to the hydrogen gas supply destination 7 . When the hydrogen gas cylinder is replaced with a new one, the on-off valve 5 is controlled to restart the supply of hydrogen gas.

In FIG. 1, the hydrogen flow control device 1 is provided with a plurality of hydrogen gas supply paths 2, and each of the hydrogen gas supply paths 2 is provided with a hydrogen gas flow meter 4 and an on-off valve 5. The number of hydrogen gas supply channels 2 provided in the device 1 is not particularly limited. Therefore, the control unit 3 can be configured to control one hydrogen gas flowmeter 4 and one on-off valve 5 installed in one hydrogen gas supply line 2 .

The hydrogen gas flow meter 4 has a function of detecting the flow rate of hydrogen gas in the hydrogen gas supply channel and a function of adjusting the flow rate of hydrogen gas. The hydrogen gas flow meter 4 reduces the pressure of the hydrogen gas filled in the hydrogen gas cylinder at a pressure of 10.0 MPa or more to the optimum pressure for use at the hydrogen gas supply destination 7 such as a fuel cell or an engine, and reduces the pressure of the hydrogen gas. The flow rate of hydrogen gas supplied to the supply destination 7 is adjusted to an appropriate flow rate. The hydrogen gas flow meter 4 and the control unit 3 are connected for communication, and transmit information such as the detected flow rate of hydrogen gas to the control unit 3 and receive signals for controlling the flow rate from the control unit 3 .

The on-off valve 5 is a part that supplies and stops (shuts off) hydrogen gas, and is controlled by a built-in electromagnetic valve. When the control unit 3 receives a warning signal from the hydrogen gas supply destination 7 when some abnormality occurs in the hydrogen gas supply destination 7, the on-off valve 5 is closed. In addition, by closing the on-off valve 5 during maintenance of the hydrogen flow rate control device 1 and the hydrogen gas supply destination 7, and during replacement of the hydrogen gas cylinder, it is possible to prevent the hydrogen gas from flowing out to the outside.

FIG. 2 is a diagram showing an example of a cross-sectional view of the hydrogen flow rate control device according to the present invention as viewed from the side. The hydrogen flow control device 1 has a hydrogen gas flow meter 4 and an on-off valve 5, a valve 8 for supplying hydrogen gas into the hydrogen flow control device 1, and a hydrogen gas supply destination 7 on the upper surface of a case containing a control unit 3. The unit is designed with a valve 9 for supplying hydrogen to the . Hydrogen gas supplied from a hydrogen gas cylinder is supplied through the valve 8 into the hydrogen gas supply passage 2 and passes through the hydrogen gas flow meter 4 . The hydrogen gas that has passed through the hydrogen gas flowmeter 4 passes through the on-off valve 5 and is supplied from the valve 9 to the hydrogen gas supply destination 7 . Since the hydrogen gas flow rate fluctuates according to the supply amount to the hydrogen gas supply destination 7 such as the fuel cell or the engine, the size of the housing of the hydrogen flow control device 1 is designed according to the supply amount of the hydrogen gas each time. preferably.

As a hydrogen supply source, a cardle type equipped with a plurality of hydrogen gas cylinders can be adopted. The cardle 6 is formed by connecting a plurality of hydrogen gas cylinders with connecting pipes. By using the cardle 6, it can be transported by a forklift or the like, and more hydrogen gas can be transported at once. The hydrogen gas cylinders in the cardle 6 are connected by connecting pipes, and have a structure that can be connected to the outside as one pipe.

Next, a description will be given of the hydrogen gas flow rate control process when the hydrogen gas flow rate is adjusted according to time as described above. FIG. 3 is a diagram showing an example of a flow chart of a hydrogen gas flow rate control process in the control unit.

First, it is determined whether or not it is time to start changing the flow rate of hydrogen gas (step S1). When it is determined that it is time to start changing the flow rate of hydrogen gas (YES in step S1), a signal requesting adjustment of the flow rate of hydrogen gas is transmitted from the control unit 3 to the hydrogen gas flow meter 4 (step S2). ). When the signal is received by the hydrogen gas flow meter 4, the flow rate of hydrogen gas is adjusted to a predetermined value. After the flow rate of the hydrogen gas is adjusted, the process returns to step S1 and the series of processes is repeated.

On the other hand, if it is determined that it is not time to start changing the flow rate of hydrogen gas (NO in step S1), it is determined whether or not it is time to end changing the flow rate of hydrogen gas (step S3). When it is determined that it is time to finish changing the hydrogen gas flow rate (YES in step S3), a signal is sent from the control unit 3 to the hydrogen gas flow meter 4 requesting that the hydrogen gas flow rate be returned to the level before the change. (step S4). When the hydrogen gas flow rate is returned to the level before the change, the process returns to step S1 and the series of processes is repeated. If it is determined that it is time to finish changing the hydrogen gas flow rate (NO in step S3), the process returns to step S1 and the series of processes is repeated.

Next, the hydrogen gas flow rate control process in the case of adjusting the flow rate of the hydrogen gas according to the usage amount of the generated electric power as described above will be described. FIG. 4 is a diagram showing an example of a flow chart of a hydrogen gas flow rate control process in the control unit.

First, information on the amount of electric power per unit time in the target business facility is received from the business facility in the business development department 3 (step S11). Next, the flow rate of hydrogen gas is calculated according to the amount of power received (step S12). In accordance with the calculated flow rate, a signal requesting adjustment of the hydrogen gas flow rate is transmitted from the control unit 3 to the hydrogen gas flow meter 4 (step S13). A series of processes of steps S11 to S13 are repeatedly executed.

Next, a power generation system to which the hydrogen flow rate control device of the present invention is applied will be described. FIG. 5 is a block diagram showing an example configuration of a power generation system according to the present invention. The power generation system includes a hydrogen flow controller 1 , a cardle 6 , a generator unit 10 and a power combiner 16 . Hydrogen gas supplied to the hydrogen flow control device 1 as fuel for the generator unit 10 is enclosed in the cardle 6 .

When replacing the control unit 3 and the cardle 6 in the hydrogen flow rate control device 1, the on-off valve 5 can be controlled to be closed. Since the hydrogen flow control device 1 is connected to a plurality of cards 6, hydrogen gas can be supplied to the hydrogen flow control device 1 by the cards 6b to 6d even while the cardle 6a is being replaced. Therefore, power can be continuously supplied even while the cardle 6 is being replaced. The hydrogen flow control device 1 supplies an appropriate amount of hydrogen gas to the generator unit 10 at an appropriate timing.

The generator unit 10 is composed of an engine 11 , a generator 12 , a rectifier 13 , a battery 14 or an inverter 15 . Since a plurality of generator units 10 are provided in the power generation system, even when the generator unit 10a is being maintained, the generator units 10b and 10c can be operated to continuously supply electric power. In addition, the commercial power supply may be used as a supplementary power supply while the generator unit 10a is being maintained. In this case, the control unit 3 in the hydrogen flow rate control device 1 can adjust the flow rate of hydrogen gas according to the number of generator units in operation.

In the engine 11, the hydrogen gas supplied from the hydrogen flow control device 1 is combusted to move the piston. When the temperature or rotation speed of the engine 11 is out of the predetermined range, a warning signal is sent from the generator unit 10 to the control unit in the hydrogen flow rate control device 1, and the opening and closing valve is controlled, so that the generator unit The supply of hydrogen gas to 10 is stopped.

The generator 12 converts the kinetic energy obtained by the piston in the engine 11 into electrical energy. The generator 12 is also desirably subjected to explosion-proof treatment, such as providing a ground wire and preventing sparks from scattering.

The rectifier 13 rectifies the AC power output from the generator 12 into DC power, and outputs the rectified DC power to the battery 14 or the inverter 15 . Battery 14 stores the DC power output from rectifier 13 . The stored electric power is output to the inverter 15 as necessary, such as when the amount of power generated by the generator 12 is reduced.

The inverter 15 converts the DC power output from the rectifier 13 or the battery 14 into AC power. An inverter 15 is provided for each generator unit 10 , and each inverter 15 is connected to one power combiner 16 . The power combiner 16 combines AC power output from the plurality of inverters 15 into one power.

In order to combine the power, one of the plurality of inverters 15 is arbitrarily selected in advance as the master inverter 15a and the others as the slave inverters 15b and 15c, and the phases of the AC power output from the slave inverters 15b and 15c are determined. is controlled to match the phase of the AC power output from the master inverter 15a. By combining the power in this way, the AC powers generated by the plurality of generator units 10 are combined without canceling each other out, and the loss of the generated power can be suppressed.

1 hydrogen flow control device 2 hydrogen gas supply path 3 control unit 4 hydrogen gas flow meter 5 on-off valve 6 cardle 7 hydrogen gas supply destination 8 valve 9 valve 10 generator unit 11 engine 12 generator 13 rectifier 14 battery 15 inverter 16 power synthesis vessel

Claims (4)

a plurality of hydrogen gas sources;
a plurality of hydrogen gas supply channels capable of supplying hydrogen gas to a plurality of hydrogen gas supply destinations;
a flow rate adjusting means installed in the hydrogen gas supply channel and capable of adjusting the flow rate of the hydrogen gas;
an on-off valve installed in the hydrogen gas supply channel and capable of closing the supply of hydrogen gas;
Control means for adjusting the flow rate of hydrogen gas by the flow rate adjusting means and controlling the opening and closing of the on-off valve,
each of the hydrogen gas supply sources corresponds to each of the hydrogen gas supply channels,
Each hydrogen gas supply path corresponds to each hydrogen gas supply destination,
When power generation is performed using hydrogen gas at the hydrogen gas supply destination, the control means controls the amount of electricity generated at the hydrogen gas supply destination to increase the amount of hydrogen in the hydrogen gas supply passage corresponding to the hydrogen gas supply destination. controlling the flow regulating means to regulate the flow of gas;
Hydrogen flow controller. power amount receiving means for receiving information about the amount of power used in a facility that uses power generated at a hydrogen gas supply destination;
a flow rate calculation means for calculating the flow rate of hydrogen gas based on the received information on the amount of electric power,
The control means controls the flow rate adjusting means to adjust the flow rate of the hydrogen gas according to the calculated flow rate,
The hydrogen flow control device according to claim 1. a plurality of hydrogen gas sources;
a plurality of hydrogen gas supply channels capable of supplying hydrogen gas to a plurality of hydrogen gas supply destinations;
a flow rate adjusting means installed in the hydrogen gas supply channel and capable of adjusting the flow rate of the hydrogen gas;
an on-off valve installed in the hydrogen gas supply channel and capable of closing the supply of hydrogen gas;
Control means for adjusting the flow rate of hydrogen gas by the flow rate adjusting means and controlling opening and closing of the on-off valve;
and a timing means,
each of the hydrogen gas supply sources corresponds to each of the hydrogen gas supply channels,
Each hydrogen gas supply path corresponds to each hydrogen gas supply destination,
The control means controls the flow rate adjusting means to adjust the flow rate of the hydrogen gas according to time;
Hydrogen flow controller. The control means controls the flow rate adjusting means so as to individually adjust the flow rate of hydrogen gas for each hydrogen gas supply channel,
The hydrogen flow control device according to claim 3.

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