JP2019221062A - System for generating and supplying electric power - Google Patents

Abstract

To achieve stable supply of electric power while generating electric power using natural energy in a facility in which a large-scale power supply system is difficult to install.SOLUTION: The power supply system includes: a first class facility equipped with a first power generator for generating electric power using natural energy and consuming electric power; a second class facility equipped with a hydrogen manufacturing apparatus for manufacturing hydrogen using electric power, a hydrogen holding apparatus and a second power generator for generating electric power using hydrogen. The first class facility can supply electric power not consumed in the first class facility, of the electric power generated by the first power generator, to the second class facility. The second class facility can: generate hydrogen with the hydrogen manufacturing apparatus using the electric power supplied from the first class facility and holds the hydrogen in the hydrogen holding apparatus; generates electric power with the second power generator using hydrogen in the hydrogen holding apparatus and supply the generated electric power to the first class facility.SELECTED DRAWING: Figure 1

Description

  The present disclosure relates to power supply that generates power using natural energy and supplies power to facilities that consume power.

  BACKGROUND ART Conventionally, a power supply system including a natural energy power generation device, a storage battery, a hydrogen production device, a hydrogen storage device, and a fuel cell has been proposed (Patent Document 1). This power supply system supplies (a1) a storage battery during the daytime on the basis of (i) a predicted value of the power generation amount of the renewable energy power generation device during the day and (ii) a predicted value of the power demand amount of an external facility. And (a2) the amount of power to be supplied to the hydrogen production device at night, and (b1) the amount of power to be supplied from the storage battery to the external facility and (b2) the amount of power to be supplied from the fuel cell to the external facility at night. Determine the amount of power to be supplied. According to this power supply system, even when a disaster occurs, it is possible to continuously supply power that satisfies demand to external facilities.

WO 2017/013751 pamphlet

  However, the power supply system described in Patent Literature 1 is a dedicated facility for supplying power to other facilities, and is relatively large in size, requiring a hydrogen production device and a hydrogen storage device in addition to a natural energy power generation device. It is a large-scale facility. For this reason, it is difficult to provide the power supply system described in Patent Literature 1 in a house in each house in a residential area where safety regulations are strict or in stores in an area where commercial facilities are concentrated. That is, there are regions where it is difficult to provide the power supply system described in Patent Document 1. On the other hand, as the distance from the place where power is generated by the facility such as the power supply system described in Patent Literature 1 to the place where the power is consumed increases, the power loss accompanying power transmission increases. In the technique of Patent Document 1, such a problem is not considered.

  The present disclosure can be realized as the following embodiments.

(1) According to one embodiment of the present disclosure, a system for supplying power is provided. The system includes: a first-generation facility that consumes power and includes a first power generation device that generates power using natural energy; a hydrogen production device that generates hydrogen using power, and holding hydrogen. And a second power generation device that includes a hydrogen holding device capable of performing the above-described process and a second power generation device that generates electric power using hydrogen. The first-type facility can supply at least a part of the power not consumed by the first-type facility to the second-type facility among the power generated by the first power generation device. The second-type facility can generate hydrogen by the hydrogen-producing apparatus using the electric power supplied from the first-type facility and cause the hydrogen to be retained in the hydrogen storage apparatus; , Power can be generated by the second power generator, and at least a part of the generated power can be supplied to the first-type facility.
By adopting such an aspect, the electric power generated in the first-class facility can be consumed in the first-class facility. For this reason, the loss of power accompanying the transmission of power can be reduced as compared with a mode in which the first-type facility that consumes power always supplies power from outside. The surplus power in the first-type facility can be transmitted to the second-type facility and stored as hydrogen, and the insufficient power in the first-type facility can be supplied from the second-type facility. it can. For this reason, the first-class facility can consume the power while receiving a stable power supply while utilizing the power generated by using the natural energy.

(2) In the system according to the aspect described above, the second-type facility further includes a hydrogen supply device that can supply hydrogen in the hydrogen storage device to a vehicle that travels using hydrogen. You can also.
With such an embodiment, it is possible to supply hydrogen to the vehicle by utilizing the electric power generated using natural energy.

(3) In the system according to the aspect, the first power generation device is a power generation device that generates power using solar energy; and the second type facility converts at least a part of the generated power into nighttime power. Then, it may be in a mode of supplying to the first type facility.
According to this aspect, the shortage of power in the first facility that obtains power using solar energy at night can be supplied from the second facility. Therefore, the first-class facility can perform activities involving power consumption by receiving stable power supply while utilizing power generated by using solar energy. Further, it is not necessary to provide a first power generation device having an excessive power generation capacity in the first type facility.

(4) In the system according to the aspect, the first power generation device is a power generation device that generates power using solar energy; and the second type facility is configured to control at least one of the generated power in winter. And supplying more electric power per unit period to the first-type facility than in summer.
According to such an embodiment, the shortage of power in winter in the first facility that obtains power using solar energy can be supplied from the second facility. Therefore, the first-class facility can perform activities involving power consumption by receiving stable power supply while utilizing power generated by using solar energy.

(5) In the system of the above aspect, the second type facility may supply at least a part of the generated power to the first type facility when a disaster occurs.
According to this aspect, even if a disaster occurs and the first power generation device cannot perform power generation, the first-type facility receives power supply from the second-type facility and performs an activity that consumes power. It can be performed.

(6) In the system of the above aspect, the second type facility may not supply hydrogen to the vehicle by the hydrogen supply device when a disaster occurs.
When a disaster occurs, there is a high possibility that the type 1 facility needs to be supplied with power from the type 2 facility. According to the above aspect, in the event of a disaster, the supply of power to the first-class facility can be prioritized over the supply of hydrogen to the vehicle.

(7) In the system according to the aspect, supply of power from the second-type facility to the first-type facility is performed in exchange for a price determined for the first-type facility; during a predetermined period. In the case where the supply amount of electric power from the first-type facility to the second-type facility in the above is the first supply amount, May be lower than the consideration in the case where the supply amount of the second supply amount is the second supply amount smaller than the first supply amount.
According to such an embodiment, it is possible to encourage generation of electricity at the first-class facility and reduction of electric power consumption through setting of the price of electric power when receiving the supply.

(8) In the system according to the aspect, supply of power from the second-type facility to the first-type facility is performed according to a priority determined for the first-type facility; a predetermined period. The priority when the amount of power supplied from the first facility to the second facility during the period is the first supply amount; from the first facility to the second facility during the period; May be higher than the priority in the case where the second power supply is smaller than the first power supply.
According to such an embodiment, it is possible to encourage power generation in the type 1 facility and reduction of power consumption through setting of priorities when receiving supply.

(9) In the system according to the aspect, the hydrogen holding device is a first hydrogen holding device capable of holding gaseous hydrogen; the second type facility further receives liquid hydrogen, An embodiment may be provided in which a second hydrogen holding device that can hold the liquid hydrogen and that can directly or indirectly supply the held hydrogen to the second power generation device is provided.
According to such an embodiment, the second-type facility can supply stable power to the first-type facility by using liquid hydrogen supplied from the outside. The first-type facility can perform activities involving power consumption by receiving stable power supply.

  The present disclosure can be realized in various forms other than the power supply system. For example, the present invention can be realized in the form of a control method of a power supply system, a computer program for realizing the control method, a non-transitory recording medium storing the computer program, and the like.

It is an explanatory view showing a power supply system of the present embodiment. It is a table | surface which shows the example of the value for 1 kWh of the electric power supplied to the 1st kind facility 100 from the 2nd kind facility 200. It is a table | surface which shows the example of the priority at the time of supplying electric power from the type 2 facility 200 to the type 1 facility 100.

A. Embodiment:
(1) Configuration of power supply:
FIG. 1 is an explanatory diagram illustrating a power supply system according to the present embodiment. This power supply includes a plurality of first type facilities 100, a second type facility 200, a hydrogen gas generation facility 500, a hydrogen gas delivery vehicle 550, and a large-scale power storage facility 600. The plurality of first-class facilities 100 are general houses, apartments, public facilities, and the like provided in the same area. The second-type facility 200 is a store provided in an area adjacent to the area where the plurality of first-type facilities 100 are provided. The hydrogen gas generation facility 500 and the large-scale power storage facility 600 are provided at locations relatively distant from the area where the plurality of first-type facilities 100 are provided.

  The power generated by this power supply is used in the first-class facility 100. The electric power generated by this electric power supply is also used in electric vehicles 150 and 450. Further, the hydrogen generated by this power supply is used in the hydrogen vehicle 400.

  The first-type facility 100 is a general house, apartment, public facility, or the like. The first-type facility 100 includes a solar power generation device 106, a power storage device 107, a power interface 108, and a power consumption device 109. Note that the first-type facility 100 does not include the hydrogen production device and the hydrogen holding device included in the second-type facility 200. Further, the first-type facility 100 does not include the liquid hydrogen holding device provided in the second-type facility 200.

  The solar power generation device 106 generates electric power by receiving irradiation of sunlight. The solar power generation device 106 is, specifically, a single-crystal silicon solar cell. Power storage device 107 stores electric power generated by solar power generation device 106. Power storage device 107 is, specifically, a lithium ion battery. The power consumption devices 109 are various devices that operate by receiving power supply from the power storage device 107. The power consuming device 109 is, for example, an air conditioner, a lighting device, a refrigerator, a cooking appliance, an audio device, or the like of each house.

  The power interface 108 is capable of converting received DC power to AC power, converting received AC power to DC power, and changing the voltage and current of the received power. Device. The power interface 108 can supply the power stored in the power storage device 107 to the outside of the first-class facility 100. Specifically, the electric power interface 108 supplies electric power to the electric vehicle 150, the second-type facility 200, and the large-scale power storage facility 600. The power interface 108 can further store the power supplied from outside the first type facility 100 in the power storage device 107. Specifically, the power interface 108 receives power supply from the second-type facility 200 and the large-scale power storage facility 600.

  In the present embodiment, the second-type facility 200 is a store such as a convenience store or a drug store installed on a flat ground. The second-type facility 200 receives and stores the surplus power in the first-type facility 100, and supplies the first-type facility 100 with the insufficient power. The second-type facility 200 includes a store building 201 that displays products and holds inventory, a hydrogen production device 202, a hydrogen gas storage device 204, a liquid hydrogen storage device 205, a fuel cell device 206, and a power storage device 207. , A power interface 208, and a hydrogen gas supply device 209.

  The hydrogen production device 202 is a device that generates hydrogen by electrolyzing water using electric power. The hydrogen gas holding device 204 is a tank that stores gaseous hydrogen generated by the hydrogen production device 202. The hydrogen gas holding device 204 can hold 300 liters of hydrogen gas at a maximum pressure of about 82 MPa.

  The liquid hydrogen holding device 205 is a tank that can be supplied with liquid hydrogen from outside the second facility 200 and hold the liquid hydrogen. The liquid hydrogen holding device 205 can vaporize the held liquid hydrogen and supply the hydrogen gas Hg4 to the hydrogen gas holding device 204. The liquid hydrogen held in the liquid hydrogen holding device 205 is indirectly supplied to the fuel cell device 206 via the hydrogen gas holding device 204 as hydrogen gas Hg4, Hg2.

  Since the second-type facility 200 includes the liquid hydrogen holding device 205, the second-type facility 200 is stable to the first-type facility 100 by using liquid hydrogen supplied from outside the second-type facility 200. Power can be supplied. The first-type facility 100 can perform activities involving power consumption by receiving stable power supply.

  The fuel cell device 206 is supplied with gaseous hydrogen from the hydrogen gas holding device 204 and generates electric power using the hydrogen.

  Power storage device 207 stores power generated by fuel cell device 206. The power storage device 207 is further supplied with electric power from outside the second type facility 200 and stores the electric power. Power storage device 207 is, specifically, a lithium ion battery.

  A power interface 208 can convert the received DC power to AC power, convert the received AC power to DC power, and change the voltage and current of the received power. Device. The power interface 208 can supply the power stored in the power storage device 207 to the outside of the second-type facility 200. The target to which the power interface 208 supplies power is, specifically, the first type facility 100, the electric vehicle 450, and the large-scale power storage facility 600. The power interface 208 can further store the power supplied from outside the second-type facility 200 in the power storage device 207. The target to which the power interface 208 is supplied with power is, specifically, the first-class facility 100.

  The hydrogen gas supply device 209 can supply the hydrogen gas in the hydrogen gas holding device 204 to the outside of the second type facility 200. The target to which the hydrogen gas supply device 209 supplies power is, specifically, the hydrogen vehicle 400.

  In the present embodiment, the hydrogen gas generation facility 500 is a steel mill. The hydrogen gas generation facility 500 includes a blast furnace 501, a hydrogen production device 502, and a liquid hydrogen holding device 504. In the blast furnace 501, iron ore is heated by coke, and pig iron is taken out. The hydrogen production device 502 is a coke oven. In a coke oven, coal is carbonized to produce coke. Coke is used in blast furnace 501. The coke oven as the hydrogen production device 502 extracts hydrogen from gas generated when producing coke. The liquid hydrogen holding device 504 is a tank that stores the hydrogen generated by the hydrogen production device 502 as liquid hydrogen.

  The hydrogen gas delivery vehicle 550 receives the liquid hydrogen Hr in the liquid hydrogen holding device 504 of the hydrogen gas generation facility 500 and delivers it to the liquid hydrogen holding device 205 of the second type facility 200.

  Large-scale power storage facility 600 is a large-scale power storage facility held by a power company. Large-scale power storage facility 600 includes power storage device 607 and power interface 208. Power storage device 607 stores power. Power storage device 607 is, specifically, a sodium-sulfur battery (NAS battery).

  A power interface 608 can convert the received DC power to AC power, convert the received AC power to DC power, and change the voltage and current of the received power. Device. The power interface 608 can store power supplied from outside the large-scale power storage facility 600 in the power storage device 607. The target to which the power interface 608 is supplied with power is, specifically, the first-type facility 100 and the second-type facility 200.

  The electric vehicle 150 is a vehicle that runs on electric power. The electric vehicle 150 is owned by a resident of the first-class facility 100 that is a house. The electric vehicle 150 includes a power storage device 157. Power storage device 157 is supplied with electric power from the outside of electric vehicle 150, and stores the electric power. Power storage device 157 is, specifically, a lithium ion battery. The electric vehicle 150 runs on an electric motor (not shown) using electric power held by the power storage device 157.

  The electric vehicle 450 is also a vehicle that runs on electric power. The electric vehicle 450 includes a power storage device 457. The configuration and functions of electric vehicle 450 including power storage device 457 are the same as those of electric vehicle 150 including power storage device 157.

  The hydrogen vehicle 400 is a vehicle that runs using hydrogen. The hydrogen vehicle 400 includes a hydrogen gas holding device 404 and a fuel cell device 406. The hydrogen gas holding device 404 is a tank that stores hydrogen gas. The hydrogen gas holding device 404 can hold about 130 liters of hydrogen gas at a maximum pressure of about 70 MPa. The fuel cell device 406 is supplied with gaseous hydrogen from the hydrogen gas holding device 404 and generates electric power using the hydrogen. The hydrogen vehicle 400 runs using an electric motor (not shown) using the electric power generated by the fuel cell device 406.

(2) Generation, consumption and transmission of electricity in Type 1 facilities:
In the first-type facility 100, power is generated in the solar power generation device 106 during the daytime. The power not consumed by the power consumption device 109 among the power generated by the solar power generation device 106 is stored in the power storage device 107. Part of the power generated by the photovoltaic power generator 106 that is not consumed by the power consuming device 109, EP13, is supplied to the electric vehicle 150 via the power interface 108 as needed.

  A part EP11 of the power generated by the photovoltaic power generator 106 that is not consumed by the power consuming device 109 is supplied to the second-type facility 200 via the power interface 108. The owner of the first-type facility 100 receives compensation from the owner or the manager of the second-type facility 200 according to the amount of the electric power EP11 supplied to the second-type facility 200.

  Part of the power generated by the photovoltaic power generator 106 that is not consumed by the power consuming device 109, EP12, is supplied to the large-scale power storage facility 600 via the power interface 108. The owner of the first-type facility 100 receives consideration from the power company that owns the large-scale power storage facility 600 according to the amount of power EP12 supplied to the large-scale power storage facility 600.

  In the first-type facility 100, power is not generated in the solar power generation device 106 at night. Therefore, the power consumed by the power consuming device 109 is supplied from the power storage device 107. When the power consumed by the power consuming device 109 is larger than the power supplied from the power storage device 107, the first-type facility 100 receives the power EP21 from the second-type facility 200 via the power interface 108. .

  The amount of power generation by the solar power generation device 106 in winter is smaller than the amount of power generation by the solar power generation device 106 in summer. For this reason, in winter, even in the daytime, the power consumed by the power consuming device 109 may be larger than the power generated by the solar power generation device 106. Even in such a case, the first type facility 100 receives the supply of the power EP21 from the second type facility 200 via the power interface 108. The supply of the electric power EP21 from the second-type facility 200 to the first-type facility 100 is performed in exchange for a predetermined price for each first-type facility 100.

  Furthermore, when a disaster occurs and the photovoltaic power generator 106 malfunctions, power generation is not performed in the photovoltaic power generator 106. Therefore, the power consumed by the power consuming device 109 is supplied from the power storage device 107. When the power consumed by the power consuming device 109 is larger than the power supplied from the power storage device 107, the first-type facility 100 receives the power EP21 from the second-type facility 200 via the power interface 108. . The supply of the electric power EP21 from the second facility 200 to the first facility 100 in the event of a disaster may be performed in exchange for a predetermined price for each first facility 100, or may be performed free of charge. May be performed.

(3) Generation, consumption, and transmission of electricity in Type 2 facilities:
In the second-type facility 200, the hydrogen gas Hg1 is generated by the hydrogen production apparatus 202 using the electric power EP11 supplied from the first-type facility 100. The generated hydrogen gas Hg1 is held in the hydrogen gas holding device 204.

  In the second-type facility 200, electric power is generated by the fuel cell device 206 using the hydrogen gas Hg2 in the hydrogen gas holding device 204. Electric power generated by the fuel cell device 206 is stored in the power storage device 207.

  A part of the electric power EP21 generated by the fuel cell device 206 is supplied to the first-class facility 100 via the electric power interface 208 as needed. Part of the electric power EP23 generated by the fuel cell device 206 is supplied to the electric vehicle 450 via the electric power interface 208 as needed.

  Part of the electric power EP22 generated by the fuel cell device 206 is supplied to the large-scale power storage facility 600 via the electric power interface 208 as needed. The owner of the second-type facility 200 receives consideration from the power company that owns the large-scale power storage facility 600 according to the amount of the electric power EP22 supplied to the large-scale power storage facility 600.

  As described above, the second type facility 200 supplies a part of the electric power EP21 generated by the fuel cell device 206 to the first type facility 100 at night. By performing such a process, the shortage of power in the first-type facility 100 that obtains power using solar energy at night can be supplied from the second-type facility 200. For this reason, the first-type facility 100 receives the stable power supply day and night while utilizing the power generated by using the solar energy, and the power consuming device 109 performs the activity involving the power consumption. It can be performed. In addition, in the first-type facility 100, it is not necessary to provide a power generation device having an excessive power generation capacity so that a sufficient power generation amount can be secured independently irrespective of a change in daylight hours.

  As described above, the second type facility 200 supplies a part of the electric power EP21 generated by the fuel cell device 206 to the first type facility 100 even in the daytime in winter. As a result, in the winter, more electric power is supplied to the first-class facility 100 in the same period than in the summer, for example, around 30 days. By performing such a process, the insufficient power in winter in the first-type facility 100 that obtains power using solar energy can be supplied from the second-type facility 200. For this reason, the first-type facility 100 receives the stable power supply regardless of the season while utilizing the power generated by using the solar energy, and the power consuming device 109 performs the activity involving the power consumption. It can be performed. In addition, in the first-type facility 100, it is not necessary to provide a power generation device having an excessive power generation capacity in summer in order to ensure sufficient power generation alone in winter.

  As described above, when a disaster occurs, the second-type facility 200 supplies a part EP21 of the electric power generated by the fuel cell device 206 to the first-type facility 100. By performing such processing, even when a disaster occurs and power cannot be generated by the photovoltaic power generator 106, the first-type facility 100 receives power from the second-type facility 200 and With the device 109, activities involving power consumption can be performed.

(4) Generation and consumption of hydrogen in Type 2 facilities:
In the second type facility 200, as described above, the hydrogen gas Hg1 is generated by the hydrogen production device 202 using the electric power EP11 supplied from the first type facility 100. The generated hydrogen gas Hg1 is held in the hydrogen gas holding device 204.

  The second-type facility 200 supplies the hydrogen gas Hg3 in the hydrogen gas holding device 204 to the hydrogen vehicle 400 via the hydrogen gas supply device 209 as needed. By performing such processing, the hydrogen gas Hg3 generated by the hydrogen production device 202 is supplied to the hydrogen vehicle 400 using the electric power EP11 generated by using natural energy in the first-type facility 100. Can be.

  The second-type facility 200 does not supply the hydrogen gas Hg3 to the hydrogen vehicle 400 by the hydrogen gas supply device 209 when a disaster occurs. When a disaster occurs, there is a high possibility that the first type facility 100 needs to be supplied with the electric power EP21 from the second type facility 200. In order to supply a sufficient amount of power EP21 to the first-type facility 100, it is necessary to generate a sufficient amount of power by the fuel cell device 206 using the hydrogen gas Hg2 in the hydrogen gas holding device 204. is there. By performing the above-described processing, when a disaster occurs, the supply of the electric power EP21 of the first-type facility 100 can be prioritized over the supply of the hydrogen gas Hg3 to the hydrogen vehicle 400.

(5) Consideration for the power supplied from the Type 2 facility to the Type 1 facility:
FIG. 2 is a table showing an example of consideration for 1 kWh of electric power supplied from the second-type facility 200 to the first-type facility 100. As described above, the supply of the electric power EP21 from the second-type facility 200 to the first-type facility 100 is performed in exchange for a predetermined price. The first-type facility 100 is assigned an identification ID in advance, and the price of the supplied power is determined according to the classification of the supplied power for one month.

  In the example of FIG. 2, the power EP <b> 21 is supplied to a user whose identification ID is ABC1234 at a price of 20 yen per kWh in a section of a power amount of less than 120 kWh. In the section of the electric energy of 120 to 300 kWh, electric power EP21 is supplied at a price of 25 yen per kWh. In a section having a power amount exceeding 300 kWh, power EP21 is supplied at a price of 27 yen per kWh (see FIG. 1). On the other hand, the power EP21 is supplied to the user whose identification ID is XYX9876 at a lower price than the user whose ABC1234 is ID in any power amount section.

  The price of the electric power is determined according to the category to which the amount of electric power supplied from the first-type facility 100 to the second-type facility 200 during the previous year is one year. It is assumed that the supply amount of power from the first-type facility 100 owned by the user whose identification ID is ABC1234 to the second-type facility 200 during the previous year is Ea. It is assumed that the amount of power supplied from the first-type facility 100 to the second-type facility 200 owned by the user whose identification ID is XYX9876 in the previous year is Ex for one year. When the division of the supply amount to which Ex belongs is larger than the division of the supply amount to which Ea belongs, as shown in the example of FIG. 2, the identification ID of the user whose identification ID is XYX9876 is lower than that of the user whose ABC1234 is ABC1234. For the price, electric power EP21 is supplied.

  Similarly, it is assumed that the supply amount of power from the first-type facility 100 to the second-type facility 200 owned by the user whose identification ID is PQR4567 during the previous year is Ep. When the division of the supply amount to which Ep belongs is smaller than the division of the supply amount to which Ea belongs, the identification ID is higher than the user of ABC1234 for the user whose identification ID is PQR4567 as shown in the example of FIG. For the price, electric power EP21 is supplied.

  By setting the price in this way, power generation in the first type facility 100 and reduction of power consumption can be achieved through setting of the price of power when the first type facility 100 receives power supply from the second type facility 200. , Can be encouraged.

(6) Priority of supply of power supplied from the type 2 facility to the type 1 facility:
FIG. 3 is a table showing an example of priorities when power is supplied from the second-type facility 200 to the first-type facility 100. The supply of the electric power EP21 from the second-type facility 200 to the first-type facility 100, which is performed when a disaster occurs, is performed in accordance with predetermined first and second priorities. The first-type facility 100 is assigned an identification ID in advance, and a first priority and a second priority of power supply are determined.

  In the event of a disaster, the smaller the value of the first priority, the higher the priority of power supply. For example, only when the required amount of power can be supplied to the first-type facility 100 owned by the user with the first priority of 1, the first-type facility 100 owned by the user with the first priority of 2 is provided. On the other hand, electric power is supplied.

  In the example of FIG. 3, the first priority 1 is assigned to the user whose identification ID is ABC1234. The first type facility 100 of the user whose first priority is 1 is, for example, a hospital or a fire department. The first priority 2 is assigned to the user whose identification ID is XYX9876 and the user whose identification ID is PQR4567. The first-type facility 100 having the first priority of 2 is, for example, a general house or apartment.

  Among users having the same first priority, power supply is preferentially received as the value of the second priority is smaller. For example, when power is supplied to the first-type facilities 100 having the first priority of 2, the minimum required power is supplied to all the first-type facilities 100 having the first priority of 2. Supplied. In contrast, as the value of the second priority of the first-type facility 100 is smaller, the first-type facility 100 is additionally supplied with more power. The second priority is determined according to the category to which the amount of power supply from the first-type facility 100 to the second-type facility 200 for one year in the previous year belongs, similarly to the consideration.

  In the example of FIG. 3, the second priority 1 is assigned to the user whose identification ID is XYX9876. The second priority 2 is assigned to the user whose identification ID is PQR4567. For this reason, when the minimum power is supplied to the first type facility 100 of the user whose identification ID is PQR4567, the first type facility 100 of the user whose identification ID is XYX9876 is more often supplied. Of power may be supplied.

  By setting the price in this way, through the setting of the priority when the first-type facility 100 receives the power supply from the second-type facility 200, the power generation in the first-type facility 100 and the reduction of the power consumption can be performed. Can be encouraged.

  The solar power generation device 106 in the present embodiment is also referred to as a “first power generation device”. The hydrogen gas holding device 204 is also called a “hydrogen holding device”. The fuel cell device 206 is also called a “second power generation device”. The hydrogen vehicle 400 is also called a “vehicle”. The hydrogen gas supply device 209 is also called a “hydrogen supply device”. The liquid hydrogen holding device 205 is also referred to as a “second hydrogen holding device”.

B. Other embodiments:
B1. Other Embodiment 1:

(1) In the embodiment, the first-class facility 100 is a house, an apartment, a public facility, or the like (see FIG. 1). However, the first type facility 100 may be another facility such as a store or a factory.

(2) In the above embodiment, the first-class facility 100 supplies a part of the electric power EP12 generated by the photovoltaic power generator 106 to the large-scale power storage facility 600 (see FIG. 1). However, the first-type facility 100 may be supplied with power from the large-scale power storage facility 600 as needed.

(3) In the above embodiment, the first type facility 100 supplies a part EP13 of the electric power generated by the solar power generation device 106 as the first power generation device to the electric vehicle 150 (see FIG. 1). However, the first type facility 100 may not be able to supply the electric power generated by the first power generation device to the electric vehicle 150.

(4) In the above embodiment, the second type facility 200 includes, as the second power generation device, the fuel cell device 206 that is supplied with gaseous hydrogen and generates electric power using the hydrogen (see FIG. 1). . However, the second power generation device may be a power generation device that generates power based on another principle, such as a hydrogen gas turbine power generation device that receives hydrogen and burns hydrogen to generate power. However, the second power generation device is preferably a device that generates power using hydrogen.

(5) If necessary, all of the power generated by the fuel cell device 206 except for the loss may be supplied to the first-class facility 100 (see EP21 in FIG. 1). If necessary, all of the power generated by the fuel cell device 206 except for the loss may be supplied to the large-scale power storage facility 600 (see EP22 in FIG. 1).

(6) In the above embodiment, the second type facility 200 supplies a part EP23 of the electric power generated by the fuel cell device 206 as the second power generation device to the electric vehicle 450 (see FIG. 1). However, the second type facility 200 may not be able to supply the electric power generated by the second power generator to the electric vehicle.

(7) In the above embodiment, the second type facility 200 supplies a part of the electric power EP22 generated by the fuel cell device 206 to the large-scale power storage facility 600 (see FIG. 1). However, the second-type facility 200 is provided with power consuming devices such as an air conditioner, a lighting device, a refrigerator, a cooking appliance, and an audio device that are operated by receiving the supply of electric power. May be supplied.

(8) In the above embodiment, the hydrogen gas generation facility 500 is a steel mill including a coke oven as a hydrogen production device (see FIG. 1). However, the hydrogen gas generation facility may be a facility that reforms petroleum, natural gas, or the like to extract hydrogen. The hydrogen gas generation facility may be a facility that generates electric power using natural energy and electrolyzes water using the electric power to generate hydrogen.

(9) The power supply system of the above embodiment includes a hydrogen gas generation facility 500 and a large-scale power storage facility 600. However, the power supply system may not include one or both of the hydrogen gas generation facility and the large-scale power storage facility.

B2. Other Embodiment 2:
In the above embodiment, the second-type facility 200 includes the hydrogen gas supply device 209 that supplies the hydrogen gas in the hydrogen gas holding device 204 to the hydrogen vehicle 400 (see FIG. 1). However, the second-type facility may not include a hydrogen supply device that can supply hydrogen in the hydrogen storage device to a vehicle that travels using hydrogen. In such an embodiment, the hydrogen in the hydrogen gas storage device 204 as the hydrogen storage device is used for power generation by the fuel cell device 206 as the second power generation device.

B3. Other Embodiment 3:
(1) In the above-described embodiment, the first-class facility 100 includes, as the first power generation device, the solar power generation device 106 that generates electric power by receiving sunlight (see FIG. 1). However, the first power generation device may be a power generation device that generates power based on other principles, such as solar thermal power generation and small-scale hydroelectric power generation. Further, the first power generation device may be a fuel cell device that reforms a hydrocarbon gas such as methane, ethane, propane, and butane to generate hydrogen and generate power. The hydrocarbon gas may be supplied from a so-called gas company through a pipe, or may be filled in a tank and supplied to a first-class facility. However, it is preferable that the first power generation device is a device that converts natural energy into electric power.

(2) In the mode in which sunlight is not used for power generation in the first power generation device of the first type facility, the power generated by the second power generation device in the second type facility is supplied to the first type facility at night. It is not necessary. Further, in the first power generation device, even in a mode in which sunlight is used for power generation, the daytime power generation allows the first-type facility to generate power having a power amount exceeding the daily consumption amount, and thus a sufficient amount of power can be obtained. In the case where a power storage facility is provided, the power generated by the second power generation device in the second-type facility does not have to be supplied to the first-type facility at night.

B4. Other Embodiment 4:
In the mode in which sunlight is not used for power generation in the first power generation device of the first type facility, the power generated by the second power generation device in the second type facility does not need to be supplied to the first type facility in winter. Good. Further, in the first power generation device, even in a mode in which sunlight is used for power generation, the daytime power generation allows the first-type facility to generate power of an amount of power that exceeds daily consumption throughout the year, which is sufficient. In the case of having a power storage facility, the electric power generated by the second power generation device in the second-type facility does not have to be supplied to the first-type facility in winter.

B5. Other Embodiment 5:
In the above embodiment, when a disaster occurs, part EP21 of the electric power generated by the fuel cell device 206 of the second type facility 200 is supplied to the first type facility 100 (see FIG. 1). However, the second-type facility may be configured not to have a function of supplying the generated power to the first-type facility when a disaster occurs.

B6. Other Embodiment 6:
In the above embodiment, the second-type facility 200 does not supply the hydrogen gas Hg3 to the hydrogen vehicle 400 by the hydrogen gas supply device 209 when a disaster occurs. However, even when a disaster occurs, such a restriction may not be made. In addition, only in some vehicles such as an emergency vehicle, even when a disaster occurs, the hydrogen supply device may supply hydrogen to the vehicle.

B7. Other Embodiment 7:
(1) In the above embodiment, the price of the electric power supplied from the second-type facility 200 to the first-type facility 100 is determined according to the category of the supplied power for one month (see FIG. 2). ). However, the supply of power from the second-type facility to the first-type facility can be determined as a fixed price that is determined for the first-type facility and does not depend on the supply amount per unit period. In addition, the price of power supplied from the second-type facility 200 to the first-type facility 100 may be determined according to the season or time.

(2) In the above embodiment, when the amount of power supplied from the first-type facility 100 to the second-type facility 200 in the previous year is the first supply amount, the consideration from the first-type facility 100 in the previous year is The supply amount of power to the two-type facility 200 is lower than the price when the second supply amount is smaller than the first supply amount (see FIG. 2). However, the price of power supplied from the second facility 200 to the first facility 100 can be determined without depending on the amount of power supplied from the first facility 100 to the second facility 200 in the past.

B8. Other Embodiment 8:
In the above embodiment, the supply of the electric power EP21 from the second type facility 200 to the first type facility 100, which is performed when a disaster occurs, is performed according to the first priority and the second priority determined in advance. (See FIG. 3). However, the priority in the power supply from the second-type facility to the first-type facility may be set only for the first priority, or may be set only for the second priority.
In addition, the priority in supplying power from the type 2 facility to the type 1 facility is not limited to the time of occurrence of a disaster, and can be applied.

B9. Other Embodiment 9:
(1) In the above-described embodiment, the second-type facility 200 includes the hydrogen gas holding device 204 that stores gaseous hydrogen as the first hydrogen holding device. However, the first hydrogen holding device provided in the second-type facility may be a liquid hydrogen tank that can hold liquid hydrogen.

(2) In the above embodiment, the liquid hydrogen holding device 205 as the second hydrogen holding device vaporizes the held liquid hydrogen and supplies it to the hydrogen gas holding device 204. The hydrogen gas holding device 204 supplies the hydrogen gas held therein to the fuel cell device 206. However, the second hydrogen holding device vaporizes the held liquid hydrogen and directly passes through the fuel cell device 206 as the second power generation device without passing through the hydrogen gas holding device 204 as the hydrogen holding device. It can also be in a mode that can be supplied.

  The present invention is not limited to the above-described embodiment, and can be implemented with various configurations without departing from the spirit of the invention. For example, the technical features of the embodiments corresponding to the technical features in each embodiment described in the summary of the invention may be used to solve some or all of the above-described problems, or to provide some of the above-described effects. Or, in order to achieve all of them, replacement and combination can be appropriately performed. If the technical features are not described as essential in this specification, they can be deleted as appropriate.

Reference Signs List 100: first-class facility, 106: photovoltaic power generator, 107: power storage device, 108: power interface, 109: power consumption device, 150: electric vehicle, 157: power storage device, 200: second-class facility, 201: building , 202: hydrogen production device, 204: hydrogen gas holding device, 205: liquid hydrogen holding device, 206: fuel cell device, 207: power storage device, 208: power interface, 209: hydrogen gas supply device, 400: hydrogen vehicle, 404 ... Hydrogen gas holding device, 406 ... Fuel cell device, 450 ... Electric vehicle, 457 ... Power storage device, 500 ... Hydrogen gas generation facility, 501 ... Blast furnace, 502 ... Hydrogen production device, 504 ... Liquid hydrogen holding device, 550 ... Hydrogen gas Delivery vehicle, 600: large-scale power storage facility, 607: power storage device, 608: power interface, EP11 to EP13 Power, EP21~EP23 ... power, Hg1~Hg4 ... hydrogen gas, Hr ... liquid hydrogen

Claims (9)

A first-generation facility that includes a first power generation device that generates power using natural energy and consumes power;
A second-type facility comprising: a hydrogen production device that generates hydrogen using electric power, a hydrogen holding device that can hold hydrogen, and a second power generation device that generates electric power using hydrogen. With
The first-type facility can supply at least a part of power not consumed by the first-type facility to the second-type facility, out of the power generated by the first power generation device,
The second kind facility,
Hydrogen is generated by the hydrogen production device using the electric power supplied from the first type facility, and can be held in the hydrogen holding device,
A system capable of using the hydrogen in the hydrogen holding device to generate electric power by the second power generation device and supplying at least a part of the generated electric power to the first type facility. The system of claim 1, wherein
The system wherein the second type facility further includes a hydrogen supply device capable of supplying hydrogen in the hydrogen holding device to a vehicle traveling using hydrogen. The system according to claim 1 or 2,
The first power generation device is a power generation device that generates power using solar energy,
The system wherein the second facility supplies at least a part of the generated power to the first facility at night. The system according to claim 1 or 2,
The first power generation device is a power generation device that generates power using solar energy,
The system according to claim 2, wherein the second type facility supplies at least a part of the generated power in winter in the winter and more power per unit period than in summer in the first type facility. The system according to any one of claims 1 to 4, wherein
The system according to claim 2, wherein the second facility supplies at least a part of the generated power to the first facility when a disaster occurs. 6. The system according to claim 5, which depends directly or indirectly on claim 2.
The system wherein the second facility does not supply hydrogen to the vehicle by the hydrogen supply device when a disaster occurs. The system according to any one of claims 1 to 4, wherein
The supply of power from the second-type facility to the first-type facility is performed in exchange for a price determined for the first-type facility,
In the case where the supply amount of power from the first type facility to the second type facility during the predetermined period is the first supply amount, the consideration is from the first type facility during the period to the second type facility. A system in which the supply amount of power to the two types of facilities is lower than the price when the second supply amount is smaller than the first supply amount. The system according to any one of claims 1 to 4, wherein
The power supply from the second-type facility to the first-type facility is performed according to a priority determined for the first-type facility,
The priority in the case where the amount of power supplied from the first type facility to the second type facility during the predetermined period is the first supply amount,
The system, wherein the supply amount of power from the first type facility to the second type facility during the period is higher than the priority when the second supply amount is smaller than the first supply amount. The system according to any one of claims 1 to 8, wherein
The hydrogen holding device is a first hydrogen holding device capable of holding gaseous hydrogen,
The second kind facility further comprises:
A second hydrogen holding device capable of receiving the supply of liquid hydrogen and holding the liquid hydrogen, and capable of directly or indirectly supplying the held hydrogen to the second power generation device; ,system.

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