JP7254737B2 - POWER CONTROL DEVICE, POWER CONTROL SYSTEM, POWER CONTROL METHOD, AND PROGRAM - Google Patents

Description

The present disclosure relates to a power control device, a power control system, a power control method, and a program.

In recent years, there is a system in which a power company that manages power supply and demand in a given area submits a power procurement plan to a cross-regional organization and controls power demand in a given area according to this procurement plan (for example, Patent Document 1 reference).

JP 2019-126157 A

In the system as described above, if the actual value of power demand in a predetermined area deviates from the power procurement plan, a power imbalance charge may be incurred depending on the degree of such deviation. Therefore, it is desirable to reduce such power imbalance. Further, when a power storage device is installed in a predetermined area, power imbalance adjustment can be performed by controlling charging and discharging of the power storage device. On the other hand, such imbalance adjustment may cause economic disadvantages. Therefore, it is desirable to reduce such economic disadvantages as much as possible.

An object of the present disclosure is to provide a power control device, a power control system, a power control method, and a program that can economically and profitably control charging and discharging of a power storage device within a predetermined area.

A power control apparatus according to one embodiment generates a plan for power to be procured in a predetermined area based on a power demand forecast in the predetermined area and a power generation forecast in the predetermined area.
The power control device performs a surplus imbalance of power in the predetermined area according to a comparison between a predicted unit price of power in the predetermined area and a predicted imbalance unit price of power in the predetermined area. Alternatively, the amount of electric power to be charged and discharged by the power storage device in the predetermined area is adjusted in the plan so that an insufficient imbalance may occur.

Further, the power control system according to one embodiment includes:
a power storage device within a predetermined area;
a power control device that generates a plan for power to be procured in the predetermined area based on the power demand forecast in the predetermined area and the power generation forecast in the predetermined area;
including.
The power control device performs a surplus imbalance of power in the predetermined area according to a comparison between a predicted unit price of power in the predetermined area and a predicted imbalance unit price of power in the predetermined area. Alternatively, the amount of electric power to be charged and discharged by the power storage device is adjusted in the plan so that an insufficient imbalance may occur.

Further, a power control method according to one embodiment includes:
generating a power plan to be procured in the predetermined area based on the power demand forecast in the predetermined area and the power generation forecast in the predetermined area;
comparing a predicted unit price of electricity in the predetermined area and a predicted imbalance unit price of electricity in the predetermined area;
A power amount to be charged/discharged by the power storage device in the predetermined area according to the plan so that a power surplus imbalance or insufficient power imbalance may occur in the predetermined area according to the result of the comparison in the comparing step. and adjusting
including.

Further, a program according to one embodiment is
to the computer,
generating a power plan to be procured in the predetermined area based on the power demand forecast in the predetermined area and the power generation forecast in the predetermined area;
comparing a predicted unit price of electricity in the predetermined area and a predicted imbalance unit price of electricity in the predetermined area;
A power amount to be charged/discharged by the power storage device in the predetermined area according to the plan so that a power surplus imbalance or insufficient power imbalance may occur in the predetermined area according to the result of the comparison in the comparing step. and adjusting
to run.

According to one embodiment, it is possible to provide a power control device, a power control system, a power control method, and a program that can economically and profitably control charging and discharging of a power storage device within a predetermined area.

It is a figure showing an example of composition of a power control system concerning one embodiment of the present invention. 2 is a diagram showing a configuration example of a first power control device shown in FIG. 1; FIG. 2 is a diagram showing a configuration example of a second power control device shown in FIG. 1; FIG. 2 is a diagram showing a configuration example of the device shown in FIG. 1; FIG. 2 is a diagram showing an example of power control by the power storage device shown in FIG. 1; FIG. 2 is a diagram showing an example of power control by the power storage device shown in FIG. 1; FIG. It is a figure explaining the example of the unit price of electric power. 2 is a sequence diagram showing an example of operation of the power control system shown in FIG. 1; FIG. 2 is a sequence diagram showing an example of the operation of the first power control device shown in FIG. 1; FIG. 2 is a sequence diagram showing an example of the operation of the first power control device shown in FIG. 1; FIG. 2 is a sequence diagram showing an example of the operation of the first power control device shown in FIG. 1; FIG.

A power control system, a power control device, a power control method, and a program according to one embodiment will be described below with reference to the drawings.

FIG. 1 is a diagram showing a configuration example of a power control system 1 according to one embodiment. The power control system 1 according to one embodiment may configure an AEMS (Area Energy Management System) that controls power in a predetermined area such as a municipality unit, for example. Hereinafter, "predetermined area" may mean, for example, the same specific region (area).

As shown in FIG. 1 , the power control system 1 according to one embodiment includes a first power control device 10, a second power control device 20, and equipment 30. The first power control device 10 may be a control device that controls the AEMS. Also, the second power control device 20 may be a control device that constitutes an FES (Front End Server). The first power control device 10 is connected to the second power control device 20 . The second power control device 20 is connected to the device 30 via a gateway (GW) 40 . The device 30 is provided within a predetermined area where the power control system 1 controls power. The device 30 includes, for example, a solar cell 30A, a power meter 30B, and a power storage device 30C. FIG. 1 shows an example in which the second power control device 20 and the device 30 are connected via the GW 40 . However, the power control system 1 according to one embodiment is not limited to the configuration shown in FIG. For example, the second power control device 20 and the device 30 may be connected without going through the GW 40 .

The first power control device 10 drafts (generates) a power procurement plan for a predetermined area, and in accordance with the drafted procurement plan, for each predetermined period (hereinafter also referred to as a “demand interval” as appropriate), the power in the predetermined area. is a power control device that controls the In this case, the first power control device 10 draws up a plan for power to be procured within a predetermined area in accordance with the power demand forecast in the predetermined area and the power generation forecast in the predetermined area for each demand section. You can Hereinafter, a plan for power to be procured in a predetermined area is also simply referred to as a “procurement plan”. Here, to “procure” electric power may mean, for example, to procure (for example, purchase power from) the Japan Electric Power Exchange (JEPX) or the like.

The first power control device 10 subtracts the power generation prediction in the predetermined area from the power demand prediction in the predetermined area, and adds or subtracts a value according to the charging plan and discharging plan of the power storage device 30C in the predetermined area. to formulate a procurement plan. This charging plan and discharging plan may be, for example, a charging/discharging plan for the power storage device 30C for peak cutting or peak shifting of power demand in a predetermined area. A demand section may be, for example, 30 minutes. In the power control system 1, it is required that the actual value of the power demand in a predetermined area matches the procurement plan, that is, that the procurement plan is achieved for each demand section. As described above, if the actual value of power demand in a predetermined area deviates from the procurement plan, an imbalance fee for power may be incurred according to the degree of such deviation.

The first power control device 10 may draw up a procurement plan for a predetermined time (for example, 48 hours) ahead. However, the procurement plan, demand forecast, and power generation forecast may each be changeable up to a predetermined time before the target demand section. For example, the procurement plan may be changeable up to one hour before the target demand section. Therefore, if the target demand section is from 13:00 to 13:29, the procurement plan may be changed until 11:59. Further, the demand forecast and power generation forecast may be changed up to 30 minutes before the target demand section. Therefore, if the target demand section is from 13:00 to 13:29, the demand forecast and power generation forecast may be changed until 12:29. The charge plan and discharge plan may be changeable even within the target demand section. After the procurement plan, demand forecast, and power generation forecast cannot be changed, the procurement plan may be achieved by adjusting the charging plan and the discharging plan.

The first power control device 10 may submit the drafted procurement plan to, for example, the Organization for Cross-regional Coordination of Transmission Operators (OCCTO). The first power control device 10 may control charging/discharging of the power storage device 30C according to the prepared procurement plan for each demand section. That is, the first power control device 10 may control charging and discharging of the power storage device 30C in units of a predetermined period (demand section) according to a power procurement plan based on power demand forecast and power generation forecast. The first power control device 10 may allocate a chargeable/dischargeable charge/discharge amount to the power storage device 30C for each demand section. The first power control device 10 may control the charge/discharge of the power storage device 30C within the range of the charge/discharge amount assigned to the demand section for each demand section. Further, the first power control device 10 may control charging and discharging of the power storage device 30C in order to perform peak cut or peak shift of power demand in a predetermined area. The first power control device 10 may transmit to the second power control device 20 a control instruction for controlling charging and discharging of the power storage device 30C. Charging and discharging of power storage device 30C is controlled according to this control instruction. Also, the first power control device 10 may transmit the procurement plan, demand forecast, and power generation forecast to the second power control device 20 .

Also, the first power control device 10 generates a control instruction for instructing the operation of the device 30 . For example, the first power control device 10 generates a control instruction instructing charging/discharging of the power storage device 30C. In addition, the first power control device 10 generates a control instruction to stop the device 30 (hereinafter referred to as “stop instruction”) in response to occurrence of an event such as a failure of the device 30 . The first power control device 10 also generates, for example, a control instruction (hereinafter referred to as “startup instruction”) instructing to start up the stopped device 30 . The first power control device 10 transmits the generated control instruction to the device 30 via the second power control device 20 . The control instructions may be transmitted to the device 30 according to a protocol based on the OpenADR (Automated Demand Response) standard, for example.

FIG. 2 is a diagram showing a configuration example of the first power control device 10. As shown in FIG.

The first power control device 10 shown in FIG. 2 includes a storage unit 11 , a communication unit 12 and a control unit 13 .

The storage unit 11 is a memory that stores various information necessary for the operation of the first power control device 10 . The storage unit 11 may store a program according to one embodiment. The storage unit 11 may store various data such as calculation results by the control unit 13 . The storage unit 11 can be configured by, for example, a semiconductor memory, a magnetic disk, or the like, but is not limited to these, and can be configured by an arbitrary storage device. The storage unit 11 may be a storage medium such as a memory card inserted into the first power control device 10 . The storage unit 11 may be an internal memory of a CPU (Central Processing Unit) used as a control unit 13, which will be described later.

The communication unit 12 is a communication interface having various communication functions including wireless communication. The communication unit 12 may realize communication by various communication schemes such as LTE (Long Term Evolution), for example. The communication unit 12 may include, for example, a modem whose communication method is standardized by the ITU-T (International Telecommunication Union Telecommunication Standardization Sector). The communication unit 12 may realize wireless communication by various methods such as WiFi (Wireless Fidelity) or Bluetooth (registered trademark). Various types of information transmitted and received by the communication unit 12 may be stored in the storage unit 11 . The communication unit 12 may include an antenna for transmitting and receiving radio waves, an appropriate RF (Radio Frequency) unit, and the like. Since the communication unit 12 can be configured by a known technology for wireless communication, a more detailed description of hardware is omitted.

The communication unit 12 transmits a control instruction to the second power control device 20 under the control of the control unit 13 . The communication unit 12 may transmit the procurement plan, the demand forecast, and the power generation forecast to the second power control device 20 under the control of the control unit 13 . The communication unit 12 may receive performance data indicating the actual value of power demand by the device 30 from the second power control device 20 and output the data to the control unit 13 .

The control unit 13 is a controller that controls the operation of the first power control device 10 as a whole. Control unit 13 may include at least one processor, such as a CPU, to provide control and processing power for performing various functions. The control unit 13 may be realized by one processor or may be realized by a plurality of processors. The controller 13 may be implemented as a single integrated circuit. A processor may be implemented as a number of integrated and discrete circuits communicatively coupled. The control unit 13 may be configured as a CPU and a program executed by the CPU. Programs executed by the control unit 13 , results of processing executed by the control unit 13 , and the like may be stored in the storage unit 11 .

The control unit 13 may formulate a power procurement plan according to the power demand forecast and the power generation forecast in a predetermined area. The control unit 13 controls charging and discharging of the power storage device 30C for each demand section according to the procurement plan. The control unit 13 may control the communication unit 12 so that the procurement plan, demand forecast, and power generation forecast are transmitted to the second power control device 20 . The control unit 13 receives a control instruction for the device 30, for example, a control instruction for controlling charging/discharging of the power storage device 30C, a stop instruction for instructing the stop of the device 30, and a start instruction for instructing the start of the device 30 according to the second power control device. The communication unit 12 may be controlled to transmit to 20 .

Referring to FIG. 1 again, the second power control device 20 reduces the inconsistency (hereinafter referred to as “imbalance”) between the actual power demand and the procurement plan in a predetermined area. It is a power control device that performs imbalance adjustment to adjust power demand. Here, imbalance includes insufficient imbalance and surplus imbalance. The shortage imbalance may be an inconsistency in which the amount of electric power in the actual demand afterward is larger than the amount of electric power in the procurement plan in advance. The surplus imbalance may be an inconsistency in which the power amount in the later actual demand is smaller than the power amount in the advance procurement plan.

The second power control device 20 adjusts the imbalance based on whether or not the procurement plan can be achieved without charge/discharge control of the power storage device 30C based on the error between the procurement plan and the actual value of power demand in a predetermined area. You may decide whether to do it or not. When determining to perform imbalance adjustment, the second power control device 20 may control charging and discharging of the power storage device 30C in units of a predetermined period (for example, one minute) shorter than the demand period.

Also, the second power control device 20 receives the control instruction for the device 30 transmitted from the first power control device 10 and transmits it to the device 30 via the GW 40 . The second power control device 20 also receives the actual value (actual data) of the power demand in the device 30 transmitted from the device 30 via the GW 40 at predetermined time intervals (for example, one minute). The second power control device 20 may collect performance data acquired from each device 30 for a predetermined period of time (for example, 30 minutes) and transmit it to the first power control device 10 .

FIG. 3 is a diagram showing a configuration example of the second power control device 20. As shown in FIG.

The second power control device 20 shown in FIG. 3 includes a storage section 21 , communication sections 22 and 23 and a control section 24 .

The storage unit 21 is a memory that stores various information necessary for the operation of the second power control device 20 . The storage unit 21 may store various data such as calculation results by the control unit 24 . The storage unit 21 can be configured by, for example, a semiconductor memory, a magnetic disk, or the like, but is not limited to these, and can be configured by an arbitrary storage device. The storage unit 21 may be a storage medium such as a memory card inserted into the second power control device 20 . The storage unit 21 may be an internal memory of a CPU used as a control unit 24, which will be described later.

The communication unit 22 is a communication interface having a communication function according to a communication method corresponding to the communication method with the communication unit 12 of the first power control device 10 .

The communication unit 22 receives control instructions transmitted from the first power control device 10 and outputs the control instructions to the control unit 24 . The communication unit 22 may receive procurement plans, demand forecasts, power generation forecasts, and the like transmitted from the first power control device 10 and output them to the control unit 24 . Under the control of the control unit 24 , the communication unit 22 may collect power demand performance data of the devices 30 for a predetermined time period (for example, 30 minutes) and transmit the data to the first power control device 10 .

The communication unit 23 is a communication interface having various communication functions including wireless communication. The communication unit 23 may realize communication by various communication schemes such as LTE, for example. The communication unit 23 may include, for example, a modem whose communication method is standardized by ITU-T. The communication unit 23 may realize wireless communication by various methods such as WiFi or Bluetooth (registered trademark). Various types of information transmitted and received by the communication unit 23 may be stored in the storage unit 21 . The communication unit 23 may include an antenna for transmitting and receiving radio waves, an appropriate RF unit, and the like. Since the communication unit 23 can be configured by a known technology for wireless communication, a more detailed description of hardware is omitted. Although the communication unit 22 and the communication unit 23 are described separately in this embodiment, the present invention is not limited to this. The communication unit 22 and the communication unit 23 may be configured by one communication module.

The communication unit 23 may transmit control instructions to the device 30 under the control of the control unit 24 . Further, the communication unit 23 may receive actual power demand data transmitted from the device 30 via the GW 40 and output the data to the control unit 24 .

The control unit 24 is a controller that controls the operation of the second power control device 20 as a whole. Control unit 24 may include at least one processor, such as a CPU, to provide control and processing power for performing various functions. The control unit 24 may be implemented by one processor or may be implemented by a plurality of processors. Controller 24 may be implemented as a single integrated circuit. A processor may be implemented as a number of integrated and discrete circuits communicatively coupled. The control unit 24 may be configured as a CPU and a program executed by the CPU. Programs executed by the control unit 24 and results of processes executed by the control unit 24 may be stored in the storage unit 21 .

When the control instruction for the device 30 is output from the communication section 22 , the control section 24 may control the communication section 23 so that the control instruction is transmitted to the device 30 via the GW 40 . When the power demand performance data of the device 30 is output from the communication unit 23 , the control unit 24 controls the communication unit 22 so that the performance data for a predetermined time is collected and transmitted to the first power control device 10 . You can

The control unit 24 may determine whether or not to perform imbalance adjustment based on the procurement plan and actual data (actual values) of power demand. When the control unit 24 determines to perform the imbalance adjustment, the control unit 24 may control the charge/discharge of the power storage device 30</b>C in units of a predetermined period (for example, one minute) shorter than that of the first power control device 10 .

Referring to FIG. 1 again, the device 30 is connected to the second power control device 20 via the GW40. The device 30 transmits performance data of power demand in the device 30 to the second power control device 20 via the GW 40 at predetermined time intervals (for example, one-minute intervals). As described above, the device 30 includes, for example, a solar cell 30A, a power meter 30B, and a power storage device 30C.

The solar cell 30A converts solar energy into DC power. The solar cell 30A is configured such that, for example, power generation units having photoelectric conversion cells are connected in a matrix to output a predetermined direct current. The type of the solar cell 30A is not limited as long as it can be photoelectrically converted, such as a silicon-based polycrystalline solar cell, a silicon-based monocrystalline solar cell, or a thin-film solar cell such as CIGS.

The power meter 30B measures the amount of power consumed by the load and/or the amount of power supplied to the load. Here, the amount of power supplied to the load is, for example, the amount of power supplied to the load from the outside such as the system, and the amount of power supplied to the load from the solar cell 30A and the power storage device 30C in the device 30. good.

The power storage device 30C includes a storage battery such as a lithium ion battery or a nickel metal hydride battery. The power storage device 30C can supply power by discharging the charged power. Further, the power storage device 30C can be charged with electric power supplied from the power system, the solar battery 30A, or the like. Power storage device 30</b>C can be charged and discharged according to control instructions transmitted from second power control device 20 .

FIG. 4 is a diagram showing a configuration example of the device 30. As shown in FIG. As described above, the device 30 includes various devices such as the solar cell 30A, power meter 30B, and power storage device 30C. In FIG. 4, only configurations common to various devices 30 are shown.

A device 30 shown in FIG. 4 includes a storage unit 31 , a communication unit 32 and a control unit 33 .

The storage unit 31 is a memory that stores various information necessary for the operation of the device 30 . The storage unit 31 may store a program according to one embodiment. The storage unit 31 may store various data such as calculation results by the control unit 33 . The storage unit 31 can be configured by, for example, a semiconductor memory, a magnetic disk, or the like, but is not limited to these, and can be configured by an arbitrary storage device. The storage unit 31 may be a storage medium such as a memory card inserted into the device 30 . The storage unit 31 may be an internal memory of a CPU used as a control unit 33, which will be described later.

The communication unit 32 is a communication interface having a communication function according to a communication method corresponding to communication with the communication unit 23 of the second power control device 20 via the GW 40 .

The communication unit 32 receives control instructions transmitted from the second power control device 20 and outputs the control instructions to the control unit 33 . Under the control of the control unit 33 , the communication unit 32 may transmit actual power demand data of the device 30 to the second power control device 20 via the GW 40 at predetermined time intervals (for example, 1-minute intervals).

The control unit 33 is a controller that controls the operation of the device 30 as a whole. Controller 33 may include at least one processor, such as a CPU, to provide control and processing power to perform various functions. The control unit 33 may be realized by one processor or may be realized by a plurality of processors. The controller 33 may be implemented as a single integrated circuit. A processor may be implemented as a number of integrated and discrete circuits communicatively coupled. The control unit 33 may be configured as a CPU and a program executed by the CPU. Programs executed by the control unit 33 , results of processing executed by the control unit 33 , and the like may be stored in the storage unit 31 .

The control unit 33 receives control instructions transmitted from the second power control device 20 and operates according to the received control instructions. For example, the control unit 33 stops the device 30 when receiving a stop instruction as the control instruction. Further, when receiving the start instruction while stopping the device 30 according to the stop instruction, the control unit 33 starts the device 30 . Further, the control unit 33 may control the communication unit 32 so that the power demand performance data of the device 30 is transmitted to the second power control device 20 at predetermined time intervals.

Next, power control by the power control system 1 according to one embodiment will be described. In the following description, the control performed by the first power control device 10 may be the control performed by the control unit 13 of the first power control device 10, for example. Further, the control performed by the second power control device 20 may be the control performed by the control unit 24 of the second power control device 20, for example. Further, the control performed by the device 30 may be the control performed by the control unit 33 of the device 30, for example.

As described above, in the power control system 1, the first power control device 10 generates a power procurement plan for a predetermined area, and controls the power in the predetermined area in units of demand intervals such as 30 minutes. you can Also, the first power control device 10 may submit (transmit) the procurement plan generated as described above to a cross-regional organization such as OCCTO.

Here, the procurement plan may be the amount of electric power to be procured from outside the predetermined area. As described above, the procurement plan is obtained by subtracting the power generation prediction in the predetermined area from the power demand prediction in the predetermined area, and adding a value corresponding to the charging plan and discharging plan of the power storage device 30C in the predetermined area. may be added or subtracted. The value according to the charging plan and discharging plan of the power storage device 30C in the predetermined area is, for example, the amount of electric power instructed to charge/discharge the power storage device 30C in the predetermined area (hereinafter referred to as “charge/discharge instruction amount ”) may be used.

In the power control system 1, the charge/discharge instruction amount described above may include the following two points of view.
(1) Before the first power control device 10 generates a procurement plan, the charge/discharge instruction amount is an instruction to charge/discharge the power storage device 30C in order to perform peak shift and/or peak cut of power demand. It may be the amount of power that is used. Such peak shift and/or peak cut may be instructed by the first power control device 10, for example.
(2) After the first power control device 10 generates the procurement plan, the charge/discharge instruction amount is the amount of power that the power storage device 30C is instructed to charge/discharge in order to adjust the imbalance of the power demand. may be Such imbalance adjustment may be directed by the second power control device 20, for example.

In the power control system 1, charging and discharging of the power storage device 30C within a predetermined area may be controlled as follows. That is, when there are a plurality of power storage devices 30C within a predetermined area, the plurality of power storage devices 30C may be controlled separately and independently in power control system 1 . On the other hand, when there are a plurality of power storage devices 30C within a predetermined area, the plurality of power storage devices 30C may be collectively controlled as one power storage device in the power control system 1 . Alternatively, only one power storage device 30</b>C may be provided in a predetermined area, and the power control system 1 may control this one power storage device. Hereinafter, in the power control system 1, the power storage device 30C in the predetermined area may be any number of one or more power storage devices.

In the power control system 1, when controlling charging/discharging of the power storage device 30C in a predetermined area, the amount of power that can be charged/discharged by the power storage device 30C may be controlled by dividing it into two areas, for example. Hereinafter, the amount of electric power that can be charged and discharged by the power storage device 30C is also referred to as the “capacity” of the power storage device 30C as appropriate.

5 and 6 are diagrams showing examples of power control by the power storage device 30C in the power control system 1. FIG. 5 and 6 are diagrams for explaining an example of the capacity of the power storage device 30C for a predetermined period of time.

For example, as shown in (1) of FIG. 5 and (1) of FIG. 6, it is assumed that the capacity of the power storage device 30C in a predetermined area for 30 minutes is, for example, 100 kWh as a whole. Here, as shown in (2) of FIG. 5, of the capacity of 100 kWh of the power storage device 30C, for example, 50 kWh, which is half of the capacity, may be used as the capacity for peak shifting. In this case, as shown in (3) of FIG. 5, the remaining half, 50 kWh, of the 100 kWh capacity of the power storage device 30C may be used as the capacity for imbalance adjustment. That is, in the case of the example shown in FIG. 5, if the maximum capacity for peak shifting is used out of the capacity of the power storage device 30C, the maximum capacity that can be used for imbalance adjustment is 50 kWh. Become.

On the other hand, as shown in (2) of FIG. 6, the capacity for performing the peak shift may be set to, for example, 30 kWh out of the capacity of 100 kWh of the power storage device 30C. In this case, as shown in (3) of FIG. 6, the remaining 70 kWh of the 100 kWh capacity of the power storage device 30C may be used as the capacity for imbalance adjustment. That is, in the case of the example shown in FIG. 6, the maximum capacity that can be used for imbalance adjustment without using the maximum capacity of 50 kWh for peak shifting out of the capacity of the power storage device 30C. up to 70 kWh.

Information related to the capacity for performing peak shifting shown in (2) of FIG. 5 and (2) of FIG. 6 is transmitted from the first power control device 10 to the second power control device 20 as, for example, a procurement plan you can Further, the information related to the capacity for performing the imbalance adjustment shown in (3) of FIG. 5 and (3) of FIG. good. Thus, in the power control system 1 according to one embodiment, imbalance adjustment may be performed by charging and discharging the power storage device 30C.

As described above, if the actual value of power demand in a predetermined area deviates from the procurement plan, an imbalance charge for power may occur depending on the degree of such deviation. Here, the power imbalance charge includes a surplus imbalance charge and an insufficient imbalance charge. The surplus imbalance charge may be a charge for selling surplus power when the amount of power in the actual demand later becomes smaller than the amount of power in the procurement plan in advance. The unit price of the surplus imbalance charge tends to be lower than the electricity selling unit price at the time the procurement plan is generated. Further, the shortage imbalance fee may be a fee for purchasing the insufficient power when the amount of power in the actual demand later becomes larger than the amount of power in the procurement plan in advance. The unit price of the insufficient imbalance charge tends to be higher than the power purchase unit price at the time of generating the procurement plan. In either case, the occurrence of power imbalance can result in economic penalties. Therefore, when the power storage device 30C is installed in a predetermined area, the power imbalance can be adjusted by controlling the charge/discharge of the power storage device 30C.

However, the unit price of electricity may differ from time to time. Also, imbalance fees may change due to changes in regulations regarding imbalance fees or the like. Therefore, depending on the time period, the unit price of imbalance charges may be more economically beneficial than the unit price of electricity at the time of generation of the procurement plan. For example, the unit price of electricity generally tends to be higher during the day than during the night. However, for example, even during the daytime when the unit price of electricity is relatively high, the unit price of the insufficient imbalance charge (power purchase unit price) may be lower than the unit price of electricity when the procurement plan was generated.

FIG. 7 is a diagram illustrating an example of a unit price of electricity. FIG. 7 exemplifies the unit price of electricity, the unit price of surplus imbalance charge, and the unit price of insufficient imbalance charge at the time of generation of the procurement plan for three dates (time zones).

As shown in FIG. 7A, at 00:00 on April 1, 2019, the power unit price at the time of generating the procurement plan is 5.75 yen per kWh. At this time, as shown in FIG. 7A, the surplus imbalance charge unit price is 5.19 yen per kWh, and the insufficient imbalance charge unit price is 6.45 yen per kWh.

In the time period shown in (A) of FIG. 7, the unit price of the surplus imbalance charge is lower than the electricity unit price when the procurement plan is generated. In this case, if a surplus imbalance occurs, the electric power will be sold at a low price, which may result in an economic disadvantage. Also, in the time period shown in FIG. 7A, the unit price of the insufficient imbalance charge is higher than the electricity unit price at the time of generating the procurement plan. In this case, if an insufficient imbalance occurs, the electric power will be purchased at a high price, which may result in an economic disadvantage. In other words, during the time period shown in FIG. 7A, economic disadvantages may occur regardless of whether excess imbalance or insufficient imbalance occurs. Therefore, it may be economically beneficial to perform power control (imbalance adjustment) so that neither excessive imbalance nor insufficient imbalance occurs during the time period shown in FIG. 7(A).

On the other hand, as shown in FIG. 7B, at 18:30 on April 2, 2019, the power unit price at the time of generation of the procurement plan is assumed to be 10.34 yen per 1 kWh. At this time, as shown in FIG. 7B, the surplus imbalance charge unit price is 19.99 yen per kWh, and the insufficient imbalance charge unit price is 21.25 yen per kWh.

In the time period shown in FIG. 7B, the unit price of surplus imbalance charges is higher than the unit price of electricity when the procurement plan was generated. In this case, even if a surplus imbalance occurs, electric power will be sold at a higher price, and no economic disadvantage will occur. Also, in the time period shown in FIG. 7B, the unit price of the insufficient imbalance charge is also higher than the electricity unit price at the time of generation of the procurement plan. In this case, if an insufficient imbalance occurs, the electric power will be purchased at a high price, which may result in an economic disadvantage. That is, during the time period shown in FIG. 7B, the occurrence of insufficient imbalance may cause economic disadvantages, but the occurrence of excess imbalance may be economically beneficial. Therefore, it is desirable to perform power control (imbalance adjustment) so that insufficient imbalance does not occur during the time period shown in FIG. 7B. On the other hand, during the time period shown in FIG. 7B, it may be economically beneficial to generate excess imbalance, so control may be performed so that imbalance adjustment is not performed.

Also, as shown in FIG. 7C, at 8:30 on June 3, 2019, the power unit price at the time of generation of the procurement plan is assumed to be 7.01 yen per kWh. At this time, as shown in FIG. 7C, the surplus imbalance charge unit price is 0.65 yen per kWh, and the insufficient imbalance charge unit price is 1.91 yen per kWh.

In the time period shown in (C) of FIG. 7, the unit price of the surplus imbalance charge is lower than the unit price of electricity when the procurement plan was generated. In this case, if a surplus imbalance occurs, the electric power will be sold at a low price, which may result in an economic disadvantage. In addition, in the time period shown in (C) of FIG. 7, the unit price of the insufficient imbalance charge is also lower than the electricity unit price at the time of generation of the procurement plan. In this case, if an insufficient imbalance occurs, the electric power will be purchased at a low price, and no economic disadvantage will occur. That is, during the time period shown in FIG. 7C, occurrence of surplus imbalance may be economically disadvantageous, but occurrence of insufficient imbalance may be economically beneficial. Therefore, it is desirable to perform power control (imbalance adjustment) so that excess imbalance does not occur during the time period shown in FIG. 7(C). On the other hand, in the time zone shown in FIG. 7C, it may be economically beneficial to generate insufficient imbalance, so control may be performed so that imbalance adjustment is not performed.

In general, the amount of power that can be charged and discharged by a power storage device in a power control system can be a valuable resource for performing imbalance adjustment as described above. Therefore, in general, it is desirable for the power storage device to suppress unnecessary imbalance adjustment as much as possible for the purpose of leaving a margin for performing imbalance adjustment. However, as described above, if the imbalance adjustment results in an economic disadvantage, then valuable resources are used and the economic disadvantage is further incurred.

In order to deal with such a situation, in the power control system 1 according to one embodiment, the first power control device 10 may generate the procurement plan as follows when generating the procurement plan. That is, the first power control device 10 prevents the second power control device 20 from performing imbalance control when it is expected that it is economically beneficial to generate excess imbalance or insufficient imbalance. The plan may be included to generate a procurement plan. The generation of such a procurement plan is further described below.

When generating the procurement plan, for example, as shown in FIG. 7, the first power control device 10 determines whether it is expected to be economically beneficial to generate a surplus imbalance or a shortage imbalance. may be judged from the viewpoint of
(1) Predicted power charge unit price at the time of procurement plan generation (2) Predicted surplus imbalance charge unit price (3) Predicted deficit imbalance charge unit price

The above (1) may be based on information obtained from, for example, JEPX. Further, the surplus imbalance charge unit price in (2) above may be the surplus imbalance charge unit price described above. The unit price of insufficient imbalance charge in (3) above may be the unit price of the aforementioned insufficient imbalance charge.

First, when “(2) predicted surplus imbalance charge unit price” is higher than “(1) predicted charge unit price of electricity at the time of procurement plan generation” ((1)<(2)) Describes the procurement plan that should be generated in This corresponds to, for example, the state of charges in the time period shown in FIG. 7B. In this case, as described above, the occurrence of insufficient imbalance can be economically disadvantageous, while the occurrence of excess imbalance can be economically beneficial. Therefore, the first power control device 10 may generate a procurement plan that sets a relatively large amount of power to be procured in a predetermined area. For example, the first power control device 10 may generate a plan that sets a relatively large amount of electric power that can be charged and discharged by the power storage device 30C so that the procurement plan will be relatively large. This can result in excess imbalance of power in a given area.

Thus, when the predicted surplus imbalance charge unit price of power in a predetermined area is higher than the predicted charge unit price of power in the predetermined area, the first power control device 10 operates as follows. good too. That is, in this case, the first power control device 10 adjusts the amount of power to be charged and discharged by the power storage device 30C in the predetermined area in the procurement plan so that the surplus imbalance of power in the predetermined area may occur. good too.

Specifically, in the above-described case, first power control device 10 issues an instruction to charge power storage device 30C (hereinafter referred to as “charging instruction ”) may be generated. Here, as the charging instruction, the first power control device 10 may issue an instruction to charge an arbitrary predetermined amount of power with respect to the predicted remaining amount of power charged in the power storage device 30C. . In this case, the first power control device 10 may include the power amount for the imbalance adjustment performed by the second power control device 20 in the charging instruction.

In this manner, when the power charged in the power storage device 30C is less than the target value, the first power control device 10 may adjust the amount of power to be charged by the power storage device 30C in the procurement plan. In this case, the first power control device 10 is prepared for power imbalance adjustment in a predetermined area among the amount of electric power to be charged by the power storage device 30C in the procurement plan and the amount of power that can be charged by the power storage device 30C. At least part of the amount of power may be included.

Here, the procurement plan generated by the first power control device 10 is obtained by subtracting the power generation prediction in the predetermined area from the power demand prediction in the predetermined area and adding the power indicated in the charging instruction. may be By increasing the power charged in the power storage device 30C as described above, a relatively large procurement plan is generated. As a result, the risk of economic disadvantages can be reduced.

On the other hand, in the above-described case, first power control device 10 issues an instruction to discharge power storage device 30C (hereinafter referred to as a “discharge instruction”) when the amount of power charged in power storage device 30C satisfies a predetermined target value. note) may be generated. Here, as the discharge instruction, the first power control device 10 may instruct, for example, the power storage device 30C to discharge a predetermined amount of power as usual. In this case, the first power control device 10 does not have to include the power amount for the imbalance adjustment performed by the second power control device 20 in the discharge instruction.

In this manner, when the power charged in the power storage device 30C is equal to or greater than the target value, the first power control device 10 may adjust the amount of power to be discharged by the power storage device 30C in the procurement plan. In this case, the first power control device 10 is prepared for power imbalance adjustment in a predetermined area of the amount of power that should be discharged by the power storage device 30C in the procurement plan and the amount of power that can be discharged by the power storage device 30C. It is also possible not to include the amount of electric power.

Here, the procurement plan generated by the first power control device 10 may be obtained by subtracting the power generation prediction in a predetermined area from the power demand prediction in the predetermined area. That is, in this case, the procurement plan generated by the first power control device 10 does not need to take into account the power indicated in the discharge instruction. As described above, a relatively large number of procurement plans are generated. As a result, the risk of economic disadvantages can be reduced.

In generating the procurement plan described above, (2) the predicted surplus imbalance charge unit price may be adjusted based on the expected error of the predicted surplus imbalance charge. For example, if the expected error for the predicted surplus imbalance charge is 5%, then (2) the predicted surplus imbalance charge unit price may be taken as 95%. That is, in this case, (2) the predicted surplus imbalance charge unit price may be set to a small value based on the expected error of the predicted surplus imbalance charge. This makes it possible to further reduce the risk of economic disadvantages.

In this way, the first power control device 10 may employ, as the surplus imbalance charge unit price, a reduced unit price based on an assumed error in the predicted surplus imbalance charge for power in a predetermined area.

Further, when "(1)<(2)" as described above, the first power control device 10 instructs not to perform the imbalance adjustment for the surplus imbalance in this time period. good. Such instructions may be sent from the first power controller 10 to the second power controller 20 .

Thus, the first power control device 10 may include the communication unit 12 that communicates with other power control devices such as the second power control device 20 that controls charging and discharging of the power storage device 30C. The communication unit 12 of the first power control device 10 may communicate with the communication unit 22 of the second power control device 20, for example. In this case, the first power control device 10 may control the communication unit 12 so as to transmit to the other power control device an instruction to control charging and discharging of the power storage device 30C according to the procurement plan.
On the other hand, the first power control device 10 controls the communication unit 12 so as to transmit to other power control devices an instruction to the effect that power imbalance adjustment in a predetermined area will not be performed during the period in which the procurement plan is executed. You may

Next, when “(3) predicted shortage imbalance charge unit price” is cheaper than “(1) predicted charge unit price of electricity at the time of procurement plan generation” ((1)>(3) ) describes the procurement plan that should be generated. This corresponds to, for example, the state of charges in the time period shown in FIG. 7(C). In this case, as described above, excessive imbalance can be economically disadvantageous, while insufficient imbalance can be economically beneficial. Therefore, the first power control device 10 may generate a procurement plan that sets a relatively small amount of power to be procured in a predetermined area. For example, the first power control device 10 may generate a plan in which the amount of electric power that can be charged and discharged by the power storage device 30C is set relatively small so that the procurement plan becomes relatively small. This can result in a power deficit imbalance in a given area.

In this way, when the predicted power charge unit price in the predetermined area is higher than the predicted shortage imbalance charge unit price of power in the predetermined area, the first power control device 10 operates as follows. good too. That is, in this case, the first power control device 10 adjusts the amount of electric power to be charged and discharged by the power storage device 30C in the predetermined area in the procurement plan so that an electric power shortage imbalance may occur in the predetermined area. good too.

Specifically, in the case described above, the first power control device 10 may generate a procurement plan including a charging instruction when the amount of power charged in the power storage device 30C is less than a predetermined target value. Here, as the charging instruction, the first power control device 10 may instruct, for example, that the power storage device 30C is charged with a predetermined amount of power as usual. In this case, the first power control device 10 does not have to include the power amount for the imbalance adjustment performed by the second power control device 20 in the discharge instruction.

In this manner, when the power charged in the power storage device 30C is less than the target value, the first power control device 10 may adjust the amount of power to be charged by the power storage device 30C in the procurement plan. In this case, the first power control device 10 is prepared for power imbalance adjustment in a predetermined area among the amount of electric power to be charged by the power storage device 30C in the procurement plan and the amount of power that can be charged by the power storage device 30C. It is also possible not to include the amount of electric power.

Here, the procurement plan generated by the first power control device 10 may be obtained by subtracting the power generation prediction in a predetermined area from the power demand prediction in the predetermined area. That is, in this case, the procurement plan generated by the first power control device 10 does not need to take into account the power indicated in the charging instruction. As described above, a relatively small number of procurement plans are generated. As a result, the risk of economic disadvantages can be reduced.

On the other hand, in the case described above, the first power control device 10 may generate a procurement plan including a discharge instruction when the amount of power charged in the power storage device 30C satisfies a predetermined target value. Here, as the discharge instruction, the first power control device 10 may issue an instruction to discharge an arbitrary predetermined amount of power with respect to the predicted remaining amount of power charged in the power storage device 30C. . In this case, the first power control device 10 may include the power amount for the imbalance adjustment performed by the second power control device 20 in the discharge instruction.

In this manner, when the power charged in the power storage device 30C is equal to or greater than the target value, the first power control device 10 may adjust the amount of power to be discharged by the power storage device 30C in the procurement plan. In this case, the first power control device 10 is prepared for power imbalance adjustment in a predetermined area of the amount of power that should be discharged by the power storage device 30C in the procurement plan and the amount of power that can be discharged by the power storage device 30C. At least part of the amount of power may be included.

Here, the procurement plan generated by the first power control device 10 is obtained by subtracting the power generation prediction in the predetermined area from the power demand prediction in the predetermined area, and further subtracting the power indicated in the discharge instruction. Good as a thing. By increasing the power discharged by the power storage device 30C as described above, a relatively small procurement plan is generated.

In generating the procurement plan as described above, (3) the predicted shortfall imbalance charge unit price may be adjusted based on the expected error of the predicted shortfall imbalance charge. For example, if the expected error for the predicted shortfall imbalance charge is 5%, then (3) the predicted shortfall imbalance charge unit price may adopt a value of 105%. That is, in this case, (3) the predicted insufficient imbalance charge unit price may be set to be somewhat large based on the error assumed for the predicted insufficient imbalance charge. This makes it possible to further reduce the risk of economic disadvantages.

In this way, the first power control device 10 may employ, as the insufficient imbalance charge unit price, an increased unit price based on an assumed error in the predicted insufficient imbalance charge for power in a predetermined area.

Further, when "(1)>(3)" as described above, the first power control device 10 may instruct not to perform imbalance adjustment for insufficient imbalance during this time period. good. Such instructions may be sent from the first power controller 10 to the second power controller 20 . However, even if "(1)>(3)" is satisfied as described above, it may be economically beneficial to use the power of the power storage device 30C that has been charged at night, for example. is assumed. In consideration of such a case, the first power control device 10 instructs not to perform the imbalance adjustment for the insufficient imbalance only when the predicted insufficient imbalance unit price is equal to or less than a predetermined unit price. may Here, the predetermined unit price may be set based on, for example, the average value of the unit price of power procured in the section (time slot) in which the power storage device 30C is charged.

In this way, the first power control device 10 may perform control as follows when the estimated insufficient imbalance charge unit price of power in a predetermined area is lower than a predetermined amount. That is, in this case, the first power control device 10 issues an instruction not to perform power shortage imbalance adjustment in a predetermined area during the period in which the procurement plan is executed. The communication unit 12 may be controlled so as to transmit to the control device.

As described above, the first power control device 10 generates a plan for power to be procured in a predetermined area based on the power demand forecast in the predetermined area and the power generation forecast in the predetermined area. you can Also, the first power control device 10 may compare the predicted unit price of electricity in a predetermined area with the predicted imbalance unit price of electricity in the predetermined area. Then, according to the result of the above comparison, the first power control device 10 determines that the power storage devices 30C in the predetermined area are included in the procurement plan so that a power surplus imbalance or insufficient power imbalance may occur in the predetermined area. You may adjust the electric energy which should be charged/discharged.

According to the power control system 1 according to one embodiment, the charging and discharging of the power storage device 30C is controlled so that the excess imbalance can occur when the occurrence of the excess imbalance can be economically beneficial. Further, according to the power control system 1 according to one embodiment, when the occurrence of insufficient imbalance can be economically beneficial, the charging and discharging of the power storage device 30C is controlled so that the insufficient imbalance can occur. be. Therefore, according to the power control system 1 according to one embodiment, it is possible to economically and beneficially control the charging and discharging of the power storage device within the predetermined area.

FIG. 8 is a sequence diagram showing an example of the operation of the power control system 1. As shown in FIG. The operation of the power control system 1 described above will be described below, including communication between the elements included in the power control system 1 .

As shown in FIG. 8, the operation of the power control system 1 includes, for example, communication between the first power control device 10, the second power control device 20, the gateway (GW) 40, the power storage device 30C, and the cross-regional organization 50. It may be performed through The first power control device 10, the second power control device 20, the gateway (GW) 40, the power storage device 30C, and the cross-regional organization 50 shown in FIG. 8 may be the same as those shown in FIGS. 1 to 4, respectively. .

The following operations performed by the first power control device 10 may be performed by, for example, the control unit 13 of the first power control device 10 controlling each functional unit. Similarly, the operations performed by the second power control device 20 may be performed by, for example, the control unit 24 of the second power control device 20 controlling each functional unit. Also, the operation performed by the power storage device 30C may be performed by, for example, the control unit 33 of the device 30 controlling each functional unit.

The operation shown in FIG. 8 may start when the power control system 1 performs power control in a predetermined area. Moreover, the operation shown in FIG. 8 may be performed periodically, for example, every predetermined period such as a demand interval, or may be performed irregularly.

When the operation shown in FIG. 8 starts, the first power control device 10 predicts power demand in a predetermined area (step S1). In step S1, the first power control device 10 may predict power demand in a predetermined area based on various information. For example, the first power control device 10 may predict power demand in a predetermined area based on information stored in the storage unit 11 . Further, the first power control device 10 may predict power demand in a predetermined area based on information acquired from the communication unit 12 .

In step S1, the first power control device 10 may predict the power demand (for example, trend) in a predetermined area based on the history of power consumption in the predetermined area. In this case, the first power control device 10 may predict the power demand in a predetermined area, for example, taking into account learning results and/or judgments by artificial intelligence (AI). Likewise, the first power control device 10 may make various predictions, for example, taking into consideration the results of learning and/or judgment by AI.

When power importance is predicted in step S1, the first power control device 10 predicts power generation in a predetermined area (step S2). In step S2, the first power control device 10 may, for example, predict the power generated by the solar cell 30A included in the device 30 for each time period. Further, in step S2, the first power control device 10 may predict the power generated by various power generation devices such as fuel cells installed in a predetermined area for each time zone.

In step S2, the first power control device 10 may predict power generation in a predetermined area based on various information. For example, the first power control device 10 may predict power generation in a predetermined area based on information stored in the storage unit 11 . Also, the first power control device 10 may predict power generation in a predetermined area based on information acquired from the communication unit 12 . For example, the first power control device 10 may predict the power generation of the power generation device by acquiring the power generation performance (spec) of the power generation device in a predetermined area from the storage unit 11 or the communication unit 12 . Further, for example, the first power control device 10 may predict the power generation of the power generator based on the past power generation record of the power generator in a predetermined area.

When power generation is predicted in step S2, the first power control device 10 predicts the price of power to be purchased in a predetermined area (step S3). For example, in step S<b>3 , the first power control device 10 may predict the price of power purchased in a predetermined area based on information stored in the storage unit 11 . Also, the first power control device 10 may predict the price of power to be purchased in a predetermined area based on the information acquired from the communication unit 12 . For example, in step S<b>3 , the first power control device 10 may predict the price of power to be purchased in a predetermined area based on information distributed from JEPX or the like acquired from the communication unit 12 .

Further, in step S3, the first power control device 10 may acquire a predicted power purchase price of power in a predetermined area from the storage unit 11, the communication unit 12, or the like. For example, in step S<b>3 , the first power control device 10 may acquire a predicted power purchase price of power in a predetermined area from JEPX or the like via the communication unit 12 .

After the power price is predicted in step S3, the first power control device 10 predicts an imbalance price in a predetermined area (step S4). In step S4, the first power control device 10 may predict a surplus imbalance price in a predetermined area and/or a deficit imbalance price in a predetermined area. For example, in step S<b>4 , the first power control device 10 may predict imbalance prices in a predetermined area based on information stored in the storage unit 11 . Also, the first power control device 10 may predict the imbalance price in a predetermined area based on the information acquired from the communication unit 12 . Further, in step S4, the first power control device 10 may acquire a predicted imbalance price of power in a predetermined area from the storage unit 11, the communication unit 12, or the like. In step S4, the first power control device 10 calculates the imbalance price based on, for example, information indicating past imbalance price results in a predetermined area, weather information in a predetermined area, and/or calendar information. can be predicted.

When the imbalance price is predicted in step S4, the first power control device 10 generates a power procurement plan for a predetermined area based on various types of information predicted or obtained (step S5). In step S5, the first power control device 10 may generate a procurement plan as described above. A specific example of the operation performed by the first power control device 10 in step S5 will be further described later.

After the procurement plan is generated in step S5, the first power control device 10 submits (transmits) the procurement plan to the cross-regional organization 50 such as OCCTO (step S6). Further, after step S<b>6 , the cross-regional organization 50 may return to the first power control device 10 information indicating that the procurement plan received from the first power control device 10 has been approved.

After the procurement plan is submitted in step S6, first power control device 10 transmits an instruction to control power storage device 30C to second power control device 20 (step S7). The first power control device 10 may transmit the procurement plan from the communication unit 12 . The second power control device 20 may receive the procurement plan transmitted from the communication section 12 of the first power control device 10 by the communication section 22 .

When the procurement plan is transmitted in step S7, the second power control device 20 performs imbalance adjustment based on the received procurement plan (step S8). In step S8, the second power control device 20 may perform imbalance adjustment as described above.

When the imbalance adjustment starts in step S8, the second power control device 20 transmits a control instruction to control the power storage device 30C to the GW 40 (step S9). When the control instruction is transmitted in step S9, GW 40 can control power storage device 30C (step S10).

Next, generation of the procurement plan performed by the first power control device 10 in step S5 of FIG. 8 will be further described.

FIG. 9 is a diagram showing an example flow of operations performed by the first power control device 10 in step S5 of FIG.

When the operation shown in FIG. 9 (that is, step S5 in FIG. 8) starts, the control unit 13 of the first power control device 10 determines whether or not the surplus imbalance charge unit price is higher than the power charge unit price. Determine (step S11).

If the surplus imbalance charge unit price is higher in step S11, control unit 13 adjusts the amount of electric power to be charged and discharged by power storage device 30C so that surplus imbalance can occur (step S12). A specific example of the operation performed by the control unit 13 in step S12 will be described later.

On the other hand, if the surplus imbalance charge unit price is not higher in step S11, the control unit 13 determines whether or not the power charge unit price is higher than the insufficient imbalance charge unit price (step S13).

If the unit price of power is higher in step S13, control unit 13 adjusts the amount of power to be charged/discharged by power storage device 30C so that an insufficient imbalance can occur (step S14). A specific example of the operation performed by the control unit 13 in step S14 will be described later.

After the amount of electric power to be charged/discharged by the power storage device 30C is adjusted in step S12 or step S14, the control unit 13 generates a procurement plan based on the adjusted amount of electric power (step S15). On the other hand, if the unit price of power is not higher in step S13, the control unit 13 may generate the procurement plan without particularly adjusting the amount of power to be charged/discharged by the power storage device 30C (step S15).

Next, the operation performed by the first power control device 10 in step S12 of FIG. 9 will be further described.

FIG. 10 is a diagram showing an example flow of operations performed by the first power control device 10 in step S12 of FIG.

When the operation shown in FIG. 10 (that is, step S12 in FIG. 9) starts, the control unit 13 of the first power control device 10 determines whether or not the charge amount of the power storage device 30C is equal to or greater than the target value (step S21). . When the charged amount is equal to or greater than the target value in step S21, control unit 13 adjusts the amount of electric power to be discharged by power storage device 30C (step S22). As described above, the power amount adjusted in step S22 may not include the power amount for imbalance adjustment.

On the other hand, if the charging amount is not equal to or greater than the target value in step S21, control unit 13 adjusts the amount of power to be charged by power storage device 30C (step S23). As described above, the power amount adjusted in step S23 may include the power amount for imbalance adjustment.

Next, the operation performed by the first power control device 10 in step S14 of FIG. 9 will be further described.

FIG. 11 is a diagram showing an example flow of operations performed by the first power control device 10 in step S14 of FIG.

When the operation shown in FIG. 11 (that is, step S14 in FIG. 9) starts, the control unit 13 of the first power control device 10 determines whether or not the charge amount of the power storage device 30C is equal to or greater than the target value (step S31). . When the charged amount is equal to or greater than the target value in step S31, control unit 13 adjusts the amount of electric power to be discharged by power storage device 30C (step S32). As described above, the power amount adjusted in step S22 may include the power amount for imbalance adjustment.

On the other hand, when the charge amount is not equal to or greater than the target value in step S31, the control unit 13 adjusts the amount of electric power to be charged by the power storage device 30C (step S33). As described above, the power amount adjusted in step S33 may not include the power amount for imbalance adjustment.

Although the above embodiments have been described as representative examples, it will be apparent to those skilled in the art that many modifications and substitutions are possible within the spirit and scope of this disclosure. Therefore, the present disclosure should not be construed as limited by the above-described embodiments, and various modifications and changes are possible without departing from the scope of the claims. For example, it is possible to combine a plurality of configuration blocks described in the configuration diagrams of the embodiments into one, or divide one configuration block.

The embodiments described above are not limited to being implemented only as the power control system 1 , the first power controller 10 and the second power controller 20 . For example, the above-described embodiments are implemented as a control method for a power control device such as the first power control device 10 or the second power control device 20 and/or a control method for a power control system such as the power control system 1. You may Further, the above-described embodiment may be implemented as a program executed in a computer such as the first power control device 10 or the second power control device 20. FIG.

The 17 international goals adopted at the United Nations Summit in September 2015 are the "Sustainable Development Goals: SDGs". The power control system 1 according to one embodiment achieves, among the 17 goals of the SDGs, for example, "7. Affordable and clean energy", "9. Build a foundation for industry and technological innovation", and "11. It can contribute to the achievement of goals such as "building a city where people can continue to live".

Reference Signs List 1 power control system 10 first power control device 11 storage unit 12 communication unit 13 control unit 20 second power control unit 21 storage unit 22 communication unit 23 communication unit 24 control unit 30 device 31 storage unit 32 communication unit 33 control unit 30A sun Battery 30B Power meter 30C Power storage device 40 Gateway (GW)
50 Occupational Organization (OCCTO)

Claims (19)

A power control device that generates a plan for power to be procured in a predetermined area based on a power demand forecast in the predetermined area and a power generation forecast in the predetermined area,
A surplus imbalance or insufficient imbalance of power occurs in the predetermined area according to a comparison between the predicted unit price of electricity in the predetermined area and the predicted imbalance unit price of electricity in the predetermined area. A power control device that adjusts the amount of power to be charged and discharged in the plan by the power storage device in the predetermined area so as to obtain the desired power. When a predicted surplus imbalance charge unit price of power in the predetermined area is higher than a predicted surplus imbalance charge unit price of power in the predetermined area, the surplus imbalance of power in the predetermined area may occur. 2. The power control device according to claim 1, which adjusts the amount of power to be charged and discharged by the power storage device in the predetermined area according to the plan. 3. The power control device according to claim 2, wherein when the power charged in said power storage device is less than a target value, the amount of power to be charged by said power storage device is adjusted in said plan. wherein the amount of power to be charged by the power storage device in the plan includes at least part of the power amount prepared for power imbalance adjustment in the predetermined area among the power amounts that can be charged by the power storage device. Item 4. The power control device according to item 3. 4. The power control device according to claim 2, wherein when the power charged in said power storage device is equal to or greater than a target value, said power storage device adjusts the amount of power to be discharged in said plan. 6. The method according to claim 5, wherein the amount of power to be discharged by the power storage device in the plan does not include the power amount prepared for power imbalance adjustment in the predetermined area among the power amounts that can be discharged by the power storage device. A power controller as described. 7. The power control according to any one of claims 2 to 6, wherein, as said surplus imbalance charge unit price, a reduced unit price is adopted based on an assumed error of a predicted surplus imbalance charge for electric power in said predetermined area. Device. When the predicted charge unit price for power in the predetermined area is higher than the predicted shortage imbalance charge unit price for power in the predetermined area, the power shortage imbalance may occur in the predetermined area. 8. The power control device according to any one of claims 1 to 7, wherein the power storage device within a predetermined area adjusts the amount of power to be charged and discharged in the plan. 9. The power control device according to claim 8, wherein when the power charged in said power storage device is less than a target value, the amount of power to be charged by said power storage device in said plan is adjusted. 10. The method according to claim 9, wherein the amount of power to be charged by the power storage device in the plan does not include the power amount prepared for power imbalance adjustment in the predetermined area among the power amounts that can be charged by the power storage device. A power controller as described. 11. The power control device according to claim 9, wherein when the power charged in said power storage device is equal to or greater than a target value, said power storage device adjusts the amount of power to be discharged in said plan. wherein the amount of power to be discharged by the power storage device in the plan includes at least part of the power amount prepared for power imbalance adjustment in the predetermined area among the power amounts that can be discharged by the power storage device. Item 11. The power control device according to Item 10. 13. The power control according to any one of claims 8 to 12, wherein, as said shortage imbalance charge unit price, a unit price increased based on an assumed error of a predicted shortage imbalance charge for electric power in said predetermined area is adopted. Device. A communication unit that communicates with another power control device that controls charging and discharging of the power storage device,
14. The power control device according to any one of claims 1 to 13, controlling said communication unit to transmit an instruction to control charging/discharging of said power storage device according to said plan to said another power control device. 15. The power according to claim 14, wherein said communication unit is controlled to transmit to said another power control device an instruction to the effect that power imbalance adjustment in said predetermined area will not be performed during a period in which said plan is executed. Control device. If the unit price of the electric power shortage imbalance in the predetermined area is lower than a predetermined amount, an instruction is issued to the effect that the electric power shortage imbalance adjustment in the predetermined area will not be performed during the period in which the plan is executed. 16. The power control device according to claim 15, controlling said communication unit to transmit to said another power control device. a power storage device within a predetermined area;
a power control device that generates a plan for power to be procured in the predetermined area based on the power demand forecast in the predetermined area and the power generation forecast in the predetermined area;
A power control system comprising:
The power control device performs a surplus imbalance of power in the predetermined area according to a comparison between a predicted unit price of power in the predetermined area and a predicted imbalance unit price of power in the predetermined area. Alternatively, the power control system adjusts the amount of power to be charged and discharged by the power storage device in the plan so that an insufficient imbalance may occur. generating a power plan to be procured in the predetermined area based on the power demand forecast in the predetermined area and the power generation forecast in the predetermined area;
comparing a predicted unit price of electricity in the predetermined area and a predicted imbalance unit price of electricity in the predetermined area;
A power amount to be charged/discharged by the power storage device in the predetermined area according to the plan so that a power surplus imbalance or insufficient power imbalance may occur in the predetermined area according to the result of the comparison in the comparing step. and adjusting
power control method, including to the computer,
generating a power plan to be procured in the predetermined area based on the power demand forecast in the predetermined area and the power generation forecast in the predetermined area;
comparing a predicted unit price of electricity in the predetermined area and a predicted imbalance unit price of electricity in the predetermined area;
A power amount to be charged/discharged by the power storage device in the predetermined area according to the plan so that a power surplus imbalance or insufficient power imbalance may occur in the predetermined area according to the result of the comparison in the comparing step. and adjusting
program to run.

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