JP7012265B2 - Control device, power storage system, program - Google Patents

Description

The present invention relates to a control device for controlling electric power, a power storage system, and a program.

The power supply system includes a power conditioner that performs power conversion for both the solar cell system and the power storage system. Such a power supply system can also charge the power storage system with the output of the solar cell system. Further, the demand response (DR) request is a request regarding power reduction issued by the electric power company mainly in a state where the electric power supply amount of the electric power company is tight. The consumer who receives such a request reduces the amount of electricity used in the specified demand time period, and receives a reward from the electric power company according to the amount of reduction. In order to respond to such a DR request, the amount of electric power used at the time of the DR request is secured in the power storage system as the DR adjustment capacity, and the leveling control is performed using the capacity other than the DR adjustment capacity (for example). See Patent Document 1).

International Publication No. 16/136260

The monthly maximum value of the amount of power used every 30 minutes on each day, that is, the amount of power purchased is defined as the peak power. In addition, the basic charge in the actual volume contract is determined based on the largest value of the peak power of each month in the past year. Such real-life contracts have been introduced into household electricity prices with the liberalization of electricity. In order to lower the basic charge of the actual volume contract, it is necessary to lower the maximum value of the peak power of each month in the past year, but it is possible to facilitate the setting to lower the peak power at home. Desired.

The present invention has been made in view of such a situation, and an object of the present invention is to provide a technique for facilitating a setting for lowering a peak value of the amount of power purchased from a power system per unit time.

In order to solve the above problems, the control device of a certain aspect of the present invention is a control device connected to an electric power system and controlling a power storage system installed in a consumer, and is a reception unit that receives an operation by a user. , Based on the operation received by the reception unit, the set value of the amount of power purchased from the power system per unit time is the target value for the peak value of the amount of power purchased from the power system per unit time minus the predetermined value. When it exceeds, the setting unit that sets whether to assist the power supply to the electric equipment in the consumer by the discharge of the power storage system, and the power system per unit time when it is set to assist in the setting unit. It is provided with a communication unit that transmits an assist command instructing discharge to the power storage system when the amount of power purchased from the power exceeds a set value. The setting unit sets the assist capacity that the power storage system should reserve exclusively for assist, and is smaller than the power storage capacity of the power storage system, and the communication unit uses the assist capacity set in the setting unit for the power storage system. When the setting unit sets to assist, the setting unit automatically adjusts the assist capacity based on the capacity of the past month when the amount of power purchased from the power system per unit time exceeds the set value. Set to.

It should be noted that any combination of the above components and the conversion of the expression of the present invention between a method, a device, a system, a computer program, a recording medium on which a computer program is recorded, or the like is also effective as an embodiment of the present invention. be.

According to the present invention, it is possible to easily set the peak value of the amount of power purchased from the power system per unit time.

It is a figure which shows the composition of the consumer which concerns on Example. 2 (a)-(b) are diagrams showing an outline of the actual quantity contract in the power system of FIG. 1. 3 (a)-(c) are diagrams showing an outline of operation of the economic priority mode by the control device of FIG. 1. 4 (a)-(b) are diagrams showing an outline of operation of the environment priority mode by the control device of FIG. 1. It is a figure which shows the time change of the electric power generated by the solar cell system of FIG. 1 and the electric power used by an electric device. 6 (a)-(c) are views showing a screen displayed on the display unit. It is a figure which shows the structure of the storage capacity in SB of FIG. It is a flowchart which shows the command procedure by the control device of FIG. It is a flowchart which shows the discharge procedure by the power storage system of FIG.

An outline of the present embodiment will be described before the embodiment of the present invention is specifically described. The embodiment relates to a control device that controls a power storage system connected to an electric power system in a consumer. A consumer is a facility that receives electric power from an electric power company or the like, and is, for example, a house, an office, a store, a factory, a park, or the like. Here, we especially assume a house. For example, a solar cell system is also installed in the consumer as a power generation device, and the solar cell system is connected to a power system and a power storage system. Consumers are also equipped with smart meters, which are connected to the power system and control devices.

The smart meter measures the amount of power purchased or sold by the consumer (hereinafter collectively referred to as "power amount"), and the control device charges the power storage system based on the amount of power measured by the smart meter. Control the discharge. By such control, the power storage system charges the power generated in the solar cell system, the power purchased from the power system, and discharges the power to the electric equipment in the consumer. In addition, the electric power generated in the solar cell system is supplied to the electric equipment in the consumer, charged in the power storage system, and sold. In particular, when the electric power consumed by the electric equipment in the consumer becomes large, the power storage system executes discharge in order to suppress the increase in the amount of electric power purchased.

As mentioned above, with the liberalization of electricity, a real-life contract has been introduced into electricity prices for households. In the actual volume contract, the basic charge is determined based on the largest value of the peak power of each month in the past year, so in order to lower the basic charge, the highest of the peak power of each month in the past year Large values need to be reduced. Since the peak power is the monthly maximum value in the amount of power purchased every 30 minutes on each day, it is effective to reduce the peak power. In the control device according to this embodiment, the following three controls can be set in order to reduce the peak power. It should be noted that these settings are easily performed by the user's operation.

The first is notification control. When the amount of power purchased every 30 minutes exceeds a threshold value (hereinafter referred to as "notification threshold value"), the control device executes notification by voice or image. Residents of consumers who are aware of this operate electrical equipment to reduce the amount of electricity purchased. When the electric device is, for example, an air conditioner, the air conditioner is turned off or the set temperature is changed. The second is device operation control. When the amount of power purchased every 30 minutes exceeds a threshold value (hereinafter referred to as "threshold value for device operation"), the control device operates the electric device so as to reduce the amount of power purchased. This operation is also performed in the same manner as in the case of the first notification control. The third is storage battery assist control. When the amount of power purchased every 30 minutes exceeds a threshold value (hereinafter referred to as "set value"), the control device instructs the power storage system to discharge.

FIG. 1 shows the configuration of the consumer 100. The customer 100 is provided with a power system 10, a smart meter 12, a distribution board 14, an electric device 16, a solar cell system 18, a power storage system 20, and a control device 22. The solar cell system 18 includes PV (Photovoltaics) 30, DC (Direct Current) / DC 32 for PV, and DC / AC (Alternating Current) 34 for PV. The power storage system 20 includes an SB (Storage Battery) 40, a DC / DC 42 for SB, a bidirectional DC / AC inverter 44, a control unit 46, and a communication unit 48, and the communication unit 48 includes a transmission unit 50 and a reception unit 52. .. The control unit 46 includes a display unit 60, a reception unit 64, a control unit 66, and a communication unit 68, and the control unit 66 includes a setting unit 62. A heat pump water heater or the like may be installed in the consumer 100, but these are omitted here.

The consumer 100 is, for example, a detached house, an apartment house such as an apartment, a store such as a convenience store or a supermarket, a commercial facility such as a building, or a factory. It is a facility that is located. Here, a house or an apartment house is assumed. The electric power system 10 is provided by an electric power company or the like. A real-life contract has been introduced for electricity charges in electric power companies. Here, the actual quantity contract will be described with reference to FIGS. 2 (a) and 2 (b). 2 (a)-(b) show the outline of the actual quantity contract in the electric power system 10.

FIG. 2A shows a change in the amount of power purchased with respect to time. Here, the amount of power purchased from the power system 10 per unit time (30 minutes) is shown, and the amount of power purchased from 11:30 to 12:30 is the largest. The amount of power purchased from the power system 10 per unit time (30 minutes) is measured all day long, and the largest value in January is the peak of the amount of power purchased from the power system 10 per unit time. Selected as a value. The peak value corresponds to the above-mentioned peak power. FIG. 2B shows the change in the peak value with respect to the moon. Assuming that the present is December, the peak value in December and the maximum value among the peak values in the past 11 months, that is, from January to November, are selected as contract power. Here, the peak value in July is selected as the contract power. Further, the basic charge is calculated by multiplying the contract power by the charge unit price. Return to FIG.

The smart meter 12 is a digital electric energy meter connected to the power system 10. The smart meter 12 can measure the electric energy of the power flow entering from the power system 10 and the electric power amount of the reverse power flow going out to the power system 10. The former corresponds to the amount of power purchased and the latter corresponds to the amount of power sold. The smart meter 12 has a communication function and can communicate with the control device 22, and transmits the measured electric energy to the control device 22. The electric energy may be measured by a device other than the smart meter 12. For example, it may be measured by a distribution board 14 with a measurement function such as Smart Cosmo or an energy measurement unit. Here, the energy measurement unit is a unit for adding a measurement function to the existing distribution board 14. The amount of electric power measured in this way is also transmitted to the control device 22.

The distribution board 14 is connected to the smart meter 12 and is connected to the power system 10 via the smart meter 12. Further, the distribution board 14 connects the electric device 16 and supplies electric power to the electric device 16. The electric device 16 is a device that consumes the electric power supplied from the distribution board 14. The electric device 16 includes a device such as an air conditioner (air conditioner), a television receiver (television), a lighting device, and a refrigerator. Here, one electric device 16 is connected to the distribution board 14, but a plurality of electric devices 16 may be connected to the distribution board 14. The distribution board 14 and the electric device 16 may have a communication function and may be able to communicate with the control device 22.

PV30 is a solar cell and is a renewable energy power generation device. The PV30 utilizes the photovoltaic effect to directly convert light energy into electric power. As the solar cell, a silicon solar cell, a solar cell made of a compound semiconductor or the like, a dye-sensitized type (organic solar cell), or the like is used. The PV 30 is connected to the PV DC / DC 32 and outputs the generated DC power to the PV DC / DC 32.

The PV DC / DC 32 is a DC-DC converter, converts the DC power output from the PV 30 into a DC power having a desired voltage value, and outputs the converted DC power to the PV DC / AC34. The PV DC / DC 32 is composed of, for example, a step-up chopper. The PV DC / DC 32 is MPPT (Maximum Power Point Tracking) controlled so that the output power of the PV 30 is maximized. The PV DC / AC34 is a DC-AC inverter, converts the DC power output from the PV DC / DC 32 into AC power, and outputs the AC power to the distribution board 14. Here, the PV30, the PV DC / DC32, and the PV DC / AC34 may be integrally formed, and even in that case, this is referred to as a solar cell system 18.

The SB 40 is a storage battery capable of charging and discharging electric power, and includes a lithium ion storage battery, a nickel hydrogen storage battery, a lead storage battery, an electric double layer capacitor, a lithium ion capacitor, and the like. The SB 40 is connected to the SB DC / DC 42. The SB DC / DC 42 is a DC-DC converter, and performs conversion between the DC power on the SB 40 side and the DC power on the bidirectional DC / AC inverter 44 side.

The bidirectional DC / AC inverter 44 is connected between the SB DC / DC 42 and the distribution board 14. The bidirectional DC / AC inverter 44 converts the AC power from the distribution board 14 into DC power, and outputs the converted DC power to the SB DC / DC 42. Further, the bidirectional DC / AC inverter 44 converts the DC power from the SB DC / DC 42 into AC power, and outputs the converted AC power to the distribution board 14. That is, the SB 40 is charged and discharged by the bidirectional DC / AC inverter 44. The control of such a bidirectional DC / AC inverter 44 is performed by the control unit 46. A communication unit 48 is connected to the control unit 46. The communication unit 48 can communicate with the control device 22. Further, the SB 40, the SB DC / DC 42, the bidirectional DC / AC inverter 44, and the control unit 46 may be housed in one housing, and even in that case, this is referred to as a power storage system 20. ..

The control device 22 is a computer for executing the processing of the power management system, and has a function as, for example, a HEMS (Home Energy Management System) controller. Therefore, the control device 22 communicates with the smart meter 12, the distribution board 14, the electric device 16, and the power storage system 20 (hereinafter, also collectively referred to as “device”) in the consumer 100 by HAN (Home Area Network). It is possible and controls these devices. The control device 22 may control the interconnection between the equipment installed in the consumer 100 and the power system 10. The control device 22 disconnects between the device and the power system 10 at the time of a power failure, and interconnects the device and the power system 10 at the time of power recovery.

Further, the control device 22 controls the operation of the power storage system 20, for example, discharging and charging. The control by the control device 22 is classified into an economic priority mode, an environment priority mode, and a storage priority mode, and any one of them is executed. Here, the operation of the economic priority mode and the environment priority mode will be described with reference to FIGS. 3 (a)-(c) and 4 (a)-(b). The description of the storage priority mode will be omitted. FIGS. 3 (a)-(c) show an outline of the operation of the economic priority mode by the control device 22. Here, for the sake of clarity, the smart meter 12 and the control device 22 are omitted from the configuration of FIG. FIG. 3A shows the operation in the daytime on a sunny day. (I) Power is generated in the solar cell system 18. (Ii) The generated electric power is supplied to the electric device 16 via the distribution board 14. (Iii) The surplus electric power among the generated electric power is sold to the electric power system 10 via the distribution board 14. (Iv) The power storage system 20 does not discharge during power sale.

FIG. 3B shows the operation in the daytime in the evening and in the cloudy sky. (I) Since the amount of power generation in the solar cell system 18 decreases, the electric power supplied from the solar cell system 18 to the electric device 16 via the distribution board 14 decreases. (Ii) If the electric power supplied to the electric device 16 is insufficient, the power storage system 20 is discharged and the electric power is supplied to the electric device 16 via the distribution board 14. In this way, the electric device 16 can be supplied with electric power from the solar cell system 18 and the power storage system 20. (Iii) When the electric power supplied from the solar cell system 18 and the power storage system 20 is insufficient, the electric power is supplied to the electric device 16 via the distribution board 14 by purchasing the electric power from the electric power system 10.

FIG. 3 (c) shows the operation at night. (I) By purchasing electric power from the electric power system 10, electric power is supplied to the electric device 16 via the distribution board 14. Here, the unit price of the electric energy charge of the electric power system 10 is cheaper than that in the daytime. (Ii) The power storage system 20 executes charging by purchasing power from the power system 10.

4 (a)-(b) show an outline of the operation of the environment priority mode by the control device 22. FIG. 4A shows the operation in the daytime on a sunny day. (I) Power is generated in the solar cell system 18. (Ii) The generated electric power is supplied to the electric device 16 via the distribution board 14. (Iii) The surplus electric power among the generated electric power is charged in the power storage system 20 via the distribution board 14. (Iv) The surplus electric power of the generated electric power is sold to the electric power system 10. Since the operation in the evening and the daytime in the cloudy sky is the same as in FIG. 3 (b), the description thereof will be omitted.

FIG. 4B shows the operation at night. (I) The power storage system 20 is discharged, and electric power is supplied to the electric device 16 via the distribution board 14. (Ii) When the electric power supplied from the power storage system 20 is insufficient, the electric power is supplied to the electric device 16 via the distribution board 14 by purchasing the electric power from the electric power system 10.

Next, the change in the remaining capacity of the power storage system 20 in the economic priority mode will be described. FIG. 5 shows the time variation of the power generated by the solar cell system 18 and the power used by the electric device 16 202. The horizontal axis shows the time. The generated power 200 increases from the morning, reaches the maximum in the daytime, and decreases toward the evening. Further, it is assumed that the power consumption 202 increases around 6:00 to 7:00 and 21:00. Under such circumstances, the power storage system 20 is charged until 6 o'clock, so that the remaining capacity increases. Further, since the power storage system 20 discharges after 6 o'clock as the power consumption 202 increases, the remaining capacity decreases. In the daytime when the generated power 200 is sold, the power storage system 20 stops discharging, so that the remaining capacity is maintained.

Since the power storage system 20 discharges in the evening after 18:00, the remaining capacity decreases and becomes zero at about 20:30. Even if the power consumption 202 increases at 21:00, the power storage system 20 cannot be discharged, and power is supplied to the electric device 16 by purchasing power from the power system 10. As a result, the amount of power purchased from the power system 10 from 20:30 to 21:00 or from 21:00 to 21:30 may increase, and the peak value may increase. In order to suppress the increase in the peak value, the occurrence of such a situation should be prevented. Return to FIG.

The display unit 60 receives the power control setting screen (hereinafter referred to as “power control setting screen”) from the setting unit 62 and displays the power control setting screen. 6 (a)-(c) show a screen displayed on the display unit 60. FIG. 6A shows a power control setting screen. Here, the "30-minute unit peak power" button corresponds to the button related to the setting for suppressing the increase in the peak value described above. When the display unit 60 is a touch panel, the user selects the button by touching the "30-minute unit peak power" button. 6 (b)-(c) will be described later, and the process returns to FIG. When the control device 22 is provided with an operation unit such as a button, the user may select the "30-minute unit peak power" button by operating the operation unit.

The reception unit 64 receives the operation of selection by the user. Here, the selection operation of the "30-minute unit peak power" button is accepted. When the reception unit 64 receives the selection operation of the "30-minute unit peak power" button, the setting unit 62 generates a "30-minute unit target value" setting screen (hereinafter referred to as "target value setting screen"). It is displayed on the display unit 60. The display unit 60 displays the target value setting screen. FIG. 6B shows a target value setting screen. The notification setting indicates the setting for the above-mentioned notification control. When the user selects the "change" button of the notification setting, the setting unit 62 can set the notification control threshold value when the notification control is turned on / off and turned on via the reception unit 64. The device setting indicates the setting for the device operation control described above. When the user selects the "Details / Change" button of the notification setting, the threshold value for device operation can be set in the setting unit 62 via the reception unit 64 with or without device operation control. .. Further, the content of the operation, for example, on / off, temperature change, and air volume change may be set.

The storage battery assist indicates the setting for the storage battery assist control described above. When the user selects the "battery assist control" button in the notification setting, the setting unit 62 generates a screen for "battery assist setting" (hereinafter referred to as "battery assist setting screen") and displays it on the display unit 60. .. The display unit 60 displays the storage battery assist setting screen. FIG. 6C shows a storage battery assist setting screen. The setting unit 62 can be set with or without the storage battery assist control via the reception unit 64. The storage battery assist control assists the power supply to the electric device 16 in the consumer 100 by discharging the power storage system 20 when the amount of power purchased from the power system 10 per unit time (30 minutes) exceeds the set value. It is a control to do.

Further, the storage battery assist setting screen shows the setting value when the storage battery assist control is executed. This set value is a value obtained by subtracting a predetermined value from the target value for the peak value of the amount of power purchased from the power system 10 per unit time (30 minutes). The set value may be a fixed value or a value that can be set by the user. In the latter case, the set value may be directly set, or the target value and the predetermined value may be set. Therefore, the setting unit 62 sets whether or not to execute the storage battery assist control based on the operation received by the reception unit 64.

Further, the storage battery assist setting screen shows the capacity for the storage battery assist. The capacity for assisting the storage battery is an assist capacity that should be secured by the power storage system 20 exclusively for assist for lowering the peak value. The setting unit 62 sets the assist capacity by the operation via the reception unit 64. FIG. 7 shows the configuration of the storage capacity in the SB 40. The storage capacity in the SB 40 is changed by discharging or charging. Here, a part of the storage capacity is secured as the assist capacity. The assist capacity is smaller than the storage capacity of the SB40. Further, the remaining capacity is defined as the storage capacity other than the assist capacity. The remaining capacity is used in the discharge of the power storage system 20 in FIGS. 3 (a)-(c) and 4 (a)-(b). Here, the assist capacity is secured with priority over the remaining capacity. Return to FIG.

The communication unit 68 can communicate with each device of the consumer 100, a smart meter 12, a distribution board 14, an electric device 16, and a power storage system 20. The communication unit 68 receives from the smart meter 12 the amount of power purchased from the power system 10 per unit time (30 minutes). When the smart meter 12 is not included in the consumer 100, the communication unit 68 may receive the amount of power purchased from the power system 10 per unit time (30 minutes) from the distribution board 14. The communication unit 68 outputs the amount of power purchased from the power system 10 per unit time (30 minutes) to the control unit 66.

The control unit 66 receives from the communication unit 68 the amount of power purchased from the power system 10 per unit time (30 minutes). When the notification control is set to ON in the setting unit 62, the control unit 66 compares the received power purchase power amount with the notification threshold value, and when the power purchase power amount exceeds the notification threshold value. Run the notification. The notification is given by the screen display on the display unit 60, or by voice from a speaker (not shown).

When the device operation control is set to "ON" in the setting unit 62, the control unit 66 compares the received power purchase power amount with the device operation threshold value. The control unit 66 determines the operation of the electric device 16 when the amount of power purchased exceeds the threshold value for operating the device. The operation of the electric device 16 is an operation in which the power consumption of the electric device 16 is reduced. When the electric device 16 is an air conditioner, the operation of the electric device 16 corresponds to turning off the air conditioner or changing the set temperature. The communication unit 68 transmits a command (hereinafter referred to as “operation command”) indicating the operation of the electric device 16 determined by the control unit 66 to the electric device 16. The electric device 16 executes an operation according to an operation command received from the control device 22.

When the storage battery assist control is set to "Yes" in the setting unit 62, the control unit 66 outputs the assist capacity to the communication unit 68 if the assist capacity is set in the setting unit 62. The communication unit 68 transmits the assist capacity to the power storage system 20. Further, when the storage battery assist control is set to "Yes" in the setting unit 62, the control unit 66 compares the amount of power purchased and the set value. The control unit 66 outputs an assist command instructing discharge to the communication unit 68 when the amount of power purchased exceeds the set value. The communication unit 68 transmits an assist command to the power storage system 20.

When the receiving unit 52 of the power storage system 20 receives the assist capacity from the control device 22, the receiving unit 52 outputs the assist capacity to the control unit 46, and the control unit 46 sets the assist capacity. Further, when the receiving unit 52 receives the assist command from the control device 22, the receiving unit 52 outputs the assist command to the control unit 46. When the receiving unit 52 does not receive the assist command, the control unit 46 causes the bidirectional DC / AC inverter 44 to discharge power so as to supply electric power to the electric device 16 within the range of the remaining capacity. This corresponds to the discharge of the power storage system 20 in FIGS. 3 (a)-(c) and 4 (a)-(b). Since the control at this time is a known technique, the description thereof is omitted here. By such a process, the assist capacity is secured even if the discharge is performed. On the other hand, when the receiving unit 52 receives the assist command, the control unit 46 discharges the bidirectional DC / AC inverter 44 so as to supply electric power to the electric device 16 within the range of the storage capacity including the assist capacity. Let me. The transmission unit 50 may appropriately transmit information on the storage capacity, the remaining capacity, and the assist capacity of the SB 40 to the control device 22.

The subject of the device, system, or method in the present disclosure comprises a computer. By executing the program by this computer, the function of the subject of the device, system, or method in the present disclosure is realized. A computer has a processor that operates according to a program as a main hardware configuration. The type of processor does not matter as long as the function can be realized by executing the program. The processor is composed of one or more electronic circuits including a semiconductor integrated circuit (IC) or an LSI (Large Scale Integration). A plurality of electronic circuits may be integrated on one chip or may be provided on a plurality of chips. A plurality of chips may be integrated into one device, or may be provided in a plurality of devices. The program is recorded on a non-temporary recording medium such as a computer-readable ROM, optical disc, or hard disk drive. The program may be stored in a recording medium in advance, or may be supplied to the recording medium via a wide area communication network including the Internet or the like.

The operation of the control device 22 with the above configuration will be described. FIG. 8 is a flowchart showing a command procedure by the control device 22. When the amount of power purchased in the control unit 66 exceeds the set value (Y in S10), the communication unit 68 transmits an assist command to the power storage system 20 (S12). If the amount of power purchased in the control unit 66 does not exceed the set value (N in S10), step 12 is skipped.

The operation of the power storage system 20 with the above configuration will be described. FIG. 9 is a flowchart showing a discharge procedure by the power storage system 20. When the receiving unit 52 receives the assist command (Y in S50), the control unit 46 supplies electric power within the range of the storage capacity (S52). When the receiving unit 52 has not received the assist command (N in S50), the control unit 46 supplies power within the range of the remaining capacity (S54).

According to this embodiment, it is set whether or not to assist the power supply to the electric device 16 in the consumer 100 when the amount of power purchased exceeds the set value by the operation by the user, so that per unit time. The setting for lowering the peak value of the amount of power purchased from the power system 10 can be easily set. Further, when the amount of power purchased exceeds the set value, the power storage system 20 is discharged by transmitting an assist command, so that an increase in the peak value of the amount of power purchased can be suppressed.

In addition, since it is set whether or not to execute the notification when the power purchase power amount exceeds the notification threshold value by the operation by the user, the peak value of the power purchase power amount from the power system 10 per unit time is lowered. Can be easily set for. Further, since it is set whether or not to execute the operation of the electric device 16 when the amount of power purchased exceeds the threshold value for operating the device by the operation by the user, the amount of power purchased from the power system 10 per unit time. You can easily set to lower the peak value of. Moreover, since the assist capacity is set, the assist capacity can be secured. Further, since the assist capacity is secured, it is possible to suppress the occurrence of a situation in which discharge cannot be executed when the peak value should be suppressed. Moreover, since the peak value is suppressed, the increase in the basic charge can be suppressed.

Further, since the electric power is supplied to the electric device 16 within the range of the remaining capacity when the assist command is not received, it is possible to secure the electric power for lowering the peak value of the electric power purchased from the electric power system 10 per unit time. .. Further, since the power for lowering the peak value of the amount of power purchased from the power system 10 per unit time is secured, it is possible to suppress the occurrence of a situation in which discharge cannot be executed when the peak value should be suppressed. Further, when the receiving unit 52 receives the assist command, the electric power is supplied to the electric device 16 within the range of the storage capacity including the assist capacity, so that the peak value can be suppressed.

The outline of one aspect of the present invention is as follows. The control device 22 of a certain aspect of the present invention is a control device 22 that is connected to the power system 10 and controls the power storage system 20 installed in the consumer 100, and is a reception unit 64 that receives an operation by a user and a reception unit. Based on the operation received in the unit 64, the amount of power purchased from the power system 10 per unit time is set by subtracting a predetermined value from the target value for the peak value of the amount of power purchased from the power system 10 per unit time. When the value is exceeded, the setting unit 62 that sets whether or not to assist the power supply to the electric device 16 in the consumer 100 by the discharge of the power storage system 20, and the setting unit 62 that sets to assist. A communication unit 68 that transmits an assist command instructing discharge to the power storage system 20 when the amount of power purchased from the power system 10 per unit time exceeds a set value.

The setting unit 62 sets an assist capacity that is the assist capacity that the power storage system 20 should secure exclusively for assist and is smaller than the power storage capacity of the power storage system 20, and the communication unit 68 sets the assist capacity set by the setting unit 62. The capacity is transmitted to the power storage system 20.

When the setting unit 62 is set to assist, the setting unit 62 automatically adjusts the assist capacity based on the capacity of the past month in which the amount of power purchased from the power system 10 per unit time exceeds the set value. Set to.

In the power storage system 20 connected to the control device 22, the receiving unit 52 that receives the assist capacity and the assist command set by the setting unit 62 from the control device 22, and the receiving unit 52 have not received the assist command. In addition, power is supplied to the electric device 16 within the range of the remaining storage capacity while leaving the amount of power corresponding to the assist capacity, and when the receiving unit 52 receives the assist command, the storage capacity including the assist capacity A control unit 46 that supplies electric power to the electric device 16 may be provided.

The present invention has been described above based on the examples. This embodiment is an example, and it is understood by those skilled in the art that various modifications are possible for each of these components or combinations of each processing process, and that such modifications are also within the scope of the present invention. ..

In this embodiment, the assist capacity is set in the setting unit 62 based on the operation received from the user by the reception unit 64. That is, the assist capacity is set manually. However, the present invention is not limited to this, and for example, the setting unit 62 may automatically set the assist capacity. Specifically, the setting unit 62 determines the assist capacity based on the capacity of the past month in which the amount of power purchased from the power system 10 per unit time exceeds the set value when it is set to assist. Set. At that time, the value obtained by subtracting the set value from the capacity of the past month in which the amount of power purchased from the power system 10 per unit time exceeds the set value is defined as the assist capacity. According to this embodiment, it is possible to eliminate the need for user setting.

10 power system, 12 smart meter, 14 distribution board, 16 electrical equipment, 18 solar cell system, 20 power storage system, 22 control device, 30 PV, 32 PV DC / DC, 34 PV DC / AC, 40 SB, 42 SB DC / DC, 44 Bidirectional DC / AC Inverter, 46 Control Unit, 48 Communication Unit, 50 Transmitter Unit, 52 Receiver Unit, 60 Display Unit, 62 Setting Unit, 64 Reception Unit, 66 Control Unit, 68 Communication Unit , 100 consumers.

Claims (3)

A control device that is connected to the power system and controls the power storage system installed in the consumer.
The reception department that accepts operations by users,
Based on the operation received by the reception unit, the amount of power purchased from the power system per unit time is obtained by subtracting a predetermined value from the target value for the peak value of the amount of power purchased from the power system per unit time. When the set value is exceeded, a setting unit that sets whether or not to assist the power supply to the electric equipment in the consumer by discharging the power storage system, and a setting unit.
It is provided with a communication unit that transmits an assist command instructing discharge to the power storage system when the amount of power purchased from the power system per unit time exceeds the set value when it is set to assist in the setting unit. ,
The setting unit sets an assist capacity that is the assist capacity that the power storage system should secure exclusively for assist and is smaller than the power storage capacity of the power storage system.
The communication unit transmits the assist capacity set by the setting unit to the power storage system, and the communication unit transmits the assist capacity set by the setting unit to the power storage system.
When the setting unit is set to assist, the setting unit obtains the assist capacity based on the capacity of the past month in which the amount of power purchased from the power system per unit time exceeds the set value. Set automatically,
Control device. A power storage system connected to the control device according to claim 1 .
A receiving unit that receives the assist capacity and the assist command set in the setting unit from the control device, and
When the receiving unit has not received the assist command, power is supplied to the electric device within the range of the remaining storage capacity while leaving the amount of power corresponding to the assist capacity, and the receiving unit issues the assist command. A control unit that supplies electric power to the electric device within the range of the storage capacity including the assist capacity when received.
A power storage system equipped with. A program in a control device that is connected to an electric power system and controls a power storage system installed in a consumer.
Steps to accept user operations and
Based on the received operation, the amount of power purchased from the power system per unit time exceeds the set value obtained by subtracting the predetermined value from the target value for the peak value of the amount of power purchased from the power system per unit time. In that case, a step of setting whether or not to assist the power supply to the electric device in the consumer by the discharge of the power storage system, and
When the amount of power purchased from the power system per unit time exceeds the set value when assist is set, an assist command instructing discharge is transmitted to the power storage system.
A step of setting an assist capacity that is the assist capacity that the power storage system should secure exclusively for assist and that is smaller than the power storage capacity of the power storage system.
A step of transmitting the set assist capacity to the power storage system is provided.
In the step of setting the assist capacity, when the assist capacity is set, the assist capacity is set based on the capacity of the past month in which the amount of power purchased from the power system per unit time exceeds the set value. A program that lets your computer perform automatic settings .

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