JP2024049749A - POWER CONTROL DEVICE, SYSTEM AND CONTROL METHOD - Google Patents

Abstract

[Problem] To provide a power control device, system, and control method that can appropriately control the charging and discharging of a storage battery in response to various power rate plans offered by electricity retailers. [Solution] The power control device includes an acquisition unit that acquires information about a plurality of power rate plans for commercial power, an identification unit that identifies one plan from the plurality of power rate plans, a setting unit that sets a standard for controlling the charging and discharging of the storage battery based on information about the identified plan, and a control unit that controls the charging and discharging of the storage battery based on the current time and the standard. [Selected Figure] Figure 4

Description

This disclosure relates to a power control device, a system, and a control method.

A hybrid power supply system is known that includes a photovoltaic power generation system and a power storage system that stores in a storage battery the power generated in excess of the power supplied to the load (i.e., surplus power). The hybrid power supply system is capable of being interconnected with the grid, for example, by supplying the generated power to the grid according to the power generation state of the photovoltaic power generation system.

In addition, by utilizing a storage battery device (hereinafter referred to as a stationary storage battery device) installed in a house or an on-board storage battery mounted on a vehicle, not only can electricity be supplied to the home as an emergency source during a power outage, but electricity bills can also be reduced by appropriately controlling the charging and discharging of the storage battery. A power conversion system that uses an on-board storage battery to supply power to electrical appliances in the home is known as V2H (Vehicle to Home). The storage battery is charged with surplus power from the solar power generation system and commercial power during late-night hours when electricity rates are low, and the storage battery is discharged during hours when the solar power generation system is not generating electricity and electricity rates are high to supply power to electrical appliances in the home, thereby reducing electricity bills.

The following Patent Document 1 discloses a system that is equipped with a power conditioner to which an on-board storage battery, a fixed storage battery, and a solar power generation device are connected, and is connected to a commercial power source. The power control device of this system controls power consumption by setting the operating conditions of each electrical device based on setting information indicating multiple energy saving modes. Each energy saving mode is a predefined combination of operating conditions for each electrical device in the house. For example, the power control device changes the operating conditions of each electrical device based on the power supplied from the power conditioner and the electricity rate for power supplied from the commercial power source, so as to cover the power consumed by the electrical devices in the house while the on-board storage battery is not connected, and to suppress power consumption without impairing the comfort of the people living in the house.

Regarding the charging and discharging of storage batteries connected to a commercial power grid, various modes (e.g., night charging mode, solar power generation charging mode, and timer mode) have been proposed to reduce the charging costs of the storage batteries. In the night charging mode, the storage battery is charged by commercial power at night when commercial electricity rates are low, and the storage battery is discharged to supply power to the load during the day when electricity rates are high. If a solar power generation system is provided, in the solar power generation charging mode, the storage battery is charged only by surplus power from the solar power generation system, and power is supplied from the storage battery in the evening and at night when the solar power generation system is not generating power. In addition, in the timer mode, the charging time and power supply time of the storage battery in a day can be set as desired.

Patent Document 2 below discloses a system that can charge an on-board battery using power generated by a solar power generation device and commercial power from a grid. In this system, the user can select whether to charge the on-board battery using only the generated power, using both the generated power and commercial power, or using only commercial power, and charging can be performed with priority given to charging costs.

JP 2018-121449 A JP 2015-228714 A

The night-time charging mode and solar power generation charging mode proposed so far do not take into account the various electricity rate plans offered by retail electricity suppliers. Therefore, there is a problem that the storage battery is not appropriately charged and discharged depending on the electricity rate plan to which each household has a contract. In addition, there is a problem with the timer mode, in that the settings are complicated. Neither Patent Document 1 nor Patent Document 2 can solve these problems.

Therefore, the present disclosure aims to provide a power control device, system, and control method that can appropriately control the charging and discharging of storage batteries in accordance with the various electricity rate plans offered by retail electricity suppliers.

A power control device according to an aspect of the present disclosure includes an acquisition unit that acquires information relating to a plurality of commercial power rate plans, an identification unit that identifies one plan from the plurality of power rate plans, a setting unit that sets a standard for controlling charging and discharging of the storage battery based on information relating to the identified plan, and a control unit that controls charging and discharging of the storage battery based on the current time and the standard.

This disclosure provides a power control device, system, and control method that can appropriately control the charging and discharging of storage batteries in accordance with the various electricity rate plans offered by retail electricity suppliers.

FIG. 1 is a block diagram showing a configuration of a power control system according to an embodiment of the present disclosure. FIG. 2 is a block diagram showing a configuration of the controller shown in FIG. FIG. 3 is a block diagram showing a configuration of the power control device shown in FIG. FIG. 4 is a block diagram showing a functional configuration related to charge/discharge control of the storage battery in the power control system shown in FIG. FIG. 5 is a graph showing electricity rate plans. FIG. 6 is a graph showing another electricity rate plan different from that shown in FIG. FIG. 7 shows a screen for designating an electricity rate plan. FIG. 8 shows a screen for specifying a target value for the remaining battery charge. FIG. 9 is a flowchart showing the operation of the power control device. FIG. 10 is a flowchart showing the operation of the power control device, which is different from that shown in FIG.

[Description of the embodiments of the present disclosure]
The contents of the embodiments of the present disclosure will be listed and described below. At least some of the embodiments described below may be combined in any combination.

(1) A power control device according to a first aspect of the present disclosure includes an acquisition unit that acquires information relating to multiple power rate plans for commercial power, an identification unit that identifies one plan from the multiple power rate plans, a setting unit that sets a standard for control of charging and discharging the storage battery based on information relating to the identified plan, and a control unit that controls charging and discharging the storage battery based on the current time and the standard. This makes it possible to appropriately control charging and discharging the storage battery in response to various power rate plans offered by retail electricity suppliers. For example, a user can easily realize appropriate control of charging and discharging the storage battery in response to the power rate plan to which the user has subscribed.

(2) In (1) above, the setting unit can set, as standards, a first time period in which the purchase price of commercial electricity is a first unit price and a second time period in which the purchase price is a second unit price, the first unit price being the highest power purchase price included in the plan and the second unit price being the cheapest power purchase price included in the plan, and the control unit can discharge the storage battery if the current time falls within the first time period, and can charge the storage battery with commercial electricity if the current time falls within the second time period. This can reduce the electricity bill required to charge the storage battery.

(3) In the above (2), when discharging the storage battery, the control unit may discharge the storage battery until the charge amount of the storage battery reaches a lower limit value or until the current time does not belong to the first time zone. This makes it possible to prevent the storage battery from being discharged more than necessary.

(4) In any one of (1) to (3) above, the power control device may further include a target value setting unit that sets a target value for the SOC (State of Charge) that represents the charge amount of the storage battery, and the control unit may charge the storage battery to the target value when charging the storage battery with commercial power. This makes it possible to prevent the storage battery from being charged with commercial power more than necessary, thereby reducing electricity charges.

(5) In the above (4), the target value may be specified by the user. This allows the user to directly set an appropriate target value taking into account the amount of power consumption planned for the future (e.g., the next day) and the weather that will affect the amount of power generated by the solar power generation system, and the storage battery is appropriately charged.

(6) In the above (4), the target value setting unit may set the target value according to the planned power consumption, which represents the planned value of the amount of power consumed by discharging the storage battery. In this way, an appropriate target value is set according to the planned power consumption in the future (e.g., the next day), and the storage battery is appropriately charged.

(7) In the above (6), the planned power consumption may be specified by the user. In this way, the user only needs to specify the planned power consumption in the future (e.g., the next day), and an appropriate target value is set and the storage battery is appropriately charged.

(8) In the above (6), the planned power consumption may be set based on the operation history of the power control device. This allows the planned power consumption for the future (e.g., the next day) to be properly calculated, and an appropriate target value to be automatically set according to the calculated planned power consumption.

(9) In any one of (1) to (8) above, the acquisition unit may acquire information on a plurality of electricity rate plans at a predetermined time interval. This allows electricity rate plans to be appropriately presented to the user, and allows the user to efficiently set the electricity rate plan to which he or she has subscribed.

(10) In any one of (1) to (9) above, the identification unit may identify the plan based on the region in which the storage battery is installed. This allows the power rate plan to be appropriately presented to the user, and the user can easily set the power rate plan to which he or she has signed up.

(11) In the above (10), the power control device further includes an operation unit, and the identification unit, in response to a region being specified by the operation unit, may present one or more power rate plans corresponding to the specified region, and identify the power rate plan selected by the operation unit as the plan from among the presented one or more power rate plans. This allows the user to more easily set the power rate plan to which he or she has a contract.

(12) A system according to a second aspect of the present disclosure includes a storage battery and any one of the power control devices (1) to (11) above, and the power control device controls the charging and discharging of the storage battery. This allows the system to respond to various electricity rate plans offered by retail electricity suppliers and appropriately control the charging and discharging of the storage battery. For example, a user can easily realize appropriate control of the charging and discharging of the storage battery according to the electricity rate plan to which the user has subscribed.

(13) A control method according to a third aspect of the present disclosure includes an acquisition step of acquiring information relating to a plurality of electricity rate plans for commercial electricity, an identification step of identifying one plan from the plurality of electricity rate plans, a setting step of setting a standard for control of charging and discharging the storage battery based on information relating to the identified plan, and a control step of controlling charging and discharging the storage battery based on the current time and the standard. This makes it possible to appropriately control charging and discharging the storage battery in response to various electricity rate plans offered by retail electricity suppliers. For example, a user can easily realize appropriate control of charging and discharging the storage battery in response to the electricity rate plan to which the user has subscribed.

[Details of the embodiment of the present disclosure]
In the following embodiments, the same parts are denoted by the same reference numerals, and their names and functions are also the same, so detailed description thereof will not be repeated.

(System configuration)
Referring to FIG. 1, a power control system 100 according to an embodiment of the present disclosure includes a power control device 102, a stationary storage battery device 104, a solar power generation system 106, and a controller 108. The power control device 102 includes a power measurement circuit 110, a control circuit 112, and a charge/discharge circuit 114. The stationary storage battery device 104 includes a control circuit 120 and a storage battery 122. The power control device 102 and the stationary storage battery device 104 are installed outdoors of a house 900. The solar power generation system 106 includes a photovoltaic (PV) panel 130 and a power conditioning system (PCS) 132. The PV panel 130 is installed on the roof of the house 900, and the PCS 132 is installed indoors of the house 900. The controller 108 is installed indoors of the house 900.

The storage battery 122 of the stationary storage battery device 104 is a rechargeable storage battery such as a lithium ion secondary battery. The storage battery 122 functions as a DC power source. The storage battery 122 is connected to a control circuit 120. The control circuit 120 has a function of calculating the current charge amount (i.e., SOC) of the storage battery 122, a function of preventing overcharging and overdischarging of the storage battery 122, and the like. The control circuit 120 is, for example, a BMS (Battery Management System). The storage battery 122 is connected to the PCS 132, the commercial power system 902, and the load 906 via the charge/discharge circuit 114 of the power control device 102. The load 906 is an electrical device (such as a home appliance) in the house 900. The commercial power system 902 is a system for supplying commercial power from a retail electricity supplier. As a result, the storage battery 122 can supply power to the load 906 or the commercial power grid 902 by discharging, and can be charged by power generated by the PV panel 130 or commercial power from the commercial power grid 902. The control circuit 120 manages the state of the storage battery 122. The storage battery 122 may be an on-board storage battery. That is, the stationary storage battery device 104 may be replaced by a vehicle such as an EV (Electric Vehicle) or a PHEV (Plug-in Hybrid Electric Vehicle) having a V2H function.

The PV panel 130 of the solar power generation system 106 is a flat surface on which multiple solar cells connected in series are arranged and sealed using tempered glass or the like. The PV panel 130 functions as a DC power source. The PV panel 130 is connected to the commercial power system 902 and the load 906 via the PCS 132. The PCS 132 functions as a DC/AC converter, and converts the DC power generated by the PV panel 130 into AC power and supplies it to the load 906. The PCS 132 can also supply surplus power from the PV panel 130 to the commercial power system 902 (i.e., selling the power).

The charge/discharge circuit 114 of the power control device 102 functions as a bidirectional DC/AC converter. The charge/discharge circuit 114 is connected to the storage battery 122, converts the DC power output from the storage battery 122 into AC power, and supplies it to the load 906. The charge/discharge circuit 114 is connected to the commercial power system 902, converts the AC power supplied from the commercial power system 902 into DC power, and supplies it to the storage battery 122. This charges the storage battery 122 with commercial power. In addition, when AC power generated by the solar power generation system 106 and converted by the PCS 132 is input, the charge/discharge circuit 114 generates DC power for charging the storage battery 122 and supplies it to the storage battery 122. In other words, the storage battery 122 is charged with the power generated by the solar power generation system 106. If the PCS 132 is capable of outputting DC power and the charge/discharge circuit 114 has a DC/DC converter function, the storage battery 122 can be configured to be charged with DC power generated by the PV panel 130.

The power measurement circuit 110 of the power control device 102 measures the power supplied from the commercial power system 902 using the power sensor 140, and measures the power output from the PCS 132 (i.e., the power generated by the solar power generation system 106) using the power sensor 142. The power measurement circuit 110 is connected to the control circuit 112 and outputs the measured value (i.e., the power value) to the control circuit 112. This allows the control circuit 112 to determine whether or not there is surplus power in the power generated by the solar power generation system 106. That is, if the power generated by the solar power generation system 106 is W1 and the power supplied from the commercial power system 902 is W2, and W1>0 and W2=0, the control circuit 112 determines that there is surplus power. Otherwise, the control circuit 112 determines that there is no surplus power.

The control circuit 112 is connected to the charge/discharge circuit 114. The control circuit 112 controls the operation of the charge/discharge circuit 114 based on the measured value input from the power measurement circuit 110. As a result, as described above, it is possible to supply power to the load 906 by discharging the storage battery 122, and to charge the storage battery 122 by the solar power generation system 106 or the commercial power system 902. In addition, if there is surplus power in the power generated by the solar power generation system 106, the control circuit 112 can stop the charge/discharge circuit 114 and sell the power to the commercial power system 902. The control circuit 112 is also connected to the controller 108 and the control circuit 120. The control circuit 112 obtains information (e.g., a power rate plan) from the controller 108 and obtains the charge amount (i.e., SOC) of the storage battery 122 via the control circuit 120. The control circuit 112 uses the obtained information to control the charge/discharge of the storage battery 122.

The controller 108 is connected to a communication network 904 by wireless communication or wired communication. The communication network 904 is, for example, the Internet. A server computer (not shown; hereinafter simply referred to as a server) of an electricity retailer is connected to the communication network 904. The server of the electricity retailer publishes information on the electricity rate plans offered by the electricity retailer. The controller 108 accesses the server to obtain the information on the electricity rate plans.

(Controller configuration)
2, the controller 108 includes a CPU (Central Processing Unit) 200, a memory 202, a communication unit 204, an operation unit 206, and a display unit 208. The CPU 200 controls each unit to realize the functions of the controller 108. The memory 202 is configured of a rewritable non-volatile semiconductor memory. The memory 202 may include a large-capacity storage device such as a HDD (Hard Disk Drive). A program executed by the CPU 200 is stored in the memory 202, and the CPU 200 reads and executes the program to realize various functions of the controller 108, which will be described later. The memory 202 is also used as a video memory.

The communication unit 204 connects to a communication network 904 such as the Internet by wired or wireless communication. The communication unit 204 also has a function of communicating with the power control device 102 (specifically, the control circuit 112) by wired or wireless communication. As a result, the communication unit 204, under the control of the CPU 200, acquires information on the power rate plan from the communication network 904 as described above. The information on the power rate plan includes, for example, information identifying the area in which the power rate plan is offered, information identifying the retail electricity supplier, and information on the power rate plan itself. The information on the power rate plan includes information indicating the power rate unit price and information indicating the time period in which the power rate unit price applies. The CPU 200 stores the information on the multiple power rate plans acquired via the communication unit 204 in the memory 202.

The operation unit 206 is a touch panel or the like, and accepts user operations. The display unit 208 is a display device such as a liquid crystal display, and reads and displays an image from the memory 202. The operation unit 206 and the display unit 208 may be formed integrally. The operation unit 206 and the display unit 208 may be, for example, a touch panel display in which the operation unit 206 is arranged on the display surface of the display unit 208. As a result, the display unit 208 presents a plurality of power rate plans, and the user can operate the operation unit 206 to select the power rate plan to which the user has a contract from among the presented power rate plans. Information regarding the operation of the operation unit 206 (for example, touched position information) is output from the operation unit 206 to the CPU 200. The CPU 200 can identify the operation on the image displayed on the display unit 208 based on the input position information, and identify the power rate plan selected by the user. The CPU 200 stores information identifying the power rate plan selected by the user in the memory 202. Additionally, the CPU 200 transmits information about the electricity rate plan selected by the user to the power control device 102 (specifically, the control circuit 112) via the communication unit 204.

(Configuration of control circuit 112)
3, the control circuit 112 of the power control device 102 includes a CPU 220, a memory 222, a communication unit 224, and a timer 226. The CPU 220 controls each unit to realize the function of the control circuit 112. The memory 222 is composed of a rewritable non-volatile semiconductor memory. The memory 222 may include a large-capacity storage device such as a HDD. The memory 222 stores a program to be executed by the CPU 220, and the CPU 220 reads and executes the program to realize various functions of the control circuit 112, which will be described later. The timer 226 outputs information indicating the current time (hereinafter simply referred to as the current time) to the CPU 220 upon receiving a request from the CPU 220.

The communication unit 224 communicates with the controller 108 and the stationary storage battery device 104 by wired communication or wireless communication. As a result, the CPU 220 acquires information (i.e., information on the power rate plan) transmitted from the controller 108 via the communication unit 224, and stores the acquired information in the memory 222. The CPU 220 also acquires information (i.e., the SOC of the storage battery 122) transmitted from the stationary storage battery device 104 (specifically, the control circuit 120) via the communication unit 224, and stores the acquired information in the memory 222. The communication unit 224 also communicates with the power measurement circuit 110 and the charge/discharge circuit 114. The CPU 220 acquires a measured value (i.e., a power value) from the power measurement circuit 110 via the communication unit 224, and stores the acquired measured value in the memory 222. The CPU 220 instructs the charge/discharge circuit 114 to perform a charging operation or a discharging operation via the communication unit 224.

(Functional configuration)
Functions relating to charge/discharge control of the storage battery 122 in the power control system 100 will be described with reference to Fig. 4. The power control system 100 includes an acquisition unit 150, a determination unit 152, a target value setting unit 154, a setting unit 156, and a charge/discharge control unit 158. The acquisition unit 150, the determination unit 152, and the target value setting unit 154 are realized by the controller 108. The setting unit 156 and the charge/discharge control unit 158 are realized by the power control device 102.

The acquisition unit 150 acquires multiple electricity rate plans from the communication network 904 as described above. The acquisition unit 150 outputs the acquired multiple electricity rate plans to the identification unit 152.

As described above, the information of each electricity rate plan includes information identifying the region in which the electricity rate plan is offered, information identifying the retail electricity supplier, and information on the electricity rate plan itself. The information on the electricity rate plan itself is expressed, for example, as a set of a time period (identified, for example, by a start time and an end time) and an electricity rate unit price. An example of an electricity rate plan is shown in Figures 5 and 6. The vertical axis represents the electricity rate unit price (unit: yen/kWh), and the horizontal axis represents the time of day. In the case of the electricity rate plan shown in Figure 5, the information on the electricity rate plan itself includes, for example, (0:00, 6:00, 20 yen), (6:00, 10:00, 30 yen), (10:00, 16:00, 22:00, 30 yen), and (22:00, 24:00, 20 yen). Since the end time is the same as the start time of the next time period, the information in the electricity rate plan itself may include (0:00, 20 yen), (6:00, 30 yen), (10:00, 15 yen), (16:00, 30 yen), and (22:00, 20 yen) without including the end time.

Similarly, in the case of the electricity rate plan shown in FIG. 6, the information of the electricity rate plan itself includes, for example, (0:00, 6:00, 20 yen), (6:00, 8:00, 30 yen), (8:00, 18:00, 40 yen), (18:00, 22:00, 30 yen), and (22:00, 24:00, 20 yen). The information of the electricity rate plan itself may also include (0:00, 20 yen), (6:00, 30 yen), (8:00, 40 yen), (18:00, 30 yen), and (22:00, 20 yen) without including the end time. The electricity rate plan shown in FIG. 5 may be offered, for example, in spring or autumn. The electricity rate plan shown in FIG. 6 may be offered, for example, in summer or winter when electricity consumption is concentrated during the daytime.

The identification unit 152 in FIG. 4 presents multiple electricity rate plans input from the acquisition unit 150, and identifies the electricity rate plan selected by the user as the electricity rate plan to be used for charge/discharge control of the storage battery 122. The identification unit 152 outputs information on the identified electricity rate plan to the setting unit 156.

With reference to FIG. 7, a method in which the identification unit 152 identifies the electricity rate plan to which the user has signed up will be specifically described. The identification unit 152 displays, for example, a screen 240 on the display unit 208. The screen 240 includes a setting item display area 242, a setting content display area 244, a pull-down key display area 246, a setting key 250, and a cancel key 252. The setting item display area 242 displays the name of the item to be set. In FIG. 7, the names of three items are shown. "Area of residence" means the area in which the electricity rate plan is provided, and "Electric power company" means the retail electricity supplier. The pull-down key display area 246 displays pull-down keys corresponding to each item in the setting item display area 242. The operation of each pull-down key is performed by the operation unit 206. When the pull-down key is operated, a pull-down menu is displayed. When one option is selected from the pull-down menu, the selected option is displayed in the setting content display area 244. FIG. 7 shows a state in which "Kansai" and "A Electric Power" are selected in order, the pull-down key corresponding to "electricity rate plan" is operated, and "Plan B" is selected as the electric power rate plan to which the user has a contract from among multiple options included in the pull-down menu 248. In the setting content display area 244, the selected "Plan B" is displayed in the portion corresponding to "electricity rate plan". The pull-down menu 248 is then erased. When the setting key 250 is operated, the content displayed in the setting content display area 244 is set. That is, the identification unit 152 identifies the content displayed in the setting content display area 244 as the electric power rate plan to be used for charge/discharge control of the storage battery 122. When the cancel key 252 is operated, the content displayed in the setting content display area 244 is discarded, and the screen 240 returns to a state in which no setting item is selected (that is, the setting content display area 244 is all blank).

The setting unit 156 in FIG. 4 receives the information of the power rate plan identified as described above from the identification unit 152 and sets the criteria for controlling the charging and discharging of the storage battery 122. The setting unit 156 outputs the set criteria to the charging and discharging control unit 158. The criteria include the power rate unit price and the corresponding time period included in the information of the power rate plan. For example, a day can be divided into three time periods based on the power rate unit price. For example, with respect to FIG. 5, the time period with the lowest unit price (i.e., 15 yen) is the low period, the time period with the highest unit price (i.e., 30 yen) is the high period, and the time period with the unit price in between (i.e., 20 yen) is the medium period. Therefore, with respect to the power rate plan shown in FIG. 5, the criteria are set such that time period T3 is the low period, time period T2 and time period T4 are the high period, and time period T1 and time period T5 are the medium period.

Similarly, with respect to FIG. 6, the time period with the lowest unit price (i.e., 20 yen) is the low period, the time period with the highest unit price (i.e., 40 yen) is the high period, and the time period with the unit price in between (i.e., 30 yen) is the medium period. Therefore, with respect to the electricity rate plan shown in FIG. 6, the standards are set such that time period T3 is the high period, time periods T1 and T5 are the low periods, and time periods T2 and T4 are the medium periods.

The target value setting unit 154 in FIG. 4 sets the target value of the charge amount when charging the storage battery 122 with commercial power during the nighttime or other times when the unit price of electricity is low, by the user's operation. The target value setting unit 154 outputs the set target value to the charge/discharge control unit 158. For example, when the amount of electricity consumed in the future (e.g., the next day) is small, the user can set the SOC of the storage battery 122 relatively small in order to suppress the cost of charging the storage battery 122 with commercial power. When the amount of electricity consumed in the future is expected to be large, the SOC of the storage battery 122 can be set relatively large. Even when the amount of electricity consumed in the future is expected to be large, when it is expected that most of the power consumption will be covered by the power generated by the solar power generation system 106, the SOC of the storage battery 122 can be set relatively small. For example, if the next day is a weekday and the amount of power consumption at home is small due to going to work, the target value can be set small. If the next day is a holiday and the amount of power consumption at home is large, the target value can be set large. Even if the next day is a holiday and power consumption is high, if the weather is good and it is expected that the amount of power generated by the solar power generation system 106 will be high, the target value may be set to a small value. Also, if the solar power generation system 106 generates surplus power on the next day and it is expected that the storage battery 122 can be charged with the surplus power, the SOC of the storage battery 122 may be set to a relatively small value. This makes it possible to avoid the waste of overcharging the storage battery 122 with commercial power at night and being unable to charge the storage battery 122 with the surplus power the next day. In this way, the user sets the target value of the SOC of the storage battery 122 to an appropriate value. This makes it possible to prevent the storage battery 122 from being charged with commercial power more than necessary, thereby reducing electricity bills.

When the stationary storage battery device 104 is replaced by a vehicle and the storage battery 122 is an on-board storage battery, the user can set the target value according to the distance traveled by the vehicle on the next day. For example, if the planned distance traveled is relatively long, the target value can be set large, and if the planned distance traveled is relatively short, the target value can be set small.

Setting of the target value of the SOC of the storage battery 122 will be specifically described with reference to FIG. 8. The display unit 208 displays, for example, a screen 260. The screen 260 includes a setting item 262, a setting content 264, a pull-down key 266, a setting key 270, and a cancel key 272. The setting item 262 indicates that the item to be set is the "target value" of the SOC. The setting content 264 displays the target value. The pull-down key 266 is a key for displaying a pull-down menu. When the pull-down key 266 is operated, a pull-down menu 268 is displayed. FIG. 8 shows a state in which the pull-down key 266 is operated to display the pull-down menu 268, and "80%" is selected from among the multiple options included in the pull-down menu 268. The selected "80%" is displayed in the setting content 264. The pull-down menu 268 is then erased. When the setting key 270 is operated, the content displayed in the setting content 264 is set. When the cancel key 272 is operated, the contents displayed in the setting contents 264 are discarded, and the screen 260 returns to a state in which no target value has been selected (i.e., the setting contents 264 is blank).

The charge/discharge control unit 158 in FIG. 4 executes charge/discharge control of the storage battery 122 using the reference input from the setting unit 156 and the target value input from the target value setting unit 154. The charge/discharge control unit 158 is realized by the power measurement circuit 110, the control circuit 112, and the charge/discharge circuit 114 of the power control device 102. Specifically, as described below, the charge/discharge control is executed by the CPU 220 (see FIG. 3) of the control circuit 112.

The method by which the user specifies the electricity rate plan and target value is not limited to selecting from a plurality of options presented, as described above. For example, the user may specify the plan and target value by directly inputting the plan and target value. For example, the target value setting unit 154 may display a numeric keypad on the display unit 208 of the controller 108, and set the numeric value input by the user by operating the numeric keypad (specifically, the operation unit 206) as the target value.

(motion)
With reference to Figs. 9 and 10, the operation of controlling the charging and discharging of the storage battery 122 in the power control system 100 will be described. The processes shown in Figs. 9 and 10 are realized by the CPU 220 of the power control device 102 reading and executing a program stored in the memory 222. The process shown in Fig. 9 is executed when the selling price of the power generated by the photovoltaic power generation system 106 is lower than the purchasing price from the retail electricity supplier (i.e., the power rate unit price of the power rate plan). The process shown in Fig. 10 is executed when the selling price of the power generated by the photovoltaic power generation system 106 is higher than the purchasing price from the retail electricity supplier. Note that the process shown in Fig. 10 is executed even when the photovoltaic power generation system 106 cannot generate power or when the power control system 100 does not include the photovoltaic power generation system 106. The user can specify which of the processes shown in Figs. 9 and 10 is to be executed. The CPU 220 may also determine which of the processes shown in Figs. 9 and 10 is to be executed. For example, the CPU 220 may determine whether to execute the process of FIG. 9 or FIG. 10 based on the weather that affects the power generated by the solar power generation system 106 or the history of the power generated by the solar power generation system 106 in the past.

(First Operation)
9 , in step 300, the CPU 220 acquires an electricity rate plan and a current time. The CPU 220 stores the acquired electricity rate plan and the current time in the memory 222. Thereafter, control proceeds to step 302. The electricity rate plan is the currently contracted electricity rate plan designated by the user. Specifically, the CPU 220 acquires information on the electricity rate plan itself from the controller 108 (see the identification unit 152 in FIG. 4 ). The CPU 220 acquires the current time from the timer 226.

In step 302, the CPU 220 acquires the SOC of the storage battery 122 from the control circuit 120 of the stationary storage battery device 104. The CPU 220 stores the acquired SOC in the memory 222. Then, control proceeds to step 304.

In step 304, the CPU 220 determines whether or not there is currently surplus power in the power generated by the solar power generation system 106. If it is determined that there is surplus power, control proceeds to step 306. If not (if there is no surplus power), control proceeds to step 312. Specifically, the CPU 220 determines whether or not there is surplus power using the power values measured by the power sensor 140 and the power sensor 142, which are input from the power measurement circuit 110, as described above.

In step 306, the CPU 220 determines whether the SOC obtained in step 302 is equal to or greater than the upper limit. If it is determined that the SOC is equal to or greater than the upper limit, control proceeds to step 308. If not (i.e., SOC<upper limit), control proceeds to step 310. The upper limit may be stored in advance in the memory 222 of the control circuit 112. The CPU 220 can read the upper limit from the memory 222 and use it for the determination.

In step 308, the CPU 220 sells the surplus power generated by the photovoltaic power generation system 106, i.e., outputs it to the commercial power grid 902. Then, control proceeds to step 324. If the SOC has reached the upper limit, the storage battery 122 is not charged any further, and the surplus power generated by the photovoltaic power generation system 106 can be sold.

If the result of the determination in step 306 is NO (i.e., the SOC has not reached the upper limit), in step 310, the CPU 220 charges the storage battery 122 with surplus power from the solar power generation system 106. Then, control proceeds to step 324.

If the result of the determination in step 304 is NO (i.e., there is no surplus power from the photovoltaic power generation system 106), in step 312, the CPU 220 determines whether the commercial power purchase price is high. If it is determined that it is high, control proceeds to step 320. If not, control proceeds to step 314. The power purchase price is the above-mentioned power rate price. As described above, a day is divided into a high period, a low period, and a medium period according to the power rate price. Therefore, the CPU 220 reads out from the memory 222 the time period corresponding to the high period and the current time acquired in step 300, and determines whether the current time belongs to the time period corresponding to the high period. If the current time belongs to the time period corresponding to the high period, the CPU 220 determines that the power purchase price is high. For example, in the case of the power rate plan shown in FIG. 5, time period T2 and time period T4 are high periods, so the CPU 220 determines whether the current time belongs to either time period T2 or time period T4.

In step 314, the CPU 220 determines whether the unit price of commercial electricity purchase is low. If it is determined that it is low, control proceeds to step 316. If not, control proceeds to step 324. Specifically, the CPU 220 reads from the memory 222 the time slot corresponding to the low period and the current time acquired in step 300, and determines whether the current time belongs to the time slot corresponding to the low period. If the current time belongs to the time slot corresponding to the low period, the CPU 220 determines that the unit price of electricity purchase is low. For example, in the case of the electricity rate plan shown in FIG. 5, time slot T3 is a low period, so the CPU 220 determines whether the current time belongs to time slot T3.

In step 316, the CPU 220 reads the SOC obtained in step 302 from the memory 222 and determines whether the read SOC is less than the target value. If it is determined that the SOC is less than the target value, control proceeds to step 318. If not, control proceeds to step 324. As described above, the target value is the target value of the SOC of the storage battery 122 specified by the user, and is transmitted from the controller 108 to the control circuit 112 and stored in the memory 222.

In step 318, the CPU 220 charges the storage battery 122 with commercial power supplied from the commercial power system 902. Specifically, the CPU 220 instructs the charge/discharge circuit 114 to convert the AC power supplied from the commercial power system 902 into DC power and output it to the storage battery 122. This charges the storage battery 122. Control then proceeds to step 324.

If the determination result in step 312 is YES (i.e., the electricity purchase price is high), in step 320, the CPU 220 reads the SOC obtained in step 302 from the memory 222 and determines whether it is equal to or lower than the lower limit. If it is determined that the SOC is equal to or lower than the lower limit, control proceeds to step 324. Otherwise (i.e., SOC > lower limit), control proceeds to step 322. The lower limit may be stored in advance in the memory 222 of the control circuit 112. The CPU 220 can read the lower limit from the memory 222 and use it for the determination.

In step 322, the CPU 220 supplies power to the load 906 by discharging the storage battery 122. Specifically, the CPU 220 instructs the charge/discharge circuit 114 to convert the DC power supplied from the storage battery 122 to AC power and supply it to the load 906. After that, control proceeds to step 324.

In step 324, the CPU 220 determines whether or not to terminate. If it is determined that the program is to terminate, the program terminates. If not, control returns to step 300, and the above process is repeated. For example, the CPU 220 determines that the program is to terminate when a predetermined code is received from the controller 108. When the user operates the controller 108 to input an instruction to stop the system, the controller 108 transmits the above-mentioned predetermined code to the control circuit 112 of the power control device 102.

(Second Operation)
As described above, in cases such as when the selling price of the power generated by the photovoltaic power generation system 106 is higher than the purchasing price from the retail electricity supplier, the process shown in Fig. 10 is executed. The flowchart in Fig. 10 is obtained by deleting steps 304 to 310 from the flowchart in Fig. 9, changing the control so that the process proceeds from step 302 to step 312, and replacing step 316 with step 330. In Fig. 10, the process of steps with the same reference numerals as in Fig. 9 is the same as in Fig. 9. Therefore, the explanation will not be repeated and the differences will be mainly described.

Referring to FIG. 10, if the determination result in step 314 is YES, in step 330, the CPU 220 determines whether the SOC acquired in step 302 is equal to or greater than the upper limit. If it is determined that the SOC is equal to or greater than the upper limit, control proceeds to step 324. Otherwise (i.e., SOC<upper limit), control proceeds to step 318, and the storage battery 122 is charged by commercial power.

As a result, the power control system 100 can respond to various electricity rate plans offered by retail electricity suppliers and appropriately control the charging and discharging of the storage battery. In other words, the power control system 100 can appropriately control the charging and discharging of the storage battery in accordance with the electricity rate plan with which the user has voluntarily signed up.

As described above, the setting unit 156 (see FIG. 4) can set multiple time periods according to the unit price of commercial power purchase as a criterion for controlling the charging and discharging of the storage battery, and if the current time falls within a time period when the unit price of power purchase is high (i.e., a time period corresponding to a high period), the setting unit 156 discharges the storage battery 122 from the commercial power grid 902 if the current time falls within a time period when the unit price of power purchase is low (i.e., a time period corresponding to a low period). This is the processing of step 318 shown in FIG. 9. This makes it possible to reduce the electricity fee for charging the storage battery 122 from the commercial power grid 902.

Even if an electricity rate plan includes four or more types of electricity purchase prices, it can be divided into three types of time periods. For example, by treating similar electricity purchase prices as one electricity purchase price, it is possible to set three types of electricity purchase prices and divide into three types of time periods. It may also be divided into two types of time periods. For example, if an electricity rate plan includes two types of electricity purchase prices, it can be divided into two types of time periods. In that case, a time period with a high electricity purchase price (i.e., a time period corresponding to a high period) and a time period with a low electricity purchase price (i.e., a time period corresponding to a low period) are set. Even if an electricity rate plan includes three or more types of electricity purchase prices, it may be divided into two types of time periods by treating similar electricity purchase prices as one electricity purchase price as described above.

As described above, when discharging the storage battery 122, the CPU 220 discharges the storage battery 122 until the charge amount of the storage battery 122 reaches the lower limit or until the current time is no longer in a time period when the repurchase price is high (i.e., a time period corresponding to a high period). That is, if there is no surplus power (i.e., the judgment result of step 304 is NO) and the current time is in a time period when the repurchase price is high, the CPU 220 discharges the storage battery 122 in step 322 until the SOC of the storage battery 122 reaches the lower limit (i.e., until the judgment result of step 320 is YES). Furthermore, if the current time is no longer in a time period when the repurchase price is high, the CPU 220 does not execute the discharge in step 322. This makes it possible to prevent the storage battery 122 from being discharged more than necessary.

As described above, the power control system 100 includes a target value setting unit 154 that sets a target value for the SOC of the storage battery 122. When the CPU 220 charges the storage battery 122 with commercial power, the storage battery 122 is charged to the target value. That is, if the determination result in step 316 is YES (i.e., SOC<target value), the storage battery 122 is charged by the commercial power system 902 in step 318. This makes it possible to prevent the storage battery 122 from being charged with commercial power more than necessary, thereby reducing electricity bills.

As described above, the user can directly specify the target value for the SOC of the storage battery 122 (see FIG. 8). Therefore, taking into consideration the amount of power consumption (i.e., the planned amount of power consumption) planned for the future (e.g., the next day) and the weather that will affect the power generation of the solar power generation system, an appropriate target value can be directly set, and the storage battery 122 can be appropriately charged.

The controller 108 (see the target value setting unit 154 in FIG. 4) may set a target value according to the planned power consumption, which represents the planned value of the amount of power consumed by discharging the storage battery 122. For example, a user may operate the operation unit 206 of the controller 108 to input the planned power consumption (e.g., the planned power consumption for the next day), and the CPU 200 of the controller 108 may set a target value for the SOC of the storage battery 122 according to the input planned power consumption. This allows an appropriate target value to be set according to the power consumption that the user plans for the future (e.g., the next day), and allows the storage battery 122 to be appropriately charged.

The planned power consumption may also be set based on the operation history of the power control device 102, i.e., the history of charging control of the storage battery 122 by the power control device 102. To this end, for example, the CPU 220 of the control circuit 112 may store in the memory 222 the change in the SOC of the storage battery 122 during the period when the storage battery 122 was charged and during the period when the storage battery 122 was discharged. This allows the planned power consumption in the future (for example, the next day) to be calculated, and an appropriate target value to be automatically set according to the calculated planned power consumption. For example, the planned power consumption can be calculated according to the day of the week, or according to holidays or weekdays, and an appropriate target value can be set.

In the above, the acquisition unit 150 shown in FIG. 4 may acquire information about a plurality of electricity rate plans at a predetermined time interval. This allows electricity rate plans to be appropriately presented to the user, and the user can efficiently set the electricity rate plan to which he or she has subscribed.

As described above, the identification unit 152 shown in FIG. 4 identifies an electricity rate plan based on the region in which the storage battery 122 is installed. That is, by allowing the user to select a region using the screen 240 shown in FIG. 7, electricity rate plans can be appropriately presented to the user, and the user can easily set the electricity rate plan to which he or she has subscribed.

(Modification)
In the above, as shown in FIG. 1 , a case has been described in which the power control device 102 and the stationary storage battery equipment 104 are installed outdoors of the residence 900, and the PCS 132 and the controller 108 are installed indoors of the residence 900. However, the power control device 102, the stationary storage battery equipment 104, the PCS 132, and the controller 108 may be installed in any location. For example, the power control device 102 and the stationary storage battery equipment 104 may be installed indoors of the residence 900. The controller 108 and the PCS 132 may be installed outdoors of the residence 900.

In the above, as shown in FIG. 1, the power control device 102, the stationary storage battery device 104, and the PCS 132 of the solar power generation system 106 are each configured as separate devices. However, they may be arbitrarily combined and configured as an integrated device. For example, the power control device 102 may be incorporated into the stationary storage battery device 104 and configured as an integrated device. Also, the power control device 102 and the PCS 132 may be incorporated into the stationary storage battery device 104 and configured as an integrated device.

In the above, the controller 108 is external to the power control device 102, but this is not limiting. The power control device 102 may include the controller 108 (i.e., the operation unit 206 for implementing the functions of the identification unit 152 and the target value setting unit 154 shown in FIG. 4). As described above, the identification unit 152 displays one or more power rate plans corresponding to the specified region on the display unit 208 in response to the region being specified by the operation unit 206. The identification unit 152 identifies the power rate plan selected by the operation unit 206 from the one or more displayed power rate plans as the power rate plan for determining the standard for controlling the charging and discharging of the storage battery 122. This allows the user to more easily set the power rate plan to which he or she has a contract.

In the above, the power control device 102 controls the charging and discharging of the storage battery 122 included in the stationary storage battery device 104, but this is not limited to the above. The stationary storage battery device 104 may be replaced by an EV or PHEV having a V2H function. In that case, the power control device 102 can control the charging and discharging of the storage battery 122, which is an on-board storage battery, in the same manner as described above (for example, according to the flowcharts shown in Figures 9 and 10).

If the storage battery 122 is an on-board storage battery, in Figs. 9 and 10, between steps 300 and 302, it may be determined whether or not the on-board storage battery is connected to the charge/discharge circuit 114. If it is connected, the process from step 302 onwards (i.e., charge/discharge control of the storage battery 122) can be executed, but if it is not connected (for example, the vehicle equipped with the storage battery 122 is being used as a means of transportation), the process from step 302 onwards cannot be executed.

The present disclosure has been described above by explaining the embodiments, but the above-mentioned embodiments are merely examples, and the present disclosure is not limited to only the above-mentioned embodiments. The scope of the present disclosure is indicated by each claim in the claims, taking into consideration the detailed description of the invention, and includes all modifications within the meaning and scope equivalent to the wording described therein.

Reference Signs List 100 Power control system 102 Power control device 104 Stationary storage battery device 106 Photovoltaic power generation system 108 Controller 110 Power measurement circuit 112, 120 Control circuit 114 Charging and discharging circuit 122 Storage battery 130 PV panel 132 PCS
140, 142 Power sensor 150 Acquisition unit 152 Identification unit 154 Target value setting unit 156 Setting unit 158 Charge/discharge control unit 200, 220 CPU
202, 222 Memory 204, 224 Communication section 206 Operation section 208 Display section 226 Timer 240, 260 Screen 242 Setting item display area 244 Setting content display area 246 Pull-down key display area 248, 268 Pull-down menu 250, 270 Setting key 252, 272 Cancel key 262 Setting item 264 Setting content 266 Pull-down key 300, 302, 304, 306, 308, 310, 312, 314, 316, 318, 320, 322, 324, 330 Step 900 Residence 902 Commercial power system 904 Communication network 906 Load T1, T2, T3, T4, T5 Time period

Claims (13)

An acquisition unit that acquires information regarding a plurality of electricity rate plans for commercial electricity;
an identification unit that identifies one plan from the plurality of electricity rate plans;
A setting unit that sets a standard for charge/discharge control of a storage battery based on the information related to the identified plan;
and a control unit that controls charging and discharging of the storage battery based on a current time and the criterion. The setting unit sets, as the standard, a first time period during which a power purchase price of the commercial power is a first unit price and a second time period during which the power purchase price is a second unit price;
The first unit price is the highest electricity purchase price included in the plan,
The second unit price is the cheapest electricity purchase price included in the plan,
The control unit is
If the current time belongs to the first time zone, discharging the storage battery;
The power control device according to claim 1 , wherein if the current time falls within the second time zone, the storage battery is charged by the commercial power. The power control device according to claim 2, wherein the control unit discharges the storage battery until the charge amount of the storage battery reaches a lower limit or until the current time does not belong to the first time zone. A target value setting unit that sets a target value of an SOC representing a charge amount of the storage battery,
The power control device according to claim 1 , wherein the control unit charges the storage battery to the target value when the storage battery is charged by the commercial power. The power control device according to claim 4, wherein the target value is specified by a user. The power control device according to claim 4, wherein the target value setting unit sets the target value according to a planned power consumption amount that represents a planned value of the amount of power consumed by discharging the storage battery. The power control device according to claim 6, wherein the planned power consumption is specified by a user. The power control device according to claim 6, wherein the planned power consumption is set based on the operation history of the power control device. The power control device according to any one of claims 1 to 3, wherein the acquisition unit acquires the information regarding the plurality of power rate plans at a predetermined time interval. The power control device according to any one of claims 1 to 3, wherein the identification unit identifies the plan based on the area in which the storage battery is installed. Further comprising an operation unit,
The identification unit is
In response to the region being designated by the operation unit, presenting one or more electricity rate plans corresponding to the designated region;
The power control device according to claim 10 , wherein an power rate plan selected by the operation unit is identified as the plan from among the one or more presented power rate plans. A storage battery,
The power control device according to any one of claims 1 to 3,
The power control device controls charging and discharging of the storage battery. An acquisition step of acquiring information regarding a plurality of electricity rate plans for commercial electricity;
A specifying step of specifying one plan from the plurality of electricity rate plans;
A setting step of setting a standard for charge/discharge control of the storage battery based on the information related to the identified plan;
and a control step of controlling charging and discharging of the storage battery based on a current time and the criterion.

Images