JPWO2019044708A1 - Power system, power storage device, and method of controlling power system - Google Patents

Abstract

The power system includes a power storage device and a power device. The power device receives power supply from the power storage device. When the power storage device and the power device are connected to each other, the power storage device or the power device controls the supply of electric power received by the power device from the power storage device based on charge/discharge history information regarding charging/discharging of the power storage device.

Description

Cross-reference of related applications

This application claims the priority of Japanese Patent Application No. 2017-166071 filed in Japan on Aug. 30, 2017, and the entire disclosure of the previous application is incorporated herein by reference.

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

Conventionally, a technique of selling power from a customer facility to a commercial power source is known. For example, Patent Document 1 discloses an energy system that sells power from a private power storage device to the grid side.

JP2012-186963A

A power system according to an embodiment of the present disclosure includes a power storage device and a power device. The power device receives power supply from the power storage device. When the power storage device and the power device are connected to each other, the power storage device or the power device determines, based on charge/discharge history information regarding charging/discharging of the power storage device, supply of electric power that the power device receives from the power storage device. Control.

The power storage device according to an embodiment of the present disclosure supplies power to a power device. The power storage device includes a control unit. When connected to the power device, the control unit controls the supply of electric power that the power device receives from the power storage device, based on charge/discharge history information regarding charging/discharging of the power storage device.

A power system control method according to an embodiment of the present disclosure is a power system control method that includes a power storage device and a power device. The power device receives power supply from the power storage device. A method for controlling an electric power system is such that, when the electric storage device or the electric power device is connected to the electric storage device and the electric power device, the electric power device receives the supply of electric power from the electric power storage device to charge and discharge the electric power storage device. Control based on the charge/discharge history information regarding.

It is a figure showing the schematic structure of the electric power system concerning one embodiment of this indication. It is a block diagram which shows schematic structure of the electrical storage apparatus of FIG. It is a block diagram which shows schematic structure of the electric power apparatus of FIG. It is a block diagram which shows schematic structure of the charging device of FIG. It is a figure which shows the example of charging/discharging history information. FIG. 4 is a sequence diagram showing operations of the power storage device and the power device according to an embodiment of the present disclosure. FIG. 8 is a sequence diagram showing operations of a power storage device and a power device according to another embodiment of the present disclosure.

Conventionally, it has been desired to improve the convenience of technology for selling electric power. The present disclosure relates to a power system, a power storage device, and a power system control method that improve the convenience of a technique for selling power. According to the power system, the power storage device, and the method for controlling the power system according to the embodiment of the present disclosure, the convenience of the technique for selling power is improved. Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.

(Structure of power system)
FIG. 1 is a diagram showing a schematic configuration of a power system 1 according to an embodiment of the present disclosure. The power system 1 includes a power storage device 10, a power device 20, a charging device 30, and a moving body 40. The numbers of the power storage device 10, the power device 20, the charging device 30, and the moving body 40 may be arbitrarily determined.

The power storage device 10 is used by a user who is, for example, a consumer. The power storage device 10 is charged by, for example, a charging device 30 installed at a user's home, a charging station, or the like, as described later. The power storage device 10 may supply electric power to a load device provided in the user's home. The power storage device 10 has portability. In the present embodiment, the power storage device 10 is mounted on a moving body 40 described later. For example, the electric power supplied from the power storage device 10 may be consumed by the moving body 40. Specifically, the electric power supplied from the power storage device 10 to the moving body 40 may be consumed for moving the moving body 40, driving an auxiliary machine mounted on the moving body 40, and the like. In another embodiment, the power storage device 10 may be portable by the user. Details of power storage device 10 will be described later.

The power device 20 may be installed in any place. For example, the power device 20 may be installed in any facility other than the home of the user of the power storage device 10. Specifically, the power device 20 may be installed in a facility such as a convenience store, a supermarket, a department store, a restaurant, a hospital, or a parking lot. The power device 20 receives the supply of power from the power storage device 10. As will be described later, a reward may be given to the user according to the amount of power supplied from the power storage device 10 to the power device 20. Hereinafter, supplying power from the power storage device 10 to the power device 20 is also referred to as power sale by the power storage device 10. In the present disclosure, "power sale" includes supplying power in exchange for money, and supplying power by regarding the power itself as virtual currency. The amount of power supplied from the power storage device 10 to the power device 20 is also referred to as the amount of power sold. The power device 20 may supply the power sold from the power storage device 10 to, for example, a load device or a storage battery provided in a facility where the power device 20 is installed. The power device 20 may function as a charger that charges the power storage device 10. In such a case, the power device 20 supplies power to the power storage device 10 from, for example, a commercial power source or a storage battery provided in a facility in which the power device 20 is installed. Details of the power device 20 will be described later.

The charging device 30 may be installed in an arbitrary place different from the installation place of the power device 20, for example. For example, charging device 30 may be installed in the home of the user of power storage device 10 or in a facility such as a charging station. Charging device 30 functions as a charger that charges power storage device 10. The charging device 30 can supply electric power derived from renewable energy or exhaustible energy to the power storage device 10. Electric power derived from renewable energy may include electric power generated using energy such as sunlight, wind power, hydraulic power, or geothermal energy. Electric power derived from exhaustible energy may include electric power generated using fossil energy such as petroleum, coal, or natural gas. Hereinafter, the charging device 30 that supplies electric power derived from renewable energy is also referred to as a first charging device 30a. For example, the charging device 30 connected to the solar power generation device can function as the first charging device 30a. Hereinafter, the charging device 30 that supplies electric power derived from exhaustible energy is also referred to as a second charging device 30b. For example, the charging device 30 connected to the commercial power source derived from exhaustible energy may function as the second charging device 30b. As described below, when the power storage device 10 is charged by the charging device 30, information that can identify whether the charging device 30 is the first charging device 30a or the second charging device 30b is stored in the power storage device 10. Remembered. The charging device 30 may supply electric power to any load device connected to the charging device 30. For example, the charging device 30 and the load device may be installed in the home of the user of the power storage device 10. The charging device 30 may function as an EMS (Energy Management System). The charging device 30 can supply power to at least one of the power storage device 10 and the load device. The charging device 30 may supply power to the load device, for example, when the power storage device 10 is not connected. Details of the charging device 30 will be described later.

The mobile body 40 mounts the power storage device 10. The moving body 40 may include any movable device. The moving body 40 may or may not use the electric power supplied from the power storage device 10 to move. When the power supplied from power storage device 10 is not used for moving, mobile body 40 may be used simply for carrying power storage device 10. For example, the moving body 40 may include a vehicle, a walking robot, a flight device, and the like. For example, vehicles may include electric vehicles, hybrid electric vehicles, gasoline vehicles, bicycles, and the like. For example, flight devices may include drones, multicopters, and the like. The mobile 40 may be driven or steered by a user. At least a part of the user operation related to driving or manipulating the moving body 40 may be automated. The moving body 40 may be able to move autonomously without depending on a user operation. In the present embodiment, an example will be described in which the moving body 40 is an electric vehicle that moves using the power supplied from the power storage device 10. The moving body 40 may use at least a part of the regenerative power generated by the regenerative brake to charge the power storage device 10. Details of the moving body 40 will be described later.

A usage example of the power system 1 by a user will be described. The user charges the power storage device 10 mounted on the moving body 40, for example, by the charging device 30 provided in the user's home or a charging station. The user moves by the moving body 40 to the facility where the power device 20 is installed. The user connects the power storage device 10 and the power device 20 to start power sale by the power storage device 10. When the power sale ends, a reward is given to the user according to the amount of power sold. The content of the reward given to the user may be arbitrarily determined. For example, the reward may include money, virtual currency, points available for a predetermined service, and the like. For example, the reward may include the right to reduce the payment fee of the user at the facility where the power device 20 is installed. The facility may include, for example, a commercial facility such as a restaurant and an electric merchandiser, and parking lots related thereto. The reward may be given by, for example, issuing a ticket corresponding to the reward. The reward may be given by storing electronic data corresponding to the reward in association with the identification information of the user. In the present embodiment, the reward is given by the power device 20. In another embodiment, the reward may be given by an external server capable of communicating with the power device 20 via a communication network such as the Internet. For example, when the user clicks the settlement start button on the smartphone application, the power device 20 ends the power receiving operation according to the communication from the external server. The power device 20 calculates the reward of the power sold from the power storage device 10 up to that point and transmits it to the external server. The external server creates a code image such as a reduced barcode or QR code (registered trademark) corresponding to the reward, and transmits it to the user's smartphone. The user can receive a reduction in payment by presenting the code image displayed on the smartphone, for example, at the time of settlement of meals or product purchases.

In this way, a user who uses the power system 1 can sell the power stored in the power storage device 10 at any place where the power device 20 is installed. Therefore, the user has more opportunities to sell power, and the convenience of the technology for selling power is improved. Moreover, since the use of the electric power stored in the power storage device 10 is promoted, the use efficiency of the electric power is improved for the user. In addition, the user can be motivated to move to the place where the power device 20 is installed. Therefore, for example, the economic activity of the user at the location is activated.

(Structure of power storage device)
FIG. 2 is a block diagram showing a schematic configuration of power storage device 10 in FIG. In the present embodiment, the power storage device 10 includes a storage battery 11, a communication unit 12, a sensor unit 13, a storage unit 14, and a control unit 15. In another embodiment, at least one of the storage battery 11, the communication unit 12, the sensor unit 13, the storage unit 14, and the control unit 15 may be provided in the moving body 40 in which the power storage device 10 is mounted.

The storage battery 11 includes any type of battery that can be charged and discharged. For example, the storage battery 11 may include a lead storage battery, a lithium-ion battery, a nickel-cadmium battery, a nickel-hydrogen battery, or the like.

The communication unit 12 may include a first interface that transmits and receives information and power to and from an external device. The first interface may include a module and a connector corresponding to an arbitrary standard regarding a charging/discharging method of the storage battery 11. The standard regarding the charging/discharging method may include standards such as CHAdeMO (registered trademark) and USB (registered trademark). In the present embodiment, the communication unit 12 can transmit and receive information and power to and from the power device 20 and the charging device 30, respectively, via the first interface. The communication unit 12 may include a second interface that transmits and receives information to and from an external device. The second interface may include a communication module compatible with any communication standard via wire or wireless. The communication standard may include a communication standard via an in-vehicle network such as CAN (Controller Area Network). In the present embodiment, the communication unit 12 can send and receive information to and from the mobile unit 40 via the second interface. The communication unit 12 may include a third interface that transmits and receives information to and from an external device via a communication network such as the Internet. The third interface may include, for example, a communication module compatible with any wireless communication standard. The communication unit 12 may connect to an external server via the third interface and the communication network to send and receive information regarding power and position. The communication unit 12 may receive more advanced service information from the server.

The sensor unit 13 includes one or more optional sensors or detection mechanisms. For example, the sensor unit 13 may include a charge/discharge power sensor and a remaining capacity sensor. The charge/discharge power sensor measures the current by using, for example, a CT (Current Transformer) to detect the charge/discharge power amount of the storage battery 11. For example, the charge/discharge power sensor may detect the amount of electric power sold when the electric power device 20 is sold. The charging/discharging power sensor may detect the amount of charging power during charging by the charging device 30. The remaining capacity sensor monitors the discharge current amount and the charging current amount of the storage battery 11 using CT, for example, and detects the remaining capacity. Any algorithm can be adopted for detecting the remaining capacity. For example, the remaining capacity estimation algorithm such as the current integration method or the open-circuit voltage method may be used to detect the remaining capacity.

The storage unit 14 includes one or more memories. For example, the storage unit 14 may include a semiconductor memory, a magnetic memory, an optical memory, or the like. The storage unit 14 may function as, for example, a primary storage device or a secondary storage device. The storage unit 14 may store arbitrary information used for the operation of the power storage device 10. For example, the storage unit 14 may store in advance a power storage device ID that can uniquely identify the power storage device 10. The storage unit 14 may store charge/discharge history information described later.

The control unit 15 includes one or more processors. The processor may include a general-purpose processor and a special-purpose processor specialized for specific processing. In another embodiment, a processor such as an ECU (Electronic Control Unit) provided in the moving body 40 may function as the control unit 15. Control unit 15 controls the overall operation of power storage device 10. A specific example of the operation of power storage device 10 will be described later.

(Structure of power device)
FIG. 3 is a block diagram showing a schematic configuration of the power device 20 of FIG. In the present embodiment, the power device 20 includes a communication unit 21, a sensor unit 22, a storage unit 23, and a control unit 24.

The communication unit 21 may include a first interface that transmits and receives information and power to and from an external device. In the present embodiment, the communication unit 21 can transmit and receive information and electric power to and from the power storage device 10 via the first interface. The communication unit 21 may include a third interface that transmits/receives information to/from an external device via a communication network. The communication unit 21 may connect to an external server via the third interface and the communication network to transmit/receive information regarding the charge/discharge history. According to such a configuration, for example, when the amount of past measurement data is large and cannot be stored in the storage unit 23 described later, at least a part of the charge/discharge history information can be stored in the server. Becomes

The sensor section 22 includes one or more optional sensors or sensing mechanisms. For example, the sensor unit 22 may include a charge/discharge power sensor. The charge/discharge power sensor measures the current by using, for example, CT, and detects the charge/discharge power amount of the power storage device 10 connected via the communication unit 21. For example, the charge/discharge power sensor may detect the amount of electric power sold when the electric power device 20 is sold.

The storage unit 23 includes one or more memories. For example, the storage unit 23 may include a semiconductor memory, a magnetic memory, an optical memory, or the like. The storage unit 23 may function as, for example, a primary storage device or a secondary storage device. The storage unit 23 may store any information used for the operation of the power device 20.

The control unit 24 includes one or more processors. The processor may include a general-purpose processor and a dedicated processor specialized for specific processing. The control unit 24 controls the overall operation of the power device 20. A specific example of the operation of the power device 20 will be described later.

(Configuration of charging device)
FIG. 4 is a block diagram showing a schematic configuration of the charging device 30 of FIG. The charging device 30 includes a communication unit 31, a sensor unit 32, a storage unit 33, and a control unit 34.

The communication unit 31 may include a first interface that transmits and receives information and power to and from an external device. In the present embodiment, the communication unit 31 can send and receive information to and from the power storage device 10 via the first interface. The communication unit 31 can transmit electric power to the power storage device 10 via the first interface. Specifically, the communication unit 31 of the first charging device 30a can transmit electric power derived from renewable energy to the power storage device 10. On the other hand, the communication unit 31 of the second charging device 30b can transmit electric power derived from exhaustible energy to the power storage device 10. The communication unit 31 may include a third interface that transmits/receives information to/from an external device via a communication network. The communication unit 31 may connect to an external server via the third interface and the communication network to send and receive information regarding power. For example, when the charging device 30 is connected to the solar power generation device and the load device, the communication unit 31 may obtain real-time weather information or information such as past power generation results from the server as information regarding electric power. Good. According to such a configuration, for example, when both the power storage device 10 and the load device are connected to the charging device 30, the charging device 30 gives priority to either the power storage device 10 or the load device based on the information about the electric power. Power can be distributed to each other.

The sensor portion 32 includes one or more optional sensors or sensing mechanisms. For example, the sensor unit 32 may include a charging power sensor. The charging power sensor measures the current by using, for example, CT, and detects the charging power amount of the power storage device 10 connected via the communication unit 31.

The storage unit 33 includes one or more memories. For example, the storage unit 33 may include a semiconductor memory, a magnetic memory, an optical memory, or the like. The storage unit 33 may function as, for example, a primary storage device or a secondary storage device. The storage unit 33 may store any information used for the operation of the charging device 30.

The control unit 34 includes one or more processors. The processor may include a general-purpose processor and a dedicated processor specialized for specific processing. The control unit 34 controls the operation of the entire charging device 30. For example, when charging power storage device 10, control unit 34 may notify power storage device 10 which of first charging device 30a and second charging device 30b performs charging.

(Configuration of moving body)
The mobile unit 40 shown in FIG. 1 includes one or more auxiliary machines, one or more processors, and an in-vehicle network. The accessories may include, for example, an air conditioner and a navigation device. The processor may include, for example, an ECU. The processor controls the operation of the entire mobile unit 40. For example, the processor may use at least a part of the regenerative electric power generated by the regenerative braking of the moving body 40 to charge the power storage device 10.

(Operation of power storage device and power device)
The operations of power storage device 10 and power device 20 will be specifically described. The operation is an operation related to power sale from the power storage device 10 to the power device 20.

The control unit 15 of the power storage device 10 stores charge/discharge history information in the storage unit 14 every time charging/discharging of the power storage device 10 is performed, for example. The charge/discharge history information may include any history regarding charge/discharge of the power storage device 10. For example, as illustrated in FIG. 5, the charge/discharge history information includes a user ID, a power storage device ID, a date and time, a charge/discharge power amount, an attribute, a remaining capacity, a first parameter, and a second parameter. Including.

The user ID is information that can uniquely identify the user. The power storage device ID is information that can uniquely identify the power storage device ID as described above.

The date and time is a time stamp when the power storage device 10 was charged and discharged. For example, when charging/discharging of power storage device 10 is completed, control unit 15 may store the date and time when charging/discharging is completed in storage unit 14.

The charging/discharging power amount is the charging/discharging power amount when the charging/discharging of the power storage device 10 is executed. In FIG. 5, the charging power amount is shown by a positive numerical value and the discharging power amount is shown by a negative numerical value. The control unit 15 may store the amount of charge/discharge power detected by the sensor unit 13 in the storage unit 14 when charging/discharging of the power storage device 10 is completed, for example. At this time, the charging/discharging electric energy may be calculated in consideration of the discharging efficiency and the charging efficiency. In the following description, when the numerical value of the specific charge/discharge power amount is used for description, the charging efficiency and the discharging efficiency are assumed to be 1.0 for simplification.

The attribute is information indicating a device that has supplied charging power to the power storage device 10 or a device that has supplied discharging power to the power storage device 10. For example, the attribute may indicate any of the power device 20, the first charging device 30a, the second charging device 30b, or the moving body 40. The control unit 15 may store the attribute in the storage unit 14 as “power device” when the power storage device 10 is charged and discharged while the power storage device 10 and the power device 20 are connected, for example. For example, when the power storage device 10 is charged while the power storage device 10 and the charging device 30 are connected, the control unit 15 causes the charging device 30 to perform the first charging based on the notification obtained from the charging device 30. The device 30a or the second charging device 30b may be specified. The control unit 15 may store the attribute in the storage unit 14 as “first charging device” or “second charging device” according to the identification result of the charging device 30. For example, when charging/discharging of power storage device 10 is executed when power storage device 10 is not connected to power device 20 or charging device 30, control unit 15 stores the attribute in storage unit 14 as “moving object”. You may.

The remaining capacity is the remaining capacity of the storage battery 11 when charging/discharging of the power storage device 10 is completed. The control unit 15 may store the remaining capacity detected by using the sensor unit 13 in the storage unit 14.

The first parameter is a parameter corresponding to the amount of electric power derived from renewable energy in the remaining capacity of the storage battery 11. The control unit 15 may increase the first parameter according to the amount of charging power from the first charging device 30a. For example, the control unit 15 may increase the first parameter by the amount of charging power from the first charging device 30a.

The second parameter is a parameter corresponding to the amount of electric power derived from the exhaustible energy in the remaining capacity of the storage battery 11. The control unit 15 may increase the second parameter according to the amount of charging power from the second charging device 30b. For example, the control unit 15 may increase the amount of charging power from the second charging device 30b.

As described above, power storage device 10 can also be charged by the regenerative brake of moving body 40. In the present embodiment, the control unit 15 increases the second parameter according to the amount of electric power charged by the regenerative brake of the moving body 40. For example, the control unit 15 may increase the second parameter by the charge output amount of the regenerative brake of the moving body 40. Such a configuration is based on the idea described below. That is, a situation in which only electric power derived from renewable energy is stored in power storage device 10 is relatively rare, and both electric power derived from renewable energy and power derived from exhaustible energy are stored in power storage device 10. The probability is high. Therefore, it can be considered that the moving body 40 consumes both the electric power derived from the renewable energy and the electric power derived from the exhaustible energy accumulated in the power storage device 10. The regenerative brake recovers a part of the electric power consumed by the traveling of the moving body 40. Therefore, the electric power charged by the regenerative brake can be considered as a part of the electric power derived from exhaustible energy. In the present embodiment, the second parameter increases according to the amount of electric power charged by the regenerative braking of the moving body 40. According to this configuration, the accuracy of the first parameter corresponding to the amount of electric power derived from the renewable energy in the remaining capacity of the storage battery 11 is improved.

In another embodiment, the control unit 15 may increase the first parameter according to the amount of electric power charged by the regenerative brake of the moving body 40. Such a configuration is based on the idea described below. That is, the regenerative brake recovers a part of the electric power consumed for traveling the moving body 40 as described above. The electric power recovered by the regenerative brake differs from the electric power derived from exhaustible energy, for example, in that the generation of electric power does not involve the emission of carbon dioxide. Therefore, it can be considered that the electric power charged by the regenerative brake has a property closer to the electric power derived from the renewable energy than the electric power derived from the exhaustible energy. In another embodiment, the first parameter increases according to the amount of electric power charged by the regenerative brake of the moving body 40. Therefore, the accuracy of the second parameter corresponding to the amount of electric power derived from the exhaustible energy in the remaining capacity of the storage battery 11 is improved.

The control unit 15 may decrease the first parameter according to the amount of power sold from the power storage device 10 to the power device 20. For example, the control unit 15 may decrease the first parameter by the amount of power sold to the power device 20. Such a configuration corresponds to the preferential use of electric power derived from renewable energy in the sale of electric power from the power storage device 10 to the electric power device 20.

Control unit 15 may decrease the total value of the first parameter and the second parameter according to the amount of discharged power when power storage device 10 discharges except for power sale to power device 20. When reducing the total value of the first parameter and the second parameter, the control unit 15 may preferentially reduce the second parameter over the first parameter when the second parameter is greater than zero, for example. Such a configuration corresponds to that the electric power derived from the exhaustible energy is preferentially used in the discharge from the power storage device 10 to the power device 20 other than the power sale.

Specific contents indicated by the charge/discharge history information in FIG. 5 will be described. In the description of the charge/discharge history information, the value of each electric energy is a tentative numerical value for the purpose of explanation, and does not necessarily match the actual numerical value.

The first line of the charge/discharge history information indicates the initial state of power storage device 10. Specifically, in the initial state, the state of charge of power storage device 10 is 0 kWh. The first parameter and the second parameter are each 0 points.

The second line of the charging/discharging history information indicates that the electricity storage device 10 was charged with the electric energy of 30 kWh from the first charging device 30a at 8:00 on July 28th. The state of charge of the power storage device 10 has increased from 0 kWh to 30 kWh. Since the charging is performed by the first charging device 30a, the first parameter is increased from 0 point to 30 points. On the other hand, the second parameter remains 0 points.

The third line of the charge/discharge history information indicates that the electricity amount of 5 kWh was discharged from the power storage device 10 to the moving body 40 at 9:00 on July 28. The remaining capacity of the power storage device 10 is reduced from 30 kWh to 25 kWh. Since the discharge is other than power sale, the total value of the first parameter and the second parameter is reduced from 30 points to 25 points. In detail, since the second parameter is 0 point, the first parameter is reduced from 30 points to 25 points. On the other hand, the second parameter remains 0 points.

The fourth line of the charge/discharge history information indicates that the electric energy of 1 kWh was charged in the power storage device 10 by the regenerative brake of the moving body 40 at 9:01 on July 28. The remaining capacity of the power storage device 10 has increased from 25 kWh to 26 kWh. The second parameter is increased from 0 point to 1 point because the charging is performed by regenerative braking. On the other hand, the first parameter remains 25 points.

The fifth line of the charging/discharging history information indicates that the electricity storage device 10 was charged with the electric energy of 20 kWh from the second charging device 30b at 10:00 on July 28. The remaining capacity of the power storage device 10 has increased from 26 kWh to 46 kWh. Since the charging is performed by the second charging device 30b, the second parameter increases from 1 point to 21 points. On the other hand, the first parameter remains 25 points.

The sixth line of the charge/discharge history information indicates that the electricity amount of 5 kWh was discharged from the power storage device 10 to the moving body 40 at 11:00 on July 28. The remaining capacity of the power storage device 10 is reduced from 46 kWh to 41 kWh. Since the discharge is other than power sale, the total value of the first parameter and the second parameter is reduced from 46 points to 41 points. Specifically, since the second parameter is greater than 0 points, the second parameter that takes precedence over the first parameter has decreased from 21 points to 16 points. On the other hand, the second parameter remains 25 points.

The seventh line of the charge/discharge history information indicates that the electricity storage device 10 was charged with the electric energy of 1 kWh by the regenerative brake of the moving body 40 at 11:01 on July 28. The remaining capacity of the power storage device 10 has increased from 41 kWh to 42 kWh. Since the charging is performed by regenerative braking, the second parameter has increased from 16 points to 17 points. On the other hand, the first parameter remains 25 points.

The eighth line of the charge/discharge history information indicates that the power amount of 5 kWh was sold from the power storage device 10 to the power device 20 at 12:00 on July 28. The remaining capacity of the power storage device 10 is reduced from 42 kWh to 37 kWh. Since the power is sold to the electric power device 20, the first parameter is reduced from 25 points to 20 points. On the other hand, the second parameter remains 17 points.

When power storage device 10 and power device 20 are communicably connected, control unit 15 controls power sale by power storage device 10 based on charge/discharge history information. Specifically, the control unit 15 may determine the upper limit power amount based on the first parameter included in the charge/discharge history information. For example, the control unit 15 may determine the upper limit power amount to be a value equal to or less than the first parameter. The control unit 15 permits power sale up to the upper limit power amount. Specifically, the control unit 15 may end the power sale when the power sale power amount reaches the upper limit power amount after the power sale is started. The control unit 15 may start selling power from the power storage device 10 to the power device 20. When the power sale ends, the control unit 24 of the power device 20 gives the user a reward according to the amount of power sold.

6 is a sequence diagram showing the operation of the power storage device 10 and the power device 20 according to an embodiment of the present disclosure.

Step S100: The power storage device 10 stores charge/discharge history information regarding charge/discharge of the power storage device 10.

Step S101: The power storage device 10 determines the upper limit power amount based on the first parameter of the charge/discharge history information.

Step S102: The power storage device 10 permits power sale up to the upper limit power amount.

Step S103: The power storage device 10 starts selling power to the power device 20.

Step S104: When the power sale ends, the power device 20 gives the user a reward according to the amount of power sold.

As described above, in power system 1, power storage device 10 controls power sale by power storage device 10 based on charge/discharge history information regarding charge/discharge of power storage device 10. According to such a configuration, it is possible to sell electric power in consideration of the origin of the electric power stored in power storage device 10. Therefore, the convenience of the technology for selling electric power is improved.

For example, the charge/discharge history information may include the first parameter and the second parameter. The said 1st parameter increases according to the charging electric energy from the 1st charging device 30a which supplies the electric power derived from renewable energy. The said 2nd parameter increases according to the charging electric energy from the 2nd charging device 30b which supplies the electric power derived from exhaustible energy. Power storage device 10 may permit power sale up to the upper limit amount of power determined based on the first parameter. Such a configuration can correspond to the fact that only the electric power derived from the renewable energy is allowed to be sold among the electric power stored in the power storage device 10. According to such a configuration, it is possible to give the user motivation to charge the power storage device 10 using the electric power derived from the renewable energy. Therefore, the use of electric power derived from renewable energy is promoted, and the occurrence of adverse effects on the environment is reduced. For this reason, the convenience of the technology for selling electric power is further improved.

Although the present disclosure has been described based on the drawings and the embodiments, it should be noted that those skilled in the art can easily make various variations and modifications based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present disclosure. For example, the functions included in each means or each step can be rearranged so as not to logically contradict. It is possible to combine or divide a plurality of means or steps into one.

For example, at least part of the operation of the power storage device 10 in the above-described embodiment may be executed by the power device 20. For example, steps S100 to S102 described above may be executed by the power device 20 communicatively connected to the power storage device 10.

For example, the power device 20 in the above-described embodiment may be divided into a plurality of devices communicatively connected to each other. Of the plurality of devices, at least one device that performs an operation of giving a reward to the user according to the amount of power sold, for example, may be arranged in the facility where the power device 20 is installed. According to such a configuration, the user can be motivated to enter the facility to receive the reward. Therefore, activation of the user's economic activities in the facility can be promoted.

In the above-described embodiment, as a method of controlling the power sale by the power storage device 10 based on the charge/discharge history information, the power sale up to the upper limit power amount determined based on the first parameter included in the charge/discharge history information is permitted. The configuration has been described. The method of controlling power sale based on the charge/discharge history information is not limited to the above-described embodiment. In another embodiment, for example, control unit 15 of power storage device 10 may permit power sale by power storage device 10 when the second parameter included in the charge/discharge history information is 0 point. The control unit 15 may prohibit the power storage device 10 from selling power when the second parameter included in the charge/discharge history information is not 0 point.
FIG. 7 is a sequence diagram showing operations of the power storage device 10 and the power device 20 according to another embodiment of the present disclosure.

Step S200: The power storage device 10 stores charge/discharge history information regarding charge/discharge of the power storage device 10.

Step S201: The power storage device 10 permits the power sale by the power storage device 10 when the second parameter included in the charge/discharge history information is 0 point, and prohibits the power sale when the second parameter is not 0 point. Here, it is assumed that power sale by the power storage device 10 is permitted.

Step S202: The power storage device 10 starts selling power to the power device 20.

Step S203: When the power sale ends, the power device 20 gives the user a reward according to the amount of power sold.

The above steps S200 to S202 may be executed by the power device 20 communicatively connected to the power storage device 10.

In the above-described embodiment, the configuration in which the first parameter increases according to the amount of charging power by the first charging device 30a that supplies power derived from renewable energy has been described. In another embodiment, only the specific first charging device 30a may have a configuration in which the first parameter increases in accordance with the amount of electric power charged by the first charging device 30a. The specific first charging device 30a may be, for example, the first charging device 30a associated with the user of the power storage device 10. The first charging device 30a associated with the user may be, for example, the first charging device 30a owned or rented by the user. For example, the first charging device 30a may store the correspondence relationship between the user and the first charging device 30a according to a user operation when owned or rented by the user. With such a configuration, it is possible to give the user motivation to own or rent the first charging device 30a. Therefore, the use of electric power derived from renewable energy is promoted, and the occurrence of adverse effects on the environment is reduced. For this reason, the convenience of the technology for selling electric power is further improved.

In the embodiment described above, the configuration in which the amount of electric power discharged from the power storage device 10 to the mobile object 40 and the amount of electric power charged to the power storage device 10 by the regenerative braking of the mobile device 40 are separately stored in the charge/discharge history information will be described. did. In another embodiment, the amount of discharge power from the power storage device 10 to the moving body 40 and the amount of charge power of the power storage device 10 by the regenerative braking of the moving body 40 may be collectively stored in the charge/discharge history information. In general, the amount of electric power discharged from power storage device 10 to mobile body 40 is larger than the amount of electric power charged to power storage device 10 by the regenerative braking of mobile body 40. Therefore, the remaining capacity of the power storage device 10 at the end of the movement of the moving body 40 is smaller than that at the start of the movement of the moving body 40. Therefore, the total value of the first parameter and the second parameter may decrease as described above, depending on the amount of decrease in the remaining capacity of power storage device 10 before and after movement of moving body 40.

In another embodiment, the charging device 30 may be one device having both the functions of the first charging device 30a and the second charging device 30b. The charging device 30 can select and use the electric power derived from the renewable energy or the electric power derived from the exhaustible energy, for example, by performing an arbitrary process such as switching inside the device and power measurement separately. it can. The charging device 30 supplies electric power derived from renewable energy as the first charging device 30a, and supplies electric power derived from exhaustible energy as the second charging device 30b when the supply of electric power derived from the renewable energy is stopped. You can

In other embodiments, the charging device 30 may include a storage battery. For example, the charging device 30 may function as the first charging device 30a capable of supplying the electric power derived from the renewable energy stored in the storage battery, when the storage battery is charged with only the electric power derived from the renewable energy. Good.

In another embodiment, charge/discharge history information regarding charge/discharge of the power storage device 10 may be stored in a device other than the power storage device 10. The other devices may include, for example, a computer provided in the home of the user of the power storage device 10, a storage device installed in the mobile unit 40, a server connected to the communication network, and the like. In such a case, the control unit 15 of the power storage device 10 transmits the charge/discharge history information to the other device via the communication unit 12 every time charging/discharging of the power storage device 10 is performed, for example. The other device stores the charge/discharge history information received from the power storage device 10.

1 power system 10 power storage device 11 storage battery 12 communication unit 13 sensor unit 14 storage unit 15 control unit 20 power device 21 communication unit 22 sensor unit 23 storage unit 24 control unit 30 charging device 30a first charging device 30b second charging device 31 communication Unit 32 sensor unit 33 storage unit 34 control unit 40 moving body

Claims (12)

A power system comprising: a power storage device; and a power device that receives supply of power from the power storage device,
When the power storage device and the power device are connected to each other, the power storage device or the power device determines, based on charge/discharge history information regarding charging/discharging of the power storage device, supply of electric power that the power device receives from the power storage device. Controlled by the electric power system. The power system according to claim 1, wherein
The charge/discharge history information increases in accordance with a first parameter that increases according to the amount of charge power from the first charging device that satisfies a predetermined condition, and according to the amount of charge power from the second charging device that does not satisfy the predetermined condition. A second parameter and a power system. The power system according to claim 2, wherein
The power storage system, wherein the power storage device or the power device permits the power device to accept power supply from the power storage device up to an upper limit power amount determined based on the first parameter. The power system according to claim 2, wherein
The power storage device or the power device allows the power device to accept the supply of power from the power storage device when the second parameter is zero, and the power device is allowed when the second parameter is not zero. A power system that prohibits acceptance of power supply from the power storage device. The power system according to any one of claims 2 to 4,
An electric power system including the condition that the predetermined condition is a charging device that supplies electric power generated using renewable energy. The power system according to any one of claims 2 to 4,
The predetermined condition includes an electric power system that supplies electric power generated using renewable energy and is a charging device associated with a user of the power storage device. The power system according to any one of claims 2 to 6,
When the power storage device discharges other than supplying power to the power device, the total value of the first parameter and the second parameter is reduced by the amount of discharged power,
A power system, wherein the second parameter is preferentially reduced if the second parameter is greater than zero. The power system according to any one of claims 2 to 7,
The power storage system reduces the first parameter by an amount of power supplied to the power device when the power device supplies power to the power device. The power system according to any one of claims 2 to 8, wherein:
The power storage device is mounted on a moving body that charges the power storage device by a regenerative brake,
The second parameter increases according to an amount of electric power charged by a regenerative brake of the moving body. The power system according to any one of claims 1 to 9,
The power system, wherein the power device gives a reward to the user of the power storage device according to the amount of power supplied by the power storage device. A power storage device that supplies power to a power device,
A power storage device comprising: a control unit that, when connected to the power device, controls the supply of electric power that the power device receives from the power storage device based on charge/discharge history information regarding charging/discharging of the power storage device. A method for controlling a power system, comprising: a power storage device; and a power device that receives power supply from the power storage device,
When the power storage device or the power device is connected to the power storage device and the power device, the power supply receives power supplied from the power storage device based on charge/discharge history information about charge/discharge of the power storage device. A method of controlling a power system, the method including controlling the power system.

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