JP6805763B2 - Storage battery control device, storage battery control system, storage battery control method, and program - Google Patents

Description

The present invention relates to a storage battery control device, a storage battery control system, a storage battery control method, and a program.

Patent Document 1 is a supply and demand management device that manages a power consumption state in a consumer area that consumes power supplied from a plurality of power plants with at least one electric load, and has characteristics of each of the plurality of power stations. A power characteristic index calculation unit that calculates a power characteristic index indicating, a command value calculation unit that calculates a command value including at least an allowable value of power consumption in an electric load using at least the power characteristic index, and an electric load. A supply and demand management device including a load control unit that controls an electric load so that the power consumption in the above is less than an allowable value is disclosed.

Patent Document 2 describes a distributed power source connected to a power system, a voltage measuring unit for measuring the voltage of an interconnection point connected to the power system provided for each distributed power system, and a predetermined group set in advance. A centralized control device that allocates a voltage adjustment amount to the distributed power supply with a predetermined weight, and a distributed processing device that causes the distributed power supply to adjust the voltage at the interconnection point according to the voltage adjustment amount assigned by the centralized control device. A power system control system having a, is disclosed.

Patent Document 3 discloses a communication device that communicates with a first meter reading device having a communication function. The first meter reading device communicates with the second meter reading device and the communication device using the same communication medium. The first meter reading device communicates with the second meter reading device with a predetermined transmission cycle and transmission time length. When the communication device detects a signal transmitted from the first meter reading device to the second meter reading device, the communication device sets a transmission prohibition time section of the communication device based on at least one of the transmission cycle and the transmission time length.

Patent Document 4 discloses a power control system used for a group of consumers having a distributed power source and a power conditioner for each of a plurality of consumers. The power control system is provided with a control unit for each of a plurality of consumers, which controls a power conditioner to sell power over a predetermined length of power selling period. Further, the power control system includes a server configured to be able to communicate with each of the plurality of control units. The server allocates a power selling period to each of the plurality of control units according to the magnitude of the voltage of the commercial power system.

Japanese Unexamined Patent Publication No. 2016-92885 JP-A-2015-188313 JP 2015-070507 Japanese Unexamined Patent Publication No. 2016-7133

Technology that uses storage batteries of electric power consumers is being studied to adjust the balance between supply and demand of electric power systems. That is, the storage battery is charged / discharged according to the state of the power system.

When the storage battery is controlled according to a fluctuation with a short cycle of several minutes or less, it is preferable to measure the state information of the power system on the storage battery side in consideration of the real-time property required for the control. However, when a device for measuring the state information of the electric power system is installed in each of a plurality of consumers, a cost problem arises.

An object of the present invention is to solve a cost problem that occurs when measuring the state information of an electric power system on the storage battery side in a technique of using a storage battery of an electric power consumer for adjusting the balance between supply and demand of the electric power system.

According to the present invention
Acquisition means for acquiring power system status information from the measuring device,
A control means for controlling charging / discharging of the storage battery using the state information,
A transmission means for transmitting the state information to another storage battery control device, and
Have a,
The state information includes the frequency of the power system.
The control means is based on control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system and the frequency of the power system acquired by the acquisition means. A storage battery control device for determining the control content of the storage battery is provided.

Further, according to the present invention,
An acquisition means for acquiring power system status information from one or more other storage battery control devices, and
A control means for controlling charging / discharging of the storage battery using one or more of the above state information, and
Have a,
The state information includes the frequency of the power system.
The control means includes control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system, and one or a plurality of power systems acquired by the acquisition means. A storage battery control device for determining the control content of the storage battery based on the frequency is provided.

Further, according to the present invention, a storage battery control system having the storage battery control device is provided.

Further, according to the present invention,
The computer
The acquisition process to acquire the status information of the power system from the measuring device,
A control process that controls charging / discharging of the storage battery using the state information,
A transmission process for transmitting the state information to another storage battery control device, and
And run
The state information includes the frequency of the power system.
In the control step, the power to be charged or discharged by the storage battery is determined based on the control information determined according to the degree of deviation from the reference value of the frequency of the power system, and the frequency of the power system acquired in the acquisition step . A storage battery control method for determining the control content of the storage battery is provided.

Further, according to the present invention,
Computer,
Acquisition means for acquiring power system status information from the measuring device,
A control means for controlling charging / discharging of a storage battery using the state information,
A transmission means for transmitting the state information to another storage battery control device,
To function as,
The state information includes the frequency of the power system.
The control means is based on control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system and the frequency of the power system acquired by the acquisition means. A program for determining the control content of the storage battery is provided.

Further, according to the present invention,
The computer
An acquisition process for acquiring power system status information from one or more other storage battery control devices,
A control step that controls charging / discharging of the storage battery using one or more of the above state information, and
And run
The state information includes the frequency of the power system.
In the control step, control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system, and one or a plurality of power systems acquired in the acquisition step. A storage battery control method for determining the control content of the storage battery based on the frequency is provided.

Further, according to the present invention,
Computer,
Acquisition means for acquiring power system status information from one or more other storage battery control devices,
A control means for controlling charging / discharging of a storage battery using one or more of the above state information.
To function as,
The state information includes the frequency of the power system.
The control means includes control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system, and one or a plurality of power systems acquired by the acquisition means. A program is provided that determines the control content of the storage battery based on the frequency .

According to the present invention, in the technique of using the storage battery of the electric power consumer for adjusting the supply-demand balance of the electric power system, it is possible to solve the cost problem that occurs when the state information of the electric power system is measured on the storage battery side.

This is an example of a functional block diagram of the storage battery control system of the present embodiment. It is a figure which conceptually shows an example of the hardware composition of the storage battery control device of this embodiment. This is an example of a functional block diagram of the first storage battery control device of the present embodiment. It is a flowchart which shows an example of the processing flow of the power management apparatus of this embodiment. This is an example of a functional block diagram of the second storage battery control device of the present embodiment. It is a figure which shows the configuration example of the storage battery control system of this embodiment.

<First Embodiment>
First, the overall picture and outline of the storage battery control system of the present embodiment will be described. FIG. 1 shows an example of a functional block diagram of the storage battery control system of the present embodiment. As shown in the figure, the storage battery control system includes a plurality of first storage battery control devices 10, a plurality of second storage battery control devices 20, and a server 30. The number of the first storage battery control device 10 and the number of the second storage battery control devices 20 may be the same or different.

The first storage battery control device 10, the second storage battery control device 20, and the server 30 are configured to be able to communicate with each other by any communication means. For example, the communication between the first storage battery control device 10 and the server 30 and the communication between the second storage battery control device 20 and the server 30 are communication networks such as LAN (Local Area Network) and WAN (Wide Area Network). May be realized by. Then, the communication between the first storage battery control device 10 and the second storage battery control device 20 may be realized by the same method as described above, or may be realized by another method. For example, communication between the first storage battery control device 10 and the second storage battery control device 20 may be realized by the 920 MHz wireless system or other wireless system adopted in a smart meter or the like.

The storage battery control system of the present embodiment controls the storage battery according to fluctuations in a short cycle of several minutes or less (changes in the state of the power system).

The server 30 generates control information (eg, function, correspondence table, etc.) for each storage battery, which defines the power [W] to be charged or discharged by the storage battery according to the degree of deviation from the reference value of the frequency of the power system. The power is transmitted to each storage battery control device (first storage battery control device 10 and second storage battery control device 20). The server 30 generates control information (example: function, corresponding table, etc.) for each storage battery, which defines the power [W] to be charged or discharged by the storage battery according to the degree of deviation from the reference value of the voltage of the power system. Then, it may be transmitted to each storage battery control device (first storage battery control device 10 and second storage battery control device 20). For example, the server 30 may review the content of the control information in a cycle of several minutes to several tens of minutes, and transmit new control information to each storage battery control device in the cycle.

Both the first storage battery control device 10 and the second storage battery control device 20 determine the control content of the storage battery based on the control information received from the server 30 and the state information of the power system, and the storage battery is determined based on the determined content. To control. However, the first storage battery control device 10 and the second storage battery control device 20 have different means for acquiring state information of the electric power system.

The first storage battery control device 10 acquires power system status information from the measuring device. The measuring device is installed, for example, on the premises of the electric power consumer who manages the first storage battery control device 10.

On the other hand, the second storage battery control device 20 acquires the state information of the power system from the first storage battery control device 10. That is, the first storage battery control device 10 transmits the state information of the power system acquired from the measuring device to the second storage battery control device 20. Then, the second storage battery control device 20 receives the state information of the power system from the first storage battery control device 10.

In the case of the storage battery control system of the present embodiment as described above, a measuring device for measuring the state information of the power system may be installed corresponding to the first storage battery control device 10, and corresponds to the second storage battery control device 20. There is no need to install the measuring device. In such a case, the number of measuring devices to be installed can be reduced. As a result, the cost burden can be reduced as compared with the case where the measuring device is installed corresponding to all the storage battery control devices.

Next, the configurations of the first storage battery control device 10 and the second storage battery control device 20 will be described in detail.

First, an example of the hardware configuration of the first storage battery control device 10 and the second storage battery control device 20 of the present embodiment will be described. Each functional unit included in the first storage battery control device 10 and the second storage battery control device 2010 of the present embodiment stores a CPU (Central Processing Unit) of an arbitrary computer, a memory, a program loaded into the memory, and the program. Storage unit such as a hard disk (in addition to programs stored from the stage of shipping the device in advance, it can also store programs downloaded from storage media such as CDs (Compact Discs) and servers on the Internet), communication networks It is realized by any combination of hardware and software centering on the connection interface. And, it is understood by those skilled in the art that there are various modifications of the realization method and the device.

FIG. 2 is a block diagram illustrating a hardware configuration of the first storage battery control device 10 and the second storage battery control device 20 of the present embodiment. As shown in FIG. 2, the first storage battery control device 10 and the second storage battery control device 20 include a processor 1A, a memory 2A, an input / output interface 3A, a peripheral circuit 4A, and a bus 5A. The peripheral circuit 4A includes various modules. It is not necessary to have the peripheral circuit 4A.

The first storage battery control device 10 and the second storage battery control device 20 may each be realized by one physically and / or logically integrated device, and may be physically and / or logically integrated. It may be realized by a plurality of devices separated from each other. In the latter case, each of the plurality of devices may have a hardware configuration as shown in FIG. Then, a plurality of devices may cooperate to realize the functions of the first storage battery control device 10 and the second storage battery control device 20.

The bus 5A is a data transmission line for the processor 1A, the memory 2A, the peripheral circuit 4A, and the input / output interface 3A to transmit and receive data to and from each other. The processor 1A is, for example, an arithmetic processing unit such as a CPU (Central Processing Unit) or a GPU (Graphics Processing Unit). The memory 2A is, for example, a memory such as a RAM (Random Access Memory) or a ROM (Read Only Memory). The input / output interface 3A is an interface for acquiring information from an input device (example: keyboard, mouse, microphone, etc.), an external device, an external server, an external sensor, etc., and an output device (example: display, speaker, printer, mailer). Etc.), including an interface for outputting information to an external device, an external server, etc. The processor 1A can issue commands to each module and perform calculations based on the calculation results thereof.

Next, the function of the first storage battery control device 10 of the present embodiment will be described in detail. FIG. 3 shows an example of a functional block diagram of the first storage battery control device 10 of the present embodiment. As shown in the figure, the first storage battery control device 10 includes an acquisition unit 11, a control unit 12, and a transmission unit 13.

The acquisition unit 11 acquires the state information of the power system from the measuring device. Examples of the state information include frequency [Hz] and voltage [V] of the power system.

The measuring device repeatedly measures the state information at predetermined time intervals (eg, several seconds, several seconds of commas), and transmits the measurement result to the first storage battery control device 10 by real-time processing. Then, the acquisition unit 11 repeatedly acquires the state information at predetermined time intervals (example: several seconds, several seconds of commas).

The communication between the measuring device and the first storage battery control device 10 may be wired communication or wireless communication. However, considering the troublesomeness of wiring and accidents related to wiring (eg, a person getting his foot caught in the wiring), wireless communication is preferable.

The measuring device is installed at a position where the state information as described above can be measured and at a position where communication with the first storage battery control device 10 is possible. The position where the state information can be measured as described above is exemplified, but is not limited to the distribution board, the outlet, the wiring, and the like. For example, the measuring device is installed at a position where the above-mentioned state information can be measured and within a predetermined distance from the first storage battery control device 10 (a value determined according to the communication distance of wireless communication or the like). You may.

The control unit 12 determines the control content of charging / discharging of the storage battery by using the state information acquired by the acquisition unit 11. Then, the control unit 12 controls the storage battery so as to charge and discharge according to the determined contents.

The control unit 12 receives from the server 30 control information (example: function, correspondence table, etc.) that defines the power [W] to be charged or discharged by the storage battery according to the degree of deviation from the reference value of the frequency of the power system. To do. For example, the control unit 12 may receive the latest control information from the server 30 at a cycle of several minutes to several tens of minutes.

Then, the control unit 12 determines the control content of the storage battery based on the latest control information and the frequency (state information) of the power system acquired by the acquisition unit 11. That is, the control unit 12 calculates the degree of deviation from the reference value of the frequency of the power system based on the frequency of the power system acquired by the acquisition unit 11. Then, the control unit 12 determines the electric power to be charged or discharged by the storage battery based on the calculated degree of dissociation and the control information. Next, the control unit 12 controls the storage battery so as to charge or discharge the determined electric power.

The control information received from the server 30 is control information (example: function, correspondence table, etc.) that defines the power [W] to be charged or discharged by the storage battery according to the degree of deviation from the reference value of the voltage of the power system. It may be. Then, the control unit 12 may determine the control content of the storage battery based on the control information and the voltage (state information) of the power system acquired by the acquisition unit 11.

The acquisition unit 11 can acquire the power system status information (frequency or voltage) at a time interval (several seconds to a few seconds) shorter than the time interval (several minutes to several tens of minutes) for receiving control information from the server. it can. Then, the control unit 12 controls the storage battery based on the latest control information and the latest state information of the electric power system. Until the latest new control information is received from the server, it is based on the control information received before that (the latest control information at that time) and the latest power system status information (frequency or voltage). Control the storage battery. Then, when the new latest control information is received from the server, the storage battery is controlled based on the newly received control information and the latest power system status information.

Here, an example of the processing flow of the control unit 12 will be described with reference to the flowchart of FIG. When the control unit 12 acquires the state information from the acquisition unit 11 (S10), the control unit 12 determines the control content of the storage battery based on the state information and the latest control information received from the server 30 (S11). Then, the control unit 12 charges and discharges the storage battery according to the determined control content (S12).

Returning to FIG. 3, the transmission unit 13 transmits the state information acquired by the acquisition unit 11 to another storage battery control device (second storage battery control device 20). For example, the transmission unit 13 may broadcast to the second storage battery control device 20 within a predetermined distance from the first storage battery control device 10 by broadcasting. It is preferable that the transmission unit 13 performs the transmission with a smaller time loss from the acquisition of the state information by the acquisition unit 11.

The transmission unit 13 may transmit the state information in association with the information that identifies the own device (first storage battery control device 10). Further, the transmission unit 13 may transmit the state information in association with information indicating the measurement timing of the state information (example: measurement date and time).

It should be noted that the transmission timing of each of the plurality of first storage battery control devices 10 may be shifted so that the data is not congested due to the transmission of the state information by the plurality of first storage battery control devices 10. That is, the transmission unit 13 may transmit the state information at a timing different from that of the transmission unit 13 of the other first storage battery control device 10. It should be noted that transmission may be performed at a timing different from the transmission unit 13 of another first storage battery control device 10 (eg, another first storage battery control device 10 located within a predetermined distance) in the vicinity where there is a risk of congestion. .. It is not necessary to adjust the transmission timing with the transmission unit 13 of the other first storage battery control device 10 in the distance where there is no risk of congestion. For example, the transmission timing of each of the plurality of first storage battery control devices 10 may be determined in advance and registered in each of the first storage battery control devices 10. Each first storage battery control device 10 transmits the state information according to the registered transmission timing. The transmission timings of the plurality of first storage battery control devices 10 are shifted from each other by a predetermined time.

Next, the function of the second storage battery control device 20 of the present embodiment will be described in detail. FIG. 5 shows an example of a functional block diagram of the second storage battery control device 20 of the present embodiment. As shown in the figure, the second storage battery control device 20 has an acquisition unit 21 and a control unit 22.

The acquisition unit 21 acquires power system status information from another one or more storage battery control devices (first storage battery control device 10). That is, the acquisition unit 21 of the second storage battery control device 20 receives the state information transmitted by the transmission unit 13 of the first storage battery control device 10. When a plurality of first storage battery control devices 10 are present at communicable positions, the acquisition unit 21 can receive state information from each of the plurality of first storage battery control devices 10.

The control unit 22 determines the control content of charging / discharging of the storage battery by using one or a plurality of state information acquired by the acquisition unit 21. Then, the control unit 22 controls the storage battery so as to charge and discharge according to the determined contents.

The control unit 22 receives from the server 30 control information (example: function, correspondence table, etc.) that defines the power [W] to be charged or discharged by the storage battery according to the degree of deviation from the reference value of the frequency of the power system. To do. For example, the control unit 22 may receive the latest control information from the server 30 at a cycle of several minutes to several tens of minutes.

Then, the control unit 22 determines the control content of the storage battery based on the latest control information and the frequency (state information) of the power system acquired by the acquisition unit 21. That is, the control unit 22 calculates the degree of deviation from the reference value of the frequency of the power system based on the frequency of the power system acquired by the acquisition unit 21. When the acquisition unit 21 receives power system frequencies (state information) from the plurality of first storage battery control devices 10, the control unit 22 receives statistical values (example: average value, mode value) of the plurality of frequencies. , Maximum value, minimum value, median value, etc.) as the frequency of the power system, and the degree of deviation from the reference value of the frequency of the power system can be calculated. The control unit 22 can calculate the above statistical value by collecting a plurality of state information among those measured at the same timing based on the information indicating the measurement timing associated with the state information (example: measurement date and time). it can.

Then, the control unit 22 determines the electric power to be charged or discharged by the storage battery based on the calculated degree of dissociation and the control information. Next, the control unit 22 controls the storage battery so as to charge or discharge the determined electric power.

The control information received from the server 30 is control information (example: function, correspondence table, etc.) that defines the power [W] to be charged or discharged by the storage battery according to the degree of deviation from the reference value of the voltage of the power system. It may be. Then, the control unit 22 may determine the control content of the storage battery based on the control information and the voltage (state information) of the power system acquired by the acquisition unit 21.

The acquisition unit 11 can acquire the power system status information (frequency or voltage) at a time interval (several seconds to a few seconds) shorter than the time interval (several minutes to several tens of minutes) for receiving control information from the server. it can. Then, the control unit 12 controls the storage battery based on the latest control information and the latest state information of the electric power system. Until the latest new control information is received from the server, it is based on the control information received before that (the latest control information at that time) and the latest power system status information (frequency or voltage). Control the storage battery. Then, when the new latest control information is received from the server, the storage battery is controlled based on the newly received control information and the latest power system status information.

Here, an example of the processing flow of the control unit 22 will be described with reference to the flowchart of FIG. When the control unit 22 acquires the state information from the acquisition unit 21 (S10), the control unit 22 determines the control content of the storage battery based on the state information and the latest control information received from the server 30 (S21). Then, the control unit 22 charges and discharges the storage battery according to the determined control content (S22).

According to the storage battery control system of the present embodiment described above, it is sufficient to install a measuring device for measuring the state information of the power system corresponding to the first storage battery control device 10, and it corresponds to the second storage battery control device 20. Therefore, it is not necessary to install the measuring device. In such a case, the number of measuring devices to be installed can be reduced. As a result, the cost burden can be reduced as compared with the case where the measuring device is installed corresponding to all the storage battery control devices.

<Second embodiment>
In the storage battery control system of the present embodiment, the first storage battery control device 10 receives the state information of the power system from the other first storage battery control device 10, and the state information acquired from the measuring device and the other first storage battery. It differs from the first embodiment in that the storage battery is controlled based on the state information acquired from the control device 10. Other configurations are the same as in the first embodiment.

The functional block diagram of the first storage battery control device 10 is shown in FIG. 3 as in the first embodiment. As shown in the figure, the first storage battery control device 10 includes an acquisition unit 11, a control unit 12, and a transmission unit 13.

The acquisition unit 11 acquires the state information of the power system from the measuring device as in the first embodiment. Further, the acquisition unit 11 acquires the state information from the other one or a plurality of first storage battery control devices 10. That is, the acquisition unit 11 receives the state information transmitted by the transmission unit 13 of the other first storage battery control device 10 (the other first storage battery control device 10 having a positional relationship capable of communicating with the own device).

The control unit 12 of the storage battery is based on a plurality of state information (state information acquired from the measuring device, state information acquired from the other one or a plurality of first storage battery control devices 10) acquired by the acquisition unit 11. Determine the control content. Then, the control unit 12 controls the storage battery so as to charge and discharge according to the determined contents.

The control unit 12 receives from the server 30 control information (example: function, correspondence table, etc.) that defines the power [W] to be charged or discharged by the storage battery according to the degree of deviation from the reference value of the frequency of the power system. To do. For example, the control unit 22 may receive the latest control information from the server 30 at a cycle of several minutes to several tens of minutes.

Then, the control unit 12 determines the control content of the storage battery based on the latest control information and the frequency (state information) of the power system acquired by the acquisition unit 11. That is, the control unit 12 calculates the degree of deviation from the reference value of the frequency of the power system based on the frequency of the power system acquired by the acquisition unit 11. In the case of the present embodiment in which the acquisition unit 11 receives frequencies (state information) of a plurality of power systems, the control unit 12 has statistical values (example: average value, mode value, maximum value, etc.) of the plurality of frequencies. The degree of deviation from the reference value of the frequency of the power system can be calculated by using the minimum value, the median value, etc.) as the frequency of the power system. Based on the information indicating the measurement timing associated with the state information (example: measurement date and time), the control unit 12 can collect a plurality of state information measured at the same timing and calculate the above statistical value. it can.

Then, the control unit 12 determines the electric power to be charged or discharged by the storage battery based on the calculated degree of dissociation and the control information. Next, the control unit 12 controls the storage battery so as to charge or discharge the determined electric power.

The control information received from the server 30 is control information (example: function, correspondence table, etc.) that defines the power [W] to be charged or discharged by the storage battery according to the degree of deviation from the reference value of the voltage of the power system. It may be. Then, the control unit 12 may determine the control content of the storage battery based on the control information and the voltage (state information) of the power system acquired by the acquisition unit 11.

The configuration of the transmission unit 13 of the first storage battery control device 10 is the same as that of the first embodiment. The configuration of the second storage battery control device 20 and the server 30 is the same as that of the first embodiment.

According to the storage battery control system of the present embodiment described above, the same operation and effect as those of the first embodiment can be realized. Further, according to the storage battery control system of the present embodiment, the first storage battery control device 10 is a storage battery based on the state information acquired from the measuring device and the state information acquired from the other first storage battery control device 10. The control content of can be determined.

When the control content of the storage battery is determined based on only one state information, the storage battery is controlled based on the incorrect state information when the measurement accuracy deteriorates due to noise in the state information or a failure of the measuring device. The inconvenience of doing so can occur. According to the storage battery control system of the present embodiment, in which the first storage battery control device 10 capable of acquiring state information from the measuring device can also control the storage battery based on a plurality of state information, the occurrence of the above-mentioned inconvenience can be suppressed.

Here, a modified example applicable to the first and second embodiments will be described. In the modified example, the second storage battery control device 20 may have a transmission unit that transmits predetermined information to other nearby storage battery control devices (first storage battery control device 10 and second storage battery control device 20). Good.

Then, the transmission unit 13 of the first storage battery control device 10 and the transmission unit of the second storage battery control device 20 correspond to the information about the own device (hereinafter, "first information") with the identification information of the own device. It may be attached and simultaneously transmitted (eg, broadcast) to other nearby storage battery control devices (first storage battery control device 10 and second storage battery control device 20). The other storage battery control device (first storage battery control device 10 and second storage battery control device 20) that has received the first information stores the received first information in association with the identification information of the transmission source device. To do. The storage battery control device (first storage battery control device 10 and second storage battery control device 20) has the first information at an arbitrary timing (eg, every 3 minutes, every 1 hour, every 12 hours, every 1 day, etc.). Can be transmitted all at once.

Further, the transmission unit 13 of the first storage battery control device 10 and the transmission unit of the second storage battery control device 20 associate the request for the first information with the identification information of the own device at an arbitrary timing. Simultaneous transmission (eg, broadcast) may be performed to other nearby storage battery control devices (first storage battery control device 10 and second storage battery control device 20). For example, the above request may be sent at the first startup after recovery from a failure, or after deleting the information stored up to that point by a reset operation, or the above request may be sent according to an operation from the operator. You may.

Other nearby storage battery control devices (first storage battery control device 10 and second storage battery control device 20) that have received the request store the first information in association with the device from which the request is transmitted. , The identification information of the device of the transmission source is associated with the simultaneous transmission (eg, broadcast) to other storage battery control devices (first storage battery control device 10 and second storage battery control device 20) in the vicinity.

The storage battery control device (first storage battery control device 10 and second storage battery control device 20) that has transmitted the above request is another nearby storage battery control device (first storage battery control device 10 and second storage battery control device 20). ), The first information received from) is recorded in the own device. As a result, the storage battery control device (the first storage battery control device 10 and the second storage battery control device 20) can restore the information recorded in the own device before the failure or before the reset.

The content of the first information is not particularly limited, but for example, it may be measurement data measured by a smart meter within the latest predetermined time, or the acquisition unit 11 of the first storage battery control device 10 obtains the state information. It may be information indicating the timing of transmission.

According to the modification, the information recorded in each device before the failure or reset can be restored by the cooperation between the neighboring storage battery control devices.

Here, other modifications applicable to the first and second embodiments will be described. In the modified example, the second storage battery control device 20 may have a transmission unit that transmits predetermined information to other nearby storage battery control devices (first storage battery control device 10 and second storage battery control device 20). Good.

Then, the first storage battery control device 10 and the second storage battery control device 20 that have received the state information simultaneously transmitted by the first storage battery control device 10 transfer the state information to another storage battery control device (first storage battery). Simultaneous transmission (transfer) may be performed toward the control device 10 and the second storage battery control device 20). In the case of the modified example in which the state information transmitted by the first storage battery control device 10 can be transferred, the state information is transferred to a farther storage battery control device (first storage battery control device 10 and second storage battery control device 20). Can be delivered.

In the case of the modified example, the storage battery control device (first storage battery control device 10 and second storage battery control device 20) that has received the state information provides means for determining whether or not to transfer the received state information. You may have. For example, the means may determine that the received state information is not transferred when the elapsed time from the measurement timing exceeds the reference value, but is transferred when it is within the reference value. In addition, when the status information transmitted by the own device in the past is received from another storage battery control device (first storage battery control device 10 and second storage battery control device 20), even if it is determined that the status information is not transferred. Good. In addition, the number of times transferred may be recorded in the transferred state information. That is, each storage battery control device (first storage battery control device 10 and second storage battery control device 20) may update the number of times of transfer each time. Then, it may be determined that the forwarding is not performed when the number of transfers exceeds the reference value and is transferred when the number of transfers is within the reference value.

Further, the storage battery control device (first storage battery control device 10 and / or second storage battery control device 20) including means for transmitting information all at once has not only the status information of the power system but also the control information received from the server 30. May be transmitted to other storage battery control devices (first storage battery control device 10 and second storage battery control device 20) at predetermined intervals.

It should be noted that the storage battery control device (first storage battery control device 10 and second storage battery control device 20) is based on the attribute information (rated output, SOC (State Of Charge), manufacturer, date of manufacture, deterioration status, etc.) related to the storage battery. May be grouped and control information may be sent and received within the same group. In this case, for example, the storage battery control device (first storage battery control device 10 and / or second storage battery control device 20) that simultaneously transmits control information includes information for identifying the group to which the own device belongs in the transmitted control information. It may be given and transmitted all at once. Then, in the storage battery control device (first storage battery control device 10 and second storage battery control device 20) that has received the control information transmitted all at once, the information that identifies the given group identifies the group to which the own device belongs. If it is information, the information may be stored in the own device, and if it is not information that identifies the group to which the own device belongs, the information may be discarded. By doing so, it is not necessary for some storage control devices (first storage battery control device 10 and second storage battery control device 20) to receive control information from the server 30. As a result, it is possible to prevent data congestion from occurring between the server 30 and the plurality of storage battery control devices (first storage battery control device 10 and second storage battery control device 20).

Further, other modifications applicable to the first and second embodiments will be described. The storage battery control device (the first storage battery control device 10 and / or the second storage battery control device) is a storage battery determined based on the control information and the state information of the power system in place of or in addition to the state information of the power system. The control content may be simultaneously transmitted to another storage battery control device (first storage battery control device 10 and / or second storage battery control device).

Here, a configuration example of the storage battery control system of the first and second embodiments will be described with reference to FIG. The illustrated server corresponds to the server 30 described above. The server is managed by RA (Resource Aggregator).

The consumer 1 has a consumer EMS, a measuring device, an energy device (eg, a storage battery), and a smart meter. Demander 2 differs from Demander 1 in that it does not have a measuring device.

The consumer EMS of the consumer 1 corresponds to the first storage battery control device 10 described above. The consumer EMS of the consumer 2 corresponds to the second storage battery control device 20 described above.

The server and the consumer EMS communicate with each other via a communication network managed by the telecommunications carrier. Consumer EMSs located within a predetermined distance communicate with each other by a predetermined wireless communication method (example: 920 MHz wireless method). Although not shown, the customer EMSs of the customer 1 located within a predetermined distance (first storage battery control devices 10) communicate with each other by a predetermined wireless communication method (example: 920 MHz wireless method). You may.

In the present specification, "acquisition" means that the own device retrieves data or information stored in another device or storage medium (active acquisition), for example, requesting or requesting another device. Inquiring and receiving, accessing and reading other devices and storage media, and inputting data or information output from other devices to own device (passive acquisition), for example, distribution Includes at least one of receiving data or information (or being transmitted, push notifications, etc.). It also includes selecting and acquiring the received data or information, or selecting and receiving the delivered data or information.

Hereinafter, an example of the reference form will be added.
1. 1. Acquisition means for acquiring power system status information from the measuring device,
A control means for controlling charging / discharging of the storage battery using the state information,
A transmission means for transmitting the state information to another storage battery control device, and
Battery control device with.
2. 2. In the storage battery control device according to 1.
The state information includes the frequency of the power system.
The control means is based on control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system and the frequency of the power system acquired by the acquisition means. A storage battery control device that determines the control content of the storage battery.
3. 3. In the storage battery control device according to 2.
The control means is a storage battery control device that determines the control content of the storage battery based on the control information acquired from the other storage battery control device.
4. In the storage battery control device according to 2 or 3,
The control means
Based on the control information acquired from another device at a predetermined cycle, the control content of the storage battery is determined.
A storage battery control device that determines the control content of a storage battery based on the control information acquired before the acquisition of the new control information and the state information.
5. In the storage battery control device according to any one of 1 to 4,
The acquisition means acquires the state information from another one or a plurality of storage battery control devices, and obtains the state information.
The control means is a storage battery control device that determines the control content of the storage battery based on the plurality of state information acquired by the acquisition means.
6. In the storage battery control device according to 5, which is subordinate to any of 2 to 4.
The control means is a storage battery control device that determines the control content of the storage battery based on the statistical values of frequencies of a plurality of electric power systems acquired by the acquisition means and the control information.
7. In the storage battery control device according to any one of 1 to 6,
The transmission means is a storage battery control device that transmits the state information at a timing different from that of other storage battery control devices.
8. An acquisition means for acquiring power system status information from one or more other storage battery control devices, and
A control means for controlling charging / discharging of the storage battery using one or more of the above state information, and
Battery control device with.
9. In the storage battery control device according to 8.
The state information includes the frequency of the power system.
The control means includes control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system, and one or a plurality of power systems acquired by the acquisition means. A storage battery control device that determines the control content of a storage battery based on the frequency.
10. In the storage battery control device according to 9.
The control means is a storage battery control device that determines the control content of the storage battery based on the control information acquired from the other storage battery control device.
11. In the storage battery control device according to 9 or 10.
The control means
Based on the control information acquired from another device at a predetermined cycle, the control content of the storage battery is determined.
A storage battery control device that determines the control content of a storage battery based on the control information acquired before the acquisition of the new control information and the state information.
12. In the storage battery control device according to any one of 9 to 11.
The control means is a storage battery control device that determines the control content of the storage battery based on the statistical values of frequencies of a plurality of electric power systems acquired by the acquisition means and the control information.
13. In the storage battery control device according to any one of 1 to 12,
The state information is a storage battery control device including the voltage of the power system.
14. The storage battery control device according to any one of 1 to 7 and
The storage battery control device according to any one of 8 to 13 and
Battery control system with.
15. The computer
The acquisition process to acquire the status information of the power system from the measuring device,
A control process stage that controls charging and discharging of the storage battery using the state information,
A transmission process for transmitting the state information to another storage battery control device, and
Battery control method to perform.
16. Computer,
Acquisition means for acquiring power system status information from the measuring device,
A control means for controlling charging / discharging of a storage battery using the state information,
A transmission means for transmitting the state information to another storage battery control device,
A program that functions as.
17. The computer
An acquisition process for acquiring power system status information from one or more other storage battery control devices,
A control step that controls charging / discharging of the storage battery using one or more of the above state information, and
Battery control method to perform.
18. Computer,
Acquisition means for acquiring power system status information from one or more other storage battery control devices,
A control means for controlling charging / discharging of a storage battery using one or more of the above state information.
A program that functions as.

1A processor 2A memory 3A I / O I / F
4A Peripheral circuit 5A Bus 10 1st storage battery control device 11 Acquisition unit 12 Control unit 13 Transmission unit 20 2nd storage battery control device 21 Acquisition unit 22 Control unit 30 Server

Claims (16)

Acquisition means for acquiring power system status information from the measuring device,
A control means for controlling charging / discharging of the storage battery using the state information,
A transmission means for transmitting the state information to another storage battery control device, and
Have,
The state information includes the frequency of the power system.
The control means is based on control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system and the frequency of the power system acquired by the acquisition means. A storage battery control device that determines the control content of the storage battery. In the storage battery control device according to claim 1,
The control means is a storage battery control device that determines the control content of the storage battery based on the control information acquired from the other storage battery control device. In the storage battery control device according to claim 1 or 2.
The control means
Based on the control information acquired from another device at a predetermined cycle, the control content of the storage battery is determined.
A storage battery control device that determines the control content of a storage battery based on the control information acquired before the acquisition of the new control information and the state information. In the storage battery control device according to any one of claims 1 to 3.
The acquisition means acquires the state information from another one or a plurality of storage battery control devices, and obtains the state information.
The control means is a storage battery control device that determines the control content of the storage battery based on the plurality of state information acquired by the acquisition means. The storage battery control device according to claim 4 , which is subordinate to any one of claims 1 to 3.
The control means is a storage battery control device that determines the control content of the storage battery based on the statistical values of frequencies of a plurality of electric power systems acquired by the acquisition means and the control information. In the storage battery control device according to any one of claims 1 to 5,
The transmission means is a storage battery control device that transmits the state information at a timing different from that of other storage battery control devices. An acquisition means for acquiring power system status information from one or more other storage battery control devices, and
A control means for controlling charging / discharging of the storage battery using one or more of the above state information, and
Have,
The state information includes the frequency of the power system.
The control means includes control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system, and one or a plurality of power systems acquired by the acquisition means. A storage battery control device that determines the control content of a storage battery based on the frequency. In the storage battery control device according to claim 7.
The control means is a storage battery control device that determines the control content of the storage battery based on the control information acquired from the other storage battery control device. In the storage battery control device according to claim 7 or 8.
The control means
Based on the control information acquired from another device at a predetermined cycle, the control content of the storage battery is determined.
A storage battery control device that determines the control content of a storage battery based on the control information acquired before the acquisition of the new control information and the state information. In the storage battery control device according to any one of claims 7 to 9.
The control means is a storage battery control device that determines the control content of the storage battery based on the statistical values of frequencies of a plurality of electric power systems acquired by the acquisition means and the control information. In the storage battery control device according to any one of claims 1 to 10.
The state information is a storage battery control device including the voltage of the power system. The storage battery control device according to any one of claims 1 to 6.
The storage battery control device according to any one of claims 7 to 11.
Battery control system with. The computer
The acquisition process to acquire the status information of the power system from the measuring device,
A control process that controls charging / discharging of the storage battery using the state information,
A transmission process for transmitting the state information to another storage battery control device, and
And run
The state information includes the frequency of the power system.
In the control step, the power to be charged or discharged by the storage battery is determined based on the control information determined according to the degree of deviation from the reference value of the frequency of the power system, and the frequency of the power system acquired in the acquisition step . A storage battery control method that determines the control content of the storage battery. Computer,
Acquisition means for acquiring power system status information from the measuring device,
A control means for controlling charging / discharging of a storage battery using the state information,
A transmission means for transmitting the state information to another storage battery control device,
To function as
The state information includes the frequency of the power system.
The control means is based on control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system and the frequency of the power system acquired by the acquisition means. A program that determines the control content of a storage battery. The computer
An acquisition process for acquiring power system status information from one or more other storage battery control devices,
A control step that controls charging / discharging of the storage battery using one or more of the above state information, and
And run
The state information includes the frequency of the power system.
In the control step, control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system, and one or a plurality of power systems acquired in the acquisition step. A storage battery control method that determines the control content of the storage battery based on the frequency. Computer,
Acquisition means for acquiring power system status information from one or more other storage battery control devices,
A control means for controlling charging / discharging of a storage battery using one or more of the above state information.
To function as
The state information includes the frequency of the power system.
The control means includes control information in which the power to be charged or discharged by the storage battery is determined according to the degree of deviation from the reference value of the frequency of the power system, and one or a plurality of power systems acquired by the acquisition means. A program that determines the control content of a storage battery based on the frequency.

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