JP7360895B2 - Control device, server device, management method, and terminal device - Google Patents

Description

The present invention relates to a control device, a server device, and a management method used in a power management system.

Patent Document 1 describes that a server device remotely monitors the temperature, voltage, and internal resistance of each of a plurality of storage battery devices, analyzes these parameters, detects deterioration or abnormality in the storage battery devices, and then sends a message to the user from the server device. A storage battery status monitoring system is described that provides notification to users.

JP 2019-60773 Publication

The system described in Patent Document 1 performs deterioration analysis based on individual detection data detected individually for each of a plurality of storage battery devices, but the detection data regarding the storage battery devices include data common to the plurality of storage battery devices. There may be common detection data detected in .

However, the system described in Patent Document 1 does not take into account common detection data commonly detected by a plurality of storage battery devices, and there is room for improvement in terms of the server device efficiently collecting detection data related to storage battery devices. There is.

Therefore, an object of the present invention is to provide a control device, a server device, and a management method that enable efficient collection of detection data regarding storage battery devices.

The control device according to the first aspect is a device used in a power management system. The control device collects common detection data that is commonly detected by the plurality of storage battery devices and individual detection data that is individually detected for each of the plurality of storage battery devices, from a power conversion device connected to the plurality of storage battery devices. and a second communication unit that transmits the common detection data and the individual detection data to the server device.

The server device according to the second aspect is a device used in a power management system. The server device receives common detection data commonly detected by the plurality of storage battery devices and individual detection data for each of the plurality of storage battery devices, from a control device that controls a power conversion device connected to the plurality of storage battery devices. The communication unit includes a communication unit that receives the individual detection data.

The management method according to the third aspect is a method executed by a control device used in a power management system. The management method includes common detection data that is commonly detected by the plurality of storage battery devices and individual detection data that is individually detected for each of the plurality of storage battery devices, from a power conversion device connected to the plurality of storage battery devices. and transmits the common detection data and the individual detection data to the server device.

The management method according to the fourth aspect is a method executed by a server device used in a power management system. The management method includes common detection data that is commonly detected for the plurality of storage battery devices and individual detection data for each of the plurality of storage battery devices, from a control device that controls a power conversion device connected to the plurality of storage battery devices. and receive the individual detection data.

According to one aspect of the present invention, it is possible to provide a control device, a server device, and a management method that enable efficient collection of detection data regarding a storage battery device.

1 is a diagram illustrating a power management system according to an embodiment. FIG. 1 is a diagram showing the configuration of a storage battery control device according to an embodiment. FIG. 1 is a diagram showing the configuration of a remote monitoring server according to an embodiment. FIG. 3 is a diagram illustrating data sent to a remote monitoring server according to an embodiment. FIG. 3 is a diagram illustrating an operation sequence in the power management system according to an embodiment.

Embodiments will be described with reference to the drawings. In the description of the drawings, the same or similar parts are designated by the same or similar symbols.

(power management system)
First, a power management system according to an embodiment will be described. FIG. 1 is a diagram showing a power management system 1 according to an embodiment. In FIG. 1, thick lines between blocks indicate power lines, and thin lines indicate signal lines. Note that the present invention is not limited to this, and the signal may be transmitted via a power line. The signal line may be wired or wireless.

As shown in FIG. 1, the power management system 1 includes a customer facility 10, a remote monitoring server 400, and a terminal device 500. Consumer facility 10, remote monitoring server 400, and terminal device 500 are interconnected via network 30. Network 30 is, for example, a wide area network. Network 30 may include the Internet.

The consumer facility 10 is a facility that receives power from the power system 20. The customer facility 10 includes a router 310. Router 310 is connected to network 30. Router 310 constitutes a local area network.

In one embodiment, the customer facility 10 includes a storage battery system 100, a solar battery system 200, a load device 320, and an EMS (Energy Management System) 330. In other embodiments, the customer facility 10 may not include the solar cell system 200.

In one embodiment, the storage battery system 100 includes a plurality of storage battery devices 110 (110a to 110c), a storage battery PCS (Power Conditioning System) 120, a storage battery control device 130, and a wireless communication device 140. In other embodiments, the storage battery control device 130 may not include the wireless communication device 140.

Each storage battery device 110 is a device that stores power. Each storage battery device 110 includes a plurality of cells and a BMS (Battery Management System) that manages the plurality of cells. Each storage battery device 110 is connected to a storage battery PCS 120 via a power line. Under the control of the storage battery PCS 120, each storage battery device 110 performs charging with power input via a power line, and outputs power by discharging.

The storage battery system 100 may be configured to allow addition of a storage battery device 110. For example, only the storage battery device 110a may be connected to the storage battery PCS120 at first, and then the storage battery devices 110b and 110c may be added as appropriate through expansion.

Moreover, the storage battery system 100 may be configured such that the storage battery device 110 can be removed or replaced. For example, when the storage battery device 110a has deteriorated, a new storage battery device 110a may be connected to the storage battery PCS 120 after removing the deteriorated storage battery device 110a.

Storage battery PCS120 is an example of a power conversion device that converts DC power to AC power. During discharging, the storage battery PCS 120 converts the DC power input from each storage battery device 110 into AC power, and outputs the AC power. During charging, the storage battery PCS 120 converts AC power supplied from the power system 20 into DC power, and outputs the DC power to each storage battery device 110.

The storage battery PCS 120 controls each storage battery device 110 by communicating with the BMS of each storage battery device 110 via a communication line, and acquires individual detection data detected individually for each storage battery device 110. In addition, the storage battery PCS 120 receives commands from the storage battery control device 130 and transmits individual detection data and common detection data to the storage battery control device 130 by communicating with the storage battery control device 130 via a communication line. do.

Here, the common detection data is data commonly detected by a plurality of storage battery devices 110, and is mainly data detected by storage battery PCS 120. Details of the individual detection data and common detection data will be described later.

Storage battery control device 130 is an example of a control device that controls storage battery PCS 120. The storage battery control device 130 can also be considered as a device that controls each storage battery device 110 via the storage battery PCS 120. The storage battery control device 130 may be integrated with the EMS 330, and this integrated device may be used as a control device.

The storage battery control device 130 transmits common detection data commonly detected by the plurality of storage battery devices 110 and individual detection data detected individually by each of the plurality of storage battery devices 110 via the router 310 or the wireless communication device 140. and transmits it to the remote monitoring server 400.

Storage battery control device 130 may transmit solar cell detection data regarding solar cell system 200 to remote monitoring server 400 together with at least one of common detection data and individual detection data. Details of the solar cell detection data will be described later.

In one embodiment, the battery control device 130 may be a remote control device with a user interface. The storage battery control device 130 notifies the user of information and receives input operations from the user. In other embodiments, the battery controller 130 may not have a user interface.

The wireless communication device 140 is a device that performs wireless communication with the network 30, specifically, WWAN (Wireless Wide Area Network) communication. WWAN communication is, for example, cellular communication or LPWA (Low Power Wide Area) communication. By installing the wireless communication device 140, even if the storage battery control device 130 does not have a connection with the router 310, the storage battery control device 130 communicates with the network 30 via the wireless communication device 140. be able to.

On the other hand, solar cell system 200 includes a solar cell device 210 and a solar cell PCS 220.

The solar cell device 210 is a device that generates power in response to light reception. Solar cell device 210 outputs the generated DC power to solar cell PCS 220. The amount of power generated by the solar cell device 210 changes depending on the amount of solar radiation irradiated to the solar cell device 210.

The solar cell PCS 220 is a device that converts the DC power input from the solar cell device 210 into AC power and outputs the AC power. Solar cell PCS220 may be integrated with storage battery PCS120.

The solar cell PCS 220 receives commands from the storage battery control device 130 and transmits solar cell detection data to the storage battery control device 130 by communicating with the storage battery control device 130 via a communication line. The solar cell detection data is detection data regarding the solar cell device 210, and is data detected by the solar cell PCS 220.

The load device 320 is a device that consumes power supplied from the power system 20, the storage battery system 100, and the solar cell system 200 via power lines. For example, load equipment 320 includes devices such as a refrigerator, lighting, air conditioner, and television. Load device 320 may be a single device or may include multiple devices.

EMS 330 is a device that controls each device (for example, solar cell device 210, solar cell PCS 220, and load device 320).

Remote monitoring server 400 is an example of a server device that communicates with storage battery control device 130. Remote monitoring server 400 receives common detection data and individual detection data from storage battery control device 130 via network 30 . Remote monitoring server 400 may further receive solar cell detection data transmitted from storage battery control device 130 via network 30 .

The remote monitoring server 400 accumulates the received detection data and manages the detection data in association with a user identifier. When the remote monitoring server 400 receives a data request from the terminal device 500, it transmits (distributes) corresponding detection data to the terminal device 500 based on the user identifier of the user of the terminal device 500 who made the data request.

Although FIG. 1 shows an example in which the number of customer facilities 10 to be monitored by the remote monitoring server 400 is one, the remote monitoring server 400 may monitor a plurality of customer facilities 10.

The terminal device 500 is, for example, a PC (Personal Computer), a smartphone, a tablet terminal, or a dedicated terminal. The terminal device 500 displays a monitoring screen for monitoring the status of each device in the customer facility 10, and displays data from the remote monitoring server 400 on this monitoring screen. The terminal device 500 may have application software dedicated to remote monitoring installed therein, or may display a monitoring screen on a general-purpose web browser.

The entity that operates the terminal device 500 may be a user who uses the storage battery system 100 (for example, a resident of the customer facility 10), or a business entity that maintains and manages the storage battery system 100 (for example, a maintenance company or a manufacturer). ).

(Example of configuration of storage battery control device)
Next, a configuration example of the storage battery control device 130 will be described. FIG. 2 is a diagram showing the configuration of the storage battery control device 130 according to one embodiment.

As shown in FIG. 2, the storage battery control device 130 includes a communication interface 131, a user interface 132, a storage section 133, and a control section 134.

The communication interface 131 includes a first communication section 131a, a second communication section 131b, and a third communication section 131c. Two or more communication units among the first communication unit 131a, the second communication unit 131b, and the third communication unit 131c may be integrated. The communication interface 131 does not need to include the third communication unit 131c.

The first communication unit 131a includes a transmitter/receiver, is connected to the storage battery PCS120 via a signal line, and communicates with the storage battery PCS120 under the control of the control unit 134. The first communication unit 131a receives common detection data and individual detection data from the storage battery PCS120, and outputs the received common detection data and individual detection data to the control unit 134. The cycle in which the first communication unit 131a receives common detection data and individual detection data from the storage battery PCS120 is referred to as a "detection data acquisition cycle."

The second communication unit 131b includes a transceiver, is connected to the router 310 or the wireless communication device 140 via a signal line, and communicates with the remote monitoring server 400 under the control of the control unit 134. The second communication unit 131b periodically transmits common detection data and individual detection data to the remote monitoring server 400.

The second communication unit 131b transmits the common detection data and the individual detection data to the remote monitoring server 400 at the first transmission cycle. However, the second communication unit 131b transmits part of the common detection data and part of the individual detection data in a second transmission cycle that is longer than the first transmission cycle. In the following, for convenience, the first transmission cycle may be referred to as a "short cycle", and the second transmission cycle may be referred to as a "long cycle". The second transmission period is a period that is an integral multiple of the first transmission period. The detection data acquisition cycle described above is a cycle shorter than the first transmission cycle (short cycle).

The third communication unit 131c includes a transceiver, is connected to the solar cell PCS220 via a signal line, and communicates with the solar cell PCS220 under the control of the control unit 134. The third communication unit 131c receives solar cell detection data from the solar cell PCS220, and outputs the received solar cell detection data to the control unit 134.

The user interface 132 notifies the user of information and receives input operations from the user. In one embodiment, the user interface 132 includes a display section 132a that displays information regarding the storage battery system 100, and an operation section 132b that receives input operations regarding the storage battery system 100. The display section 132a and the operation section 132b may be integrated as a touch panel display.

The storage unit 133 includes volatile memory and nonvolatile memory, and stores various data and information.

The control unit 134 includes at least one processor, and controls the communication interface 131, the user interface 132, and the storage unit 133. The control unit 134 causes the storage unit 133 to store the common detection data and individual detection data received by the first communication unit 131a and the solar cell detection data received by the third communication unit 131c. Further, the control unit 134 controls the second communication unit 131b to periodically transmit the common detection data, individual detection data, and solar cell detection data to the remote monitoring server 400.

(Example configuration of remote monitoring server)
Next, a configuration example of the remote monitoring server 400 will be described. FIG. 3 is a diagram showing the configuration of a remote monitoring server 400 according to an embodiment.

As shown in FIG. 3, the remote monitoring server 400 includes a communication section 401, a storage section 402, and a control section 403.

The communication unit 401 includes a transmitter/receiver, is connected to the network 30 , and communicates with the storage battery control device 130 and the terminal device 500 via the network 30 . The communication unit 401 periodically receives common detection data, individual detection data, and solar cell detection data from the storage battery control device 130 and outputs the received detection data to the control unit 403.

Further, the communication unit 401 receives a data request from the terminal device 500 via the network 30 and outputs the received data request to the control unit 403. Further, the communication unit 401 transmits (distributes) the detection data to the terminal device 500 under the control of the control unit 403.

The storage unit 402 includes volatile memory and nonvolatile memory, and stores various data and information.

The control unit 403 includes at least one processor, and controls the communication unit 401 and the storage unit 402. The control unit 403 controls the storage unit 402 to store and accumulate the detection data received by the communication unit 401. The control unit 403 manages detection data in association with a user identifier. When the communication unit 401 receives a data request from the terminal device 500, the control unit 403 transmits (distributes) the corresponding detection data to the terminal device 500 based on the user identifier of the user of the terminal device 500 who made the data request. ) the communication unit 401 is controlled so as to

The control unit 403 may detect an abnormality (error) in the storage battery system 100 by analyzing the detection data accumulated in the storage unit 402. For example, when an error is detected, the control unit 403 may control the communication unit 401 to transmit a warning message to that effect and indicating the type of error to the terminal device 500.

(Data sent from the storage battery control device to the remote monitoring server)
Next, detection data regarding the storage battery system 100 will be described as data transmitted from the storage battery control device 130 to the remote monitoring server 400. FIG. 4 is a diagram showing data transmitted from the storage battery control device 130 to the remote monitoring server 400 according to an embodiment.

As described above, the storage battery control device 130 (second communication unit 131b) collects common detection data commonly detected by the plurality of storage battery devices 110 and individual detection data detected individually by each of the plurality of storage battery devices 110. and is periodically transmitted to the remote monitoring server 400. The storage battery control device 130 (second communication unit 131b) may include the common detection data and the individual detection data in one message and transmit it. The individual detection data may have a field provided for each storage battery device 110. This field stores detection data of the corresponding storage battery device 110.

By transmitting detection data common to a plurality of storage battery devices 110 to remote monitoring server 400 as common detection data, an increase in the amount of transmitted data can be suppressed. Furthermore, the remote monitoring server 400 (control unit 403) can not only grasp the individual state of each storage battery device 110 using individual detection data, but also the state common to a plurality of storage battery devices 110 using common detection data.

As shown in FIG. 4A, the common detection data includes storage battery number data indicating the total number (number) of storage battery devices 110 connected to storage battery PCS 120. The transmission cycle of the storage battery number data may be a second transmission cycle (long cycle).

Thereby, the remote monitoring server 400 can grasp the storage battery devices 110 included in the storage battery system 100 under the premise that the number of storage battery devices 110 included in the storage battery system 100 may increase or decrease.

As shown in FIG. 4(b), the common detection data includes a common start time when a plurality of storage battery devices 110 start maintenance mode all at once. The individual detection data includes individual end times at which each of the plurality of storage battery devices 110 individually ends the maintenance mode.

Here, the maintenance mode refers to a mode in which the BMS performs maintenance on the storage battery cells in each storage battery device 110. For example, the maintenance mode is started when the storage battery control device 130 transmits a maintenance start command to the storage battery PCS 120. The time required for maintenance mode may differ between storage battery devices 110 due to individual differences between each storage battery device 110.

By transmitting the individual end time as individual detection data to the remote monitoring server 400, even if the time required for maintenance mode differs between storage battery devices 110, the remote monitoring server 400 can determine the time when each storage battery device 110 has executed the maintenance mode. Can be understood efficiently. Furthermore, by sending the common start time as common detection data to the remote monitoring server 400, the amount of data sent to the remote monitoring server 400 is reduced compared to the case where start time data is sent separately for each storage battery device 110. can.

As shown in FIG. 4C, the common detection data includes common error data indicating at least one of the presence or absence of an error in the storage battery PCS 120 and the presence or absence of an error in the storage battery control device 130. The individual detection data includes individual error data indicating the presence or absence of an error in each of the plurality of storage battery devices 110.

Here, an error refers to some kind of abnormality, and for example, the storage battery control device 130 can detect an error by comparing detected data with a threshold value. When the error data indicates "error present", the storage battery control device 130 may include an identifier (error code) indicating the type of error in the error data.

Thereby, the remote monitoring server 400 (control unit 403) can efficiently grasp errors in the storage battery system 100.

When an error is detected, the storage battery control device 130 (second communication unit 131b) may transmit error status data indicating the error occurrence status to the remote monitoring server 400. The error status data includes detection data detected at a cycle shorter than the transmission cycle to the remote monitoring server 400 (specifically, the detection data acquisition cycle) within a certain period of time before and after the error occurs.

For example, the storage battery control device 130 (second communication unit 131b) transmits time-series data including all detection data (common detection data and individual detection data) acquired at the detection data acquisition cycle within a certain period of time before and after the occurrence of an error. are sent together to the remote monitoring server 400. Thereby, the remote monitoring server 400 (control unit 403) can grasp the error occurrence situation in the storage battery system 100 in detail.

As shown in FIG. 4(d), the common detection data includes common configuration data indicating at least one of the serial number of the storage battery PCS120, the firmware version number of the storage battery PCS120, and the model of the storage battery PCS120. It is assumed that the common detection data is stored in the memory within the storage battery PCS120.

The individual detection data indicates at least one of the serial number of each of the plurality of storage battery devices 110, the firmware version number of each of the plurality of storage battery devices 110 (the plurality of BMSs), and the model of each of the plurality of storage battery devices 110. Contains individual configuration data. It is assumed that the individual configuration data is stored in the memory within each storage battery device 110 or the memory within storage battery PCS 120.

By transmitting such common detection data and individual detection data to the remote monitoring server 400, the remote monitoring server 400 (control unit 403) can grasp each device constituting the storage battery system 100 in detail.

As shown in FIG. 4(e), the common detection data includes the total charging power amount ([kWh]) of the plurality of storage battery devices 110, the total discharge power amount ([kWh]) of the plurality of storage battery devices 110, and the total charging power amount ([kWh]) of the plurality of storage battery devices 110. It includes common charge/discharge data that is at least one of the total instantaneous charge/discharge power ([kW]) of the device 110, the charging time of the plurality of storage battery devices 110, and the discharge time of the plurality of storage battery devices 110. Thereby, the remote monitoring server 400 (control unit 403) can efficiently grasp the charging/discharging status of the plurality of storage battery devices 110.

Here, the storage battery control device 130 (second communication unit 131b) transmits at least one of the total charging power amount, the total discharging power amount, and the instantaneous discharge power to the remote monitoring server 400 in the first transmission cycle (short cycle). You can also send it. Thereby, the remote monitoring server 400 (control unit 403) can grasp the charging/discharging status of the plurality of storage battery devices 110 in more real time.

On the other hand, the storage battery control device 130 (second communication unit 131b) transmits at least one of the charging time and the discharging time to the remote monitoring server 400 in a second transmission cycle (long cycle) that is longer than the first transmission cycle. It's okay. Thereby, the remote monitoring server 400 (control unit 403) can grasp the time when charging or discharging is performed while suppressing an increase in the amount of data transmitted to the remote monitoring server 400.

As shown in FIG. 4(e), the individual detection data includes the charging rate ([%]) of each of the plurality of storage battery devices 110, the degree of deterioration ([%]) of each of the plurality of storage battery devices 110, and the degree of deterioration ([%]) of each of the plurality of storage battery devices 110. It includes degraded cell information of each of the devices 110 and storage battery state data that is at least one of the discharge capacities ([Ah]) of each of the plurality of storage battery devices 110. Thereby, the remote monitoring server 400 can accurately grasp the status of each storage battery device 110.

Here, the charging rate is sometimes called SOC (State of Charge), and the degree of deterioration is sometimes called SOH (State of Health). The degraded cell information is identification information indicating a cell whose degradation has been detected by the BMS.

The storage battery control device 130 (second communication unit 131b) may transmit at least one of the charging rate, the degree of deterioration, and the degraded cell information to the remote monitoring server 400 in a first transmission cycle (short cycle). Thereby, the remote monitoring server 400 (control unit 403) can grasp the status of the plurality of storage battery devices 110 in more real time.

On the other hand, the storage battery control device 130 (second communication unit 131b) may transmit the discharge capacity to the remote monitoring server 400 in a second transmission cycle (long cycle) that is longer than the first transmission cycle. Thereby, the remote monitoring server 400 (control unit 403) can grasp the discharge capacity of each storage battery device 110 while suppressing an increase in the amount of data transmitted to the remote monitoring server 400.

Furthermore, the storage battery control device 130 (second communication unit 131b) transmits solar cell detection data regarding the solar cell system 200 to the remote monitoring server 400 together with at least one of the common detection data and the individual detection data. For example, the storage battery control device 130 (second communication unit 131b) may transmit common detection data, individual detection data, and solar cell detection data in one message. Thereby, the remote monitoring server 400 (control unit 403) can grasp not only the state of the storage battery system 100 but also the state of the solar battery system 200.

(Example of operation sequence)
Next, an example of an operation sequence in the power management system 1 will be described. FIG. 5 is a diagram showing an operation sequence in the power management system 1 according to one embodiment.

As shown in FIG. 5, the storage battery control device 130 (second communication unit 131b) transmits common detection data and individual detection data to the remote monitoring server 400 at a first transmission cycle (short cycle) T.

Here, the storage battery control device 130 (second communication unit 131b) transmits a second transmission period (long period) T, which is an integral multiple of the first transmission period, for a part of the common detection data and a part of the individual detection data. Send with ×N.

Further, the storage battery control device 130 (second communication unit 131b) may transmit the solar cell detection data at the first transmission cycle T. The storage battery control device 130 (second communication unit 131b) may transmit part of the solar cell detection data in a second transmission cycle T×N that is an integral multiple of the first transmission cycle.

The remote monitoring server 400 accumulates the detection data received from the storage battery control device 130 and manages the detection data in association with a user identifier. When the remote monitoring server 400 receives a data request from the terminal device 500, it transmits corresponding detection data to the terminal device 500 based on the user identifier of the user of the terminal device 500 who made the data request. The terminal device 500 displays a monitoring screen for monitoring the status of each device in the customer facility 10, and displays data from the remote monitoring server 400 on this monitoring screen.

In this way, by transmitting detection data common to a plurality of storage battery devices 110 to the remote monitoring server 400 as common detection data, an increase in the amount of transmitted data can be suppressed. Furthermore, the remote monitoring server 400 can not only grasp the individual state of each storage battery device 110 using individual detection data, but also the state common to a plurality of storage battery devices 110 using common detection data. Therefore, it is possible to efficiently collect detection data regarding the storage battery device 110.

(Other embodiments)
In the embodiment described above, an example in which common detection data and individual detection data are periodically transmitted from the storage battery control device 130 to the remote monitoring server 400 has been described. However, the storage battery control device 130 is not limited to such periodic transmission, and the storage battery control device 130 may transmit the common detection data and the individual detection data to the remote monitoring server 400 when a predetermined event occurs. For example, the storage battery control device 130 may transmit the common detection data and the individual detection data to the remote monitoring server 400 in response to receiving a transmission request from the remote monitoring server 400.

In the embodiments described above, communication between each device may include communication of a predetermined message based on a predetermined protocol. The predetermined protocol is, for example, the ECHONET Lite method, SEP2.0, KNX, Open ADR (Automatic Demand Response), or the like.

A program that causes a computer to execute each process performed by the storage battery control device 130 or the remote monitoring server 400 may be provided. The program may be recorded on a computer readable medium. Computer-readable media allow programs to be installed on a computer. Here, the computer-readable medium on which the program is recorded may be a non-transitory recording medium. The non-transitory recording medium is not particularly limited, and may be, for example, a recording medium such as a CD-ROM or a DVD-ROM.

In addition, the functional units (circuits) that execute each process performed by the storage battery control device 130 or the remote monitoring server 400 are integrated, and at least a part of the storage battery control device 130 or the remote monitoring server 400 is implemented as a semiconductor integrated circuit (chip set, SoC). It may also be configured as

Although the embodiments have been described above in detail with reference to the drawings, the specific configuration is not limited to that described above, and various design changes can be made without departing from the scope of the invention.

The Sustainable Development Goals (SDGs) are among the 17 international goals adopted at the United Nations Summit in September 2015. The control device, server device, and management method according to one embodiment are based on the 17 goals of the SDGs, such as "7. Affordable and clean energy" and "9. Create a foundation for industry and technological innovation." , and contribute to achieving the goals of ``11. Creating a town where people can continue to live.''

1: Power management system 10: Consumer facility 20: Power system 30: Network 100: Storage battery system 110: Storage battery device 120: Storage battery PCS
130: Storage battery control device 131: Communication interface 131a: First communication section 131b: Second communication section 131c: Third communication section 132: User interface 132a: Display section 132b: Operation section 133: Storage section 134: Control section 140: Wireless Communication device 200: Solar cell system 210: Solar cell device 220: Solar cell PCS
310: Router 320: Load device 330: EMS
400: Remote monitoring server 401: Communication unit 402: Storage unit 403: Control unit 500: Terminal device

Claims (13)

A control device used in a power management system,
A power conversion device connected to a plurality of storage battery devices receives common detection data commonly detected by the plurality of storage battery devices and individual detection data detected individually for each of the plurality of storage battery devices. 1 communications department and
A control device, comprising: a second communication unit that transmits the common detection data and the individual detection data to a server device. The control device according to claim 1, wherein the second communication unit periodically transmits the common detection data and the individual detection data to the server device. The common detection data includes a common start time when the plurality of storage battery devices started maintenance mode all at once,
The control device according to claim 1 or 2, wherein the individual detection data includes individual end times at which each of the plurality of storage battery devices individually ends the maintenance mode. The common detection data includes common error data indicating at least one of the presence or absence of an error in the power conversion device and the presence or absence of an error in the control device,
The control device according to any one of claims 1 to 3, wherein the individual detection data includes individual error data indicating the presence or absence of an error in each of the plurality of storage battery devices. When the error is detected, the second communication unit transmits error status data indicating the occurrence status of the error to the server device,
The control device according to claim 4, wherein the error status data includes detection data detected at a cycle shorter than a detection data transmission cycle to the server device within a certain period of time before and after the error occurs. The common detection data includes common configuration data indicating at least one of a serial number of the power converter, a firmware version number of the power converter, and a model of the power converter,
The individual detection data includes individual configuration data indicating at least one of a serial number of each of the plurality of storage battery devices, a firmware version number of each of the plurality of storage battery devices, and a model of each of the plurality of storage battery devices. The control device according to any one of claims 1 to 5. The common detection data includes a total charging power amount of the plurality of storage battery devices, a total discharge power amount of the plurality of storage battery devices, a total instantaneous charging/discharging power of the plurality of storage battery devices, a charging time of the plurality of storage battery devices, and The control device according to any one of claims 1 to 6, wherein the control device includes common charge/discharge data that is at least one of the discharge times of the plurality of storage battery devices. The second communication unit includes:
transmitting at least one of the total charging power amount, the total discharging power amount, and the total instantaneous charging/discharging power to the server device in a first transmission cycle;
The control device according to claim 7, wherein at least one of the charging time and the discharging time is transmitted to the server device in a second transmission cycle that is longer than the first transmission cycle. The individual detection data includes a charging rate of each of the plurality of storage battery devices, a degree of deterioration of each of the plurality of storage battery devices, degraded cell information of each of the plurality of storage battery devices, and a discharge of each of the plurality of storage battery devices. The control device according to any one of claims 1 to 8, comprising storage battery state data that is at least one of the capacities. The second communication unit includes:
transmitting at least one of the charging rate, the degree of deterioration, and the degraded cell information to the server device in a first transmission cycle;
The control device according to claim 9, wherein the discharge capacity is transmitted to the server device in a second transmission period that is longer than the first transmission period. The control device according to any one of claims 1 to 10, wherein the common detection data includes storage battery number data indicating the total number of storage battery devices connected to the power conversion device. further comprising a third communication unit that communicates with another power conversion device connected to the solar cell device,
The second communication unit transmits solar cell detection data regarding the solar cell device or the other power conversion device to the server device together with at least one of the common detection data and the individual detection data. The control device according to any one of the above. A management method executed by a control device used in a power management system, comprising:
receiving common detection data commonly detected by the plurality of storage battery devices and individual detection data detected individually by each of the plurality of storage battery devices from a power conversion device connected to the plurality of storage battery devices;
A management method comprising transmitting the common detection data and the individual detection data to a server device.

Images