JP7202998B2 - Server device and error detection method - Google Patents

Description

The present invention relates to a server device and an error detection method used in a power management system.

In Patent Document 1, a server device remotely monitors temperature, voltage, and internal resistance as measurement data of a storage battery device, analyzes these measurement data, and detects deterioration of the storage battery device. A storage battery condition monitoring system is described.

JP 2019-60773 A

The technique described in Patent Literature 1 assumes that the server device can acquire normal measurement data, and does not take into consideration the situation where the server device cannot acquire normal measurement data. Therefore, there is a problem that the types of errors that can be detected by the server device are limited, and error detection cannot be performed appropriately.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a server device and an error detection method that perform error detection appropriately even in a situation where the server device cannot acquire normal measurement data.

A server device according to a first aspect is a device used in a power management system. The server device is capable of communicating with a communication unit that periodically receives measurement data measured at the facility by communicating with a facility that has a distributed power source, and the communication unit periodically receives the measurement data. and a control unit that detects an error related to the distributed power sources when the communication unit receives the measured data that does not include the distributed power source measurement data related to the distributed power sources over a predetermined period in the state.

An error detection method according to a second aspect is a method executed by a server device used in a power management system. The error detection method includes periodically receiving measurement data measured at the facility through communication with a facility having a distributed power source, and allowing the server device to periodically receive the measurement data. state, detecting an error regarding the distributed power source when the server apparatus receives the measurement data that does not include the distributed power source measurement data regarding the distributed power source for a predetermined period of time.

ADVANTAGE OF THE INVENTION According to one aspect of the present invention, it is possible to provide a server device and an error detection method that appropriately perform error detection even in a situation where the server device cannot acquire normal measurement data.

1 illustrates a power management system according to one embodiment; FIG. It is a figure which shows the structure of the remote monitoring server which concerns on one Embodiment. It is a figure which shows the error detection operation|movement in the remote monitoring server which concerns on one Embodiment. FIG. 3 is a diagram showing a first example of an operation sequence in a power management system according to one embodiment; FIG. 5 is a diagram showing a second example of an operation sequence in the power management system according to one embodiment;

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

(power management system)
First, a power management system according to one embodiment will be described. FIG. 1 is a diagram showing a power management system 1 according to one embodiment. In FIG. 1, thick lines between blocks indicate power lines, and thin lines indicate signal lines. In addition, it is not limited to this, You may transmit a signal by a power line. The signal line may be wired or wireless.

As shown in FIG. 1 , the power management system 1 has a facility 10 , a remote monitoring server 400 and terminal devices 500 . Facility 10 , remote monitoring server 400 , and terminal device 500 are interconnected via network 30 .

Network 30 is, for example, a wide area network. The network 30 may include a WWAN (Wireless Wide Area Network) or the Internet.

The facility 10 is a consumer facility that receives power supply from the power system 20 . Facility 10 has a router 310 . A router 310 is connected to the network 30 . Router 310 constitutes a local area network provided in facility 10 .

In one embodiment, the facility 10 includes a storage battery facility 100, a storage battery control device 130, a wireless communication device 140, a solar cell facility 200, a load device 320, a measurement device 330, an EMS (Energy Management System) 340, and have The storage battery equipment 100 is an example of a distributed power supply, and the solar battery equipment 200 is another example of a distributed power supply. In other embodiments, the facility 10 may not have the solar cell installation 200, or may have a fuel cell installation as a distributed power source.

In one embodiment, the storage battery equipment 100 has a plurality of storage battery devices 110 (110a to 110c) and a storage battery PCS (Power Conditioning System) 120. In another embodiment, only one storage battery device 110 may be included in the storage battery equipment 100 .

Each storage battery device 110 is a device that stores electric power. Each storage battery device 110 has 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. Each storage battery device 110 charges power input via a power line and outputs power by discharging under the control of the storage battery PCS 120 .

The storage battery equipment 100 may be configured so that the storage battery device 110 can be added. For example, only the storage battery device 110a may be connected to the storage battery PCS 120 at first, and then the storage battery devices 110b and 110c may be added as appropriate by expansion. The storage battery equipment 100 may be configured such that the storage battery device 110 can be removed or replaced. For example, when the storage battery device 110a deteriorates, a new storage battery device 110a may be connected to the storage battery PCS120 after removing the deteriorated storage battery device 110a.

Storage battery PCS120 is a power conversion device that converts DC power into AC power. Each storage battery device 110 and storage battery PCS 120 has a component group (charging system) for charging and a component group (discharging system) for discharging. Storage battery PCS 120 converts the DC power input from each storage battery device 110 into AC power during discharge, and outputs the AC power to the power system 20 side. During charging, storage battery PCS 120 converts AC power supplied from 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 and acquires measurement data from each storage battery device 110 by communicating with the BMS of each storage battery device 110 via a communication line. Moreover, storage battery PCS120 acquires the measurement data obtained by performing measurement with storage battery PCS120. Storage battery PCS 120 receives commands from storage battery control device 130 and transmits measurement data to storage battery control device 130 by communicating with storage battery control device 130 via a communication line. Such measurement data relating to the storage battery device 110 is referred to as "storage battery measurement data".

Here, the storage battery measurement data includes charging measurement data regarding charging of the storage battery equipment 100 and discharge measurement data regarding discharging of the storage battery equipment 100 . For example, the charge measurement data includes the total charge power amount ([kWh]), and the discharge measurement data includes the total discharge power amount ([kWh]). The charging measurement data may further include charging time. The discharge measurement data may further include discharge time. The charge measurement data and the discharge measurement data may be measurement data obtained by performing measurement with the storage battery PCS 120 .

The storage battery PCS 120 transmits to the storage battery PCS 120 error information indicating whether or not there is an error in each device (that is, each storage battery device 110 and the storage battery PCS 120 ) that constitutes the storage battery equipment 100 . The error information may form part of the battery measurement data.

Here, an error refers to some kind of abnormality. For example, the storage battery PCS 120 compares the value of storage battery measurement data with a normal range threshold, and can detect an error based on the fact that the value exceeds the normal range threshold. Such an error detected on the device side is called a "device error". When the error information indicates "error present", storage battery PCS 120 includes an error code, which is an identifier indicating the type of detected error, in the error information.

On the other hand, the solar cell installation 200 has a solar cell device 210 and a solar cell PCS 220 .

The solar cell device 210 is a device that generates power according 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 according to the amount of solar radiation with which the solar cell device 210 is irradiated.

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

In one embodiment, solar cell PCS 220 may communicate with battery controller 130 via a communication line to transmit solar cell measurement data for solar array 200 to battery controller 130 . The solar cell measurement data is measurement data related to the solar cell device 210 and is data measured by the solar cell PCS 220 . In other embodiments, solar cell PCS 220 may send solar cell measurement data to EMS 340 via router 310 .

The load device 320 is a device that consumes power supplied via a power line. For example, load devices 320 include devices such as refrigerators, lights, air conditioners, and televisions. Load device 320 may be a single device or may include multiple devices.

The measuring device 330 is a device that measures forward power flow, which is the flow of power from the power system 20 to the facility 10 , and reverse power flow, which is the flow of power from the facility 10 to the power system 20 . The measurements include measurements of at least one of current, voltage, and power. The measuring device 330 outputs measurement data obtained by measurement to the EMS 340 via a signal line.

EMS340 is an apparatus which controls the solar cell installation 200 and the load apparatus 320. FIG. The EMS 340 may periodically transmit at least one of the measured data from the solar cell installation 200 and the measured data from the measuring device 330 to the remote monitoring server 400 . The EMS 340 may transmit error information regarding the detected device error to the remote monitoring server 400 when detecting the device error of the EMS 340 .

In one embodiment, EMS 340 and battery controller 130 are configured separately. However, in other embodiments, the EMS 340 and the storage battery control device 130 may be integrated and this integrated device may be used as the control device.

The storage battery control device 130 is an example of a control device that controls the storage battery facility 100 (particularly, the storage battery PCS 120) as a distributed power source. The storage battery control device 130 can also be regarded as a device that controls each storage battery device 110 via the storage battery PCS 120 .

The storage battery control device 130 may be a so-called remote control device having a user interface. Storage battery control device 130 notifies the user of information and accepts input operations from the user. The storage battery control device 130 controls the storage battery equipment 100 (in particular, the storage battery PCS 120) according to the input operation from the user.

The storage battery control device 130 acquires storage battery measurement data from the storage battery PCS 120 and periodically transmits the storage battery measurement data to the remote monitoring server 400 via the router 310 or the wireless communication device 140 . Further, the storage battery control device 130 may acquire the solar cell measurement data from the solar cell PCS 220 and periodically transmit the storage battery measurement data to the remote monitoring server 400 via the router 310 or the wireless communication device 140 .

The wireless communication device 140 is a device that performs wireless communication with the WWAN included in the network 30 . Wireless communication device 140 is configured separately from storage battery control device 130 and is connected to storage battery control device 130 via a communication line. Being configured separately means that the wireless communication device 140 is electrically (or communicatively) connected to the storage battery control device 130 but not physically connected.

Wireless communication between the wireless communication device 140 and the WWAN may conform to the cellular communication system or may conform to the LPWA system. By electrically connecting wireless communication device 140 to storage battery control device 130 , it is possible to provide storage battery control device 130 with a communication function with network 30 .

Remote monitoring server 400 is an example of a server device that communicates with storage battery control device 130 . Remote monitoring server 400 receives measurement data transmitted from storage battery control device 130 and EMS 340 via network 30 . The measurement data includes storage battery measurement data and solar cell measurement data. The storage battery measurement data includes charge measurement data and discharge measurement data.

The remote monitoring server 400 accumulates the received measurement data and manages the measurement data in association with the user identifier. Upon receiving a data request from the terminal device 500, the remote monitoring server 400 transmits the corresponding measurement 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 one facility 10 is monitored by the remote monitoring server 400, the remote monitoring server 400 may monitor a plurality of facilities 10 (a plurality of storage battery facilities 100).

The terminal device 500 is, for example, a PC (Personal Computer), a smart phone, a tablet terminal, or a dedicated terminal. The terminal device 500 displays a monitoring screen for monitoring the status of each device in the 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, or may display a monitoring screen on a general-purpose web browser.

A subject who operates the terminal device 500 may be a user who uses the distributed power supply (for example, a resident of the facility 10), or a business operator who performs maintenance of the distributed power supply (for example, a maintenance company or a manufacturer). good too.

(Configuration of server device)
Next, the configuration of the remote monitoring server 400 will be described. FIG. 2 is a diagram showing the configuration of the remote monitoring server 400 according to one embodiment.

As shown in FIG. 2 , the remote monitoring server 400 has 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 facility 10 and the terminal device 500 via the network 30 . The communication unit 401 periodically receives measurement data measured at the facility 10 from the facility 10 and outputs the received measurement data to the control unit 403 . Periodic reception is not limited to reception in a fixed period, but may be reception in a variable period in which jitter or the like is reflected.

However, the communication unit 401 may not be able to receive the measurement data from the facility 10 due to, for example, a failure of the network 30 . Hereinafter, a state in which the communication unit 401 is periodically receiving measurement data from the facility 10 is referred to as a "communicable state", and a state in which the communication unit 401 is not periodically receiving measurement data from the facility 10 is referred to as a " "communication error state".

The communication unit 401 also receives a data request from the terminal device 500 via the network 30 and outputs the received data request to the control unit 403 . In this case, the communication section 401 transmits measurement data corresponding to the data request to the terminal device 500 under the control of the control section 403 .

The storage unit 402 includes a volatile memory and a 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 measurement data received by the communication unit 401 . The control unit 403 manages the measurement data in association with the user identifier. When the communication unit 401 receives the data request from the terminal device 500, the control unit 403 transmits the corresponding measurement 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.

The control unit 403 detects an abnormality (error) related to the distributed power sources by analyzing the measurement data accumulated in the storage unit 402 . When an error is detected, the control unit 403 controls the communication unit 401 to transmit an error notification indicating the fact and the type of the error to the terminal device 500 .

(Error detection operation in server device)
Next, an error detection operation in remote monitoring server 400 will be described. FIG. 3 is a diagram illustrating error detection operations in the remote monitoring server 400 according to one embodiment.

As shown in FIGS. 3A and 3B, the types of detected errors include errors detected on the equipment side provided in the facility 10 (equipment errors) and remote errors not detected on the equipment side. There is also an error detected on the monitoring server 400 side.

As shown in (A1) to (A3), the control unit 403 of the remote monitoring server 400 identifies the error type of the device error based on the error code included in the error information received by the communication unit 401 from the facility 10. .

Types of device errors include PCS errors, storage battery device errors, and control device errors. Types of PCS errors include a storage battery PCS120 device error and a solar cell PCS220 device error. The types of storage battery device errors include a device error of the storage battery device 110a, a device error of the storage battery device 110b, and a device error of the storage battery device 110c. Types of control device errors include a device error of the storage battery control device 130 and a device error of the EMS 340 .

On the other hand, as shown in (B1) to (B7), the control unit 403 of the remote monitoring server 400 detects an error on the remote monitoring server 400 side by analyzing the measurement data accumulated in the storage unit 402 .

As shown in (B1), when the control unit 403 of the remote monitoring server 400 determines that the communication unit 401 has not received measurement data from the facility 10 for a predetermined period of time, it detects a communication error (communication error state). An example in which the predetermined period is a fixed period (for example, 24 hours) will be described below, but the predetermined period may be a variable period that can be set for each error type, for example.

When the communication error of (B1) is detected, no measurement data is acquired by the remote monitoring server 400, so the error detections of (B2) to (B7) are not performed. On the other hand, when the communication error of (B1) is not detected, the control unit 403 of the remote monitoring server 400 performs error detection operations shown in (B2) to (B7).

As shown in (B2) to (B7), the control unit 403 of the remote monitoring server 400, in a communication enabled state in which the communication unit 401 periodically receives measurement data, measures data related to distributed power sources (hereinafter referred to as " When the communication unit 401 receives measurement data that does not include distributed power source measurement data” for a certain period of time, an error related to distributed power sources is detected. As a result, it is possible to appropriately detect errors even in a situation where the remote monitoring server 400 cannot acquire normal measurement data. For example, it is possible to detect an error such as interruption of some signal lines related to distributed power sources in the facility 10 .

As a specific example, the communication unit 401 periodically receives the measurement data from the measuring device 330 and the measurement data from the first distributed power source from the facility 10, and the measurement data from the second distributed power source is received over a certain period of time. There is a possibility that the communication unit 401 has not received it. In such a case, the control unit 403 of the remote monitoring server 400 detects an error regarding the second distributed power supply. Here, one of the first distributed power supply and the second distributed power supply may be the storage battery equipment 100 and the other may be the solar battery equipment 200 .

In addition, even if the error information received from the facility 10 does not indicate the occurrence of an equipment error, that is, even if an equipment error is not detected, the control unit 403 of the remote monitoring server 400 includes the distributed power source measurement data. If the communication unit 401 receives measurement data that does not exist for a certain period of time, an error related to distributed power sources is detected. As a result, errors that cannot be detected on the device side (that is, on the facility 10 side) can be detected on the server side.

As shown in (B2) and (B3), the control unit 403 of the remote monitoring server 400 receives measurement data that does not include storage battery measurement data regarding the storage battery equipment 100 for a certain period of time in the communicable state. , to detect an error relating to the storage battery installation 100 . Here, the control unit 403 of the remote monitoring server 400 detects an error related to charging of the storage battery equipment 100 and an error related to discharging of the storage battery equipment 100 as errors related to the storage battery equipment 100 .

As shown in (B2), control unit 403 of remote monitoring server 400 detects an error related to charging as an error related to storage battery equipment 100 when communication unit 401 receives measurement data that does not include charge measurement data for a certain period of time. . Such an error type is called a "charging data acquisition error". As described above, the charge measurement data is, for example, the total charge power amount ([kWh]).

However, as shown in (B4), even when the communication unit 401 receives measurement data including charge measurement data, the control unit 403 of the remote monitoring server 400 sets the charge measurement data including the zero value or the null value. is received by the communication unit 401 for a certain period of time, an error related to charging is detected. Such an error type is called a "charging error". When the communication unit 401 receives charge measurement data of zero value for a certain period of time, the control unit 403 of the remote monitoring server 400 determines that the charge measurement data has been correctly detected on the device side (for example, the sensor in the storage battery equipment 100). It is a valid value, and it can be inferred that communication between the device and the remote monitoring server 400 has been established. On the other hand, when the communication unit 401 receives charge measurement data including a null value for a certain period of time, the control unit 403 of the remote monitoring server 400 detects that the charge measurement data is an invalid value that cannot be correctly detected on the device side. , it can be inferred that communication between the device and the remote monitoring server 400 is established.

On the other hand, as shown in (B3), control unit 403 of remote monitoring server 400 detects an error related to discharge as an error related to storage battery equipment 100 when communication unit 401 receives measurement data that does not include discharge measurement data for a certain period of time. detect. Such an error type is called a "discharge data acquisition error". As described above, the discharge measurement data is, for example, the total discharge power amount ([kWh]).

However, as shown in (B5), even when the communication unit 401 receives measurement data including discharge measurement data, the control unit 403 of the remote monitoring server 400 controls the discharge measurement data consisting of zero or null values. is received by the communication unit 401 for a certain period of time, an error related to discharge is detected. Such an error type is called a "discharge error". When the communication unit 401 receives charge measurement data of zero value for a certain period of time, the control unit 403 of the remote monitoring server 400 determines that the discharge measurement data has been correctly detected on the device side (for example, the sensor in the storage battery equipment 100). It is a valid value, and it can be inferred that communication between the device and the remote monitoring server 400 has been established. On the other hand, when the communication unit 401 receives discharge measurement data consisting of a null value for a certain period of time, the control unit 403 of the remote monitoring server 400 detects that the discharge measurement data is an invalid value that cannot be correctly detected on the device side. , it can be inferred that communication between the device and the remote monitoring server 400 is established.

As shown in (B6), the control unit 403 of the remote monitoring server 400 controls the solar cell installation 200 when the communication unit 401 receives measurement data that does not include the solar cell measurement data related to the solar cell installation 200 for a certain period of time in the communicable state. Detect an error related to the battery equipment 200 . Such an error type is called a "power generation data acquisition error". The solar cell measurement data is, for example, total power generation ([kWh]).

However, as shown in (B7), even when the communication unit 401 receives measurement data including solar cell measurement data, the control unit 403 of the remote monitoring server 400 sets the solar cell value to zero or null. If the communication unit 401 receives measurement data over a certain period of time, an error related to the solar cell equipment 200 is detected. Such an error type is called a "power generation stop error". When the communication unit 401 receives the solar cell measurement data consisting of zero values for a certain period of time, the control unit 403 of the remote monitoring server 400 confirms that this solar cell measurement data is correct on the equipment side (for example, the sensor in the solar cell installation 200). It is a detected valid value, and it can be inferred that communication between the device and the remote monitoring server 400 is established. On the other hand, when the communication unit 401 receives the solar cell measurement data consisting of null values for a certain period of time, the control unit 403 of the remote monitoring server 400 detects that the solar cell measurement data is an invalid value that cannot be detected correctly on the device side. However, it can be inferred that communication between the device and the remote monitoring server 400 has been established.

When an error is detected, the control unit 403 of the remote monitoring server 400 controls the communication unit 401 to transmit an error notification including error type information indicating the type of the detected error to the terminal device 500 . For example, based on the user identifier associated with the measurement data in which the error was detected, the control unit 403 transmits an error notification to the user's terminal device 500 indicated by this user identifier. The control unit 403 of the remote monitoring server 400 determines whether a zero value or a null value is acquired for (B4) charge error, (B5) discharge error, and (B7) power generation stop error shown in FIG. You may transmit an error notification in the form which can identify whether.

(Example of operation sequence)
Next, an operation sequence example in the power management system 1 will be described.

FIG. 4 is a diagram showing a first example of an operation sequence in the power management system 1 according to one embodiment.

As shown in FIG. 4 , in steps S 1 to S 8 , the storage battery device 110 and the EMS 340 provided in the facility 10 periodically transmit measurement data obtained in the facility 10 to the remote monitoring server 400 . The control unit 403 of the remote monitoring server 400 stores the measurement data received by the communication unit 401 from the facility 10 in the storage unit 402 and manages the measurement data in association with the user identifier.

In step S<b>11 , the control unit 403 of the remote monitoring server 400 receives a data request from the terminal device 500 via the communication unit 401 .

In step S12, the control unit 403 of the remote monitoring server 400 transmits the corresponding measurement 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 facility 10, and displays measurement data from the remote monitoring server 400 on this monitoring screen.

FIG. 5 is a diagram showing a second example of the operation sequence in the power management system 1 according to one embodiment.

As shown in FIG. 5, in steps S1 to S8, the storage battery device 110 and the EMS 340 provided at the facility 10 periodically transmit measurement data obtained at the facility 10 to the remote monitoring server 400. FIG. The control unit 403 of the remote monitoring server 400 stores the measurement data received by the communication unit 401 from the facility 10 in the storage unit 402 and manages the measurement data in association with the user identifier.

In step S21, the control unit 403 of the remote monitoring server 400 detects an error through the error detection operation described above. The control unit 403 of the remote monitoring server 400 detects an equipment error based on the error code included in the error information that the communication unit 401 receives from the facility 10 . Alternatively, the control unit 403 of the remote monitoring server 400 detects an error on the remote monitoring server 400 side by analyzing the measurement data accumulated in the storage unit 402 .

In step S22, when an error is detected in step S21, the control unit 403 of the remote monitoring server 400 causes the communication unit 401 to transmit an error notification including error type information indicating the type of the detected error to the terminal device 500. Control. Upon receiving this error notification, the terminal device 500 displays information indicating that an error has been detected and the type of error.

(Other embodiments)
In the above-described embodiment, communication of a predetermined message conforming to a predetermined protocol may be performed as communication between devices. The predetermined protocol is, for example, ECHONET Lite system, 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 may be provided. The program may be recorded on a computer readable medium. A computer readable medium allows the installation of the program on the 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, but may be, for example, a recording medium such as CD-ROM or DVD-ROM.

Further, functional units (circuits) for executing each process performed by the storage battery control device 130 may be integrated, and the storage battery control device 130 may be configured as a semiconductor integrated circuit (chipset, SoC).

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

The 17 international goals adopted at the United Nations Summit in September 2015 include "Sustainable Development Goals (SDGs)." A server device and an error detection method according to one embodiment, among the 17 goals of the SDGs, for example, "7. Affordable and clean energy", "9. Build a foundation for industry and technological innovation", and " 11. It can contribute to the achievement of goals such as the development of a city where people can continue to live.

Reference Signs List 1: power management system 10: facility 20: power system 30: network 100: storage battery facility 110: storage battery device 120: storage battery PCS
130: storage battery control device 140: wireless communication device 200: solar cell equipment 210: solar cell device 220: solar cell PCS
310: router 320: load device 330: measurement device 340: EMS
400: Remote monitoring server 401: Communication unit 402: Storage unit 403: Control unit 500: Terminal device

Claims (12)

A server device used in a power management system,
a communication unit that periodically receives measurement data measured at the facility by communicating with the facility having a distributed power source;
In a communicable state in which the communication unit periodically receives the measurement data, if the communication unit receives the measurement data that does not include the distributed power supply measurement data related to the distributed power supply for a predetermined period, A server apparatus comprising: a controller that detects an error. The communication unit receives error information indicating whether or not an equipment error has occurred in the distributed power supply through communication with the facility,
Even if the error information does not indicate the occurrence of the device error, the control unit controls the communication unit to receive the measurement data that does not include the distributed power supply measurement data for the predetermined period of time. The server device according to claim 1, wherein an error relating to distributed power sources is detected. The distributed power supply is a storage battery facility,
3. The control unit detects an error related to the storage battery equipment when the communication unit receives the measurement data not including the storage battery measurement data related to the storage battery equipment for the predetermined period in the communication enabled state. The server device described in . The server device according to claim 3, wherein the control unit detects, as errors related to the storage battery equipment, an error related to charging of the storage battery equipment and an error related to discharging of the storage battery equipment. The storage battery measurement data includes charging measurement data related to charging of the storage battery equipment,
The server device according to claim 4, wherein when the communication unit receives the measurement data that does not include the charging measurement data over the predetermined period, the control unit detects an error related to the charging as an error related to the storage battery equipment. Even when the communication unit receives the measurement data including the charge measurement data, the control unit controls the charge measurement data including the charge measurement data when the communication unit receives the charge measurement data including a zero value or a null value for the predetermined period of time. 6. The server device according to claim 5, wherein an error relating to said charging is detected. The storage battery measurement data includes discharge measurement data related to discharging of the storage battery equipment,
7. Any one of claims 4 to 6, wherein when the communication unit receives the measurement data that does not include the discharge measurement data over the predetermined period, the control unit detects an error related to the discharge as an error related to the storage battery equipment. The server device according to the item. Even when the communication unit receives the measurement data including the discharge measurement data, the control unit controls the communication unit to receive the discharge measurement data consisting of a zero value or a null value over the predetermined period. 8. The server device according to claim 7, wherein an error relating to said discharge is detected. the facility further comprises a solar cell installation;
The control unit detects an error related to the solar cell installation when the communication unit receives the measurement data that does not include the solar cell measurement data related to the solar cell installation over the predetermined period in the communicable state. 9. The server device according to any one of items 3 to 8. Even when the communication unit receives the measurement data including the solar cell measurement data, the control unit causes the communication unit to receive the solar cell measurement data consisting of a zero value or a null value for the predetermined period of time. 10. The server device according to claim 9, wherein an error related to the solar cell equipment is detected when the solar cell equipment is installed. 11. The communication unit according to any one of claims 1 to 10, wherein when the control unit detects the error, the communication unit transmits an error notification including error type information indicating a type of the detected error to the terminal device. Server device. An error detection method executed by a server device used in a power management system,
communicating with a facility having distributed power sources to periodically receive measurement data measured at the facility;
In a communication enabled state in which the server device periodically receives the measurement data, if the server device receives the measurement data that does not include the distributed power source measurement data related to the distributed power source for a predetermined period, detecting an error; and an error detection method.

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