JP6721170B1 - Remote monitoring system for emergency charger/discharger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To display battery evaluation information based on battery information (battery remaining amount, place of use, number of charge/discharge cycles, etc.) of an emergency charger/discharger installed in a store etc. To provide a monitoring system for an emergency charger/discharger that can easily detect abnormalities in the charger/discharger. In a remote monitoring system for an emergency charger/discharger according to the present invention, a predetermined emergency charger/discharger (A), a server (B) and an administrator electronic terminal (C) are connected by a network (N). In the remote monitoring system for the emergency charger/discharger, the server (B) determines whether the emergency charger/discharger (A) is in a normal state based on a predetermined receiving unit (b1) and battery information. The manager electronic terminal (C) includes a generation unit (b2) and a transmission unit (b3) that generate battery evaluation information indicating whether the state is abnormal, and the administrator electronic terminal (C) has a predetermined reception unit (c1) and display unit (c2). It is characterized by including. [Selection diagram] Figure 1

Description

The present invention relates to an emergency charging/discharging remote monitoring system, and more particularly, based on battery information of an emergency charging/discharging device installed in a store or the like (remaining battery level, place of use, number of charging/discharging cycles, etc.). The present invention relates to a remote monitoring system for an emergency charger/discharger, in which battery evaluation information is displayed on an administrator electronic terminal so that an abnormality of the emergency charger/discharger can be easily grasped.

In recent years, with the great disasters such as heavy rain and typhoons, there are cases where electric wires are cut, utility poles are broken, various power transmission devices are damaged, etc. in the disaster area. Blackouts at stores tend to be prolonged. Therefore, an emergency/emergency power supply (emergency charger/discharger) is required until the restoration work of the electric wires is completed.

As a battery body of an emergency charger/discharger, a lead storage battery or the like is generally used from the viewpoint of being resistant to overcharge and being usable in a wide temperature range.

As disclosed in Non-Patent Document 1, in various batteries including lead-acid batteries, control conditions such as decrease in electrolyte due to overcharge and increase in internal resistance, storage temperature of the battery itself, frequency of use, charge, and so on. Depending on the number of discharges and the like, the electrical characteristics (increase in internal electrical resistance, etc.) deteriorate with time.

As a result, the battery function may be deteriorated such as a decrease in electric capacity, and in the worst case, the battery function may be lost. Then, in the event of a disaster, when using the emergency charger/discharger, a problem such as insufficient electric capacity may occur.

To prepare for such a situation, the manager of the emergency charger/discharger can check various values obtained from the abnormality detection device (sensor device) installed in the battery part, and also visually inspect the inside or outside of the battery. There is a need for regular and daily maintenance, and it is necessary to go to the place where the emergency charger/discharger is installed.

Material Life Raifu Gakkaishi, 15 [3] 88-92 (Jully 2003)

The maintenance items (inspection items) of the emergency charger/discharger are diverse, and the emergency charger/discharger is installed in, for example, public facilities, school facilities, medical facilities, commercial facilities, and even convenience stores as disaster infrastructure facilities. It has been scattered around the area.

Therefore, it is extremely inefficient for the administrator to inspect each of the emergency chargers/dischargers in his/her own area.

Therefore, as a result of diligent studies, the present inventors detected the battery information of the emergency battery stored/installed in the store, etc., transmitted the battery information to the server via the network, and based on the battery information, It was found that a system that evaluates the state (normal or abnormal) of the above, and transmits and displays this evaluation to the administrator electronic terminal solves the above problem.

According to this system, it becomes easy to confirm the abnormality or normality of the emergency chargers/dischargers scattered in the area, and the administrator can check the number and place of the emergency chargers/dischargers that show abnormality, and the abnormality. Presence/absence and its degree can be easily grasped, and even a small number of managers can monitor (manage) the emergency charger/discharger efficiently and accurately.
That is, according to the present invention, battery evaluation information based on battery information (e.g., remaining battery level, place of use, number of charge/discharge cycles) of the emergency charger/discharger placed in a store is displayed on the administrator electronic terminal. Therefore, it is an object of the present invention to provide a remote monitoring system for an emergency charger/discharger, which can easily detect abnormalities in the emergency charger/discharger.

The remote monitoring system for the emergency charger/discharger according to the present invention is as follows.
[1] A remote monitoring system for an emergency charger/discharger (A), a server (B) and an administrator electronic terminal (C) connected by a network (N),
The emergency charger/discharger (A) has a battery unit (a1) having a storage battery, a detection unit (a2) for detecting battery information of the battery unit (a1), and the detected battery information to the server (B). A transmission unit (a3) for transmitting,
The server (B) determines whether the emergency charger/discharger (A) is in a normal state or an abnormal state based on the receiving unit (b1) that receives the battery information and the received battery information. A generator (b2) for generating the battery evaluation information shown, and a transmitter (b3) for transmitting the battery evaluation information to the administrator electronic terminal (C).
An administrator electronic terminal (C) is provided with a receiving unit (c1) for receiving the battery evaluation information and a display unit (c2) for displaying the received battery evaluation information. Remote monitoring system.

[2] The server (B) includes a transmitter (b4) that transmits abnormal battery evaluation information indicating that the emergency charger/discharger (A) is in an abnormal state to the administrator electronic terminal (C). Prepare,
The manager electronic terminal (C) includes means for specifying the position information of the manager electronic terminal (C), and a position information holding unit (c3) that holds the position information,
A receiver (c4) for receiving the abnormal battery evaluation information,
A determination unit (c5) that determines whether or not the battery is present at a certain distance from the emergency battery (A) based on the position information;
The emergency charging/discharging of [1], further comprising: a display unit (c6) for displaying the abnormal battery evaluation information on the administrator electronic terminal (C) when it is determined that the vehicle exists at the certain distance. Remote monitoring system for electric appliances.

[3] For the server (B) to predict/estimate an electrical malfunction of the emergency charger/discharger by using past data including past battery information, battery evaluation information, and external environment data as teacher data By inputting current data including current battery information, battery evaluation information, and external environment data into a learned learning model that has been machine-learned, the electrical failure of the emergency charger/discharger (A) can be predicted and estimated. And a machine learning means (D) for outputting the predicted/estimated battery evaluation information, and a transmitter (b5) for transmitting the predicted/estimated battery evaluation information to the manager electronic terminal (C).
The manager electronic terminal (C) includes a receiving unit (c6) that receives the predicted/estimated battery evaluation information, and a display unit (c7) that displays the received battery evaluation information. The remote monitoring system for emergency charger/discharger according to [1] or [2].

According to the remote monitoring system for the emergency charger/discharger according to the present invention, the battery evaluation information based on the battery information of the emergency charger/discharger placed in the store or the like (remaining amount of battery, place of use, number of charge/discharge cycles, etc.) However, by displaying it on the administrator's electronic terminal, it is possible to easily grasp the abnormality of the emergency charger/discharger.

FIG. 1 is a diagram for explaining an aspect of a remote monitoring system for an emergency charger/discharger according to the present invention. FIG. 2 shows an embodiment of a remote monitoring system for an emergency charger/discharger according to the present invention, which is an administrator electronic terminal (C) present at a certain distance from the emergency charger/discharger (A) in an abnormal state. FIG. 4 is a diagram for explaining a battery monitoring system that displays battery evaluation information in FIG. FIG. 3 is an aspect of a remote monitoring system for an emergency charger/discharger according to the present invention, in which a predetermined learned learning model is provided with current data including current battery information, battery evaluation information, and external environment data. It has a machine learning means (D) that predicts/estimates the electrical failure of the emergency charger/discharger (A) by inputting, and outputs the predicted/estimated battery evaluation information. It is a figure for demonstrating the remote monitoring system of the emergency charging/discharging device which displays estimated/estimated battery evaluation information.

Hereinafter, a monitoring system for an emergency charger/discharger according to the present invention will be described in detail with reference to the drawings as appropriate. It should be noted that the drawings show an example of an aspect of a monitoring system for an emergency charger/discharger according to the present invention.

As shown in FIG. 1, the remote monitoring system for an emergency charger/discharger according to the present invention includes an emergency charger/discharger (A), a server (B) and an administrator electronic terminal (C) in a network (N). It is connected. Here, the emergency charger/discharger (A) is detected with a battery section (a1) having an identification code and having a storage battery, and a detection section (a2) for detecting battery information of the battery section (a1). And a transmission unit (a3) for transmitting the battery information to the server (B).

Numbered a1 in FIG. 1 indicates the battery part (a1) of the emergency charger/discharger (A). The battery unit (a1) includes a storage battery and has a function of discharging or charging.

Here, the storage battery is not particularly limited, and typically includes a lead storage battery, a nickel hydrogen battery, a lithium ion battery, a NAS battery, and the like, but is appropriately selected. In addition, these may be used alone or in combination.

For example, a lead storage battery is preferable in that it has characteristics required for an emergency battery, such as resistance to overcharge and use in a wide temperature range. A nickel-hydrogen battery is preferable from the viewpoint of being resistant to overcharge and overdischarge and capable of rapid charge/discharge. A lithium-ion battery is preferable from the viewpoint of miniaturization and high density, and a NAS battery is preferable from the viewpoint of long life and charge/discharge efficiency.

The number a2 in FIG. 1 indicates the detection unit (a2), and detects the battery information of the battery unit (a1). Here, the battery information is not particularly limited as long as it is information on the electrical, chemical, physical state, characteristics, etc. of the storage battery in addition to the identification code of the emergency charger/discharger (A). Data such as battery level, number of charge/discharge cycles, number of shutdowns, operating temperature cycle, etc. Here, in order to enable this detection, the detection unit (a2) is provided with a detection device such as various sensors. Specifically, it is a sensor that monitors the charging current, discharging current, voltage, battery temperature, etc. of the storage battery in real time or periodically.

Further, as indicated by a number a3 in FIG. 1, the transmitter (a3) sends the emergency charger/discharger (A) ID (identification code) and the detected battery information (data) to the network (N). To the server (B). For this transmission, a relay communication device such as a WIFI router or a wireless or wired internet network such as a LAN (Local Area Network) or a WAN (Wide Area Network) is appropriately used. Further, when both WiFi/wired LAN do not reach (when it cannot be effectively used), for example, a 3G/LTE module may be used.

As shown by the number B in FIG. 1, the server (B) includes a receiving unit (b1), a generating unit (b2), and a transmitting unit (b3). The receiver (b1) receives the identification code of the emergency charger/discharger (A) and the battery information transmitted from the transmitter (a3) of the emergency charger/discharger (A). Then, the generation unit (b2) generates battery evaluation information indicating whether the emergency charger (A) corresponding to the identification code is in a normal state or an abnormal state, based on the received battery information.

Specifically, based on the battery information such as the identification code (ID code) of the emergency charger/discharger (A), the charging current, the discharging current, the voltage, and the battery temperature transmitted by the transmitting unit (b3), the server The generation unit (b2) of (B) generates quantitative or qualitative battery evaluation information. Examples of the battery evaluation information are the charging rate (SOC), the deterioration level/health level (SOH), the chargeable/dischargeable (input/output) power (SOP), the need for maintenance, the fact of failure, the presence or absence of insufficient charging, and overcharging. Whether or not the battery is present, battery failure prediction, replacement time prediction, and the like. The administrator will grasp the generated battery evaluation information on the display unit (c2) of the administrator electronic terminal (C) described later.

Further, the battery information and the battery evaluation information are appropriately recorded as data in a storage means (for example, SSD) in the server or a storage means outside the server (B) (for example, a cloud or another external server), and the stored data or the external information is stored. It may have a machine learning unit that iteratively learns from external data acquired from the server to detect a pattern hidden in a huge amount of data. For example, deep learning based on the data stored in the storage means and external data (external environmental data) about the season and weather (temperature, precipitation, the number of lightning strikes, etc.) during a disaster or normal times, etc. The machine learning described above makes it possible to predict or estimate an electrical defect in an emergency or disaster, and to take a countermeasure based on the prediction or estimation, which leads to a proper management method of the emergency battery.
For example, as external environment data, the demand for the emergency charger/discharger (A) tends to be higher in an emergency such as a disaster than in normal times. As a result, the battery level becomes low, the number of charge/discharge cycles, the number of shutdowns, and the number of operating temperature cycles increase. As a result, the frequency of failure of the emergency charger/discharger (A) tends to increase, causing electrical problems. is there. As described above, the occurrence of the electrical failure of the emergency charger/discharger (A) has a correlation with the external environment data.

Therefore, by inputting current data including current battery information, battery evaluation information, and external environment data to a learned learning model generated by machine learning using this relationship and past data as teacher data, A mode in which estimated battery evaluation information (frequency of occurrence of electrical failure, etc.) is output can be considered.

Specifically, as shown in FIG. 3, using the past data 31 including various past data (battery information, battery evaluation information, and external data (external environmental data)) as teacher data, the emergency charger/discharger is used. (A) A learned learning model 33 that has undergone machine learning for predicting/estimating an electrical defect is generated in advance. Next, as shown by a number 34, the current data 32 including various current data (battery information, battery evaluation information and external environment data) is input to the learning model 33. By this input work 34, as indicated by number 35, the electrical failure of the emergency charger/discharger (A) is predicted/estimated, and the predicted/estimated battery evaluation information is output. As described above, the server (B) includes the machine learning means (D) as indicated by the number D in FIG. 3, and although not shown, the predicted/estimated battery evaluation information is stored in the administrator electronic terminal (C). ) And a receiver (c6) for receiving the prediction/estimated battery evaluation information, and the received prediction/ It is preferable to provide a display section (c7) for displaying estimated battery evaluation information.

As shown in FIG. 1, the server (B) includes a transmitter (b3) that transmits the battery evaluation information to the administrator electronic terminal (C), and as shown by the number C, the administrator electronic terminal (C). ) Includes a receiving unit (c1) that receives the battery evaluation information and a display unit (c2) that displays the received battery evaluation information.
The battery evaluation information may be transmitted to some (selected) administrator electronic terminals (C) by the transmission unit (b3) of the server (B), or as shown in FIG. It may be transmitted to the administrator electronic terminal (C).
Further, the transmission unit (b1) and the reception unit (c1) may each transmit and receive battery information as well as battery information.

Further, the manager electronic terminal (C) includes means for specifying position information of the manager electronic terminal (C), and a position information holding unit (c3) that holds the position information, a receiving unit (c4) described later. It is preferable to include a determination unit (c5) and a display unit (c6). Here, as indicated by number 21 in FIG. 2, when the battery evaluation information indicates that the emergency charger/discharger (A) is in an abnormal state, the transmitter (b4) concerned information ( The abnormal battery evaluation information) is transmitted to the administrator electronic terminal (C). Next, the reception unit (c4) of the administrator electronic terminal (C) receives the abnormal battery evaluation information, and the determination unit (c5) exists at a certain distance from the emergency battery (A) based on the position information. It is determined whether or not the abnormal battery evaluation information is displayed on the administrator electronic terminal (C) on the display unit (c6) when the vehicle is present at the certain distance. Here, in the position information holding unit (c3) of the administrator electronic terminal (C), GPS is typically cited as a means for specifying the position information.

With such a system configuration, the administrator electronic terminal (C) closest to the emergency battery that requires maintenance work such as component replacement or the emergency charge/discharge device that needs to be removed due to a failure or the like is set in advance. It is possible to notify (warn) the owner of the administrator electronic terminal (C) within a range (for example, a range within a radius of 20 km centering on the emergency charger/discharger and the area in charge of the administrator), and perform efficient maintenance. Can do business, etc.

Further, in addition to means/functions for issuing an alert to the administrator near the administrator's electronic terminal (C) (abnormal terminal) where an abnormality has occurred using the position information, the position of the abnormal terminal is displayed on the map. Means/functions may be added. With this configuration, the location of the abnormal terminal around the administrator base is grasped, which is useful for improving the efficiency of the patrol route.

The administrator electronic terminal (C) is not particularly limited as long as it includes the predetermined receiving unit (c1) and the display unit (c2), and examples thereof include a smartphone, a tablet terminal, a mobile phone, a PDA, and a notebook PC.

According to the present invention, battery evaluation information based on battery information (e.g., battery remaining amount, place of use, number of charging/discharging cycles) of emergency chargers/dischargers installed in stores etc. is displayed on the administrator electronic terminal. Thus, it is possible to provide a monitoring system for an emergency charger/discharger, which can easily grasp the abnormality of the emergency charger/discharger.

A: Emergency charger/discharger (A)
B: Server (B)
C: Administrator electronic terminal (C)
D: Machine learning means (D)
N: Network (N)
a1: Battery part (a1)
a2: Detection unit (a2)
a3: Transmission unit (a3)
b1: receiver (b1)
b2: generation unit (b2)
b3: transmitter (b3)
b4: transmitter (b4)
b5: Transmission unit (b5)
c1: receiver (c1)
c2: display unit (c2)
c3: Position information specifying unit (c3)
c4: receiving unit (c4)
c5: Judgment unit (c5)
c6: Display unit (c6)
21: Transmission/reception of abnormal battery evaluation information 31: Past data 32: Present data 33: Learning model 34: Input to learning model 35: Output from learning model

Claims (2)

A remote monitoring system for an emergency charger/discharger (A), a server (B) and an administrator electronic terminal (C) connected by a network ,
The emergency charger/discharger (A) has a battery unit (a1) having a storage battery, a detection unit (a2) that detects battery information of the battery unit (a1), and an identification code of the emergency charger/discharger (A). And a transmitter (a3) for transmitting the detected battery information to the server (B),
When the server (B) receives the identification code and the battery information, and the emergency charger (A) is in a normal state or an abnormal state based on the received battery information and the received battery information. A generator (b2) for generating battery evaluation information indicating whether there is any, and a transmitter (b3) for transmitting the battery evaluation information to the administrator electronic terminal (C),
Administrators electronic terminal (C) is, the reception unit for receiving battery evaluation information (c1), in emergency discharge unit of the remote monitoring system that includes a display unit and (c2) for displaying battery evaluation information received There
The server (B) includes a transmission unit (b4) that transmits abnormal battery evaluation information indicating that the emergency charger/discharger (A) is in an abnormal state to the administrator electronic terminal (C),
The manager electronic terminal (C) includes means for specifying the position information of the manager electronic terminal (C), and a position information holding unit (c3) that holds the position information,
A receiver (c4) for receiving the abnormal battery evaluation information,
A determination unit (c5) that determines whether or not the battery is present at a certain distance from the emergency battery (A) based on the position information;
Remote monitoring of an emergency charger/discharger , comprising: a display unit (c6) for displaying the abnormal battery evaluation information on the administrator electronic terminal (C) when it is determined that the battery is present at the certain distance. system. The server (B) uses past data including past battery information, battery evaluation information, and external environmental data as teacher data to perform machine learning for predicting and estimating electrical malfunctions of the emergency charger/discharger. By inputting current data including current battery information, battery evaluation information, and external environment data into the learned learning model that has been performed, the electrical failure of the emergency charger/discharger (A) is predicted/estimated and predicted. A machine learning means (D) for outputting estimated battery evaluation information, and a transmission section (b5) for transmitting the predicted/estimated battery evaluation information to the manager electronic terminal (C),
The manager electronic terminal (C) includes a receiving unit (c6) that receives the predicted/estimated battery evaluation information, and a display unit (c7) that displays the received battery evaluation information, The remote monitoring system for an emergency charger/discharger according to claim 1 .