JP2020047420A - Bolt, flood detection system, and flood detection method - Google Patents

Abstract

An object of the present invention is to provide a bolt, a flood detection system, and a flood detection method that can easily obtain the status of flooding in a switch.
The bolt is provided with a sensor that fits into a screw hole that penetrates from outside into a detection target space in a switch, and detects a state of inundation of the detection target space. Have at the tip.
[Selection diagram] FIG.

Description

  Embodiments of the present invention relate to a bolt, a flood detection system, and a flood detection method.

  The pole switch is a switch attached for controlling and operating the distribution system. For example, rust is generated in the pole switch when used for many years, and when the generated rust progresses, a hole is opened in the outer box, and rainwater may enter through the hole. If the pole switch is flooded by rainwater entering through the hole in the outer box, it may lead to a public disaster such as a power outage accident in the distribution system in which the pole switch is installed. For this reason, the pole switch is regularly inspected for inundation.

  As a technique for detecting flooding of a pole switch, a technique of detecting flooding in a pole switch using ultrasonic waves is known (for example, see Patent Document 1). In this technique, ultrasonic waves are transmitted from a transmitting probe into a steel bottom plate of a pole-mounted switch by a predetermined angle at an oblique angle, and a reflected wave from the pole-mounted switch is transmitted to the transmitting probe. Received by the receiving probe installed on the steel bottom plate facing the probe, and from the received reflected waves, the reflected wave due to the transverse wave from the steel bottom plate and the longitudinal wave reflected wave from the water interface caused by flooding Detect and display.

JP-A-7-280775

When detecting inundation in the pole switch using ultrasonic waves, it is necessary to go to the installation position of the pole switch and make the ultrasonic wave incident on the pole switch. Since a huge number of pole switches were installed in the distribution system, a great deal of labor was required.
Further, in order to detect inundation in the on-pole switch using ultrasonic waves, it is necessary to observe the waveform of the reflected wave, and judgment by a skilled technician was required.
The above applies not only to pole switches, but also to switches.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a bolt, a waterlogging detection system, and a waterlogging detection method that can easily obtain the state of waterlogging in a switch.

One embodiment of the present invention is a bolt that fits into a screw hole penetrating from the outside into a detection target space in a switch, and includes a sensor that detects a state of inundation of the detection target space, wherein the bolt is A bolt having the sensor at a threaded portion of the bolt.
The bolt according to one embodiment of the present invention includes a communication unit that transmits information indicating the state of the flooding detected by the sensor to a management device that manages the inside of the switch.
In the bolt of one aspect of the present invention, the sensor detects humidity inside and outside the switch.
In the bolt according to one embodiment of the present invention, the switch is a pole switch.
In the bolt of one aspect of the present invention, the screw hole is an airtight plug.
One aspect of the present invention includes a sensor that detects the state of flooding of the detection target space in the switch from the outside, a bolt that fits into a screw hole penetrating the detection target space, and the sensor that is detected by the sensor. A communication device that transmits information indicating the state of flooding to a management device that manages the inside of the switch, and whether the inside of the switch is flooded based on the information indicating the state of flooding transmitted by the communication device. A sensor for determining whether or not the sensor is mounted, wherein the sensor is an inundation detection system attached to a threaded portion of the bolt.
One aspect of the present invention is a management device that manages the inside of the switch with information indicating a state of flooding detected by a sensor provided on a bolt that fits into a screw hole that penetrates a detection target space in the switch from the outside. And determining whether or not the inside of the switch is flooded based on the information indicating the state of flooding transmitted in the transmitting step, wherein the bolt is: A method for detecting inundation, wherein the sensor is provided on a threaded portion of the bolt.

  According to the embodiment of the present invention, it is possible to provide a bolt, a flood detection system, and a flood detection method that can easily acquire the state of flooding in the switch.

It is a mimetic diagram showing an example of the distribution line system to which the flood detection system of a 1st embodiment is applied. It is a figure showing an example of a bolt of a 1st embodiment. It is a block diagram showing an example of the flood detection system of a 1st embodiment. It is a figure showing an example of a table. It is a sequence chart which shows an example of operation of the flood detection system of a 1st embodiment. It is a schematic diagram which shows an example of the distribution line system to which the inundation detection system of 2nd Embodiment is applied. It is a figure showing an example of a bolt of a 2nd embodiment. It is a block diagram showing an example of a flood detection system of a 2nd embodiment. It is a figure showing an example of a table. It is a sequence chart which shows an example of operation of the inundation detection system of a 2nd embodiment.

Next, a bolt, a flood detection system, and a flood detection method of the present embodiment will be described with reference to the drawings. The embodiment described below is merely an example, and the embodiment to which the present invention is applied is not limited to the following embodiment.
In all the drawings for describing the embodiments, components having the same function are denoted by the same reference numerals, and repeated description is omitted.
Further, “based on XX” in the present application means “based on at least XX”, and includes a case based on another element in addition to XX. Further, “based on XX” is not limited to a case where XX is used directly, but also includes a case where XX is based on a calculation or processing. “XX” is an arbitrary element (for example, arbitrary information).

(First embodiment)
(Inundation detection system)
FIG. 1 is a schematic diagram illustrating an example of a distribution line system to which the flood detection system according to the first embodiment is applied.
The inundation detection system of the first embodiment is applied to a distribution line system. The distribution line system supplies power from a power plant to a consumer load such as a house, a commercial facility, or an industrial facility via a substation.
Many electrical devices such as switches, automatic voltage regulators, and transformers are connected to the distribution line system. In the example illustrated in FIG. 1, a pole switch 100 is illustrated as an example of an electric device. The pole switch 100 stops transmission (power failure) of the high-voltage distribution line when an accident such as a short circuit or a ground fault occurs. As shown in FIG. 1, a pole switch 100 is installed (posted) above a power pole 102, and a high-voltage distribution line 106 a on the power supply side and a high-voltage distribution line on the load side, which are mounted on the arm 104. 106b is connected. In the waterlogging detection system according to the present embodiment, the presence or absence of waterlogging in the outer box (case) 100a of the pole switch 100 is detected.

In the manufacturing process of the pole switch 100, when confirming that the assembled outer box 100a has no airtight leakage, a gas injection port is mainly provided at a lower portion of the outer box 100a to pressurize the inside of the outer box 100a. It is formed. The gas inlet has a screw hole, and after confirming that there is no airtight leak in the outer box 100a, an airtight plug is fitted. An example of the airtight stopper is a bolt 300. Thereby, the airtightness of the inside of the outer box 100a can be maintained, so that the entry of moisture into the pole switch 100 can be reduced.
Further, a sensor is attached to the bolt 300 at the screw tip of the bolt 300. The sensor detects the state of flooding inside the outer box 100a. The sensor value obtained by the detection by the sensor is transmitted to the communication device 200 via the cable 320.
The communication device 200 is installed in association with each pole switch 100. The communication device 200 receives the sensor value from the sensor attached to the bolt 300 and generates the sensor value notification information including the received sensor value and the communication device ID of the communication device 200 and destined for the management device 400. I do. The communication device 200 transmits the created sensor value notification information to another device such as the management device 400.
The management device 400 receives the sensor value notification information transmitted by the communication device 200, and acquires the sensor value and the communication device ID included in the received sensor value notification information. The management device 400 determines whether or not the pole switch 100 inside the outer box 100a in which the bolt 300 having the sensor that has transmitted the sensor value is fitted is flooded based on the acquired sensor value. The management device 400 specifies the pole switch 100 corresponding to the acquired communication device ID, and associates the specified pole switch 100 with the determination result of whether or not the pole switch 100 is submerged. To display.

(Bolt 300)
FIG. 2 is a diagram illustrating an example of the bolt according to the first embodiment. As described above, the bolt 300 is fitted into the screw hole at the bottom of the outer box 100a of the pole switch 100.
The bolt 300 includes a sensor 310, a cable 320, and a bolt body B. Examples of the sensor 310 are a short-circuit sensor, a temperature sensor, a humidity sensor, and the like. Hereinafter, the case where a temperature sensor is used as an example of the sensor 310 will be described. The sensor 310 is attached to a screw tip portion SD of the bolt body B. The sensor 310 may be embedded in the screw tip portion SD of the bolt body B. Hereinafter, the case where the sensor 310 is attached to the threaded end portion SD of the bolt body B will be described as an example. With this configuration, when the bolt 300 is fitted into the screw hole at the lower part of the outer box 100a of the pole switch 100, the sensor 310 attached to the threaded end portion SD becomes inside the outer box 100a. , The state of water in the space inside the outer box 100a can be detected.
The sensor value obtained by the sensor 310 detecting the state of inundation in the space inside the outer box 100a is transmitted to the communication device 200 via the cable 320.

FIG. 3 is a block diagram illustrating an example of the flood detection system according to the first embodiment. In the example illustrated in FIG. 3, the inundation detection system includes a bolt 300-1, a communication device 200-1, a bolt 300-2, a communication device 200-2, a bolt 300-3, and a communication device 200-3. And a management device 400.
The bolt 300-1 is fitted into an outer box 100a-1 (not shown) of the pole switch 100-1 (not shown), and the bolt 300-2 is provided outside the pole switch 100-2 (not shown). The bolt 300-3 is fitted into a box 100a-2 (not shown) and the outer box 100a-3 (not shown) of the pole switch 100-3 (not shown).
An arbitrary bolt among the bolt 300-1, the bolt 300-2, and the bolt 300-3 is described as a bolt 300. An arbitrary sensor among the sensor 310-1, the sensor 310-2, and the sensor 310-3 is described as a sensor 310. An arbitrary communication device among the communication device 200-1, the communication device 200-2, and the communication device 200-3 is referred to as a communication device 200.
Since the bolt 300, the sensor 310, and the communication device 200 have been described above, description thereof will be omitted.

(Management device 400)
The management device 400 is realized by a device such as a personal computer, a server, or an industrial computer. The management device 400 electrically connects the above-described components to the communication unit 410, the storage unit 420, the information processing unit 430, the display unit 440, the operation unit 450, and the components as illustrated in FIG. And a bus line 460 such as an address bus or a data bus.
The communication unit 410 is realized by a communication module. The communication unit 410 communicates with an external communication device such as the communication device 200 via the network 50. Specifically, communication unit 410 receives the sensor value notification information transmitted by communication device 200, and outputs the received sensor value notification information to information processing unit 430. The communication unit 410 may transmit, to another device, information in which the pole switch ID output by the information processing unit 430 and the inundation determination result are associated with each other.

  The storage unit 420 is realized by, for example, a random access memory (RAM), a read only memory (ROM), a hard disk drive (HDD), a flash memory, or a hybrid storage device in which a plurality of these are combined. The storage unit 420 stores a program 421 executed by the information processing unit 430, an application 422, and a table 423.

The application 422 causes the management device 400 to receive the sensor value notification information transmitted by the communication device 200. The application 422 causes the management device 400 to acquire the sensor value and the communication device ID from the received sensor value notification information. The application 422 causes the management device 400 to determine whether or not the inside of the outer box 100a in which the bolt 300 having the sensor that outputs the sensor value is fitted is flooded, based on the acquired sensor value. The application 422 causes the management device 400 to acquire the pole switch ID of the pole switch 100 corresponding to the acquired communication device ID. The application 422 causes the display unit 440 to display a determination result as to whether or not the inside of the outer box 100a is flooded (hereinafter, referred to as a “flood determination result”) and a pole switch ID of the pole switch 100. At the same time, output to another device.
The table 423 is information in a table format in which the communication device ID and the pole switch ID are associated with each other.
FIG. 4 is a diagram illustrating an example of the table. In the example shown in FIG. 4, the communication device ID “CE001” is associated with the pole switch ID “PS001” of the pole switch 100 of the pole switch 100 corresponding to the communication device indicated by the communication device ID. Returning to FIG. 3, the description will be continued.
The display unit 440 displays the pole switch ID of the pole switch 100 and the inundation determination result of the pole switch 100 in association with each other. Specifically, the display unit 440 displays the pole switch ID of the pole switch 100, and when the user performs an operation of pressing the pole switch ID of the pole switch 100, the user The on-pole switch ID that has been pressed and the inundation determination result of the on-pole switch 100 corresponding to the on-pole switch ID are displayed in association with each other.
The operation unit 450 includes, for example, a touch panel, detects a touch operation on a screen displayed on the display unit 440, and outputs a detection result of the touch operation to the information processing unit 430.

All or a part of the information processing unit 430 is, for example, a functional unit (hereinafter, referred to as a software functional unit) realized by a processor such as a CPU (Central Processing Unit) executing the program 421 stored in the storage unit 420. ). Note that all or a part of the information processing unit 430 may be realized by hardware such as an LSI (Large Scale Integration), an ASIC (Application Specific Integrated Circuit), or an FPGA (Field-Programmable Gate Array), and a software function. It may be realized by a combination of a unit and hardware.
The information processing unit 430 includes, for example, an acquisition unit 431, a flood determination unit 432, and an output unit 433.

The acquisition unit 431 acquires the sensor value notification information output by the communication unit 410, and outputs the acquired sensor value notification information to the water intrusion determination unit 432.
The flood judgment unit 432 acquires the sensor value notification information output by the acquisition unit 431, and acquires the communication device ID and the sensor value included in the acquired sensor value notification information. Based on the acquired sensor value, the waterlogging determination unit 432 determines whether the pole switch 100 inside the outer box 100a in which the bolt 300 having the sensor that transmitted the sensor value is fitted is flooded. . Specifically, based on the temperature inside the outer box 100a acquired as the sensor value, the inundation determination unit 432 determines whether the difference between the temperature inside the outer box 100a and the temperature outside is greater than or equal to a threshold value. It may be determined that the upper switch 100 is submerged, and if it is less than the threshold, it may be determined that the pole switch 100 is not submerged. This is because when the pole switch 100 is submerged, it is assumed that the temperature change inside the outer box 100a is smaller than the temperature change outside the outer box 100a. Here, the temperature outside the outer box 100a may be acquired from weather information provided by the Meteorological Agency, or a thermometer may be installed in the communication device 200 and acquired from the installed thermometer. When acquiring from the thermometer installed in the communication device 200, the communication device 200 may transmit the information indicating the temperature outside the outer box 100a in the sensor value notification information. The flood determination unit 432 outputs the acquired communication device ID and the flood determination result to the output unit 433.
The output unit 433 acquires the communication device ID output by the flood determination unit 432 and the flood determination result. The output unit 433 acquires the pole switch ID associated with the acquired communication device ID from the table 423 stored in the storage unit 420. When the user performs an operation of pressing the pole switch ID of the pole switch 100, the output unit 433 outputs the pole switch ID acquired based on the detection result of the touch operation output by the operation unit 450. Is displayed on the display unit 440 in association with the inundation determination result. Further, the output unit 433 may transmit, from the communication unit 410, information relating the pole switch ID to the inundation determination result to another device.

(Operation of inundation determination system)
FIG. 5 is a diagram illustrating an example of an operation of the inundation determination system according to the first embodiment.
(Step S1)
For the bolt 300-1, the sensor 310-1 attached to the threaded portion of the bolt 300-1 detects a sensor value obtained by detecting the state of inundation inside the outer box 100a-1, and the communication device 200- Send to 1. Specifically, the sensor 310-1 detects the state of flooding inside the outer box 100a-1 at a predetermined cycle such as once a day, once a week, once a month, or the like. The sensor value obtained in this way is transmitted to the communication device 200-1.
(Step S2)
The communication device 200-1 acquires the sensor value transmitted by the volt 300-1 and the sensor value notification information including the acquired sensor value and the communication device ID-1 of the communication device 200-1 (hereinafter, “first sensor”). Value notification information ”). The communication device 200-1 transmits the created first sensor value notification information to the management device 400. The communication unit 410 of the management device 400 receives the sensor value notification information transmitted by the communication device 200-1.
(Step S3)
The communication device 200-transmits the sensor value obtained by the sensor 310-2 attached to the screw tip portion of the bolt 300-2 by detecting the state of inundation inside the outer box 100 a-2. Send to 2.

(Step S4)
The communication device 200-2 acquires the sensor value transmitted by the volt 300-2, and sensor value notification information (hereinafter, “second sensor”) including the acquired sensor value and the communication device ID-2 of the communication device 200-2. Value notification information ”). The communication device 200-2 transmits the created second sensor value notification information to the management device 400. The communication unit 410 of the management device 400 receives the sensor value notification information transmitted by the communication device 200-2.
(Step S5)
The communication device 200-outputs the sensor value obtained by the sensor 300-3 attached to the screw tip portion of the bolt 300-3 detecting the state of inundation inside the outer box 100 a-3. Send to 3.
(Step S6)
The communication device 200-3 acquires the sensor value transmitted by the volt 300-3, and sensor value notification information including the acquired sensor value and the communication device ID-3 of the communication device 200-3 (hereinafter, “third sensor”). Value notification information ”). The communication device 200-3 transmits the created third sensor value notification information to the management device 400. The communication unit 410 of the management device 400 receives the sensor value notification information transmitted by the communication device 200-3.

(Step S7)
The communication unit 410 of the management device 400 includes the first sensor value notification information transmitted by the communication device 200-1, the second sensor value notification information transmitted by the communication device 200-2, and the second sensor value notification information transmitted by the communication device 200-3. The third sensor value notification information is received, and the received first sensor value notification information, second sensor value notification information, and third sensor value notification information are output to the acquisition unit 431.
The acquisition unit 431 acquires the first sensor value notification information, the second sensor value notification information, and the third sensor value notification information output by the communication unit 410, and acquires the acquired first sensor value notification information and second sensor value. The value notification information and the third sensor value notification information are output to the flood determination unit 432.
The inundation determination unit 432 acquires the first sensor value notification information output by the acquisition unit 431, and acquires the communication device ID-1 and the sensor value included in the acquired first sensor value notification information. Based on the acquired sensor value, the waterlogging determination unit 432 determines whether the inside of the outer box 100a-1 in which the bolt 300-1 having the sensor 310-1 that has transmitted the sensor value is fitted is flooded. I do. The flood determination unit 432 outputs the acquired communication device ID and the flood determination result to the output unit 433.
The inundation determination unit 432 acquires the second sensor value notification information output by the acquisition unit 431, and acquires the communication device ID-2 and the sensor value included in the acquired second sensor value notification information. The waterlogging determination unit 432 determines whether or not the inside of the outer box 100a-2 in which the bolt 300-2 having the sensor 310-2 that has transmitted the sensor value is fitted is based on the acquired sensor value. I do. The flood determination unit 432 outputs the acquired communication device ID-2 and the flood determination result to the output unit 433.
The inundation determination unit 432 acquires the third sensor value notification information output by the acquisition unit 431, and acquires the communication device ID-3 and the sensor value included in the acquired third sensor value notification information. The waterlogging determination unit 432 determines whether or not the inside of the outer box 100a-3 in which the bolt 300-3 having the sensor 310-3 that has transmitted the sensor value is fitted is flooded, based on the acquired sensor value. I do. The flood determination unit 432 outputs the acquired communication device ID-3 and the flood determination result to the output unit 433.

(Step S8)
The output unit 433 of the management device 400 acquires the communication device ID-1 output by the flood determination unit 432 and the flood determination result. The output unit 433 acquires the pole switch ID-1 stored in association with the acquired communication device ID-1 from the table 423 stored in the storage unit 420. The output unit 433 detects a touch operation output by the operation unit 450 when the user performs an operation of pressing the pole switch ID-1 of the pole switch 100-1 by operating the operation unit 450. Based on the result, the acquired pole switch ID-1 is associated with the inundation determination result and displayed on the display unit 440. In addition, the output unit 433 may transmit, from the communication unit 410, information relating the pole switch ID-1 and the inundation determination result to another device.
In addition, the output unit 433 of the management device 400 acquires the communication device ID-2 output by the flood determination unit 432 and the flood determination result. The output unit 433 acquires the pole switch ID-2 stored in association with the acquired communication device ID-2 from the table 423 stored in the storage unit 420. The output unit 433 detects the touch operation output by the operation unit 450 when the user performs an operation of pressing the pole switch ID-2 of the pole switch 100-2 by operating the operation unit 450. Based on the result, the acquired on-pole switch ID-2 and the inundation determination result are displayed on the display unit 440 in association with each other. In addition, the output unit 433 may transmit information in which the pole switch ID-2 is associated with the inundation determination result from the communication unit 410 to another device.
Further, the output unit 433 of the management device 400 acquires the communication device ID-3 output by the flood determination unit 432 and the flood determination result. The output unit 433 acquires the pole switch ID-3 stored in association with the acquired communication device ID-3 from the table 423 stored in the storage unit 420. The output unit 433 detects the touch operation output by the operation unit 450 when the user performs an operation of pressing the pole switch ID-3 of the pole switch 100-3 by operating the operation unit 450. Based on the result, the acquired on-pole switch ID-3 is associated with the inundation determination result and displayed on the display unit 440. In addition, the output unit 433 may transmit information in which the pole switch ID-3 is associated with the inundation determination result from the communication unit 410 to another device.
In the sequence chart shown in FIG. 5, the management device 400 determines that the first sensor value notification information transmitted by the communication device 200-1, the second sensor value notification information transmitted by the communication device 200-2, and the communication device 200- After receiving the third sensor value notification information transmitted by the third unit 3, it is determined whether the inside of the outer box 100a-1, the inside of the outer box 100a-2, and the inside of the outer box 100a-3 are submerged. However, the present invention is not limited to this example. For example, immediately after receiving the first sensor value notification information transmitted by the communication device 200-1, the management device 400 determines whether or not the inside of the outer box 100a-1 is submerged. Immediately after receiving the transmitted second sensor value notification information, it is determined whether or not the inside of the outer box 100a-2 is submerged, and immediately after receiving the third sensor value notification information transmitted by the communication device 200-3. It may be determined whether or not the inside of the outer box 100a-3 is submerged.

In the above-described first embodiment, the pole switch 100 has been described. However, the present invention is not limited to this example, and can be applied to a switch. In the case of using a switch, it is possible to eliminate the trouble of traveling to a place where the switch is installed and the trouble of irradiating the pole switch 100 with ultrasonic waves. By using the pole switch 100, it is possible to eliminate the trouble of traveling to the installation location of the pole switch 100 and the time of irradiating ultrasonic waves above the electric pole 102 on which the pole switch 100 is installed. it can.
In the first embodiment described above, the case where the bolt 300 is fitted as a hermetic plug into the gas inlet at the lower part of the outer box 100a has been described, but the present invention is not limited to this example. For example, it may be a screw hole other than the gas inlet penetrating the outer box 100a. When a screw hole other than the gas injection port penetrating the outer box 100a is used, it is necessary to open a new through hole. It can be determined whether or not the inside of the pole switch 100 is submerged.
In the first embodiment described above, the case where the inundation detection system includes the bolt 300-1, the bolt 300-2, and the bolt 300-3 has been described, but the present invention is not limited to this example. For example, the number of bolts 300 may be one to two, or four or more.
In the first embodiment described above, the case where the inundation detection system includes the communication device 200-1, the communication device 200-2, and the communication device 200-3 has been described. However, the present invention is not limited to this example. For example, the number of communication devices 200 may be one or two, or four or more.

In the first embodiment described above, the case where the temperature outside the outer box 100a is obtained from the weather information provided by the Meteorological Agency and the case where the thermometer is installed in the communication device 200 and obtained from the installed thermometer Has been described, but the present invention is not limited to this example. For example, the sensor 310 may be provided on the bolt 300 so that the temperature outside the outer box 100a can also be measured. With this configuration, it is possible to obtain the temperature outside the outer box 100a from the weather information provided by the Meteorological Agency, or to obtain the temperature outside the outer box 100a from a thermometer installed in the communication device 200. Instead, the temperature outside the outer box 100a can be obtained. In this case, the sensor 310 outputs the temperature inside and outside the outer box 100a to the communication device 200 as the sensor value.
In the first embodiment described above, the case where the temperature sensor is fitted to the bolt body B has been described as an example of the sensor, but the sensor is not limited to this example. For example, a short-circuit sensor may be fitted into the bolt body B. In this case, information indicating a short circuit detected by the short circuit sensor is transmitted to the communication device 200 as sensor information.
Further, for example, a humidity sensor may be fitted into the bolt body B. In this case, information indicating the humidity detected by the humidity sensor is transmitted to the communication device 200 as sensor information. Based on the humidity inside the outer box 100a obtained as a sensor value, the waterlogging determination unit 432 determines whether the on-pole switch 100 is in the case where the difference between the humidity inside the outer box 100a and the outside humidity is equal to or greater than a threshold value. It may be determined that water is flooded, and if it is less than the threshold, it may be determined that the pole switch 100 is not flooded. This is because when the pole switch 100 is submerged, the change in humidity inside the outer box 100a is assumed to be smaller than the change in humidity outside the outer box 100a.
Here, the humidity outside the outer box 100a may be obtained from weather information provided by the Japan Meteorological Agency, or may be obtained by installing a hygrometer in the communication device 200 and installing the thermometer. Further, a sensor 310 may be provided on the bolt 300 so that the humidity outside the outer box 100a can be measured. With this configuration, it is possible to obtain the humidity outside the outer box 100a from the weather information provided by the Meteorological Agency, or to obtain the humidity outside the outer box 100a from the hygrometer installed in the communication device 200. In addition, the humidity outside the outer box 100a can be obtained. In this case, the sensor 310 outputs the humidity inside and outside the outer case 100a to the communication device 200 as the sensor value. When acquiring from the hygrometer installed in the communication device 200, the communication device 200 may transmit the information indicating the humidity outside the outer box 100a in the sensor value notification information.

According to the waterlogging detection system of the first embodiment, in the waterlogging detection system, the bolt 300 having the sensor 310 and the bolt body B is fitted into the gas inlet below the outer box 100a of the pole switch 100. . The sensor value obtained by the sensor 310 detecting the state of the water in the outer box 100a is transmitted to the communication device 200 via the cable 320. The communication device 200 receives the sensor value transmitted by the sensor 310, creates sensor value notification information including the received sensor value and the communication device ID, and transmits the created sensor value notification information to the management device 400.
The management device 400 receives the sensor value notification information transmitted by the communication device 200, and based on the received sensor value notification information, the inside of the outer box 100a in which the bolt 300 having the sensor 310 that has transmitted the sensor value is fitted. It is determined whether or not the pole switch 100 is submerged.
Conventionally, since a huge number of pole switches 100 are installed in the distribution system, ultrasonic inundation detection devices that require various functions are installed for each pole switch 100 for each pole switch. However, it was difficult to remotely control whether or not the water was inundated.
In the present embodiment, with this configuration, it is possible to remotely detect inundation of the pole switch 100 without going to the installation location of the pole switch 100. In addition, by determining whether or not the on-column switch 100 inside the outer box 100a is submerged based on the sensor value detected by the sensor 310, compared with the case of using ultrasonic waves, It is possible to determine the presence or absence of flooding even without a skilled technician. In addition, since the trouble of determining whether or not the pole switch 100 is submerged is simplified, installation on each pole switch 100 can be facilitated.

<Example of configuration>
As one configuration example, a bolt that is externally inserted into a screw hole that penetrates a detection target space in a switch (in the embodiment, a pole switch 100) and detects a state of inundation in the detection target space. A sensor is provided, wherein the bolt has the sensor on a threaded portion of the bolt.
As one configuration example, a communication unit that transmits information indicating the state of flooding detected by the sensor to a management device that manages the inside of the switch is provided.
As one configuration example, the sensor detects humidity inside and outside the switch.
As one configuration example, the switch is a pole switch.
As one configuration example, the screw hole is an airtight plug.

(Second embodiment)
(Inundation detection system)
FIG. 6 is a schematic diagram illustrating an example of a distribution line system to which the flood detection system according to the second embodiment is applied.
The flood detection system of the second embodiment is different from the flood detection system of the first embodiment in that a bolt 300a is provided instead of the bolt 300 and a management device 400a is provided instead of the management device 400.
In the manufacturing process of the pole switch 100, when confirming that the assembled outer box 100a has no airtight leakage, a gas injection port is mainly provided at a lower portion of the outer box 100a to pressurize the inside of the outer box 100a. It is formed. The gas inlet has a screw hole, and after confirming that there is no airtight leak in the outer box 100a, an airtight plug is fitted. An example of the airtight plug is a bolt 300a. Thereby, the airtightness of the inside of the outer box 100a can be maintained, so that the entry of moisture into the pole switch 100 can be reduced.

Further, a sensor is attached to the screw tip of the bolt 300a, and a control unit and a communication unit are attached to the head of the bolt 300a. The sensor detects the state of flooding inside the outer box 100a. The sensor value obtained by the detection by the sensor is output to the control unit via a cable. The control unit acquires the sensor value output by the sensor, creates the sensor value notification information including the acquired sensor value and the control unit ID, and sends the created sensor value notification information to the management device 400a. Output to The communication unit acquires the sensor value notification information output by the control unit, and transmits the acquired sensor value notification information to another device such as the management device 400a.
The management device 400a receives the sensor value notification information transmitted by the bolt 300a, and acquires the sensor value and the control unit ID included in the received sensor value notification information. The management device 400a determines whether or not the pole switch 100 inside the outer box 100a in which the bolt 300a having the sensor that has transmitted the sensor value is fitted is flooded based on the acquired sensor value. The management device 400a specifies the pole switch 100 corresponding to the acquired control unit ID, and associates the specified pole switch 100 with the determination result of whether the pole switch 100 is submerged. To display.

(Bolt 300a)
FIG. 7 is a diagram illustrating an example of a bolt according to the second embodiment. As described above, the bolt 300a is fitted into the screw hole at the bottom of the outer box 100a of the pole switch 100.
The bolt 300a includes a sensor 310, a cable 320a, a cable 320b, a bolt body B, a control unit 330, and a communication unit 340. Examples of the sensor 310 are a short-circuit sensor, a temperature sensor, a humidity sensor, and the like. Hereinafter, the case where a temperature sensor is used as an example of the sensor 310 will be described. The sensor 310 is attached to a screw tip portion SD of the bolt body B. The sensor 310 may be embedded in the screw tip portion SD of the bolt body B. Hereinafter, the case where the sensor 310 is attached to the threaded end portion SD of the bolt body B will be described as an example. With such a configuration, when the bolt 300a is fitted into the screw hole at the lower part of the outer box 100a of the pole switch 100, the sensor 310 attached to the screw point portion SD is moved inside the outer box 100a. , The state of water in the space inside the outer box 100a can be detected.
The sensor value obtained by the sensor 310 detecting the state of inundation in the space inside the outer box 100a is output to the control unit 330 via the cable 320a.
The control unit 330 stores the control unit ID of the control unit 330. The control unit 330 acquires the sensor value output by the sensor 310, and generates sensor value notification information that includes the acquired sensor value and the control unit ID and that is addressed to the management device 400a. The control unit 330 outputs the created sensor value notification information to the communication unit 340 via the cable 320b.
The communication unit 340 acquires the sensor value notification information output by the control unit 330, and transmits the acquired sensor value notification information to another device such as the management device 400a.

FIG. 8 is a block diagram illustrating an example of a flood detection system according to the second embodiment. In the example illustrated in FIG. 8, the inundation detection system includes a bolt 300a-1, a bolt 300a-2, a bolt 300a-3, and a management device 400a.
The bolt 300a-1 is fitted into an outer box 100a-1 (not shown) of the pole switch 100-1 (not shown), and the bolt 300a-2 is outside the pole switch 100-2 (not shown). The bolt 300a-3 is fitted into a box 100a-2 (not shown), and the bolt 300a-3 is fitted into an outer box 100a-3 (not shown) of the pole switch 100-3 (not shown).
An arbitrary bolt among the bolts 300a-1, 300a-2, and 300a-3 is referred to as a bolt 300a. An arbitrary sensor among the sensor 310-1, the sensor 310-2, and the sensor 310-3 is described as a sensor 310. An arbitrary control unit among the control unit 330-1, the control unit 330-2, and the control unit 330-3 is described as a control unit 330. An arbitrary communication unit among the communication unit 340-1, the communication unit 340-2, and the communication unit 340-3 is described as a communication unit 340.
The bolt 300a, the sensor 310, the control unit 330, and the communication unit 340 have been described above, and thus description thereof will be omitted.

(Management device 400a)
The management device 400a is realized by a device such as a personal computer, a server, or an industrial computer. The management device 400a electrically connects the above-described components with the communication unit 410a, the storage unit 420a, the information processing unit 430a, the display unit 440, and the operation unit 450, as shown in FIG. And a bus line 460 such as an address bus or a data bus.
The communication unit 410a is realized by a communication module. The communication unit 410a communicates with an external communication device such as the bolt 300a via the network 50. Specifically, communication unit 410a receives the sensor value notification information transmitted by bolt 300a, and outputs the received sensor value notification information to information processing unit 430a. In addition, the communication unit 410a may transmit, to another device, information in which the pole switch ID output by the information processing unit 430a and the inundation determination result are associated with each other.

  The storage unit 420a is realized by, for example, a RAM, a ROM, an HDD, a flash memory, or a hybrid storage device in which a plurality of these are combined. The storage unit 420a stores a program 421 executed by the information processing unit 430a, an application 422a, and a table 423a.

The application 422a causes the management device 400a to receive the sensor value notification information transmitted by the bolt 300a. The application 422a causes the management device 400a to acquire the sensor value and the control unit ID from the received sensor value notification information. The application 422a causes the management device 400a to determine whether or not the inside of the outer box 100a in which the bolt 300a having the sensor that outputs the sensor value is fitted is flooded, based on the acquired sensor value. The application 422a causes the management device 400a to acquire the pole switch ID of the pole switch 100 corresponding to the acquired control unit ID. The application 422a causes the display unit 440 to display the inundation determination result inside the outer box 100a and the pole switch ID of the pole switch 100, and output the result to another device.
The table 423a is information in a table format in which the control unit ID and the pole switch ID are associated with each other.

  FIG. 9 is a diagram illustrating an example of the table. In the example illustrated in FIG. 9, the communication unit ID “CU001” is associated with the pole switch ID “PS001” of the pole switch 100 of the pole switch 100 corresponding to the communication unit indicated by the communication unit ID. Returning to FIG. 8, the description will be continued.

All or a part of the information processing unit 430a is, for example, a software function unit realized by a processor such as a CPU executing a program 421 stored in the storage unit 420a. Note that all or a part of the information processing unit 430a may be realized by hardware such as an LSI, an ASIC, or an FPGA, or may be realized by a combination of a software function unit and hardware.
The information processing unit 430a includes, for example, an acquisition unit 431, a flood judgment unit 432a, and an output unit 433a.

The flood determination unit 432a acquires the sensor value notification information output by the acquisition unit 431, and acquires the control unit ID and the sensor value included in the acquired sensor value notification information. The waterlogging determination unit 432a determines, based on the acquired sensor value, whether or not the on-column switch 100 inside the outer box 100a in which the bolt 300a having the sensor that has transmitted the sensor value is fitted. . Specifically, based on the temperature inside the outer box 100a acquired as the sensor value, the inundation determination unit 432a determines whether the difference between the temperature inside the outer box 100a and the temperature outside is greater than or equal to a threshold value. It may be determined that the upper switch 100 is submerged, and if it is less than the threshold, it may be determined that the pole switch 100 is not submerged. This is because when the pole switch 100 is submerged, it is assumed that the temperature change inside the outer box 100a is smaller than the temperature change outside the outer box 100a.
Here, the temperature outside the outer box 100a may be acquired from weather information provided by the Meteorological Agency, or a thermometer may be installed in the controller 330 and acquired from the installed thermometer. When acquiring from the thermometer installed in the control unit 330, the control unit 330 may include information indicating the temperature outside the outer box 100a in the sensor value notification information and output the information to the communication unit 340. . The flood judgment unit 432a outputs the acquired control unit ID and the flood judgment result to the output unit 433a.
The output unit 433a acquires the control unit ID output by the flood determination unit 432a and the flood determination result. The output unit 433a acquires the pole switch ID associated with the acquired control unit ID from the table 423a stored in the storage unit 420a. When the user performs an operation of pressing the pole switch ID of the pole switch 100, the output unit 433a outputs the pole switch ID acquired based on the detection result of the touch operation output by the operation unit 450. Is displayed on the display unit 440 in association with the inundation determination result. In addition, the output unit 433a may transmit, from the communication unit 410a, information relating the pole switch ID and the inundation determination result to another device.

(Operation of inundation determination system)
FIG. 10 is a diagram illustrating an example of an operation of the inundation determination system according to the second embodiment.
(Step S11)
The bolt 300a-1 outputs a sensor value obtained by the sensor 310-1 attached to the threaded portion of the bolt 300a-1 to detect the state of water in the outer case 100a-1. Output to 1. The control unit 330-1 acquires the sensor value output by the sensor 310-1, includes the acquired sensor value and the control unit ID-1, and sends sensor value notification information to the management device 400a. 1 sensor value notification information ”). The control unit 330-1 outputs the created first sensor value notification information to the communication unit 340-1. The communication unit 340-1 acquires the first sensor value notification information output by the control unit 330-1 and transmits the acquired first sensor value notification information to the management device 400a. Specifically, the sensor 310-1 detects the state of flooding inside the outer box 100a-1 at a predetermined cycle such as once a day, once a week, once a month, or the like. The obtained sensor value is output to the control unit 330-1.
(Step S12)
Bolt 300a-2 outputs a sensor value obtained by sensor 310-2 attached to a threaded portion of bolt 300a-2 by detecting a state of water ingress in outer case 100a-2, and outputs control value to controller 330- Output to 2. The control unit 330-2 acquires the sensor value output by the sensor 310-2, includes the acquired sensor value, and the control unit ID-2, and sends the sensor value notification information (hereinafter, “first value”) addressed to the management device 400a. 2 sensor value notification information ”). The control unit 330-2 outputs the created second sensor value notification information to the communication unit 340-2. The communication unit 340-2 acquires the second sensor value notification information output by the control unit 330-2, and transmits the acquired sensor value notification information to the management device 400a. Specifically, the sensor 310-2 detects the state of flooding inside the outer box 100a-2 at a predetermined cycle such as once a day, once a week, once a month, or the like. The obtained sensor value is output to the control unit 330-2.
(Step S13)
The sensor value obtained by the sensor 310-3 attached to the threaded portion of the bolt 300a-3 detecting the state of inundation inside the outer box 100a-3 is supplied to the control unit 330- Output to 3. The control unit 330-3 acquires the sensor value output from the sensor 310-3, includes the acquired sensor value, and the control unit ID-3, and sends the sensor value notification information (hereinafter, “first value”) addressed to the management device 400a. 3 sensor value notification information ”). The control unit 330-3 outputs the created third sensor value notification information to the communication unit 340-3. The communication unit 340-3 acquires the third sensor value notification information output by the control unit 330-3, and transmits the acquired sensor value notification information to the management device 400a. Specifically, the sensor 310-3 detects the state of flooding inside the outer box 100a-3 at a predetermined cycle such as once a day, once a week, once a month, or the like. The obtained sensor value is output to the control unit 330-3.

(Step S14)
The communication unit 410a of the management device 400a transmits the first sensor value notification information transmitted by the bolt 300a-1, the second sensor value notification information transmitted by the bolt 300a-2, and the third sensor value transmitted by the bolt 300a-3. The notification information is received, and the received first sensor value notification information, second sensor value notification information, and third sensor value notification information are output to the acquisition unit 431.
The acquisition unit 431 of the management device 400a acquires the first sensor value notification information, the second sensor value notification information, and the third sensor value notification information received by the communication unit 410a, and acquires the acquired first sensor value notification information. And the second sensor value notification information and the third sensor value notification information are output to the inundation determination unit 432a.
The flood determination unit 432a acquires the first sensor value notification information output by the acquisition unit 431, and acquires the control unit ID-1 and the sensor value included in the acquired first sensor value notification information. Based on the acquired sensor value, the waterlogging determination unit 432a determines whether the inside of the outer box 100a-1 in which the bolt 300a-1 having the sensor 310-1 that has transmitted the sensor value is fitted is flooded. I do. The flood judgment unit 432a outputs the acquired control unit ID and the flood judgment result to the output unit 433a.

The inundation determination unit 432a acquires the second sensor value notification information output by the acquisition unit 431, and acquires the control unit ID-2 and the sensor value included in the acquired second sensor value notification information. Based on the acquired sensor value, the waterlogging determination unit 432a determines whether the inside of the outer box 100a-2 in which the bolt 300a-2 having the sensor 310-2 that has transmitted the sensor value is fitted is flooded. I do. The flood judgment unit 432a outputs the acquired control unit ID and the flood judgment result to the output unit 433a.
The inundation determination unit 432a acquires the third sensor value notification information output by the acquisition unit 431, and acquires the control unit ID-3 and the sensor value included in the acquired third sensor value notification information. Based on the acquired sensor value, the waterlogging determination unit 432a determines whether the inside of the outer box 100a-3 in which the bolt 300a-3 having the sensor 310-3 that has transmitted the sensor value is fitted is flooded. I do. The flood judgment unit 432a outputs the acquired control unit ID and the flood judgment result to the output unit 433a.

(Step S15)
The output unit 433a of the management device 400a acquires the control unit ID-1 output by the flood determination unit 432a and the flood determination result. The output unit 433a acquires the pole switch ID-1 stored in association with the acquired control unit ID-1 from the table 423a stored in the storage unit 420a. The output unit 433a displays the acquired pole switch ID-1 on the display unit 440 in association with the inundation determination result. Further, the output unit 433a may transmit, from the communication unit 410a, information relating the pole switch ID-1 and the inundation determination result to another device.
Further, the output unit 433a of the management device 400a acquires the control unit ID-2 output by the flood determination unit 432a and the flood determination result. The output unit 433a acquires the pole switch ID-2 stored in association with the acquired control unit ID-2 from the table 423a stored in the storage unit 420a. The output unit 433a displays the acquired pole switch ID-2 on the display unit 440 in association with the inundation determination result. In addition, the output unit 433a may transmit, from the communication unit 410a, information relating the pole switch ID-2 and the inundation determination result to another device.
In addition, the output unit 433a of the management device 400a acquires the control unit ID-3 output by the flood determination unit 432a and the flood determination result. The output unit 433a acquires the pole switch ID-3 stored in association with the acquired control unit ID-3 from the table 423a stored in the storage unit 420a. The output unit 433a displays the acquired pole switch ID-3 on the display unit 440 in association with the inundation determination result. Further, the output unit 433a may transmit, from the communication unit 410a, information relating the pole switch ID-3 and the inundation determination result to another device.
In the sequence chart illustrated in FIG. 10, the management device 400a transmits the first sensor value notification information transmitted by the bolt 300a-1, the second sensor value notification information transmitted by the bolt 300a-2, and the bolt 300a-3 transmits After receiving the third sensor value notification information described above, it is determined whether or not the inside of the outer box 100a-1, the inside of the outer box 100a-2, and the inside of the outer box 100a-3 are submerged. Although described, it is not limited to this example. For example, the management device 400a determines whether or not the inside of the outer box 100a-1 is submerged immediately after receiving the first sensor value notification information transmitted by the bolt 300a-1, and transmits the bolt 300a-2. Immediately after receiving the second sensor value notification information, it is determined whether or not the inside of the outer box 100a-2 is submerged, and immediately after receiving the third sensor value notification information transmitted by the bolt 300a-3, the outer box 100a is determined. It may be determined whether or not the inside of -3 is submerged.

In the above-described second embodiment, the pole switch 100 has been described. However, the present invention is not limited to this example and can be applied to a switch. In the case of using a switch, it is possible to eliminate the trouble of traveling to a place where the switch is installed and the trouble of irradiating the pole switch 100 with ultrasonic waves. By using the pole switch 100, it is possible to eliminate the trouble of traveling to the installation location of the pole switch 100 and the time of irradiating ultrasonic waves above the electric pole 102 on which the pole switch 100 is installed. it can.
In the above-described second embodiment, the case where the bolt 300a is fitted as a hermetic plug into the gas inlet below the outer box 100a has been described, but the present invention is not limited to this example. For example, it may be a screw hole other than the gas inlet penetrating the outer box 100a. When a screw hole other than the gas injection port penetrating the outer box 100a is used, it is necessary to open a new through hole. It can be determined whether or not the inside of the pole switch 100 is submerged.
In the above-described second embodiment, a case has been described where the sensor value notification information includes the control unit ID and the sensor value, but the present invention is not limited to this example. For example, a communication unit ID may be included instead of the control unit ID. In this case, the management unit 400a stores the communication unit ID and the pole switch ID in association with each other. Further, a pole switch ID may be included instead of the control unit ID. With this configuration, the process of deriving the pole switch ID from the control unit ID can be omitted.
In the second embodiment described above, the case where the immersion detection system includes the bolt 300a-1, the bolt 300a-2, and the bolt 300a-3 has been described, but the present invention is not limited to this example. For example, the number of the bolts 300a may be one to two, or may be four or more.
In the above-described second embodiment, the case where the temperature outside the outer box 100a is obtained from the weather information provided by the Meteorological Agency and the case where the thermometer is installed in the control unit 330 and is obtained from the installed thermometer Has been described, but the present invention is not limited to this example. For example, the sensor 310 may be provided on the bolt 300a so that the temperature outside the outer box 100a can be measured. With this configuration, it is possible to obtain the temperature outside the outer box 100a from the weather information provided by the Meteorological Agency, or to obtain the temperature outside the outer box 100a from a thermometer installed in the communication device 200. Instead, the temperature outside the outer box 100a can be obtained. In this case, the sensor 310 outputs the temperature inside and outside the outer box 100a to the communication unit 340 as the sensor value.

In the above-described second embodiment, the case where the temperature sensor is fitted into the bolt body B has been described as an example of the sensor, but is not limited to this example. For example, a short-circuit sensor may be fitted into the bolt body B. In this case, information indicating that a short circuit is detected by the short circuit sensor is transmitted to the control unit 330 as sensor information.
Further, for example, a humidity sensor may be fitted into the bolt body B. In this case, information indicating the humidity detected by the humidity sensor is transmitted to the control unit 330 as sensor information. Based on the humidity inside the outer box 100a acquired as a sensor value, the inundation judging unit 432a sets the on-pole switch 100 when the difference between the humidity inside the outer box 100a and the outside humidity is equal to or larger than a threshold value. It may be determined that water is flooded, and if it is less than the threshold, it may be determined that the pole switch 100 is not flooded. This is because when the pole switch 100 is submerged, the change in humidity inside the outer box 100a is assumed to be smaller than the change in humidity outside the outer box 100a.
Here, the humidity outside the outer box 100a may be obtained from weather information provided by the Meteorological Agency, or a hygrometer may be installed in the control unit 330 and may be obtained from the installed thermometer. Further, a sensor 310 may be provided on the bolt 300a so that the humidity outside the outer box 100a can be measured. With this configuration, it is possible to obtain the humidity outside the outer box 100a from the weather information provided by the Meteorological Agency or to obtain the humidity outside the outer box 100a from the hygrometer installed in the control unit 330. In addition, the humidity outside the outer box 100a can be obtained. In this case, the sensor 310 outputs the humidity inside and outside the outer box 100a to the communication unit 340 as the sensor value. When acquiring from the hygrometer installed in the control unit 330, the control unit 330 may transmit information indicating the humidity outside the outer box 100a in the sensor value notification information.

According to the inundation detection system of the second embodiment, the inundation detection system includes a bolt 300 a having a sensor 310, a bolt body B, a control unit 330, and a communication unit 340. It fits into the gas inlet below 100a. The sensor value obtained by the sensor 310 detecting the state of water in the outer box 100a is output to the control unit 330 via the cable 320a. The control unit 330 acquires the sensor value output by the sensor 310 and creates sensor value notification information including the acquired sensor value and the control unit ID of the control unit 330. The control unit 330 outputs the created sensor value notification information to the communication unit 340 via the cable 320b. The communication unit 340 acquires the sensor value notification information output by the control unit 330, and transmits the acquired sensor value notification information to the management device 400a.
The management device 400a receives the sensor value notification information transmitted by the bolt 300a, and, based on the received sensor value notification information, a column inside the outer box 100a in which the bolt 300a having the sensor 310 that has transmitted the sensor value is fitted. It is determined whether the upper switch 100 is submerged.
Conventionally, a huge number of pole switches 100 are installed in the power distribution system, so ultrasonic inundation detection devices that require various functions are installed for each pole switch 100. However, it was difficult to remotely control whether or not the water was inundated.
In the present embodiment, with this configuration, it is possible to remotely detect inundation of the pole switch 100 without going to the installation location of the pole switch 100. In addition, by determining whether or not the on-column switch 100 inside the outer box 100a is submerged based on the sensor value detected by the sensor 310, compared with the case of using ultrasonic waves, It is possible to determine the presence or absence of flooding even without a skilled technician. In addition, since the trouble of determining whether or not the pole switch 100 is submerged is simplified, installation on each pole switch 100 can be facilitated.
Further, by providing the control unit 330 and the communication unit 340 in the bolt 300a, the trouble of installing the communication device 200 can be reduced as compared with the first embodiment.

<Example of configuration>
As one configuration example, a bolt that is externally inserted into a screw hole that penetrates a detection target space in a switch (in the embodiment, a pole switch 100) and detects a state of inundation in the detection target space. A sensor is provided, wherein the bolt has the sensor on a threaded portion of the bolt.
As one configuration example, the sensor detects humidity inside and outside the switch.
As one configuration example, the switch is a pole switch.
As one configuration example, the screw hole is an airtight plug.

  Although the embodiments have been described above, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. These embodiments can be implemented in other various forms, and various omissions, replacements, changes, and combinations can be made without departing from the spirit of the invention. These embodiments are included in the scope and gist of the invention, and are also included in the invention described in the claims and their equivalents.

Note that the management device 400 and the management device 400a described above may be realized by a computer. In that case, a program for realizing the function of each functional block is recorded on a computer-readable recording medium. The program recorded on this recording medium may be read by a computer system and executed by a CPU. Here, the “computer system” includes hardware such as an OS (Operating System) and peripheral devices.
The “computer-readable recording medium” refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, and a CD-ROM. The “computer-readable recording medium” includes a storage device such as a hard disk built in the computer system.

Further, the “computer-readable recording medium” may include a medium that dynamically stores a program for a short time. What dynamically holds the program for a short time is, for example, a communication line for transmitting the program through a network such as the Internet or a communication line such as a telephone line.
Further, the “computer-readable recording medium” may include a medium holding a program for a certain period of time, such as a volatile memory in a computer system serving as a server or a client. Further, the program may be for realizing a part of the functions described above. Further, the above-mentioned program may be one that can realize the above-described functions in combination with a program already recorded in the computer system. Further, the program may be realized using a programmable logic device. The programmable logic device is, for example, an FPGA (Field Programmable Gate Array).

The management device 400 and the management device 400a each have a computer inside. The process of each process of the management device 400 and the management device 400a described above is stored in a computer-readable recording medium in the form of a program, and the program is read and executed by the computer to execute the process. Is performed.
Here, the computer-readable recording medium refers to a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Alternatively, the computer program may be distributed to a computer via a communication line, and the computer that has received the distribution may execute the program.
Further, the program may be for realizing a part of the functions described above.
Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

Reference numeral 50: network, 100: pole switch, 100a: outer box (case), 102: utility pole, 104: arm, 106a: high-voltage distribution lines 106a, 106b: high-voltage distribution lines, 200, 200-1, 200-2 , 200-3 ... communication device, 300, 300-1, 300-2, 300-3, 300a, 300a-1, 300a-2, 300a-3 ... bolt, 310, 310-1, 310-2, 310- 3. Sensor, 320, 320a, 320b ... Cable, 330, 330-1, 330-2, 330-3 ... Control unit, 340, 340-1, 340-2, 340-3 ... Communication unit, 400, 400a ... Management devices 400, 410, 410a communication unit, 420, 420a storage unit, 421 program, 422, 422a application, 423, 423a table, 430 430a ... information processing unit, 440 ... display unit, 450 ... operating unit, 431 ... acquisition unit, 432,432A ... flooding determination unit, 433,433A ... output unit, 460 ... bus line

Claims (7)

A bolt that fits into a screw hole that penetrates into the detection target space inside the switch from the outside,
A sensor for detecting a state of inundation of the detection target space,
The bolt, wherein the bolt has the sensor in a threaded portion of the bolt. The bolt according to claim 1, further comprising: a communication unit configured to transmit information indicating a state of the flooding detected by the sensor to a management device that manages the inside of the switch.   The bolt according to claim 1, wherein the sensor detects humidity inside and outside the switch.   The bolt according to any one of claims 1 to 3, wherein the switch is a pole switch.   The bolt according to any one of claims 1 to 4, wherein the screw hole is an airtight plug. A sensor that detects a state of flooding of a detection target space in the switch from the outside, a bolt that fits into a screw hole penetrating the detection target space,
A communication device that transmits information indicating the state of flooding detected by the sensor to a management device that manages the inside of the switch,
Based on the information indicating the state of flooding transmitted by the communication device, a management device that determines whether the inside of the switch is flooded,
With
The inundation detection system, wherein the sensor is attached to a threaded portion of the bolt. A step of transmitting information indicating the state of flooding detected by a sensor provided by a bolt that fits into a screw hole penetrating into a detection target space in the switch from the outside to a management device that manages the inside of the switch,
Based on the information indicating the state of flooding transmitted in the transmitting step, a step of determining whether the inside of the switch is flooded,
Has,
The method for detecting inundation of the bolt, wherein the bolt has the sensor at a screw tip of the bolt.

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