KR102408033B1 - Distribution Line Monitoring System - Google Patents

Abstract

The present invention provides an integrated monitoring system for underground distribution lines using artificial intelligence, comprising: an integrated monitoring system for underground distribution lines using artificial intelligence; and a situation management unit for managing an integrated underground distribution line monitoring system using artificial intelligence, wherein the situation management unit is installed at a preparation site for an underground distribution line integrated monitoring system using the artificial intelligence and underground distribution line using the artificial intelligence It manages the situation in which the parts of the integrated monitoring system are prepared or is pre-combined, or is installed at the construction site where the integrated underground distribution line monitoring system using the artificial intelligence is constructed. Manages the installation status, and the integrated monitoring system for underground distribution lines using the artificial intelligence includes: a plurality of distribution units disposed in each complex of a common house, and having distribution lines; a plurality of grounding units detachably installed on the distribution lines of each of the plurality of distribution units and grounding the distribution lines underground; and a grounding monitoring unit configured to monitor the grounding state in real time by detecting whether the plurality of grounding units are disconnected from the distribution line. provides an integrated monitoring system for underground distribution lines using artificial intelligence.

Description

Integrated monitoring system for underground distribution lines using artificial intelligence {Distribution Line Monitoring System}

The present invention relates to a method for providing an integrated monitoring system for an underground distribution line using artificial intelligence in the field of distribution technology, and more particularly, monitoring the grounding state in the distribution line of each terminal of an apartment house in real time, and in the distribution line It relates to an integrated monitoring system for underground distribution lines using artificial intelligence that can improve the grounding efficiency by increasing the contact area of the grounding underground.

In addition, the present invention relates to an integrated monitoring system for an underground distribution line using artificial intelligence that can monitor the grounding state of each terminal in an apartment house distribution line in real time and improve grounding efficiency by increasing the underground contact area of each distribution line grounding. .

In general, electric power is transmitted from a power plant to a substation, undergoes several stages of transformation, and then is delivered to a home through a pole transformer on an electric pole along a distribution path such as a concrete pole.

At this time, in the distribution line installed on the electric pole, it is necessary to secure the material in the distribution line and to have good grounding in order to protect the equipment by abnormal voltage such as lightning and surge and to prevent various electric disasters due to short circuit.

The grounding has a function of protecting people and power equipment from electric power or lightning. In particular, a distribution unit such as a distribution box is installed in each complex of the apartment house, and a distribution line is also installed.

Conventionally, since it was not possible to monitor the grounding state in each of the distribution units of each complex in real time, when a grounding defect occurs in the distribution unit of any one complex, there is a problem in that an electric shock accident of an operator occurs.

Republic of Korea Patent Publication No. 10-2021-0148666 (2021. 12. 08.) 'A device and method for controlling connection between distribution lines'

An object of the present invention is to monitor the grounding state in the distribution line of each terminal of the apartment house in real time, and to increase the contact area of the grounding in the distribution line underground using artificial intelligence to improve the grounding efficiency. It is to provide an integrated monitoring system for distribution lines.

In addition, in implementing an integrated monitoring system for underground distribution lines using artificial intelligence, it manages the process of handling, assembling, installation, and preparation of work and system components for each situation, and taking corrective actions and actions in real time to ensure safety and reliability. It is to provide an integrated monitoring system for underground distribution lines using artificial intelligence to which a monitoring system can be applied.

In addition, we provide an integrated monitoring system for underground distribution lines using artificial intelligence that provides data for real-time management of the operation of the integrated monitoring system for underground distribution lines using artificial intelligence, taking corrective actions, and verification of subsequent problems. will do

In addition, it is to provide an integrated monitoring system for underground distribution lines using artificial intelligence that increases the operational lifespan related to monitoring by systematically and stably managing the means for performing photography in response to various conditions and environments due to the structural characteristics of the monitoring system.

In addition, it is to provide an integrated monitoring system for underground distribution lines using artificial intelligence that can prevent the monitoring from being restricted by protecting the core components of the monitoring system from external pollution and external shocks.

In addition, it is to provide an integrated monitoring system for underground distribution lines using artificial intelligence that can selectively, quickly and easily perform external exposure and blocking from the outside for ventilation to the outside, control of temperature conditions, and release of foreign substances.

The present invention provides an integrated monitoring system for underground distribution lines using artificial intelligence, comprising: an integrated monitoring system for underground distribution lines; and a situation management unit for managing the integrated underground distribution line monitoring system, wherein the condition management unit is installed at the underground distribution line integrated monitoring system preparation site to prepare the situation or pre-combination of the components of the underground distribution line integrated monitoring system , or is installed at the construction site where the underground distribution line integrated monitoring system is constructed to manage the installation situation of the underground distribution line integrated monitoring system, and the underground distribution line integrated monitoring system is, each complex of the apartment house It is disposed in, a plurality of distribution units having a distribution line; a plurality of grounding units detachably installed on the distribution lines of each of the plurality of distribution units and grounding the distribution lines underground; and a grounding monitoring unit for real-time monitoring of an underground distribution line integrated monitoring system including a grounding monitoring unit for monitoring the grounding state in real time by detecting the presence or absence of a disconnection with the distribution line in the plurality of grounding units. Provides an integrated monitoring system for underground distribution lines.

According to the present invention as described above, there are one or more of the following effects.

The present invention provides an integrated monitoring system for an underground distribution line using artificial intelligence that can improve the grounding efficiency by increasing the underground contact area of the distribution line grounding while monitoring the grounding state in the underground distribution line of each terminal of the apartment house in real time is to provide

In addition, in implementing an integrated monitoring system for underground distribution lines using artificial intelligence, it manages the process of handling, assembling, installation, and preparation of work and system components for each situation, and taking corrective actions and actions in real time to ensure safety and reliability. It is to provide an integrated monitoring system for underground distribution lines using artificial intelligence to which a monitoring system can be applied.

In addition, we provide an integrated monitoring system for underground distribution lines using artificial intelligence that provides data for real-time management of the operation of the integrated monitoring system for underground distribution lines using artificial intelligence, taking corrective actions, and verification of subsequent problems. will do

In addition, it is to provide an integrated monitoring system for underground distribution lines using artificial intelligence that increases the operational lifespan related to monitoring by systematically and stably managing the means for performing photography in response to various conditions and environments due to the structural characteristics of the monitoring system.

In addition, it is to provide an integrated monitoring system for underground distribution lines using artificial intelligence that can prevent the monitoring from being restricted by protecting the core components of the monitoring system from external pollution and external shocks.

In addition, it is to provide an integrated monitoring system for underground distribution lines using artificial intelligence that can selectively, quickly and easily perform external exposure and blocking from the outside for ventilation to the outside, control of temperature conditions, and release of foreign substances.

1 is an overall conceptual diagram showing an integrated monitoring system for an underground distribution line using artificial intelligence of the present invention installed in a plurality of distribution units.
2 is a view showing an integrated monitoring system for underground distribution lines using artificial intelligence according to the present invention.
3 is a view showing a state in which the grounding member is separated.
4 to 5 are views showing the structure of the grounding member according to the present invention.
6 to 12 are views illustrating a configuration according to FIG. 1 .

Hereinafter, an integrated monitoring system for underground distribution lines using artificial intelligence of the present invention will be described with reference to the accompanying drawings.

1 is an overall conceptual diagram showing an underground distribution line integrated monitoring system using artificial intelligence of the present invention installed in a plurality of distribution units, and FIG. 2 is a diagram showing an underground distribution line integrated monitoring system using artificial intelligence according to the present invention. , FIG. 3 is a view showing a state in which the grounding member is separated, and FIG. 4 is a view showing the structure of the grounding member according to the present invention.

1 to 4, the earth distribution line grounding structure of the present invention is disposed in each complex of the apartment complex, and a plurality of distribution units 100 having distribution lines; a plurality of grounding units 200 that are detachably installed on the distribution line 110 of each of the plurality of distribution units 100 and ground the distribution line 110 to an underground (1); and a grounding monitoring unit 300 that detects whether the plurality of grounding units 200 are disconnected from the distribution line 110 and monitors the grounding state in real time.

Each of the plurality of grounding parts 200 includes a grounding member 210 electrically connected to the distribution line 110, and is fixedly installed in the underground 1, and the grounding member 210 is detachably connected. , a grounding device 220 for grounding the distribution line through the grounding member 210, and a connection detecting means 230 for detecting a connection state between the grounding device 220 and the grounding member 210. .

The grounding member 210 is formed as a pair.

The pair of grounding members 210 are coupled to each other in contact with each other. The coupling is made through a bolt (not shown).

A connection terminal is formed on each of the pair of ground members 210 , and an end of the distribution line 110 is connected to the connection terminal.

Accordingly, when the pair of grounding members 210 are coupled to face each other, each connection terminal is connected.

The grounding device 220 includes a disk-shaped grounding body 221 and a plurality of embedding members 222 extending from the lower end of the edge of the grounding body 221 and fixedly embedded in the underground 1, A connection end 223 formed on the upper end of the grounding body 221 and screw-fastened to the lower end of the grounding member 210, is installed inside the grounding body 221, is formed of metal, and has one end An internal grounding member 224 that is in physical contact with the lower end of the grounding member 210 that is screw-fastened, and the other end protrudes through the lower ends of the plurality of embedding members 222 and is embedded in the underground 1 . can

The connection detection means 230 is installed between the lower end of the grounding member 210 and the upper end of the inner grounding member 224, and the lower end of the grounding member 210 and the inner grounding member ( 224) may include a pressure sensor for measuring the pressure between the upper ends.

The lower end of the internal grounding member 224 includes a cone body 224a formed in a cone shape to be pointed downward, and protruding from the outer periphery of the cone body 224a to be embedded in the upper extremity ground (1). A plurality of unit ground terminals 224b are formed.

5, the lower end of the inner grounding member 224 according to the present invention is rotated by driving the motor 500, and the lower end of the inner grounding member 224 is a cone-shaped cone that is rotated. A body 224a is formed.

A screw protrusion 224c is formed on the outer periphery of the cone body 224a.

When the internal grounding member 224 is rotated by the motor 500 , it is screw-coupled to the underground 1 .

Accordingly, the grounding device 220 itself not only improves the fixing force in the ground, but also the cone body is screwed into the ground, thereby increasing the fixing force forming area and the grounding area.

The motor 500 is driven by a control signal from a controller 320 to be described later. The motor 500 is installed at the lower end of the internal grounding member 224, a motor shaft (not shown) of the motor 500 is disposed to face downward, and the center of the cone body 224a is located on the motor shaft. this is connected

When the motor 500 is driven, the motor shaft is rotated, and the cone body 224a connected to the rotating motor shaft is rotated.

The grounding monitoring unit 300 includes an on/off switch 310 for connecting and blocking the distribution line 110 of each of the plurality of grounding units 200 and the pressure measured at each of the plurality of grounding units 200 . The controller 320 is configured to determine that the grounding is faulty when the transmission is received and the preset pressure is less than or equal to the reference pressure.

The controller 320 cuts off the distribution line by using the on/off switch 310 installed in the corresponding grounding unit 200 among the plurality of grounding units 200 determined to be grounded poorly.

The grounding member 210 is formed of a circular rod-shaped metal, and on the outer surface of the grounding member 210, a plurality of connection ends 210a protruding in all directions and connected to other distribution lines 110 are formed. .

Through the above configuration, the present invention can monitor the grounding state in the distribution line of each terminal of the apartment house in real time and improve the grounding efficiency by increasing the contact area of the grounding in the distribution line underground.

In addition, the present invention can effectively prevent an electric shock accident of an administrator in a grounding condition in advance by immediately blocking the distribution line in the distribution part of the complex in which the grounding failure occurs. In addition, according to the present invention, by providing a separate connection end to one grounding member, branching from one distribution line into a plurality of strands and connecting to the connecting end, it is possible to reduce the possibility of grounding failure.

6 to 12 , there is provided a method for providing an integrated monitoring system for an underground distribution line using artificial intelligence, the method comprising: preparing an integrated monitoring system for an underground distribution line using artificial intelligence at a preparation site; Including the step of installing the underground distribution line integrated monitoring system using the artificial intelligence at the construction site, the underground distribution line integrated monitoring system using the artificial intelligence is managed by a situation management unit, the situation management unit, the preparation site It is installed on the site to manage the situation in which parts of the integrated monitoring system for underground distribution lines using artificial intelligence are prepared or pre-combined, or installed at the construction site to install the integrated monitoring system for underground distribution lines using the artificial intelligence. manage

Here, the integrated monitoring system for underground distribution lines using artificial intelligence includes: a plurality of distribution units disposed in each complex of a multi-family house, and having distribution lines; a plurality of grounding units detachably installed on the distribution lines of each of the plurality of distribution units and grounding the distribution lines underground; and a ground monitoring unit configured to detect whether the plurality of ground units are disconnected from the distribution line and monitor the ground state in real time.

Here, the situation management unit includes a first buried body 111 ′ embedded in the ground S′, and a second buried body 111 ′ that is adjacent to the first buried body 111 ′ and is embedded in the ground S′ (S′). 112'), and a third buried body 113' that is adjacent to the second buried body 112' and is buried in the ground (S'), and the third buried body 113' and adjacent to the ground (S) '), the fourth buried body 114', and the first mounting body (161, 162') mounted between the first buried body 111' and the second buried body 112', and the first Second mounting body (171, 172') mounted between the second buried body (112') and the third buried body (113'), the third buried body (113') and the fourth buried body (114') A third mounting body (181, 182') mounted therebetween, the first mounting body (161, 162') to the support panel part 121' installed above the third mounting body (181, 182'), and the support The rotation module 122' installed on the panel unit 121' and rotated in the horizontal direction, the first upper photographing body 124' installed on one side of the circumference of the rotation module 122', and the rotation module (122') includes a first photographing module (123,124') including a first lower photographing body 123' installed lower than the first upper photographing body 124' on one side of the periphery.

In addition, the situation management unit includes a second upper photographing body 126' installed on the other side of the circumference of the rotation module 122', and a second upper photographing body 126 on the other side of the circumference of the rotation module 122'. ') and a second photographing module (125, 126') including a second lower photographing body 125' installed lower. Here, the first photographing modules 123 and 124' to the second photographing modules 125 and 126' photograph the periphery through the rotation of the rotation module 122', but the peripheral portion is rotated continuously or the peripheral portion is limited to a setting range. Shooting is performed through rotation.

Meanwhile, the situation management unit further includes upper plate modules 141 and 142' installed to face the support panel part 121' via the rotation module 122', and the upper plate modules 141 and 142', The first photographing module (131,132') protruding and retracting toward the space side in which the first photographing module (123,124') is located so as to face the first photographing module (123,124') from the inside, and the second photographing module ( 125, 126 '), the second photographing modules (125, 126') are provided with the second protruding and retracting modules (133, 134') toward the space side is located.

Here, the first haunting modules 131 and 132' clean the shooting side for removing foreign matter, decontamination, moisture, and defrosting on the shooting side of the first shooting modules 123 and 124' through the haunting, and the second haunting module Reference numerals 133 and 134' clean the photographing side for removing foreign matter, decontamination, moisture, and defrosting on the photographing side of the second photographing modules 125 and 126' through the appearance and dislocation.

On the other hand, the first descending modules 131 and 132' are descended together with the first descending body 131' and the first descending body 131' that descend from the upper plate modules 141 and 142', and the first and a first cleaning body 132' which contacts the first photographing modules 123 and 124' from the descending body 131' and performs cleaning in at least one of a rotation method and a cleaning liquid spraying method.

The second protruding modules 133 and 134' include a second lowering body 133' that descends downward from the upper plate modules 141 and 142', and the second photographing modules 125 and 126 at the second lowering body 133'. ') and a second cleaning body 134' that performs cleaning by at least one of a rotation method and a cleaning liquid spraying method.

In addition, the upper panel module (141, 142') is provided with a central panel part 141' in contact with the gray point module, and one side of the central panel part 141', and the first protruding and descending modules 131 and 132' are protruded and protruded from the lower part. It includes a first driving panel unit 142 ′ that is formed, and a second driving panel unit 143 ′ provided on the other side of the central panel unit 141 ′ and in which the second protruding and protruding modules 133 and 134 ′ are protruded and protruded downward. do.

The first driving panel unit 142' is provided with a first shutter panel 151' that blocks the first space in which the first photographing modules 123 and 124' are located from the outside to be stored, and the second The driving panel unit 143' is provided with a second shutter panel 152' that blocks the second space in which the second photographing modules 125 and 126' are located from the outside and is stored.

The first driving panel unit 142' and the second driving panel unit 143' can operate in a tilt mode on both sides of the central panel unit 141', respectively, so that the first photographing modules 123 and 124' and the second photographing module (125, 126') to make it a protective state, or by exposing the first photographing module (123,124') and the second photographing module (125, 126') to external ventilation, temperature control, and humidity control make it possible

The first mounting body (161, 162'), the first embedded body (111') and the second embedded body (112') is provided in a first inserted state inserted into the first insert (162') and, It interlocks with the first insert 162 ′ and includes a first support driver 161 ′ installed on the support panel 121 ′. The second mounting body (171, 172'), the second embedded body (112') and the third embedded body (113') provided in a second inserted state to be inserted into the second insert (172') and, It interlocks with the second insert 172' and includes a second support actuator 171' installed on the support panel part 121'.

At this time, the third mounting body (181, 182') is provided in a third inserted state to be inserted into the third buried body (113') and the fourth buried body (114') with a third insert (182') and , and a third support actuator 181 ′ interlocked with the third insert 182 ′ and installed on the support panel 121 ′. The first support actuator 161' rotates the first insert body 162' in a motor rotation manner in the first inserted state, and the second support actuator 171' is the second insert In the state, the second insert 172' is rotated by a motor rotation method, and the third support actuator 181' rotates the third insert body 182' in the third inserted state by a motor rotation method. rotate the shaft with

In addition, the first embedded body 111 ′ is provided with a first main entry body 181 ′ that is inserted and mounted into the first insert 162 ′ in the first inserted state, and the second embedded body 112 . ') is provided with first sub-entry bodies 191, 192, 193, and 194' that are inserted and mounted into the first insert body 162' in the first inserted state. The second embedded body 112' is provided with a second main entry body 201' that is inserted and mounted into the second insertion body 172' in the second inserted state, and the second embedded body 112' ) is provided with a second sub-entry body (211, 212, 213, 214') inserted and mounted into the second insert body 172' in the second inserted state.

Here, the third embedded body 113 ′ is provided with a third main entry body 221 ′ that is inserted and mounted into the third insert 182 ′ in the third inserted state, and the third embedded body 113 . ') is provided with third sub-entry bodies 231,232, 233' that are inserted and mounted into the third insert body 182' in the third inserted state, and the first main entry body 181' has a plurality of upper and lower parts. A plurality of the first sub-entry bodies 191, 192, 193, and 194' are provided at the top and bottom to alternately accommodate the first main entry bodies 181' therein.

The second main entry body 201' is provided in plurality between the upper and lower sides, and the second sub entry bodies 211, 212, 213 and 214' are provided in plurality between the top and bottom to alternately accommodate the second main entry body 201' therein. The third main entry body 221 ′ is provided in plurality between the upper and lower sides, and the third sub entry bodies 231,232 and 233 ′ alternately accommodate the third main entry body 221 ′ therein. It is provided in plurality between the upper and lower parts to do so.

The first main entry body 181' and the first sub entry body 191, 192, 193, 194' are operated in a first operation mode in which a fixing force is applied to the first insert body 162' through interlocking and fixing with each other, The second main entry body 201' and the second sub entry body 211, 212, 213, 214' are operated in a second operation mode in which a fixing force is applied to the second insertion body 172' through interlocking and fixing with each other, The third main entry body 221 ′ and the second sub entry body 211 , 212 , 213 , and 214 ′ operate in a third operation mode in which a fixing force is applied to the third insertion body 182 ′ through interlocking and fixing with each other.

In addition, the lower lower body part 310 in which the first buried body 111', the second buried body 112', the third buried body 113' and the fourth buried body 114' are installed. '), and the first buried body 111' to the fourth buried body 114' that are in the first operation mode to the fourth buried mode state on the lower body part inside the set range, respectively. It is operated in the strengthening mode in which the fixing force is strengthened by the first to the fourth operation mode by descending to the .

The first sub-entry body 191 , 192 , 193 , 194 ′ includes first-first region portions 1911 , 1921 , 1931 , 1941 ′ positioned on the second embedded body 112 ′, and the second embedded body 112 ′. ) and includes first and second area portions 1912, 1922, 1932, and 1942' to which the first main entry body 181' enters and faces. The second sub-entry body 211 , 212 , 213 , 214 ′ includes a 2-1 region portion 2111,2121 , 2131,2141 ′ positioned on the third embedded body 113 ′, and the third embedded body 113 ′. ) and includes second-second region portions 2112, 2122, 2132, and 2142' that the second main entry body 201' enters and faces.

In addition, the third sub-entry body (231,232,233') includes a 3-1 region part (2311,2321,2331,2341') positioned on the fourth embedded body 114', and the fourth embedded body 114. ') and includes third-second area portions 2312,2322, 2332,2342' which the third main entry body 221' enters and faces.

The 1-2-region parts 1912, 1922, 1932, 1942', the 2-2 region parts 2112, 2122, 2132, 2142', and the 3-2 region parts 2312,2322, 2332, 2342') is provided as a standard of a preset horizontal length. The 1-2-region parts 1912, 1922, 1932, 1942', the 2-2 region parts 2112, 2122, 2132, 2142', and the 3-2 region parts 2312,2322, 2332, 2342') detects whether the first main entry body 181' enters a range set within the standard of the horizontal length and transmits status information to the outside, the first operation mode to the third operation mode; The reinforcement mode includes the 1-2 first region parts 1912, 1922, 1932, 1942', the 2-2 region parts 2112, 2122, 2132, 2142', and the 3-2 region part 2312 ,2322,2332,2342') can be operated only when the status information satisfies a preset criterion.

A first body panel 411 ′ provided on one side of the lower body part 310 ′, and a first extension body panel 412 ′ provided to be vertically movable upwards of the first body panel 411 ′, and , a first temperature variable portion 413 ′ provided inside the first body panel 411 ′ for spraying a fluid for temperature control, and a second body panel provided on one side of the lower body portion 310 ′ (511'), a second extended body panel 512' provided to be movable up and down to the upper part of the second body panel 511', and provided inside the second body panel 511' It further includes a second temperature variable unit 513' for spraying a fluid for adjustment.

Meanwhile, a cover panel 611 ′ is provided between the first extension body panel 412 ′ and the second extension body panel 512 ′ to receive the upper plate modules 141 and 142 ′ to the lower portion, and the second extension body panel 512 ′ is provided. The first extended body panel 412 ′ and the second extended body panel 512 ′ are formed during the fluid injection of the first temperature variable unit 413 ′ and the second temperature variable unit 513 ′. The first temperature variable part 413' and the second temperature variable part 513' move up and down to adjust the volume of the space where the fluid is sprayed.

The cover panel 611 ′ is provided with a plurality of sub-fluid injection modules 612 and 613 ′ capable of relocating and relocating at the lower portion to secondarily control the temperature of the situation management unit, and the first extension body panel 412 ′ and the second extension body panel 512' rotates shaft so that the sub-fluid injection modules 612 and 613' can periodically spray the upper fluid based on the shaft rotation.

In addition, the first extension body panel 412' has a first upper movable body 415', and a first lower part positioned below with the first upper movable body 415' and the cover panel 611' interposed therebetween. A movable body 414' is provided, and the first upper movable body 415' and the first lower movable body 414' move toward the cover panel 611' and press and fix, or the first upper movable body (414') 415') and the first lower movable body 414' are moved away from the cover panel 611' to release the pressure fixing.

Here, the second extended body panel 512' has a second upper movable body 515', and a second lower part positioned below with the second upper movable body 515' and the cover panel 611' interposed therebetween. A movable body 514' is provided, and the second upper movable body 515' and the second lower movable body 514' move toward the cover panel 611' and press and fix, or the second upper movable body (514') 515') and the second lower movable body 514' move away from the cover panel 611' to release the press fixation. It is sufficient if the above-described situation management unit is installed in the vicinity of the target part for shooting based on various known methods such as welding burial, embedding, bolt screw, insertion, etc. on the ground or an equivalent base.

The driving method of the physical components described above is based on a motor, an actuator, etc., and the forward and backward movement and rotational movement are made, and the shape and size of each component can be variously selected and provided according to the installation site and materials to be implemented. . Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: distribution unit
200: ground part
300: ground monitoring unit

Claims (2)

In the underground distribution line integrated monitoring system using artificial intelligence,
underground distribution line integrated monitoring system; and
It includes a situation management unit that manages an integrated monitoring system for underground distribution lines.
The situation management unit,
Installed at the underground distribution line integrated monitoring system preparation site to manage the situation in which the parts of the underground distribution line integrated monitoring system are prepared or pre-combined, or installed at the construction site where the underground distribution line integrated monitoring system is constructed Manages the installation status of the underground distribution line integrated monitoring system,
The situation management unit
A first buried body 111' buried in the ground (S'), a second buried body 112' that is adjacent to the first buried body 111' and is buried in the ground (S'), and the first 2, adjacent to the buried body 112', and a third buried body 113' buried in the ground (S'), and a fourth adjacent to the third buried body 113' and buried in the ground (S') The buried body 114 ′, the first mounting bodies 161 and 162 ′ mounted between the first buried body 111 ′ and the second buried body 112 ′, and the second buried body 112 ′). and second mounting bodies 171 and 172' mounted between the third buried body 113', and a third mounting mounted between the third buried body 113' and the fourth buried body 114'. On the body (181,182'), the first mounting body (161,162') to the third mounting body (181,182'), the support panel part 121' installed on the upper part, and the support panel part 121' A rotation module 122' installed and rotated in the horizontal direction, a first upper photographing body 124' installed on one side of the circumference of the rotation module 122', and one side of the circumference of the rotation module 122' and a first photographing module (123, 124') including a first lower photographing body 123' that is installed lower than the first upper photographing body 124',
The situation management unit,
A second upper photographing body 126' installed on the other side of the circumference of the rotation module 122', and a second installed lower than the second upper photographing body 126' on the other side of the circumference of the rotation module 122' and second photographing modules 125 and 126' including a lower photographing body 125'. Here, the first photographing modules 123 and 124' to the second photographing modules 125 and 126' take pictures of the periphery through the rotation of the rotation module 122', but the peripheral portion is rotated continuously or the perimeter is limited to a setting range Shooting is performed through rotation,
The situation management unit,
It further includes upper plate modules 141 and 142' installed to face the support panel part 121' via the rotation module 122', wherein the upper plate modules 141 and 142' include the first photographing module from the inside. (123, 124') to face the first photographing module (123, 124') is located toward the space side, the first appearing module (131, 132'), and the second photographing module (125, 126') from the inside to face the Second appearing modules (133, 134') that protrude toward the side of the space where the second photographing modules (125, 126') are located are provided,
The first haunting module (131,132') cleans the shooting side for removal of foreign matter, decontamination, moisture removal, and defrosting on the shooting side of the first shooting module (123,124') through haunting
The second appearance module (133,134') cleans the photographing side for removing foreign matter, decontamination, moisture removal, and defrosting on the photographing side of the second photographing module (125,126') through the appearance and removal,
The first protruding modules 131 and 132' include a first lowering body 131' that descends downward from the upper plate modules 141 and 142';
It descends together with the first descending body 131 ′, and the first descending body 131 ′ comes into contact with the first photographing modules 123 and 124 ′ to perform cleaning in at least one of a rotation method and a cleaning solution spraying method. An integrated monitoring system for underground distribution lines using artificial intelligence, including a first cleaning body 132'.

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