KR102404289B1 - Providing method for a distribution line monitoring system - Google Patents

Abstract

The present invention provides a method of providing a distribution line fault section monitoring system connected to a transformer using artificial intelligence, the method comprising: selecting a distribution line installation location; and performing, by a management facility disposed in a field surrounding the distribution line, monitoring and management of a target on the distribution line or the surrounding field, using the artificial intelligence to provide a system for monitoring a failure section of a distribution line connected to a transformer. , It includes a distribution line voltage real-time monitoring system consisting of a voltage status indicator lamp 700, and further includes a control unit 1000 for smoothly attaching and detaching the jump line 50 to the jump line holder 200, and , The adjusting unit 1000 includes a folding member 1010 rotatably connecting one side of the upper holder 210 to the lower holder 220; binding means (1020) for binding the other side of the upper holder (210) to the lower holder (220); and a support means (1030) for supporting the upper holder (210) while stopping the rotation of the upper holder (210), which is rotated in a direction oriented with the lower holder (220) around the folding member (1010). It provides a method of providing a system for monitoring a failure section of a distribution line connected to a transformer using artificial intelligence, including a.

Description

A method for monitoring a failure section of a distribution line connected to a transformer using artificial intelligence {Providing method for a distribution line monitoring system}

The present invention relates to a method for providing a system for monitoring a failure section of a distribution line connected to a transformer using artificial intelligence, and more particularly, to enable appropriate measures to be taken according to voltage measurement, while also enabling smooth detachment of the jump wire to the jump wire holder It relates to a method of providing a system for monitoring a failure section of a distribution line connected to a transformer using artificial intelligence for managing and monitoring around the system and at least some of the system components.

In the distribution line for distributing commercial electricity of commercial voltage, the voltage rises or falls according to the increase or decrease of the receiving load, which affects the consumer's use of electronic and electrical equipment.

Therefore, the voltage of the distribution line is monitored to maintain the voltage of the distribution line as a normal voltage.

Since the conventional distribution line voltage monitoring system is not easy to open and close the jump line holder composed of the upper and lower holders, there is a problem in that it is difficult to smoothly detach the jump line from the jump line holder.

In addition, there is a disadvantage that it is not easy to effectively manage correlations around the system as well as the system.

Republic of Korea Patent Registration No. 10-1602369 (2016. 03. 04.) 'Distribution line voltage monitoring system'

The present invention enables the voltmeter connected to the jump line to measure the voltage in real time, so that an appropriate response can be made according to the voltage measurement, and on the other hand, a distribution line voltage real-time monitoring system for smoothly attaching and detaching the jump line to the jump line holder. will provide

In addition, based on the management means, through monitoring and verification, it is possible to more clearly identify the responsibility for the occurrence of abnormalities, various disputes, and other problems.

In addition, based on the management means, the quality of the installation is improved through monitoring and verification, and through stable management in all subsequent processes, immediate maintenance and management are possible, thereby preventing further abnormalities and deterioration due to damage. .

In addition, based on the management means, these means for monitoring and verification are installed and provided in various structures and structural environments so that monitoring and verification can be operated more effectively and in a variety of ways.

The present invention provides a method of providing a distribution line fault section monitoring system connected to a transformer using artificial intelligence, the method comprising: selecting a distribution line installation location; and performing, by a management facility disposed in a field surrounding the distribution line, monitoring and management of a target on the distribution line or the surrounding field, using the artificial intelligence to provide a system for monitoring a failure section of a distribution line connected to a transformer. , It includes a distribution line voltage real-time monitoring system consisting of a voltage status indicator lamp 700, and further includes a control unit 1000 for smoothly attaching and detaching the jump line 50 to the jump line holder 200, and , The adjusting unit 1000 includes a folding member 1010 rotatably connecting one side of the upper holder 210 to the lower holder 220; binding means (1020) for binding the other side of the upper holder (210) to the lower holder (220); and a support means (1030) for supporting the upper holder (210) while stopping the rotation of the upper holder (210), which is rotated in a direction oriented with the lower holder (220) around the folding member (1010). It provides a method of providing a system for monitoring a failure section of a distribution line connected to a transformer using artificial intelligence, including a.

There are one or more of the following effects according to the present invention as described above.

The present invention enables the voltmeter connected to the jump line to measure the voltage in real time, so that an appropriate response can be made according to the voltage measurement, and on the other hand, a distribution line voltage real-time monitoring system for smoothly attaching and detaching the jump line to the jump line holder. can provide

In addition, through monitoring and verification based on management means, it is possible to make it clearer whether or not to take responsibility for the occurrence of abnormalities, various disputes, and other problems.

In addition, based on the management means, the quality of the installation is improved through monitoring and verification, and through stable management in all subsequent processes, immediate maintenance and management are possible, thereby preventing further abnormalities and deterioration due to damage. have.

In addition, based on the management means, these monitoring and verification means can be installed and provided in various structures and structural environments so that monitoring and verification can be operated more effectively and in a variety of ways.

1 is a perspective view showing a distribution line voltage real-time monitoring system according to the present invention.
2 is an exploded perspective view showing a distribution line voltage real-time monitoring system according to the present invention.
3 is a front view showing a distribution line voltage real-time monitoring system according to the present invention.
4 is an enlarged cross-sectional view taken along line IV-IV of FIG. 3 .
5 is a block diagram showing the control means in the distribution line voltage real-time monitoring system according to the present invention.
6 to 7 are diagrams showing related configurations in the distribution line voltage real-time monitoring system according to the present invention.
8 to 12 are schematic diagrams illustrating the configurations according to FIG. 1 .

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 to 5 , the distribution line voltage real-time monitoring system (hereinafter referred to as “sensing system”) according to the present invention is provided on both sides of the distribution line 30 on the full iron 20 that is fixedly installed on both sides of the electric pole 10 . is supported in an insulated state through a suspension insulator 40 and applied to an overhead distribution line having a structure in which both sides of the distribution lines 30 are connected with a jump line 50 is shown. The arm iron 20 is shown in the drawing as being fixedly installed on the electric pole 10 by means of an arm iron band and bolts/nuts, but reference numerals for this are omitted.

The detection system is formed of an insulating material and a support 100 installed between the upper surfaces of a pair of armrests 20 that are fixedly installed on the electric pole 10 and wraps around the upper half of the central outer peripheral surface of the jump line 50 and is opened downward. An upper holder 210 having a space portion 211 and an upper tightening portion 212 for tightening the upper half of the outer peripheral surface of the jump line 50 at both ends, and a space portion that wraps around the lower half of the central outer peripheral surface of the jump line 50 and opens upward ( 221) and a jump line holder 200 including a lower holder 220 having a lower tightening portion 222 for tightening the lower half of the outer circumferential surface of the jump line 50 at both ends, the space portion 211 of the upper holder 210 In the inner circumferential surface The pressing piece 300 that protrudes and presses the upper half of the outer circumferential surface of the jump line 50, the lower half of the conductor 51 of the jump line 50 protrudes from the inner circumferential surface of the space 221 of the lower holder 220 and is spaced apart from the left and right A contact 400 electrically connected to the support 100, the electric case 500 installed under the support 100, a voltmeter installed in the electric case 500 and connected to the contact 400 by a lead wire 610 ( 600), a voltage status indicator lamp 700 installed on the upper surface of the upper holder 210, a tension adjusting means 800 for adjusting the tension of the distribution line 30, the voltmeter 600 and a voltage status indicator lamp ( 700) and a control means 900 for controlling the tension adjusting means 800.

The support 100 may be fixedly installed to the arm 20 by a bolt penetrating the support 100 and the arm 20 and a nut fastened thereto in a state that spans the upper surface of the arm 20 . The upper holder 210 and the lower holder 220 constituting the jump line holder 200 may be formed of a synthetic resin of an insulating material typically used for manufacturing insulators.

Flanges 213 and 223 are formed on the edges of the upper holder 210 and the lower holder 220, and are coupled by a bolt passing through the flanges 213 and 223 and a nut fastened thereto, and the fasteners 212 and 222 are jump lines. (50) can be configured to tighten the outer peripheral surface.

The lower surface of the tightening part 212 of the upper holder 210 is formed as a circular arc surface corresponding to the upper half of the outer peripheral surface of the jump line 50, and the lower surface of the tightening part 222 of the lower holder 220 is a jump line 50. It can be formed as a circular arc surface corresponding to the lower half of the outer peripheral surface.

The inner diameter of the arc surface of the tightening parts 212 and 222 is formed smaller than the outer diameter of the jump line 50, so that when the upper holder 210 and the lower holder 220 are tightened with a bolt and a nut, the tightening parts 212 and 222 are the jump line 50 ) It is preferable to configure the insulating coating 52 to be tightened.

Also, a gasket (not shown) for maintaining airtightness may be inserted between the flange portions 213 and 223 of the upper holder 210 and the lower holder 220 .

The press piece 300 is embedded in the upper holder 210 in the process of forming the upper holder 210 and is configured to protrude downward, and the contact 400 is the lower end in the process of forming the lower holder 220 . It can be configured to protrude upward while being buried in the lower holder 220 . The pressing piece 300 may be formed of a rubber material having good elasticity and electrical insulation.

The lower end of the pressing piece 300 is formed as an arc-shaped pressing surface 310 corresponding to the upper half of the outer peripheral surface of the jump line 50 , and the upper end of the contact 400 is an arc-shaped corresponding to the lower half of the outer peripheral surface of the jumping line 50 . In the process of combining the upper holder 210 and the lower holder 220 with the jump wire 50 interposed therebetween by forming the contact blade part 410, the arc-shaped contact blade part 410 is the insulating coating of the jump wire 50 ( 52) and may be configured to contact the conductor 51.

The electric case 500 is formed in a box shape with an open upper surface by a synthetic resin having electrical insulation, and a flange part 510 is formed at the upper edge of the bolt passing through the support 100 and the flange part 510 . And it can be coupled to the lower surface of the support 100 by a nut fastened thereto. The voltmeter 600 may use a voltmeter for measuring a typical voltage. The voltage status display lamp 700 may include an LED lamp 710 and a transparent cap 720 coupled to the upper end of the upper holder 210 to protect the LED lamp 710 .

The transparent cap 720 is inserted into the lamp installation hole 214 formed in the upper holder 210 and adhered with an adhesive to maintain airtightness. When the voltage of the current flowing through the distribution line 30 is within the normal voltage range, the voltage status indicator lamp 700 maintains the off state or lights in green, and the voltage of the current flowing through the distribution line 30 is within the normal voltage range. If it is out of range, it can be configured to flicker or light in red.

The tension adjusting means 800 is mounted on the upper surface of the support 100 and includes a driving motor 810 having a hollow motor shaft 820 having a female screw portion 821 formed on an inner circumferential surface thereof, and the motor shaft 820 . It has a male screw portion 831 screwed to the female screw portion 821 and is configured to include an elevating screw 830 whose upper end is coupled to the lower surface of the lower holder 220 . The driving motor 810 may be mounted on the upper surface of the support 100 by forming a flange portion 811 at the lower end, and a bolt passing through the flange portion 811 and the support 100 and a nut fastened thereto. .

The upper end of the elevating screw 830 may be coupled in a state where it is embedded in the connecting portion 224 protruding from the lower end of the lower holder 220 . The driving motor 810 and the lifting screw 830 may be protected from intrusion of wind and rain and foreign substances by the dust cover 840 .

The dust cover 840 may be composed of a corrugated pipe made of a stretchable rubber material, and the upper end is bonded to the outer circumferential surface of the connection part 224 formed on the lower surface of the lower holder 220 by an adhesive in a state of being in close contact with the lower end by an adhesive. It is preferable to join to the upper surface of the support 100 by the configuration so that the inside thereof can be kept airtight.

The lead wire 610 of the voltmeter 600 passes through the connection part 224, passes through the inside of the dust cover 840, passes through the support 100, and is drawn into the electric case 500 to the voltmeter 600. It is preferable to configure so that the lead wire 610 is not exposed to the outside by making it electrically connected. The control unit 900 includes a normal voltage state display command or abnormality for the voltage state display lamp 700 according to the voltage measurement signal of the temperature sensor S installed in the electric case 500 and the voltmeter 600 . A control unit 910 that outputs a lift driving command to the driving motor 810 according to a voltage state display command and a temperature detection signal of the temperature sensor S, and a voltage according to a voltage state display command of the control unit 910 A lamp driving unit 920 for transmitting a voltage display driving signal to the status display lamp 700, and a motor driving unit 930 for transmitting an elevation driving signal to the driving motor 810 according to the elevation driving command of the control unit 910. include

The lead wire (not shown) of the temperature sensor S may also be introduced into the electric case 500 through the same path as the lead wire 610 of the voltmeter 600 , and detailed illustration and description thereof will be omitted. A voltmeter 600, a voltage status display lamp 700, a control unit 910, and a lamp driving unit 920 by embedding a battery (B) that can be charged using the current of the distribution line 30 in the electric casing 500 , it may be configured to provide power to the motor driving unit 930 .

The control means 900 includes a communication unit capable of communication by a local area network, and a communication device 940 is installed in the electric pole 10 to transmit the voltage state and tension state to the local management sensor or the management server of the central management center. can also be connected to

Hereinafter, the operation of the monitoring system according to the present invention will be described. In the process of power distribution through the distribution line 30 and the jump line 50 , a voltmeter 600 connected to the jump line 50 through a pair of contacts 400 and a lead wire 610 measures the voltage in real time. The voltage measured by the voltmeter 600 is transmitted to the control unit 910, the control unit 910 compares the set voltage set value (V0) with the voltage measured value (V1), and the voltage measured value (V1) is the voltage set value ( When it is within the V2) range (V1 = V0), the normal voltage state display command is output, and the lamp driving unit 920 applies the normal voltage to the voltage state display lamp 700 according to the normal voltage state display command of the control unit 910 . A state display driving signal is transmitted, and the voltage state display lamp 700 maintains a turned off state or is lit in green to indicate a normal voltage state.

Conversely, when the measured voltage value measured by the voltmeter 600 is out of the voltage set value range (V1 < V0 < V1), the control unit 910 outputs an abnormal voltage state display command, and the abnormal voltage of the control unit 910 is In accordance with the status indication command, the lamp driver 920 transmits an abnormal voltage status indication driving signal to the voltage status indication lamp 700, and the voltage status indication lamp 700 flickers or lights in red to indicate the abnormal voltage status. do.

In addition, when a communication unit is provided in the control means 900 and the communication device 940 is installed in the electric pole 10, the voltage measured by the voltmeter 600 is transmitted to the local management sensor or the management server of the central management center This makes it possible to check the voltage status of the distribution line from a remote location and to deal with it.

On the other hand, when the temperature of the jump line 50 is low, the tension increases while contracting, and when the temperature is high, the tension decreases while stretching. When transmitted to, the control unit 910 compares the temperature measured value T1 with the temperature set value T0 and the temperature measured value T1 is within the temperature set value T0 range (T1 = T0). Since the motor drive signal is not output, the jump line holder 200 does not go up and down.

When the temperature measurement value T1 is lower than the temperature set value T0 range, the control unit 910 outputs a downward driving command, and according to the downward driving command of the control unit 910, the motor driving unit 930 operates the driving motor ( 810), the driving motor 810 operates in the downward driving direction by the screw action of the female screw portion 821 of the motor shaft 820 and the male screw portion 831 of the elevating screw 830. The lifting screw 830 descends, and the jump line holder 200 coupled to the upper end of the lifting screw 830 descends to reduce the tension of the jump line 50 .

When the temperature measurement value T1 is higher than the temperature set value T0 range, the control unit 910 outputs a rising drive command, and the motor driving unit 930 operates the driving motor ( 810), the driving motor 810 operates in the upward driving direction by the screw action of the female screw portion 821 of the motor shaft 820 and the male screw portion 831 of the elevating screw 830. The elevating screw 830 rises, and the jump line holder 20) coupled to the upper end of the elevating screw 830) rises, thereby increasing the jump line 50).

By the tension control action on the jump wire, the jump wire 50 always maintains the set tension, so that the distribution line is maintained in a stable state. On the other hand, according to the monitoring system according to the present invention, the jump line 50 is not supported by using a separate line post insulator, but the support 100, the jump line holder 200 and the driving motor 810, the lifting screw 830. By supporting it, voltage monitoring and tension control can be performed, and the jump line 50 can be stably supported.

The monitoring system according to the present invention further includes a control unit 1000 for smoothly detaching the jump line 50 to the jump line holder 200 as shown in FIG. 6 . The opening of the jump sun holder 200 may be understood as opening between the upper and lower fasteners 212 and 222 while the upper and lower holders 210 and 220 are widened.

The control unit 1000 is the inlet of the jump line 50 into the jump line holder 200 or the withdrawal of the jump line 50 from the jump line holder 200 through the opening and closing of the jump line holder 200 comprising the upper and lower holders 210 and 220 . to make this happen smoothly.

In other words, the control unit 1000 is the inlet of the jump line 50 into the upper and lower tightening units 212 and 222 through the opening and closing of the jump line holder 200 or the withdrawal of the jump line 50 from the upper and lower tightening units 212 and 222 . to make this happen smoothly.

The adjusting unit 1000 includes a folding member 1010 for rotatably connecting one side of the upper holder 210 to the lower holder 220, and a binding means for binding the other side of the upper holder 210 to the lower holder 220 ( 1020) and a support means 1030 for supporting the upper holder 210 that is rotated in a direction to be oriented with the lower holder 220 around the folding member 1010 when the jump line holder 200 is opened.

The folding member 1010 is made of a hinge or the like, and connects a lower portion of one side of the upper holder 210 to an upper portion of one side of the lower holder 220 . The binding means 1020 includes a lower plate 1021 extending outwardly from the other side of the lower holder 220, an upper plate 1022 extending outwardly from the other side of the upper holder 210, and the lower plate 1021 in an upward direction. It includes a binding member 1024 for binding the upper holder 210 to the lower holder 220 while being screwed to the binding bar 1023 and the binding bar 1023 extending through the upper plate 1022 .

The lower plate 1021 has one end fixed to the upper portion of the other side of the lower holder 220 and the other end extending outward. One end of the upper plate 1022 is fixed to the other lower portion of the upper holder 210 so as to face the lower plate 1021 and the other end is formed to extend outwardly. The upper plate 1022 has a through hole 1022a through which the binding bar 1023 passes, extending from the other end in the direction of one end.

Accordingly, when the upper holder 210 is rotated around the folding member 1010 , the upper plate 1022 may be smoothly coupled to the binding bar 1023 . The binding bar 1023 is threaded on the outer circumferential surface, and the binding member 1024 is screwed to the binding bar 1023 while the thread is formed on the inner circumferential surface.

The binding member 1024 is in close contact with the upper plate 1022 according to the tightening rotation so that the upper and lower plates 1022 and 1021 are in close contact. The jump sun holder 200 is closed while the upper and lower holders 210 and 220 are bound. On the contrary, the binding member 1024 is released from the upper plate 1022 according to the loosening rotation, so that the upper and lower plates 1022 and 1021 are released in close contact.

The jump sun holder 200 may be opened while the upper and lower holders 210 and 220 are unbound. Since the upper and lower holders 210 and 220 are connected by the folding member 1010 when the jump line holder 200 is opened, the connected state can be maintained without being separated from each other.

Accordingly, it is possible to solve the inconvenience of having to support the upper holder 210 when the jump sun holder 200 is opened. The support means 1030 allows the upper holder 210, which is rotated in a direction to be oriented with the lower holder 220 around the folding member 1010, to stop rotation at a certain point, while the rotation is to be supported in a stopped state. make it possible

The support means 1030 allows the upper holder 210 to be stably supported when the jump line holder 200 is opened, so that the jump line 50 between the upper and lower holders 210 and 220 is drawn in or the upper and lower holders ( 210 and 220), so that the jump line 50 is smoothly drawn out.

The support means 1030 includes a support bar 1031 extending outwardly from one side of the lower holder 220, a control lever 1032 having upper and lower portions open and rotatably fixed to the support bar 1031, and an adjustment lever It includes a lifting bar 1033 that is screwed to the upper and lower portions 1032 and a support plate 1034 that is provided on the lifting bar 1033 and supports the upper holder 210 .

The control lever 1032 is rotatably fixed to the support bar 1031 by a bearing or the like, and it is preferable that the lower portion extends downward from the support bar 1031 so as to be gripped by an operator or the like. The control lever 1032 has a thread on its inner circumferential surface, and the lifting bar 1033 is screwed with the control lever 1032 while a screw thread is formed on its outer circumferential surface.

The lifting bar 1033 can be raised and lowered without being rotated together by a worker or the like holding the support plate 1034 by hand so that the control lever 1032 is not rotated when the control lever 1032 is rotated. While the rotating upper holder 210 is seated so that the rotation is stopped, the stopped state is maintained.

The support plate 1034 may make a stable contact with the upper holder 210 while the upper surface forms a curved surface. It is preferable that the lower portion of the support plate 1034 is rotatably coupled to the upper portion of the lifting bar 1033 in the left and right directions, and contact with the upper holder 210 is uniformly made.

The support plate 1034 is raised and lowered together with the lifting bar 1033 according to the rotation of the control lever 1032 so that the height from the support bar 1031 is adjusted. Accordingly, when the jump sun holder 200 is opened, the rotation angle of the upper holder 210 can be appropriately adjusted, and the position where the upper holder 210 can be stably supported can be appropriately adjusted. .

For this reason, the control unit 1000 is the inlet of the jump line 50 to the jump line holder 200 or the jump line 50 from the jump line holder 200 through the opening and closing of the jump line holder 200 comprising the upper and lower holders 210 and 220. ) can be smoothly withdrawn.

8 to 12 , there is provided a method of providing a distribution line failure section monitoring system connected to a transformer using artificial intelligence, the method comprising: selecting a distribution line installation location; installing a method for providing a distribution line fault section monitoring system connected to a transformer using artificial intelligence on the selected distribution line; and performing, by a management facility disposed in a field surrounding the distribution line, monitoring and management of a target in the distribution line or the surrounding field.

The method for providing a distribution line failure section monitoring system connected to a transformer using the artificial intelligence includes a distribution line voltage real-time monitoring system configured with a voltage status indicator lamp (700). It further includes a control unit 1000 to make the detachment of the jump line 50 to the jump line holder 200 smoothly.

The adjusting unit 1000 includes a folding member 1010 rotatably connecting one side of the upper holder 210 to the lower holder 220; binding means (1020) for binding the other side of the upper holder (210) to the lower holder (220); and rotation of the upper holder 210 rotating in a direction oriented with the lower holder 220 around the folding member 1010 is stopped. In addition, it includes a support means 1030 for supporting the upper holder (210).

The management facility, wherein the management facility includes a lower part including a monitoring function and an upper part mounted on the lower part, wherein the upper part includes a first driving panel 311 and the first driving A second driving panel 321 that is movably interlocked through the panel 311 and the first connecting bar 331 on the upper side and the second connecting bar 341 on the lower side, and the first driving panel 311 A first movable body 312 provided to provide a driving force, and a second movable body provided on the second drive panel 321 to interlock with the first movable body 312 based on the first base panel 333 It includes a sieve 322 and a first fluid including a first photographing monitoring module 332 mounted on the first base panel 333 .

In addition, a third movable body 313 provided on the first driving panel 311 to provide driving force, and a third movable body 313 provided on the first driving panel 311 and based on the second base panel 343 , are provided. and a second fluid including a fourth movable body 323 interlocked with the sieve 313 and a second photographing monitoring module 342 mounted on the second base panel 343 .

Also, based on the forward and backward movement, the first base panel 333 and the first photographing monitoring module 332 are accommodated inside the first movable body 312 to be protected and managed from the external environment, and the forward and backward movement Based on the above, the second base panel 343 and the second photographing monitoring module 342 are accommodated inside the third movable body 313 to be protected and managed from external mirrors.

In addition, the upper part includes a first auxiliary actuator 411 provided between the first movable body 312 and the third movable body 313 on the first driving panel 311, and the first auxiliary drive It is interlocked with the sieve 411 and injects a first fluid of a set temperature to the upper and lower perimeter and longitudinal ends into the space around the first shooting monitoring module 332 and the second shooting monitoring module 342, The first shooting monitoring module 332 and the second shooting monitoring module 342 include a first injection actuator 412 to create a suitable temperature environment for shooting and driving.

In addition, a second auxiliary actuator 511 provided between the second movable body 322 and the fourth movable body 323 on the second driving panel 321, and the second auxiliary actuator 511 The first shooting monitoring module ( 332) and a second injection actuator 512 for creating a temperature environment suitable for photographing and driving of the second photographing monitoring module 342.

In addition, the lower parts include a lower panel part 421 to which the first driving panel 311 and the second driving panel 321 are inserted and mounted, and the lower panel part 421 to which the lower panel part 421 is installed. 421) further includes a lowermost panel panel portion 422 that is rotatably provided as a peripheral portion.

The lower panel part 421 is provided with a central lower panel part 4211 in the center and retractable at one side of the central lower panel part 4211, and one lower plate on which the first driving panel 311 is inserted and mounted. It includes a panel part 4212 and the other lower panel part 4213 which is provided retractably on the other side of the central lower panel part 4211 and into which the second driving panel 321 is inserted and mounted.

Here, the one side lower panel part 4212 and the other lower panel part 4213 flow in response to the forward and backward movement on the central lower panel part 4211, and the lower part is the one side lower panel part 4212. The lower side is interlocked and the inner surface is in contact with the first driving panel 311, but the 1-1 protrusion 5111 protruding and protruding inward is the 1-1 contact mounted on the first driving panel 311 The body 511, the 1-1 moving port 5112 moving upward in the 1-1 contact body 511, and the 1-1 contact through the 1-1 moving port 5112 The first and second contact bodies 512 connected to the body 511 and whose inner surface is in contact with the middle portion of the first driving panel 311, and the first and second contact bodies 512 moving upward -Connected to the 1-2 contact body 512 through the -2 moving port 5121 and the 1-2 moving port 5121, the inner surface is in contact with the upper end of the first driving panel 311, but the first -2 includes a first contact fixing module including a 1-3 contact body 513 mounted on the first driving panel 311 with the protrusion 5131 .

In addition, the lower side of the lower panel part 4213 is interlocked and the inner surface is in contact with the second driving panel 321, but the second 2-1 protrusion 5211 protruding and protruding inward is the second driving panel 321 ) mounted on the 2-1 contact body 521, the 2-1 contact body 521 moving upward in the 2-1 moving port 5212, and the 2-1 moving port 5212 ) connected to the second-first contact body 521 and the inner side of the second-second contact body 522 in contact with the middle portion of the second driving panel 321, and the second-second contact body ( 522) is connected to the second-second contact body 522 through the 2-2 moving port 5221 and the 2-2 moving port 5221 moving upward, and the inner surface is the second driving panel (321) but in contact with the upper end includes a second contact fixing module including a second-second protrusion 5231, a second-third contact body 523 mounted on the second driving panel 321.

Here, the first contact fixing module is configured such that the first-first contact body 511 moves the first-second contact body 512 upward or downward through the first-first moving port 5112. In the 1-1 operation and the 1-2 contact body 512 , the 1-2 protrusion 5131 is attached to the first driving panel 311 via the 1-2 moving port 5121 . In the mounted state, the first-second operation of moving the first-third contact body 513 upward or downward is performed.

In addition, in the second contact fixing module, the 2-1 contact body 521 moves the 2-2 contact body 522 upward or downward via the 2-1 moving port 5212. In the 2-1 operation and the 2-2 contact body 522 , the 2-2 protrusion 5231 is attached to the second driving panel 321 via the 2-2 moving port 5221 . In the mounted state, the second-second operation of moving the second-third contact body 523 upward or downward is performed.

The first contact fixing module and the second contact fixing module are configured to attach the first driving panel 311 and the second driving panel 321 to the lower plate based on the operations 1-1 to 2-2. The panel part 421 and the lowermost panel part 422 are interlocked and fixed.

A plurality of the lower parts are provided in an adjacent area or different separate areas, and the upper parts are selectively mounted to each of the lower parts or respectively mounted in correspondence to the respective lower parts.

The lower parts are installed on the upper installation surface and positioned in a vertical inversion type, or installed on one installation surface and positioned horizontally, or installed on the other installation surface and positioned horizontally, and the 1-1 protrusion (5111) , the 1-2 convex protrusion 5131 , the 2-1 convex protrusion 5211 , and the 2-2 convex protrusion 5231 are respectively the first driving panel 311 and the second driving panel ( 321) by performing a cooling function or a heating function in the state of being mounted on the first driving panel 311, the second driving panel 321, and the first driving panel 311 and the second driving panel 321 Make sure that the temperature conditions for the surrounding area are set. 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, those skilled in the art will understand 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.

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, those skilled in the art will understand 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.

30: distribution line 50: jump line
100: support 200: jump sun holder
300: press piece 400: contact

Claims (2)

A method of providing a fault section monitoring system for a distribution line connected to a transformer using artificial intelligence, the method comprising:
selecting a distribution line installation location;
installing a distribution line failure section monitoring system connected to a transformer using artificial intelligence on the selected distribution line; and
A management facility disposed in the field surrounding the distribution line includes the step of monitoring and managing a target on the distribution line or the surrounding field,
A method of providing a fault section monitoring system for a distribution line connected to a transformer using the artificial intelligence,
Includes a distribution line voltage real-time monitoring system consisting of a voltage status indicator lamp 700,
It further includes a control unit 1000 for smoothly detaching the jump line 50 to the jump line holder 200,
The control unit 1000,
a folding member 1010 rotatably connecting one side of the upper holder 210 to the lower holder 220; binding means (1020) for binding the other side of the upper holder (210) to the lower holder (220); and a support means (1030) for supporting the upper holder (210) while stopping the rotation of the upper holder (210), which is rotated in a direction oriented with the lower holder (220) around the folding member (1010). including,
The management equipment is
It is disposed around the water sump and includes a lower part including a monitoring function and an upper part mounted on the lower part,
The upper part is
A first driving panel 311 and;
a second driving panel 321 interlocked with the first driving panel 311 and the upper first connecting bar 331 and the lower second connecting bar 341 to be movable forward and backward;
A first movable body 312 provided on the first driving panel 311 to provide a driving force, and a first movable body provided on the first driving panel 311 and based on the first base panel 333 . A first fluid including a second movable body 322 interlocked with (312) and a first photographing monitoring module 332 mounted on the first base panel 333;
A third movable body 313 provided on the first driving panel 311 to provide a driving force, and a third movable body provided on the first driving panel 311 and based on the second base panel 343 . A fourth movable body 323 interlocked with (313) and a second fluid including a second photographing monitoring module 342 mounted on the second base panel 343,
Based on the forward and backward movement, the first base panel 333 and the first photographing monitoring module 332 are accommodated in the first movable body 312 and protected and managed from the external environment,
Based on the forward and backward movement, the second base panel 343 and the second shooting monitoring module 342 are accommodated inside the third movable body 313 and are protected and managed from an external scene,
The upper part is
a first auxiliary actuator 411 provided between the first movable body 312 and the third movable body 313 on the first driving panel 311;
The first auxiliary actuator 411 is interlocked and installed, and a first fluid of a set temperature is applied to the upper and lower peripheral portions and the longitudinal ends in the space around the first photographing monitoring module 332 and the second photographing monitoring module 342 . a first injection actuator 412 to create a temperature environment suitable for photographing and driving of the first photographing monitoring module 332 and the second photographing monitoring module 342 by spraying the
a second auxiliary actuator 511 provided between the second movable body 322 and the fourth movable body 323 on the second driving panel 321;
The second auxiliary actuator 511 is interlocked and installed, and a second fluid of a set temperature is applied to the upper and lower peripheral portions and the longitudinal ends in the space around the first photographing monitoring module 332 and the second photographing monitoring module 342 . and a second injection actuator 512 to create a temperature environment suitable for shooting and driving of the first shooting monitoring module 332 and the second shooting monitoring module 342 by spraying with
The lower parts are
a lower panel part 421 to which the first driving panel 311 and the second driving panel 321 are inserted and mounted;
The lower panel portion 421 is installed and the lower panel portion 421 further includes a lowermost panel portion 422 provided to be rotatable around the circumference,
The lower panel part 421,
And the central lower panel part 4211 in the center,
One side lower panel part 4212 is provided to be retractable on one side of the central lower panel part 4211 and into which the first driving panel 311 is inserted and mounted;
A distribution line connected to a transformer using artificial intelligence, which is provided on the other side of the central lower panel part 4211 to be retractable and includes the other lower panel part 4213 into which the second driving panel 321 is inserted and mounted. A method for providing a section monitoring system. delete

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