KR102113653B1 - Real-time remote monitoring system for underground power distribution line - Google Patents

Abstract

The present invention relates to a real-time remote monitoring system for an underground distribution line which, by detecting a failure section of the underground distribution line, blocks first and second cables and, at the same time, reports the failure section to a management center server, a terminal of a patrol car, a portable terminal of a patroller, and a terminal of a manhole disposed in the failure section to make a failure quickly recovered; informs a distribution panel terminal of a customer of an expected recovery time to enable the customer to manage the failure; forms an insulation film around an end part of the blocked second cable to prevent a fire from being generated by an arc between the first and second cables; and includes an opening/closing block and an opening/closing plate interlocked with a connector to link an operation for forming the insulation film around an end part of an exposed conductor of the blocked second cable with an operation for blocking the first and second cables, thereby not using separate power. According to the present invention, the system comprises the connector, a connector operation means, an insulation film forming means, and a control means.

Description

Real-time remote monitoring system for underground power distribution line

The present invention relates to a real-time remote monitoring system of an underground distribution line among technologies in the field of distribution, and more specifically, to detect a failure section of the underground distribution line, block the first cable and the second cable, and patrol with the management center server at the same time. Along with the terminal of the vehicle and the portable terminal of the patrol, the terminal in the manhole of the failure section is notified of the failure period so that it can be quickly recovered to the failure. It is possible to prevent the fire caused by arc between the first cable and the second cable by forming an insulating film around the end of the blocked second cable, and also around the end of the exposed conductor of the blocked second cable. Separate power is used by interlocking the operation of forming the insulating film with the operation of blocking the first and second cables. As one of underground distribution lines not to relate to real-time remote monitoring system.

Underground distribution lines have a number of advantages compared to overhead power distribution lines, but they exhibit problems in terms of maintenance. Especially, when an accident occurs in an underground distribution line, it is not possible to quickly detect and recover from an accident point. There is a problem.

Therefore, power companies have developed technologies to detect and cope with faults in underground distribution lines in order to quickly find and cope with accident points.

Korean Patent Registration No. 10-0956712 (2010.05.06. Announcement) "Automatic opening and closing device for fault section of transmission and distribution lines" (hereinafter referred to as 'priority') Technology ') detects the voltage and current of the load stage by the sensor means installed on a certain part of the transmission and distribution line, and the CPU judges the fixed point in real time according to the detection signal of the sensor means to temporarily cut off the fault line. It discloses a technique.

However, the prior art also includes a connecting connection member fixedly installed at both ends of the transmission and distribution line to block the faulty line; An operation connecting member rotating by the motor means and the rotating shaft means; It has a CPU to control the motor means, and if the transmission and distribution line is normal, the working connecting member is connected to the connecting connecting member. If the transmission and distribution line is faulty, the operating connecting member is rotated and connected by the motor means and the rotating shaft means. Since the means for separating the transmission and distribution lines on both sides separated from the connecting member is installed separately for each distribution cable of each distribution line, the facility is very complicated and the motor corresponding to the number of distribution lines must be provided, so that the facility cost increases significantly. There is a problem.

In addition, the power-side cable and the load-side cable are separated, so the power-side cable is in contact with the connector, and the load-side cable is exposed in close proximity to the end and connector of the power-side cable. There is a problem that arc may occur and lead to fire.

On the other hand, as a customer of a power outage due to a failure of the underground distribution line, it is impossible to check whether it is a power outage or a problem with the internal electric wiring when a power outage occurs, and you will have the inconvenience of going outside and looking around or contacting the power company by phone. As a power company, there is a problem in that a problem arises due to a busy phone call.

Republic of Korea Registered Patent No. 10-0956712 (announced on May 6, 2010) "Automatic opening and closing device of fault section of transmission and distribution lines"

Therefore, an object of the present invention is to detect the fault section of the underground distribution line, cut off the first cable and the second cable, and at the same time, fail at the terminal of the manhole with the management center server, the patrol vehicle terminal, and the patrol's mobile terminal. By notifying the section, it is possible to quickly recover from a malfunction, and also, by alerting the customer's distribution box terminal with a power outage and scheduled recovery time, the customer can cope with it and forming an insulating film around the end of the blocked second cable. The purpose of the present invention is to provide a real-time remote monitoring system for underground distribution lines to prevent fires caused by arcs between the first cable and the second cable.

Also, another object of the present invention is to connect the operation of forming the insulating film around the ends of the exposed conductors of the blocked second cable to the operation of blocking the first and second cables, so that the underground power distribution line does not use separate power. It is intended to provide a real-time remote monitoring system.

The present invention has been devised to achieve the above object, the first cable (C1) and the second cable (2) on the shelf (20) installed in multiple layers on the inner wall surface of the underground tunnel (10), which is a concrete structure installed in the ground. C2) In the fault location notification system for each section of the underground distribution line that is settled at this interval,

In the middle of the shelf 20, an operating space 21 is formed, and a motor mount 22 is provided on the bottom surface.

A connector 100 installed between the first and second cables C1 and C2; Connector driving means (200) for driving the connector (100); An insulating film forming means 300 for forming an insulating film IM around the end of the second cable C2 separated from the first cable C1 by the connector 100; The connector driving means 200 and the control means 400 for controlling the insulating film forming means 300; is further configured to include,

The connector 100 is formed of a conductive material and has inner diameters corresponding to outer diameters of the exposed conductors C11 and C21 of the first and second cables C1 and C2, and the first and second cables formed at both ends of the front and rear. A connecting sleeve 110 provided with a cylindrical portion 111 on which the entrances 112a and 112b are formed, and an outward flange portion 113 extending on both front and rear ends of the cylindrical portion 111; An insulator 120 surrounding the cylindrical portion 111 of the connection sleeve 110, the outward flange portion 113 is buried, and first and second cable entrances 121a and 121b are formed at both ends; And a rack coupling portion 130 formed integrally under the insulator 120 and extending in the front-rear direction.

The first and second cable entrances 112a and 112b of the connection sleeve 110 are formed with tapered portions gradually narrowing while going inward, and the first and second cable entrances 121a and 121b of the insulator 120 are formed. The taper portion gradually narrowing as it goes inward is formed to be configured so that entry of the first and second cables C1 and C2 to the first and second cable entrances 112a and 112b and 121a and 121b is smooth. ,

The connector driving means 200 is respectively coupled to the lower surface of the rack coupling portion 130 of the connector 100 and installed in the longitudinal direction of the first cable C1 and the second cable C2, and the gear portion is provided on the lower surface. A plurality of racks 210 provided with (211), a drive shaft 220 installed in a direction perpendicular to the longitudinal direction of the first cable (C1) and the second cable (C2) 220, and the rack 210 ), A plurality of pinions 230 which are disposed on the lower portion and meshed with the gear part 211 and are installed in the drive shaft 220 and the drive shaft 220 installed between the drive shaft 220 and the pinion 230. It comprises an electronic clutch 240 to allow the rotational force of the pinion 230 to be transmitted or blocked, and a driving motor 250 mounted on a lower surface of the shelf 20 to rotate and drive the driving shaft 220 ,

The insulating film forming means 300 is fixed to the shelf 20 and the two-component resin container 310 divided into first and second liquid storage spaces S1 and S2 in which the internal space is partitioned by the partition 311. and,

The first and second liquid discharge pipes 321 and 322 connected to the lower end of the two-component resin container 310 and connected to the first and second liquid storage spaces S1 and S2 and opened toward the left,

Located at the bottom of the two-liquid resin container 310, the first and second liquid discharge pipes 321 and 322 receive and mix the first and second liquids L1 and L2 supplied through upper openings, A mixed discharge container (330) having a mixed liquid discharge hole (331) discharged around the conductor (C21) of the second cable (C2) with the mixed liquid (L3) at the bottom,

Opening and closing plugs (341, 342) for opening and closing the left open end of the first and second liquid discharge pipes (321, 322),

And the opening and closing plate 350 for opening and closing the upper opening of the mixed discharge container 330,

Interlocking bracket 360 is fixed to the upper surface of the insulator 120 is installed vertically, the left end of the opening and closing plugs 341, 342 and the left end of the opening and closing plate 350 are coupled,

It comprises a UV lamp 370 coupled to the right side of the mixed discharge container 330 for irradiating UV to the discharged mixed solution,

The two-component resins stored in the first and second spaces S1 and S2 of the two-component resin container 310 are disposed in the first liquid L1 and the second space S2 stored in the first space S1. Consists of a second liquid (L2) that is stored, and when irradiated with UV for 5 seconds in a state in which the first liquid (L1) and the second liquid (L2) are mixed, it hardens and flows rapidly when it is dispensed. A two-component epoxy resin capable of forming an insulating film (IM) around the end of (C2) is used,

The control means 400 is installed on the first cable (C1) and the second cable (C2) fault detection sensors (411, 412) for detecting whether or not a failure; A control unit 420 for outputting a management information transmission command, a customer notification information transmission command, a connector control command, and an insulating film formation command according to the detection signals of the first and second fault detection sensors 411 and 412; A management communication unit 430 for transmitting management information to the management center server 431 and the patrol terminal 432 according to the management information transmission command of the control unit 420; A notification communication unit 440 for transmitting the customer notification information to the distribution box terminal 441 of the prisoner according to the instruction for sending the consumer notification information of the control unit 420; A motor driving unit 450 for transmitting a motor driving signal to the driving motor 250 of the connector driving means 200 according to the connector control command of the control unit 420; An electronic clutch driving unit 460 that transmits an electronic clutch driving signal to the electronic clutch 240 of the connector driving means 200 according to the connector control command of the control unit 420; And a UV lamp driving unit 470 that transmits a UV lamp driving signal to the UV lamp 370 according to the insulating film formation command of the control unit 420. A real-time remote monitoring system for an underground distribution line, comprising: to provide.

According to the real-time remote monitoring system of the underground distribution line according to the present invention, the failure section of the underground distribution line is detected and the first cable and the second cable are blocked, and at the same time, the management center server, the patrol vehicle terminal and the patrol car's portable terminal By notifying the terminal of the manhole of the section, it is possible to quickly recover from a malfunction, as well as to alert the customer's distribution box terminal of a power outage and the expected recovery time, so that the customer can cope with the end of the disconnected second cable By forming an insulating film around it, it is possible to prevent a fire caused by an arc between the first cable and the second cable.

In addition, according to the real-time remote monitoring system of the underground distribution line according to the present invention, an operation of forming an insulating film around the ends of the exposed conductors of the second cable that is blocked by having an opening and closing plate and an opening and closing plate interlocking with the connector is provided for the first and first operations. 2 It can be interlocked with the operation of cutting off the cable to form an insulating film without using a separate power source.

1 to 9 show a preferred embodiment of a real-time remote monitoring system of the underground distribution line according to the present invention,
1 is a perspective view of a fault location notification system for each section of an underground distribution line according to the present invention,
2 and 3 is a perspective view showing a shelf, tray, cable, connector, connector driving means, insulating film forming means,
Figure 4 is an exploded perspective view of the shelf, tray, cable, connector, connector driving means, insulating film forming means,
Figure 5 is an exploded perspective view showing a cable, a connector, a connector driving means,
6 is a partially cut-away perspective view of a connector,
7 is an exploded perspective view of a partial cut of the insulating film forming means,
8 is a functional block diagram of a control means,
9 is a longitudinal sectional view showing an operating state.

Hereinafter, the real-time remote monitoring system of the underground distribution line according to the present invention will be described in detail according to a preferred embodiment illustrated in the accompanying drawings.

1 to 9 show a preferred embodiment of a real-time remote monitoring system of the underground distribution line according to the present invention.

In the following description, the coupling between the components can be made by a conventional screwing method, so a detailed illustration and description thereof are omitted.

The illustration and description of various bolts and bolt through holes and screw holes are omitted.

The real-time remote monitoring system of the underground distribution line according to this embodiment is a shelf 20 installed in multiple layers on the inner wall surface of the underground tunnel 10, which is a concrete structure installed in the underground, as shown in FIGS. 1 to 9. It applies to underground distribution systems that support distribution cables of multiple distribution lines.

The underground tunnel 10 may be constructed by placing concrete in the ground or assembling a prefabricated concrete block.

The shelf 20 can be fixed to the inner wall surface of the underground tunnel 10 by an anchor bolt that is buried and protrudes on the inner wall surface of the underground tunnel 10 and an anchor nut fastened thereto, which is equivalent to a conventional technique Therefore, detailed description and description thereof will be omitted.

In the illustrated example, three distribution cables are mounted on each shelf 20, but the number is not specified.

In the middle of the shelf 20, an operating space 21 of the connector driving means 200, which will be described later, is formed. In addition, a motor mount 22 for mounting the driving motor 250 of the connector driving means 200 to be described later is provided on one lower surface of the intermediate portion.

The distribution cable is composed of a first cable (C1) and a second cable (C2), respectively, and is installed at regular intervals.
In the drawing, C11 and C21 show conductors in which insulation coatings C12 and C22 of the first cable C1 and the second cable C2 are peeled off.

The first and second cables C1 and C2 may be mounted directly on the shelf 20, respectively, but are preferably mounted on trays 30 and 40 made of an insulating material fixed on the shelf 20. Do.

The real-time remote monitoring system of the underground distribution line according to the present invention includes a connector 100 installed between the first and second cables C1 and C2; A connector driving means 200 for driving the connector 100; An insulating film forming means 300 for forming an insulating film IM around the end of the second cable C2 separated from the first cable C1 by the connector 100; It comprises a; control means 400 for controlling the connector driving means 200 and the insulating film forming means 300.

At this time, the first and second trays 30 and 40 are not installed at the position of the operating space 21.

In addition, the first and second trays 30 and 40 are installed to be separated from both sides at positions 31 and 41 where the first and second fault detection sensors 411 and 412 of the control means 400 to be described later are installed. .

The connector 100 is formed of a conductive material and has inner diameters corresponding to outer diameters of the exposed conductors C11 and C21 of the first and second cables C1 and C2, and the first and second cables formed at both ends of the front and rear. A connecting sleeve 110 provided with a cylindrical portion 111 on which the entrances 112a and 112b are formed, and an outward flange portion 113 extending on both front and rear ends of the cylindrical portion 111; The outward flange portion 113 is wrapped around the cylindrical portion 111 of the connection sleeve 110 and corresponds to the outer diameters of the insulating coatings C12 and C22 of the first and second cables C1 and C2 at both ends. An insulator 120 having first and second cable entrances 121a and 121b having inner diameters formed thereon; And a rack coupling part 130 formed integrally under the insulator 120 and extending in the front-rear direction. (See FIG. 3).

The first and second cable entrances 112a and 112b of the connection sleeve 110 are formed with tapered portions gradually narrowing while going inward, and the first and second cable entrances 121a and 121b of the insulator 120 are formed. A taper portion gradually narrowing as it goes inward is formed to enter the conductors C11, C21 of the first and second cables C1, C2 and the first and second cables to the first and second cable entrances 112a, 112b. The first and second cables C1 and C2 to the cable entrances 121a and 121b are configured to smoothly enter the insulating coatings C12 and C22.

In addition, the tolerance between the inner diameter of the cylindrical portion 111 of the connection sleeve 110 and the outer diameters of the exposed conductors C11 and C21 of the first and second cables C1 and C2 is composed of a tight fit. By doing so, the inner circumferential surface of the cylindrical portion 111 and the outer circumferential surfaces of the conductors C11 and C21 are tightly contacted.

The connection sleeve 110 may be manufactured in a state embedded in the insulator 120 by an insert molding technique in the process of forming the insulator 120 into an insulating synthetic resin. At this time, the insulator 120, the rack coupling portion 130 is formed integrally.

The connector driving means 200 is respectively coupled to the lower surface of the rack coupling portion 130 of the connector 100 and installed in the longitudinal direction of the first cable C1 and the second cable C2, and the gear portion is provided on the lower surface. A plurality of racks 210 provided with (211), a drive shaft 220 installed in a direction perpendicular to the longitudinal direction of the first cable (C1) and the second cable (C2) 220, and the rack 210 ), A plurality of pinions 230 which are disposed on the lower portion and meshed with the gear part 211 and are installed in the drive shaft 220 and the drive shaft 220 installed between the drive shaft 220 and the pinion 230. It is configured to include an electronic clutch 240 to allow the rotational force of the pinion 230 to be transmitted or blocked, and a driving motor 250 mounted on a lower surface of the shelf 20 to rotate and drive the driving shaft 220. .

Since the driving shaft 220 is coupled to the motor shaft of the driving motor 250, a typical shaft coupling structure may be adopted, so a detailed description thereof will be omitted.

The pinion 230 is rotatably installed on the driving shaft 220 using a radial bearing or a metal bush.

The electronic clutch 240 can be used to separate the connection object when power is applied, and to connect the connection object when the power is cut off, detailed description and description thereof will be omitted.

The insulating film forming means 300 is fixed to the shelf 20 and the two-component resin container 310 divided into first and second liquid storage spaces S1 and S2 in which the internal space is partitioned by the partition 311. And, the first and second liquid discharge pipes 321 and 322 connected to the lower end of the two-component resin container 310 and connected to the first and second liquid storage spaces S1 and S2 and opened toward the left, Located in the lower portion of the two-component resin container 310, the first and second liquid discharge pipes 321 and 322 receive and mix the first and second liquids L1 and L2 supplied through upper openings, A mixed discharge container 330 having a mixed liquid discharge hole 331 discharged around the conductor C21 of the second cable C2 at the bottom of the mixed liquid L3, and the first and second liquid discharge pipes 321 and 322 ), The opening and closing plugs 341 and 342 for opening and closing the left open end, the opening and closing plate 350 for opening and closing the upper opening of the mixed discharge container 330, and fixed to the upper surface of the insulator 120, vertically installed Become , Interlocking bracket 360 to which the left end of the opening / closing plugs 341 and 342 and the left end of the opening / closing plate 350 are coupled, and coupled to the right side of the mixing discharge container 330 to irradiate UV to the discharged mixed solution It comprises a UV lamp 370.

An injection port (not shown) for injecting the first liquid and the second liquid may be provided on an upper surface of the two-component resin container 310.

The two-component resin container 310 may be mounted on a mounting plate 313 supported on the shelf 20 by a plurality of support angles 312 fixed to the upper surface of the shelf 20.

The two-component resins stored in the first and second spaces S1 and S2 of the two-component resin container 310 are disposed in the first liquid L1 and the second space S2 stored in the first space S1. It is composed of a second liquid (L2) that is stored, and when the first liquid (L1) and the second liquid (L2) are mixed, a two-component epoxy resin cured at room temperature may be used.

In general, the two-component epoxy resin has excellent electrical insulation properties, but because it takes about 24 hours to cure at room temperature, it is unsuitable for flowing down when pouring and forming a film within a desired range.

Therefore, in the present invention, the two-component epoxy resin is not cured while the first and second liquids L1 and L2 are not mixed and stored in the first and second spaces S1 and S2, respectively. When irradiated for 5 seconds, it is cured and rapidly cured without flowing when pouring, so that an insulating film IM can be formed around the end of the second cable C2.

At this time, as the first and second liquids L1 and L2 are irradiated as soon as they are dispensed, it is preferable to irradiate UV with a parallax because the insulating film IM cannot be formed in a wide range.

The opening / closing plugs 341 and 342 and the opening / closing plate 350 may be moved from side to side by using a linear actuator such as a solenoid, but in this case, a linear actuator such as a solenoid must be installed at each position where the connector 100 is installed. The cost increases and power is required. In the present invention, the connector 100 is fixed by fixing the opening / closing plugs 341 and 342 and the opening / closing plate 350 to the interlocking bracket 360 coupled to the insulator 120 of the connector 100. It can be opened and closed in conjunction with the operation of the can save cost and power.

The UV lamp 370 may be mounted on the mounting plate 313 through the lamp bracket 314.

The control means 400 is installed on the first cable (C1) and the second cable (C2) fault detection sensors (411, 412) for detecting whether the failure; A control unit 420 for outputting a management information transmission command, a customer notification information transmission command, a connector control command, and an insulating film formation command according to the detection signals of the first and second fault detection sensors 411 and 412; A management communication unit 430 for transmitting management information to the management center server 431 and the patrol terminal 432 according to the management information transmission command of the control unit 420; A notification communication unit 440 for transmitting the customer notification information to the distribution box terminal 441 of the prisoner according to the instruction for sending the consumer notification information of the control unit 420; A motor driving unit 450 for transmitting a motor driving signal to the driving motor 250 of the connector driving means 200 according to the connector control command of the control unit 420; An electronic clutch driving unit 460 that transmits an electronic clutch driving signal to the electronic clutch 240 of the connector driving means 200 according to the connector control command of the control unit 420; And a UV lamp driving unit 470 that transmits a UV lamp driving signal to the UV lamp 370 according to the insulating film forming command of the controller 420.

In addition, it further includes an input unit 480 for inputting the forced separation mode and the forced connection mode, and when the forced separation mode and the forced connection mode are input to the input unit 480, the control unit 420 issues the connector forced control command. Output, and the motor driving unit 450 and the electronic clutch driving unit 460 respectively drive the motor driving signal and the electronic clutch driving signal to the driving motor 250 and the electronic clutch 240 according to the connector control control command of the control unit 420. It can be configured to send.

The driving motor 250, electronic clutch 240, UV lamp 370, fault detection sensors 411, 412, control unit 420, management communication unit 430, notification communication unit 440, motor driving unit ( 450), the power for the electronic clutch driving unit 460 and the UV lamp driving unit 470 may be configured to be supplied from a commercial power input in the tunnel 10 or from a charging battery charged by the commercial power.

The power for the distribution box terminal 441 may be configured to be supplied from a charging battery that is normally charged by commercial power.

The control means 400 may be configured in the control box and installed in the tunnel 10, and the battery may be installed in the tunnel 10.

Communication between the management communication unit 430 and the management center server 431 and the patrol terminal 432 may use wired or wireless communication, and communication between the notification communication unit 440 and the customer's distribution box terminal 441 is Wired communication can be used.

Hereinafter, the operation of the fault location notification system for each section of the underground distribution line according to the present invention will be described.

In the initial state of construction of the underground distribution line, the connector 100 is located in the middle portion between the first and second cables C1 and C2, and the first and second cables C1 and C2 are connected to the connector 100 ) Is inserted into both ends of the connecting sleeve 110 to be connected to each other (see FIGS. 1 to 3 and 9 (a)).

In this state, when a failure of the first and second cables C1 and C2 is detected by the failure detection sensors 411 and 412, the detection signals of the failure detection sensors 411 and 412 are transmitted to the control unit 420. The control unit 420 outputs a management information transmission command, a customer notification information transmission command, a connector control command, and an insulating film formation command according to the detection signals of the failure detection sensors 411 and 412.

At this time, the management information transmission command, the customer notification information transmission command, and the connector control command are preferentially output, and the insulation film formation command is output with a time difference.

In accordance with the management information transmission command, the management communication unit 430 transmits fault information to the management center server 431 and the patrol terminal 432, and according to the customer notification information transmission command, the notification communication unit 440 distributes the customer. The fault information is transmitted to the terminal 441.

The management center server 431 receiving the fault information stores the fault information in a database and displays it on a display, so that the manager checks the fault information in the management center, and management is performed according to a prescribed procedure, and the patrol terminal ( In 432), the fault information is stored in the database and displayed on the display, so that the patrol can check the fault information.

The distribution box terminal 441 of the customer who received the fault information displays the fault information on the display to allow the customer to check the fault information, for example, a power outage state and a scheduled recovery time. Since it is possible to check whether there is a wiring problem, there is no need to go outside and look around or contact the electric power company by telephone, so the inconvenience can be resolved, and the electric power company does not experience the inconvenience caused by a busy inquiries.

According to the connector control command of the control unit 420, the motor driving unit 450 transmits a separation direction driving signal of the driving motor 250, and an electronic clutch corresponding to the first and second cables C1 and C2 where a failure has occurred. 240 connects the drive shaft 220 and the pinion 230, and the drive motor 250 rotates in the separation direction.

The pinion 230 rotates in the separation direction according to the rotation direction of the driving motor 250, and the rack 210 and the insulator 120 coupled thereto are rotated by the gear action of the pinion 230 and the rack 210. The containing connector 100 is moved in the separation direction (left in the drawing).

The first cable C1 and the second cable C2 are separated according to the movement of the connector 100 in the separation direction (see FIG. 9 (b)).

At this time, the first cable C1 may be pushed or bent to the left along with the connector 100.

On the other hand, power is not applied to the electronic clutch 240 corresponding to the first and second cables C1 and C2 in which a failure has not occurred, and the pinion 230 corresponding thereto is in a state of turning against the drive shaft 220 The first and second cables C1 and C2, which are maintained as and have no failure, are connected by the connector 100 to maintain normal distribution.

On the other hand, since the connection operation of the first and second cables C1 and C2 by the connector 100 may be performed in the reverse direction to the above-described operation, a detailed description thereof will be omitted.

The above-described operation may be performed in the same manner even when the forced separation mode or forced connection mode of the input unit 480 is input.

In addition, the first and second liquid discharge pipes 321 and 322 while the opening and closing plugs 341 and 342 and the opening and closing plate 350 coupled to the insulator 120 of the connector 100 are moved through the interlocking bracket 360. This is opened and the upper opening of the mixed discharge container 330 is opened, so that the first and second liquids L1 and L2 in the two-liquid resin container 310 are through the first and second liquid discharge pipes 321 and 322. Discharged, the discharged first light second liquid (L1, L2) is introduced into the mixed discharge container 330 and mixed, and the mixed solution is removed through the mixed liquid discharge hole 331 formed at the bottom of the mixed discharge container 330. 2 It is discharged around the exposed conductor (C21) of the cable (C2).

When the injected first liquid L1 and the second liquid L2 are mixed, room temperature curing starts. Since the room temperature curing takes about 24 hours, rapid curing is achieved in the present invention.

That is, according to the insulating film forming command of the control unit 420, the UV lamp driving unit 480 transmits a lighting driving signal to the UV lamp 340, and accordingly, the UV lamp 340 is turned on so that the injected first and first The two liquids L1 and L2 are irradiated with UV, and accordingly, the mixed first and second liquids L1 and L2 are rapidly cured to form an insulating film IM (Fig. 9 (b)) Reference].

Therefore, the injected first and second liquids L1 and L2 are cured without flowing down to form a film within a desired range.

As the insulating film IM is formed around the ends of the second cable C2, the first cable C1 and the second cable C2 are connected, and the connecting sleeves 110 and the second of the connector 100 are connected. It is possible to prevent the occurrence of an arc between the cables C2 and the resulting fire.

Here, when the forced separation mode is input to the input unit 480, only the separation operation of the first and second cables C1 and C2 proceeds, and the operation of forming an insulating film may not proceed.

The embodiments described above are not intended to limit the technical spirit and scope of the present invention, but to illustrate, and the scope of the technical spirit of the present invention is not limited by the above-described embodiments, and it is common in the technical field to which the present invention pertains. Anyone who has the knowledge of will be able to make various modifications and variations without departing from the technical spirit and scope of the present invention, and such modifications and modifications should be interpreted as belonging to the scope of the present invention.

10: tunnel 20: shelf
30, 40: Tray 100: Connector
110: connecting sleeve 120: insulator
200: connector driving means 210: rack
220: drive shaft 230: pinion
240: electronic clutch 250: drive motor
300: insulating film forming means 310: two-component resin barrel
S1, S2: first and second liquid storage spaces 321, 322: first and second liquid discharge pipes
330: mixed discharge bin 331: mixed liquid discharge hole
341, 342: opening and closing block 350: opening and closing plate
370: UV lamp 400: control means
411, 412: fault detection sensor 420: control unit
430: management communication unit 440: notification communication unit
450: motor driving unit 460: electronic clutch driving unit
470: UV lamp driving unit 480: input unit

Claims (1)

The section of the underground distribution line where the first cable (C1) and the second cable (C2) are placed at intervals on the shelf (20) installed in multiple layers on the inner wall surface of the underground tunnel (10), which is a concrete structure installed in the ground. In the failure location notification system for each star,
In the middle of the shelf 20, an operating space 21 is formed, and a motor mount 22 is provided on the bottom surface.
A connector 100 installed between the first and second cables C1 and C2; Connector driving means (200) for driving the connector (100); An insulating film forming means 300 for forming an insulating film IM around the end of the second cable C2 separated from the first cable C1 by the connector 100; The connector driving means 200 and the control means 400 for controlling the insulating film forming means 300; is further configured to include,
The connector 100 is formed of a conductive material and has inner diameters corresponding to outer diameters of the exposed conductors C11 and C21 of the first and second cables C1 and C2, and the first and second cables formed at both ends of the front and rear. A connecting sleeve 110 provided with a cylindrical portion 111 on which the entrances 112a and 112b are formed, and an outward flange portion 113 extending on both front and rear ends of the cylindrical portion 111; An insulator 120 surrounding the cylindrical portion 111 of the connection sleeve 110, the outward flange portion 113 is buried, and first and second cable entrances 121a and 121b are formed at both ends; And a rack coupling unit 130 formed integrally under the insulator 120 and extending in the front-rear direction.
The first and second cable entrances 112a and 112b of the connection sleeve 110 are formed with tapered portions gradually narrowing while going inward, and the first and second cable entrances 121a and 121b of the insulator 120 are formed. A taper portion gradually narrowing as it goes inward is formed, so that the entry of the first and second cables C1 and C2 to the first and second cable entrances 112a and 112b and 121a and 121b can be made smoothly. And
The connector driving means 200 is respectively coupled to the lower surface of the rack coupling portion 130 of the connector 100 and installed in the longitudinal direction of the first cable C1 and the second cable C2, and the gear portion is provided on the lower surface. A plurality of racks 210 provided with (211), a drive shaft 220 installed in a direction perpendicular to the longitudinal direction of the first cable (C1) and the second cable (C2) 220, and the rack 210 ), A plurality of pinions 230 which are disposed on the lower portion and meshed with the gear part 211 and are installed in the drive shaft 220 and the drive shaft 220 installed between the drive shaft 220 and the pinion 230. It comprises an electronic clutch 240 to allow the rotational force of the pinion 230 to be transmitted or blocked, and a driving motor 250 mounted on a lower surface of the shelf 20 to rotate and drive the driving shaft 220 ,
The insulating film forming means 300 is fixed to the shelf 20 and the two-part resin container 310 divided into first and second liquid storage spaces S1 and S2 in which the inner space is partitioned by the partition 311. and,
The first and second liquid discharge pipes 321 and 322 connected to the lower end of the two-component resin container 310 and connected to the first and second liquid storage spaces S1 and S2 and opened toward the left,
Located in the lower portion of the two-component resin container 310, the first and second liquid discharge pipes 321 and 322 receive and mix the first and second liquids L1 and L2 supplied through upper openings, A mixed discharge container (330) having a mixed liquid discharge hole (331) discharged around the conductor (C21) of the second cable (C2) with the mixed liquid (L3) at the bottom,
Opening and closing plugs (341, 342) for opening and closing the left open end of the first and second liquid discharge pipes (321, 322),
And the opening and closing plate 350 for opening and closing the upper opening of the mixed discharge container 330,
Interlocking bracket 360 is fixed to the upper surface of the insulator 120 is installed vertically, the left end of the opening and closing plugs 341, 342 and the left end of the opening and closing plate 350 is coupled,
It comprises a UV lamp 370 coupled to the right side of the mixed discharge container 330 for irradiating UV to the discharged mixed solution,
The two-component resins stored in the first and second spaces S1 and S2 of the two-component resin container 310 are disposed in the first liquid L1 and the second space S2 stored in the first space S1. Consists of a second liquid (L2) that is stored, and when irradiated with UV for 5 seconds in a state in which the first liquid (L1) and the second liquid (L2) are mixed, it hardens and flows rapidly when it is dispensed. A two-component epoxy resin capable of forming an insulating film (IM) around the end of (C2) is used,
The control means 400 is installed on the first cable (C1) and the second cable (C2) fault detection sensors (411, 412) for detecting whether or not a failure; A control unit 420 for outputting a management information transmission command, a customer notification information transmission command, a connector control command, and an insulating film formation command according to the detection signals of the first and second fault detection sensors 411 and 412; A management communication unit 430 for transmitting management information to the management center server 431 and the patrol terminal 432 according to the management information transmission command of the control unit 420; A notification communication unit 440 for transmitting the consumer notification information to the distribution box terminal 441 of the prisoner according to the instruction for sending the consumer notification information of the control unit 420; A motor driving unit 450 for transmitting a motor driving signal to the driving motor 250 of the connector driving means 200 according to the connector control command of the control unit 420; An electronic clutch driving unit 460 that transmits an electronic clutch driving signal to the electronic clutch 240 of the connector driving means 200 according to the connector control command of the control unit 420; And a UV lamp driving unit 470 that transmits a UV lamp driving signal to the UV lamp 370 according to the insulating film formation command of the control unit 420. A real-time remote monitoring system for an underground distribution line.

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