KR101592964B1 - Method for hot line work of power distribution equipment - Google Patents

Abstract

Disclosure of the Invention The present invention relates to a method of operating a distribution facility live wire. The present invention provides a method of operating a distribution facility live line comprising the steps of: fixing a flexible neck to an electric pole; separating the suspended insulator provided in the pole from the existing built-in flexible iron and connecting it to a wire support provided on the flexible neck; A step of dismounting the electric wire from the existing built-in iron wire, removing the existing built iron wire from the electric pole and installing a new built-in iron wire on the electric pole, a step of moving the wire supporting part upward to the newly built built iron wire, And separating the wire from the wire support and connecting the wire with the new built-in wire.

Description

METHOD FOR HOT LINE WORK OF POWER DISTRIBUTION EQUIPMENT

The present invention relates to a method of operating a distribution facility live wire, and more particularly, to a distribution facility live wire work method for replacing a built-in complete wire installed in an electric pole using an auxiliary device for live distribution facility operation.

Generally, a long shaft is installed at the upper part of the pole, and the shaft is made up of three insulators installed in the horizontal and vertical bars. The three phase wires are bound to each of the three insulators by a binder.

In managing the installed Jeonju, Jangju, and Agate, it is necessary to replace the existing insulator with a new insulator, replace the old Jeju with a new pole, replace the existing pole with a new pole, And the work of replacing the pin main shaft with the built main shaft has been carried out. In addition, the construction of new distribution facilities such as the construction of Jeonju due to the change of the extension position of the electric wire is also being carried out.

Such a work is carried out while moving a wire in a live wire state in which electricity is running, either upward or downward or in a lateral direction, thereby causing a risk of a safety accident. Accordingly, various devices and methods have been developed to smoothly perform live-line operations while reducing the risk of such safety accidents.

Related prior art is disclosed in Korean Patent Laid-Open Publication No. 2006-0082713 (published on Sep. 19, 2006, entitled "Multi-axis Robot for Distribution Line Working with Two-dimensional and Three-Dimensional Composite Driving Means").

It is an object of the present invention to provide a method of operating a distribution facility live line which can more safely and smoothly perform a distribution facility live-line operation in which a built-in surplus iron is replaced while an operator moves a wire automatically by using an electric power at a remote distance from the electric line .

The present invention provides a method of operating a live distribution line of a distribution facility, comprising the steps of: Separating a suspending insulator provided in the electric pole from the existing built-in wire and connecting it to a wire supporting portion provided on the elastic neck; Moving the wire support portion connected to the suspending insulator downward to separate the wire from the existing built-in buried iron; Removing the existing built-in wrought iron from the electric pole and installing a new built-in wrought iron on the electric pole; Moving the wire supporting portion upward to the newly built built-in buried iron; And separating the suspending insulator from the wire supporting portion and connecting the new built-in buried iron to the wire supporting portion.

The upward or downward movement of the wire support portion may be achieved by moving the entire wire support portion up and down by operating the lifting / lowering portion or by moving the sub-extension portion located above the wire support portion up and down desirable.

The upward and downward movement of the wire support portion can be achieved by moving the entire wire support portion up and down by operating the lifting and moving portion and by vertically moving the sub extension portion located above the wire support portion, .

The step of separating the suspending insulator from the existing built-in burial iron and connecting the suspending insulator to the wire supporting portion may include separating a connection portion of the suspending insulator from the existing built-in burial iron from the existing built- Wherein the step of connecting the suspending insulator connected to the wire supporting portion to the new built-in rigid iron separates the connecting portion of the suspending insulator from the insulator restricting portion from the insulator restricting portion, And bonding it to solid iron.

In addition, it is preferable that the existing built-in wrought iron and the newly-built wandering iron have a horizontal arrangement of usually a longitudinal groove.

According to the present invention, it is possible to easily perform the replacing operation of the built-in complete iron by automatically adjusting the height of the entire wire supporting portion, the height of the suspending insulator and the electric wire hanging on the insulator restraining portion by using the electric power of the actuator .

Further, according to the present invention, it is possible to apply an electric power tool such as an electric drill or an electric screwdriver, which is used for replacing electric power distribution equipment, as an actuator, thereby facilitating an operator without the hassle of having a separate electric device for moving the electric wire support portion You can do it.

In addition, according to the present invention, an operator can perform an operation of separating an electric wire from an electric wire at an upper portion of a suspending jig using an actuator, so that a work space for replacing a built-in electric wire can be easily secured.

Further, according to the present invention, since the wire supporting portion is moved first by using the actuator and the sub extending portion is moved by the second movement, the working space necessary for the live wire working can be further expanded. It is possible to reduce the risk of a safety accident caused by contact.

According to the present invention, the entire process of raising and lowering the wire support by using the actuator, switching the wires, and replacing the built-in wrought iron is performed on a short copper wire that does not exceed the width of the existing built- So that the working efficiency can be further improved.

According to the present invention, it is possible to easily carry out work while lifting and lowering the wire supporting portions individually in accordance with the height of each of the suspending insulators by using the lifting / lowering portion in the operation of replacing the built- And it is possible to smoothly carry out the work while adjusting the mounting position up and down even in the case where it is difficult to attach the tool or the apparatus used for live wire work.

FIG. 1 is a perspective view schematically showing an auxiliary device for working on a live distribution line according to an embodiment of the present invention. Referring to FIG.
2 is a perspective view schematically showing a wire support portion and a lifting / lowering portion according to an embodiment of the present invention.
3 is a conceptual diagram illustrating operation of the lifting / lowering unit according to an embodiment of the present invention.
4 is a conceptual diagram illustrating a process of inserting a wire into a wire restraining unit according to an embodiment of the present invention.
FIG. 5 is a flowchart illustrating a method of operating a distribution facility live line according to an embodiment of the present invention.
FIG. 6 is a conceptual diagram illustrating a process of fixing a flexible neck to a pole in a live wire working method according to an embodiment of the present invention. Referring to FIG.
FIG. 7 is a conceptual diagram illustrating a process of upwardly moving a wire support portion to a suspender in the method of operating a distribution facility live wire according to an embodiment of the present invention. Referring to FIG.
8 is a conceptual diagram illustrating a process of separating a suspending insulator from a conventional built-in wrought iron and connecting it to a wire supporting part in a live wire working method of a power distribution facility according to an embodiment of the present invention.
FIG. 9 is a conceptual diagram illustrating a process of moving a wire support portion downward to separate a wire from an existing built-in wrought iron in a live wire working method according to an embodiment of the present invention.
10 is a conceptual diagram illustrating a process of replacing an existing built-in wrought iron with a new built-in wrought iron according to an embodiment of the present invention.
FIG. 11 is a conceptual view illustrating a process of upwardly moving a wire support portion to a new built-in wrought iron in a method of operating a distribution facility live wire according to an embodiment of the present invention.
FIG. 12 is a conceptual diagram illustrating a process of separating a suspending insulator from a wire support and connecting a new built-in soldering iron in a method of operating a distribution facility live wire according to an embodiment of the present invention.
FIG. 13 is a conceptual view illustrating a process of removing a loose neck portion from a pole in a live wire working method of a distribution facility according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

First, an auxiliary equipment 500 for operating a distribution facility according to the present invention will be described.

FIG. 1 is a perspective view schematically showing an auxiliary device for working on a live distribution line according to an embodiment of the present invention. Referring to FIG.

Referring to FIG. 1, an auxiliary equipment 500 for operating a power distribution facility according to an embodiment of the present invention includes a flexible neck 510, a loosening machine 520, a wire support 540, and a lifting / do.

The flexible neck 510 is fixed to the electric pole 10 and forms a frame supporting the electric wire supporting portion 540 and the load of the electric wire 30 bound to the electric wire supporting portion 540. The flexible neck 510 according to an embodiment of the present invention includes a horizontal extension portion 511 and a support portion 515.

The horizontal extending portion 511 is formed to extend in the horizontal direction. The horizontal extending portion 511 is disposed in parallel with the wrought iron 21 installed on the electric pole 10 in a state where the horizontal extending portion 511 is fixed to the electric pole 10 by the horizontal rod connecting portion 521. [ One or a plurality of wire supporting portions 540 are provided on the horizontal extending portion 511.

The supporting portion 515 has a bar shape and is provided between the horizontal extending portion 511 and the electric pole 10 so as to be inclined and supports the horizontal extending portion 511. The upper portion of the support portion 515 is rotatably connected to the link member 516 provided at the end of the horizontal extension portion 511 and the lower portion of the support portion 515 is connected to the support portion connection portion 525 provided on the pole 10 . The support portion 515 supports the horizontal extension portion 511 at the lower side with reference to the connection portion between the electric pole 10 and the support arm connection portion 525 by the above connection structure.

The link member 516 is provided on the horizontal extending portion 511 in such a manner that the link member 516 is inserted into the end portion of the horizontal pivotal connection portion 521 and then a bolt member such as an eye bolt is screwed to one side portion of the link member 516 So that the link member 516 and the horizontal extending portion 511 are brought into close contact with each other.

The loosening neck fixing portion 520 is a portion for fixing the loose neck portion 510 to the electric pole 10. The loosening bridging unit 520 according to an embodiment of the present invention includes a horizontal bar connecting portion 521 and a supporting bar connecting portion 525.

The horizontal bar connecting portion 521 connects the horizontal extending portion 511 and the electric pole 10 and includes a pole connecting portion 522 connected to the pole 10 and a horizontal bar connecting portion 521 connected to the horizontal extending portion 511. [ (523) are integrally connected. The electric pole connection portion 522 has a clamp structure which is detachable to the electric pole 10 and the fixed connection portion 523 has a shape such that the horizontal extending portion 511 can penetrate in the lateral direction like the link member 516.

The horizontally extending portion 511 is provided on the electric pole 10 by inserting the electric pole connection portion 522 of the horizontal pole connection portion 521 into the electric pole 10 and fixing the electric pole 10 by using a fastening member such as an eye bolt and an eye nut The bolt member such as an eye bolt is passed through one side portion of the fastener connecting portion 523 and the horizontal extending portion 511 is inserted into the fastener connecting portion 523 connected to the pole connecting portion 522 in the lateral direction, So that the horizontal extending portion 511 and the fastener connecting portion 523 are brought into close contact with each other. On the contrary, the horizontally extending portion 511 is provided on the electric pole 10 by fixing the horizontally extending portion 511 to the rigid connection portion 523, ) To the electric pole (10).

The supporter connecting portion 525 is a portion connecting the supporter 515 to the electric pole 10. The supporter connecting portion 525 has a clamp structure detachable from the electric pole 10 and is provided at a lower portion of the horizontal abutment portion 521. [

Generally, the clamp is a member used to entangulate the first member with the second member. The clamp has a "C" shape or a C shape so as to cover the second member, or a belt shape, And a coupling member such as a nut is coupled. In one embodiment of the present invention, the relaxed gripper 520 has a clamping structure, but is not limited to a specific structure and shape if the flexible neck 510 can be fixed to the electric pole 10.

FIG. 2 is a perspective view schematically showing a wire supporting portion and a lifting / lowering moving portion according to an embodiment of the present invention, FIG. 3 is a conceptual view illustrating operation of the lifting / lowering moving portion according to an embodiment of the present invention, FIG. 3 is a conceptual diagram illustrating a process of inserting a wire into a wire restraining unit according to an embodiment of the present invention.

The wire support portion 540 is a portion that supports and receives a wire 30 connected to the electric pole 10 in a state where the wire support portion 540 is installed on the elastic neck portion 510. Referring to FIG. 2, the wire support 540 according to an embodiment of the present invention includes an extension portion 541, a wire restraining portion 545a, and an insulator restraining portion 545b.

The extension portion 541 has a vertically extending shape and is installed on the horizontal extending portion 511 and is moved up and down by the lifting / The extension portion 541 according to an embodiment of the present invention includes a main extension portion 542, a sub extension portion 543, and a fixing portion 544.

The main extension part 542 is connected to the lifting / lowering part 550 and is vertically moved by the lifting / moving part 550 which is driven by receiving power from the actuator 41. The sub extension part 543 is made of an insulating material and is installed in the cylindrical main extension part 542 with the lower part inserted therein and is moved to the upper part of the main extension part 542. That is, the sub extension portion 543 is provided to be capable of projecting and retracting to the upper portion of the main extension portion 542.

The fixing portion 544 fixes the upwardly displaced sub-extension 543 on the main extension 542. As the fixing portion 544, a rotating fixture, a through hole penetrating through the sub extension portion 543 and the main extension portion 542, and the like can be applied.

When the rotary fastener is used as the fixing portion 544, the sub-extending portion 543 is fixed to the main extending portion 542 by a rotation operation in which the fixing portion 544 is turned to one side, The coupling between the extension portion 543 and the main extension portion 542 can be released. The length of the extension portion 541 may be adjusted by moving the sub extension portion 543 to a desired height and fixing the sub extension portion 543 using the fixing portion 544 Can be adjusted manually.

The sub extension portion 543 is formed by a structure in which the arm body coupling portion and the water coupling portion are formed at the connection portion between the sub extension portion 543 and the main extension portion 542 without a separate fixing portion 544, The sub extension portion 543 is fixed to the main extension portion 542 by moving the sub extension portion 543 to the other side by rotating the sub extension portion 543 to the other side, ) Can be released.

On the other hand, when the cylinder member is used as the extended portion 541, the action of moving the sub-extended portion 543 to the upper portion of the main extended portion 542 can be implemented automatically and remotely. At this time, the main extension part 542 corresponds to the cylinder part of the cylinder, and the sub extension part 543 corresponds to the rod part. As a device for forming the hydraulic or pneumatic pressure in the main extension portion 542, a hydraulic device, a pneumatic device, or the like can be applied.

When the hydraulic device increases the internal pressure of the main extension portion 542, the sub extension portion 543 is moved to the upper portion of the main extension portion 542 by the pressure formed inside the main extension portion 542. Conversely, when the hydraulic device is operated to initialize the internal pressure of the main extension portion 542, the internal pressure of the main extension portion 542 is reduced and the sub extension portion 543 is lowered and returned to the initial position.

The wire restricting portion 545a is formed on the upper portion of the sub extension portion 543 as a portion where the electric wire 30 is caught. The wire restricting portion 545a restrains the electric wire 30 from being arbitrarily detached from the wire supporting portion 540. [ Referring to FIG. 4, in one embodiment of the present invention, the wire restraining portion 545a includes a bracket portion 546 and a lock portion 548.

The bracket portion 546 is connected to the extension portion 541, and an opening portion 546a through which the electric wire 30 can pass is formed. The locking portion 548 is connected to the bracket portion 546, and opens and closes the opening portion 546a. The opening portion 546a is formed on the upper portion of the bracket portion 546 and the locking portion 548 is pivotally connected to the one end portion of the bracket portion 546. In this embodiment,

The locking portion 548 is caught by the other end of the bracket portion 546 to close the opening portion 546a when the locking portion 548 is rotated to one side The locking portion 548 is separated from the other end of the bracket portion 546 to open the opening portion 546a (see Fig. 4). By operating the locking portion 548 as described above The electric wire 30 can be held by the electric wire restraining part 545a while the opening part 546a is opened or closed or the electric wire 30 can be separated from the electric wire restraining part 545a.

On the bracket portion 546, a lower roller 547 is rotatably installed in a fixed position, and an upper roller 549 is rotatably installed on the lock portion 548 in a fixed position. The outer surface of the electric wire 30 is brought into contact with the lower roller 547 and the upper roller 549 while the electric wire 30 is inserted into the bracket portion 546 and the lock portion 548 is filled. That is, in a state in which the electric wire 30 is fitted in the electric wire restraining part 545a, the electric wire 30 comes into a state of rolling contact with the electric wire restraining part 545a.

Accordingly, it is possible to prevent the electric wire 30 from being damaged by the electric wire restraining part 545a when the relative displacement between the electric wire restraining part 545a and the electric wire 30 occurs in the process of replacing the electric power distribution facility, The wire restraining part 545a or the electric wire 30 can be smoothly moved while the state where the part 545a and the electric wire 30 are mutually coupled stably.

The insulator restricting portion 545b is a portion where the end of the suspending insulator 22 is caught, and is provided on the sub extending portion 543. The insulator restricting portion 545b binds the suspension insulator 220 so as not to be arbitrarily detached from the wire support portion 540. [ Referring to FIG. 2, an insulator restricting portion 545b according to an embodiment of the present invention includes a main body portion 545c and a ring portion 545d.

The main body 545c is a portion coupled to the sub-extension 543. [ In an embodiment of the present invention, the main body 545c has a cylindrical shape and has a structure in which it is fitted and joined to the sub extension portion 543. In addition, the main body 545c may be provided in the sub extension portion 543 with a detachable structure such as a clamp structure, a chained structure, or the like.

The ring portion 545d is a portion connected to the end portion of the suspending insulator 220. The hook 545d is disposed symmetrically with respect to the sub-extension 543 or the main body 545c so as to connect a pair of suspending insulators 220 connected to one electric wire 30 A pair is provided. The hook portion 545d is integrally connected to the main body portion 545c and is detached from the sub extending portion 543 by detaching the main body portion 545c from the sub extending portion 543. [

In one embodiment of the present invention, the insulator restraining portion 545b has a structure provided below the wire restraining portion 545a, but may be joined onto the bracket portion 546 of the wire restraining portion 545a, Or on the main extension 542 of the sub extension 543 in accordance with FIG.

The lifting and lowering moving part 550 moves the wire supporting part 540 up and down. The lifting and lowering unit 550 is provided to independently lift and support the wire supporting units 540. Accordingly, the number of the lifting / moving portions 550 is determined in proportion to the number of the wire supporting portions 540. Referring to FIG. 3, the lifting / lowering moving unit 550 according to an embodiment of the present invention includes a lifting unit 551 and a driving unit 553.

The fastener mounting portion 551 is provided on the horizontal extending portion 511. [ The fastener mounting portion 551 has a clamp structure and is detachably coupled to the horizontal extending portion 511 by fastening members such as an eye bolt and an eye nut. A guide portion 552 for guiding the upward and downward movement of the wire support portion 540 is formed on the fastener mounting portion 551 and a hollow guide hole portion 552a extending upward and downward is formed on the guide portion 552. The wire supporting portion 540 is lifted and moved in conjunction with the operation of the lifting / lowering portion 550 in a state of being fitted in the guide hole portion 552a.

The driving unit 553 is installed in the door mounting unit 551 and receives the power from the actuator 41 to move the wire supporting unit 540 up and down. Here, as the actuator 41, a power tool such as an electric drill, an electric screwdriver, or a drive device such as a motor, which is generally used in a work for replacing a power distribution facility, can be applied. The driving unit 553 includes a power transmitting unit 554, a shaft cylinder 557, and a belt unit 558 according to an embodiment of the present invention.

The power transmitting portion 554 is rotationally driven by the actuator 41. [ In an embodiment of the present invention, the power transmitting portion 554 includes a worm 555 and a worm wheel 556. [

A power input portion 555a engaged with the actuator 41 is formed at an end of the worm 555 to receive a rotational force from the actuator 41. [ The worm wheel 556 meshes with the worm 555, is installed coaxially with the shaft tube 557, and rotates in conjunction with the worm 555. When the power tool is applied to the actuator 41, the worm 555 is rotated in conjunction with the rotation of the actuator 41, and the worm wheel 556 is rotated in conjunction with the rotation of the worm 555 to rotate at a reduced speed, .

According to the worm gear structure having the worm 555 and the worm wheel 556 as described above, it is possible to transmit the rotational power only to the worm wheel 556 side from the worm 555 side and to the worm 555 side from the worm wheel 556 side. The rotational power is not transmitted. That is, by applying a rotational force to the worm wheel 556, the worm 555 can not be rotated and the worm wheel 556 can not be rotated.

The worm wheel 556 is connected to the wire supporting portion 540 by the shaft portion 557 and the belt portion 558. According to the worm gear structure described above, since the load of the wire 30 or the like causes the wire supporting portion 540 It is possible to prevent downward movement.

The shaft portion 557 is rotated to one side or the other side by the power transmission portion 554 to wind or unwind the belt portion 558. [ The shaft portion 557 has a cylindrical outer circumferential portion around which the belt portion 558 can be wound and is coaxially connected to the worm wheel 556.

The belt portion 558 is wound around the shaft barrel 557 and the end portion is connected to the wire support portion 540. Here, as the belt portion 558, a general belt having a flat rectangular or linear sectional shape, or a linear member such as a wire or a rope can be applied. The end of the belt portion 558 is connected to the extension portion 541 by a coupling member that can be coupled and separated such as a hook or the like.

When the actuator 41 is rotated to one side with the end of the actuator 41 engaged with the power input portion 555a, the rotational force is transmitted to the shaft portion 557 through the power transmission portion 554 so that the shaft portion 557 The belt portion 558 is wound on the shaft tube portion 557 and the wire support portion 540 connected to the end portion of the belt portion 558 is pulled upward. When the actuator 41 is rotationally driven to the other side, the shaft cylinder 557 is rotated to the other side, the belt portion 558 is released and the wire support portion 540 is moved downward.

The height of the entire wire support portion 540 or the height of the sub extension portion 543 can be automatically adjusted by using the actuator 41 as described above.

More specifically, by using the actuator 41, the entire wire support portion 540 can be moved more closely to the electric wire 30, or the height of the sub-extended portion 543 can be adjusted by the second order The height of the insulator restricting portion 545b connected to the upper portion of the sub extension portion 543 can be finely adjusted or the total length of the wire support portion 540 can be adjusted.

In addition, according to the present invention, by applying the electric power tool generally used for replacing the power distribution unit as the actuator 41, the height of the insulator restraining portion 545b formed on the upper portion of the wire support portion 540 is set to the power Can be adjusted automatically.

According to the present invention, the wire supporting portion 540 supporting the weight of the electric wire 30 can be moved up and down using the electric power of the actuator 41 so that the electric wire 30 can be moved It is possible to smoothly carry out the live wire work without the hassle of moving up and down.

In addition, according to the present invention, the electric wire supporting portion 540 or the electric wire 30 can be accurately positioned at a desired height while moving the electric wire supporting portion 540 or the electric wire 30 at a constant speed by using the actuator 41 and the lifting and moving portion 550.

Next, a built-in wired iron 21 installed in the main shaft 20 is newly installed by using the auxiliary equipment 500 for operating the power distribution equipment according to the present invention having the above- A method of operating a distribution facility live line according to the present invention for replacing the built-in solid brass 24 will be described.

Here, the general shaft 20 is generally divided into a plurality of insulators, which are distributed on one side of the electric pole 10, in such a manner that the insulators are dispersed on one side and the other side with respect to the electric pole 10 It means the structure of the long river. When the existing built-in wrought iron 21 and the new built-in wrought iron 24 have the structure of the ordinary shaft 20, the operator is placed on the spaced apart space between the insulators distributed on one side and the other side with respect to the pole 10 To perform live-line operations.

FIG. 5 is a flowchart illustrating a method of operating a distribution facility live line according to an embodiment of the present invention.

5, a method of operating a distribution facility live wire according to an embodiment of the present invention includes a step S1 of fixing the flexible neck 510 to the electric pole 10, a step S1 of fixing the flexible wire 510 540 to the suspending insulator 22 connected to the electric pole 10 and separating the suspending insulator 22 provided in the electric pole 10 from the existing built-in wrought iron 21, (S4) of moving the electric wire (30) from the existing built-in wrought iron (21) by moving downward the wire supporting portion (540) connected to the suspending insulator (22) A step S5 of removing the existing built-in wrought iron 21 and installing a new built-in wrought iron 24 in the electric pole 10 and a step S6 of moving the wire supporting portion 540 upward to the new built- A step S7 of separating the suspending insulator 22 from the wire supporting part 540 and connecting the suspension insulator 22 to the newly built integrated bar 24 and the step S8 of removing the elastic supporting part 510 from the electric pole 10 .

FIG. 6 is a conceptual view for explaining a process of fixing a flexible neck part to a pole in a power distribution method live wire working method according to an embodiment of the present invention, and FIG. 7 is a flowchart illustrating a method of operating a distribution facility live wire according to an embodiment of the present invention. FIG. 8 is a schematic view illustrating a process of upwardly moving the wire support portion to the suspender insulator. FIG. 8 is a flowchart illustrating a process of separating the suspension insulator from the existing built- FIG.

FIG. 9 is a conceptual diagram illustrating a process of moving a wire support portion downward to separate a wire from an existing built-in wrought iron according to an embodiment of the present invention. FIG. 11 is a schematic view illustrating a process of replacing an existing built-in wrought iron with a new built-in wrought iron according to an embodiment of the present invention. FIG. 2 is a conceptual diagram illustrating a process of upwardly moving the image.

FIG. 12 is a conceptual view illustrating a process of separating a suspending insulator from a wire supporting part and connecting the suspension insulator to a new built-in soldering iron in the method of working a distribution line live wire according to an embodiment of the present invention. This is a conceptual diagram that illustrates the process of demolishing the elongated neck from the pole in the operation method of live distribution equipment.

6, a step S1 of fixing the flexible neck 510 to the electric pole 10 is performed by fixing the flexible neck 510 to the electric pole 10 using the flexible rope fixing unit 520, The lifting and moving part 550 and the wire supporting part 540 are fixed on the flexible neck part 510 so as to correspond to the positions of the insulators 22, respectively.

The horizontal extending portion 511 is first fixed to the electric pole 10 by using the horizontal bar connecting portion 521 and then the link member 516 and the supporting bar connecting portion 525 between the horizontally extending portion 511 and the electric pole 10 in order to install the support portion 515. [

The lifting and lowering moving part 550 and the wire supporting part 540 are fixed on the reinforcing neck part 510 by fixing the lifting and lowering moving part 550 on the retracting neck part 510, (540) are combined with each other. Also, after the wire supporting portion 540 is coupled to the lifting moving portion 550, the elevating moving portion 550 may be fixed on the reinforcing neck portion 510.

The step S1 of fixing the loose neck 510 to the electric pole 10 is performed by using the loose neck part 510 with the lifting and moving part 550 and the wire supporting part 540 already installed, (10).

7, the step S2 of upwardly moving the wire supporting portion 540 provided on the flexible neck portion 510 toward the suspending insulator 22 connected to the electric pole 10 is performed by moving the sub extending portion 543 upward Process. By moving the sub extension portion 543 upward, the insulator restraint portion 545b coupled to the sub extension portion 543 is moved upward to the same displacement.

The step S2 of moving the wire support portion 540 upward to the suspender 22 may be performed by simply moving the main extension portion 542 upward according to working conditions or an operator's convenience . The step S2 of upwardly moving the wire supporting portion 540 toward the suspender 22 may include a process of moving the main extending portion 542 upward by the actuator 41 and the lifting and moving portion 550, And moving the unit 543 upward.

Moving the wire support portion 540 upward or downward in the description of the present invention means moving the wire support portion 540 including the main extension portion 542 and the sub extension portion 543 by moving the main extension portion 542, An insulator restricting portion 545b connected to the electric wire 30 in the wire supporting portion 540 including an embodiment in which the whole of the electric wire supporting portion 540 is moved or only the sub extension portion 543 formed on the upper portion of the wire supporting portion 540 is moved That is, the height of the upper portion of the wire supporting portion 540 is adjusted upwardly or downwardly.

The step S3 of separating the suspending insulator 22 provided in the electric pole 10 from the existing built-in wrought iron 21 and connecting the electric wire supporting portion 540 with the electric wire supporting portion 540 is performed by the electric wire 30 connected to the electric pole 10 and the built- ) To the wire supporting portion 540. [0054]

8, a step S3 of separating the suspending insulator 22 from the existing built-in burr 21 and connecting it with the wire supporting portion 540 is performed by connecting the connection portion with the existing built-in burr 21 of the suspending insulator 22 And then connecting them to the wire supporting part 540. [0052] As shown in FIG. This process is performed for each of a plurality of sets of suspending insulators 22.

The two insulators 22 are connected to one electric wire 30 in pairs. In the description of the present invention, a pair of suspension insulators 22 connected to one electric wire 30 is referred to as a suspension insulator 22 set.

The suspension insulator 22 is separated from the existing built-in wrought iron 21 by using a live wire harness and a hoist link stick. The first worker and the second worker simultaneously connect the live wire harnesses to each of the pair of suspension insulators 22 and adjust the distance (Dip) of the wire 30 while giving the same tension, Can be prevented from being twisted. Here, the diagram represents the extent to which the electric wire 30 sags.

In general, the pair of suspension insulators 22 are installed at a distance corresponding to the diameter of the electric pole 10, and the flexible arm portion 510 is installed at one side of the pair of suspension insulators 22 do. Accordingly, one side of the pair of suspending insulators 22 is directly connected to the wire supporting portion 540, and the other side is connected to the wire supporting portion 540 via the hoist link stick.

The binding of the suspending jig 22 to the wire supporting portion 540 is performed by a process of fastening one end of the suspending jig 22 to the hook portion 545d provided in the retaining portion 545b. When the insulator restricting portion 545b has a structure that can be detached on the extension portion 541, the installation of the insulator restricting portion 545b on the extension portion 541 can be performed any time before the suspending insulator 22 is bound It is possible.

Step S4 of moving the electric wire 30 away from the existing built-in wrought iron 21 by moving the electric wire supporting portion 540 connected to the suspending insulator 22 downward, This is the process of securing a work space for replacement.

9, the step S4 of moving the wire supporting part 540 downward to separate the electric wire 30 from the built-in wrought iron 21 may be carried out by moving the actuator 41 at a position spaced apart from the electric wire 30, And the main extension portion 542 of the wire support portion 540 is automatically and remotely moved downward by using the lifting / lowering portion 550.

The step S4 of moving the wire supporting part 540 downward to separate the electric wire 30 from the built-in wrought iron 21 may include a step of moving the sub extending part 543 downward according to working conditions or the operator's convenience May be accomplished by performing only < / RTI > The step S4 of moving the wire supporting portion 540 downward and separating the wire 30 from the built-in wrought iron 21 may include moving the entire wire supporting portion 540, that is, moving the main extending portion 542 downward And a process of downwardly moving the sub-extension 543 may be performed.

10, the step S5 of removing the existing built-in wrought iron 21 from the electric pole 10 and installing the new built-in wrought iron 24 to the electric pole 10 moves the electric wire supporting portion 540 downward, The built-in wrought iron 21 is removed from the electric pole 10 by utilizing the work space secured through the step S4 of separating the electric wire 30 from the wired built-in iron 21, (24).

11, the step S6 of upwardly moving the wire supporting portion 540 toward the newly installed built-in ferrule 24 allows the operator to move the actuator 41 and the lifting / lowering moving portion 550 at a position apart from the electric wire 30 The main extension portion 542 of the wire support portion 540 is automatically and remotely moved upward.

The step S6 of upwardly moving the wire support portion 540 toward the newly built integrated iron bar 24 may be performed by only performing the upward movement of the sub extension portion 543 according to the working conditions or the operator's convenience have. The step S6 of upwardly moving the wire support portion 540 toward the new built-in brass rail 24 may include a process of moving the entire wire support portion 540 upward, that is, a process of upwardly moving the main extension portion 542, And then moving up the moving object.

The step S7 of separating the suspending insulator 22 from the wire supporting portion 540 and connecting the suspension insulator 22 to the new built-in full iron bar 24 is performed in such a manner that the electric wire 30 connected to the wire supporting portion 540 is connected to the built- Process.

12, the step S7 of separating the suspending insulator 22 from the wire supporting portion 540 and connecting it with the newly installed built-in bar 24 includes the step of inserting one end of the suspending insulator 22 connected to the wire supporting portion 540 And then is separated from the wire supporting portion 540 and then connected to the new built- This process is performed for each of a plurality of sets of suspending insulators 22.

The separation of the suspending insulator 22 from the wire support 540 is accomplished by separating one end of the suspending insulator 22 hooked on the hook 545d from the hook 545d.

The connection of the suspension insulator 22 to the new built-in hollow iron 24 is performed by using a live wire harness and a hoist link stick as in the case of separating the suspension insulator 22 from the existing built- Is separated from the existing built-in iron (21) in the reverse order.

13, the step S8 of removing the flexible neck portion 510 from the electric pole 10 is performed by separating the lifting / moving member 550 and the wire supporting portion 540 from the flexible neck portion 510, (520) is separated from the electric pole (10).

The wire supporting portion 540 is first separated from the lifting and lowering moving portion 550 and then the lifting and lowering moving portion 550 is separated from the retracting neck portion 510 by the separation of the lifting and lowering moving portion 550 and the wire supporting portion 540. [ 510). ≪ / RTI > At this time, when the insulator restricting portion 545b has a detachable structure, a process of separating the insulator restricting portion 545b from the extending portion 541 may be included.

The step S8 of removing the flexible neck portion 510 from the electric pole 10 is a process of separating the flexible neck portion 510 in a state in which the lifting and moving movable portion 550 and the wire supporting portion 540 are installed from the electric pole 10 .

According to the above-described method for operating a distribution facility live wire according to the present invention, the existing built-in wrought iron 21 is supplied to the existing built-in wrought iron 21 by using the auxiliary equipment 500 for live- It can be easily replaced with a new built-in solid iron (24).

7 to 12 are applied collectively to all of the plurality of sets of the hanging insulators 22, the step S2 of moving the wire supporting portions 540 upward to the suspender insulator 22 side, The existing built-in barb 21 can be replaced with the new built-in barb 24 by once passing the step S7 of connecting the suspended barb 22 and the built-in barb 24 together.

Step S2 of moving the wire supporting portions 540 upward to the suspender insulator 22 and separating the wire 30 from the existing built-in wrought iron 21 are performed for each set of the suspending insulators 22 (S4) And then the electric wire supporting portion 540 is moved upwards to the built-in wrought iron 25 side with respect to each set of the suspending insulators 22 after replacing the existing built-in wrought iron 21 with the newly built built wrought iron 24 independently The plurality of suspension insulators 22 may be sequentially installed while independently performing the steps S6 to S7 of connecting the suspending insulators 22 to the newly installed built-in bars 25. [

That is, step (S2) of moving the wire supporting portion 540 upward to the suspender insulator 22 to step (S4) of separating the wire 30 from the existing built-in burr 21 is repeated a plurality of times, (S6) and a suspending jig (22) for moving the wire supporting portions (540) upwardly to the newly built built brass (25) side with respect to each set of the suspending insulators (22) It is also possible to sequentially install each of the plurality of suspending insulators 22 while connecting the step S7 to connect the soldering iron 25 a plurality of times.

According to the present invention, the height of the entire wire support portion 540 and the height of the wire 30 connected to the wire support portion 540 can be easily adjusted by using the driving force of the actuator 41.

Further, according to the present invention, it is possible to remotely perform the operation of separating the electric wire 30 from the electric wire 30 by using the actuator 41 to the lower side of the existing built-in wrought iron 21, It is possible to easily secure a live work space for replacement and to reduce the risk of a safety accident caused when the operator touches the electric wire 30 when the pin iron is replaced.

According to the present invention, the entire process of lifting and lowering the wire support portion 540 by using the actuator 41, routing the wire 30, and replacing the built-in wrought iron can be performed by using the existing built- Can be made on a short copper line which does not exceed the width of the built-in solid iron (24), which can further improve the working efficiency.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the technical scope of the present invention should be defined by the following claims.

10: Jeonju 20: Built-in note
21: Built-in wired iron 22: Suspension insulator
24: New built-in wired iron 30: Wires
41: Actuator
500: An auxiliary device for live distribution line work 510:
511: Horizontal extension part 515: Support part
516: link member 520:
521: Horizontal band connecting portion 522: Electrode connecting portion
523: Rigid connection part 525: Support part connection part
540: wire support part 541: extension part
542: main extension part 543: sub extension part
544: Fixing portion 545a: Wire restraining portion
545b: insulator restricting portion 545c:
545d: hook portion 546: bracket portion
546a: opening portion 547: lower roller
548: locking portion 549: upper roller
550: lifting / lowering part 551:
552: guide portion 552a: guide hole portion
553: driving part 554:
555: Worm 555a: Power inlet
556: Worm wheel 557: Axial cylinder
558: Belt portion

Claims (5)

Securing the neck to the pole;
Separating a suspending insulator provided in the electric pole from the existing built-in wire and connecting it to a wire supporting portion provided on the elastic neck;
Moving the wire support portion connected to the suspending insulator downward to separate the wire from the existing built-in buried iron;
Removing the existing built-in wrought iron from the electric pole and installing a new built-in wrought iron on the electric pole;
Moving the wire supporting portion upward to the newly built built-in buried iron; And
And separating the suspending insulator from the wire supporting portion and connecting the new built-
The step of separating the suspending insulator from the existing built-in wrought iron and connecting the wire-
And separating a connection portion of the suspended insulator from the existing built-in buried iron from the existing built-in buried iron and coupling the coupled portion to the insulator restricting portion formed in the wire supporting portion,
Connecting the suspended insulator connected to the wire support to the new built-
And separating the connecting portion of the suspending insulator from the insulator restricting portion from the insulator restraining portion and coupling the insulated restraining part to the newly installed built-in soldering iron.
The method according to claim 1,
The upward or downward movement of the wire support portion is achieved by moving the entire wire support portion up and down by operating the lifting / lowering portion or by moving the sub-extension portion located above the wire support portion up and down Operating method of live distribution equipment.
The method according to claim 1,
The upward or downward movement of the wire supporting portion is performed by moving the entire wire supporting portion up and down by operating the lifting and moving portion and by moving the sub extending portion located on the upper portion of the wire supporting portion up and down Features of the distribution facility live wire working method.
delete The method according to claim 1,
Wherein the existing built-in wrought iron and the new built-in wrought iron have a horizontal arrangement of a common longitudinal run.

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