KR20240027428A - Indirect live wire type suspension insulator replacement method - Google Patents

Abstract

The present invention discloses a suspension insulator replacement method using an indirect live wire method that ensures the safety of workers by enabling the replacement work on the suspension insulator to be carried out more safely and easily using an indirect live wire method using a smart stick and a tip tool. do.
The suspension insulator replacement method of the indirect live wire method described above includes a jumper wire support step for supporting between the complete iron and a jumper wire, an overhead wire support step for supporting between the complete iron and an overhead wire, and a suspension insulator already installed between the complete iron and the human clamp. A suspension insulator separation step for removing a suspension insulator, a suspension insulator installation step for replacing a new suspension insulator between the complete iron and a human clamp, an overhead wire support release step for releasing support between the complete iron and an overhead wire, and a step for releasing the support between the complete iron and an overhead wire. It consists of a jumper wire support release step for releasing support.

Description

Indirect live wire type suspension insulator replacement method}

The present invention relates to a suspension insulator replacement method of the indirect live wire method. More specifically, the indirect live wire method of replacing the suspension insulator can be replaced with a safer and simpler work by the indirect live wire method. It is about replacement method.

In general, suspension insulators made of polymer or porcelain materials are installed on lines where extra-high voltage overhead wires are laid. These suspension insulators must be replaced with new ones when they become worn, so work to replace them is necessary. do.

Conventionally, the following methods are examples of methods for replacing suspension insulators.

First, a direct live wire suspension insulator replacement method using rubber insulating gloves, rubber sleeves, and a live wire work truck.

Second, the diagonal suspension insulator replacement method involves turning off power for dozens of spans using a track switch in the section where the suspension insulator to be replaced is installed, and then proceeding with the replacement work.

Third, an uninterruptible replacement method that replaces several spans where the suspension insulator to be replaced is installed using a construction switch or bypass cable.

However, in the conventional direct live wire suspension insulator replacement method, workers have to work in direct contact with extra-high voltage wires, which poses safety risks such as electric shock.

In addition, in the diagonal suspension insulator replacement method, the power outage section is very wide, so there is a problem of aggravated consumer complaints due to power outages.

In addition, the uninterruptible replacement method not only has the problem of higher costs compared to other methods, but also requires a lot of time for preparatory work, resulting in many difficulties in field work.

Registered Patent No. 10-2412949

The technical problem that the present invention aims to solve is an indirect live wire method that ensures the safety of workers by enabling replacement work on suspension insulators to be implemented more safely and easily using an indirect live wire method using a smart stick and tip tool. It provides a suspension insulator replacement method.

Embodiments of the present invention for solving the technical problems described above include a jumper wire support step for supporting between a complete iron and a jumper wire, an overhead wire support step for supporting between the complete iron and an overhead wire, and a support step for supporting an overhead wire between the complete iron and an overhead wire. A suspension insulator separation step of removing the installed suspension insulator, a suspension insulator installation step of replacing a new suspension insulator between the complete iron and the human clamp, an overhead wire support release step of releasing support between the complete iron and the overhead wire, and the complete iron and It is preferable to include a jumper wire support release step for releasing support between jumper wires.

In an embodiment of the present invention, the jumper wire supporting step is preferably configured to support the load of the jumper wire by installing a jumper wire fixing fixture between the iron and the jumper wire.

In an embodiment of the present invention, the overhead wire support step is preferably configured to support the load of the overhead wire by installing a toughening chain and an indirect live wire tensioner between the iron and the overhead wire.

In an embodiment of the present invention, the tensile chain is preferably installed to be fixed to the iron, and the indirect live wire tensioner is configured to fix one end to the tensile chain and the other end to the overhead wire.

In an embodiment of the present invention, in the step of separating the suspension insulator, when the suspension insulator is a lightweight polymer suspension insulator, tongs with relatively weak gripping force are used, and when the suspension insulator is a heavy porcelain suspension insulator, the gripping force is used. It is desirable to use this relatively strong insulator fork to remove the already installed suspension insulator.

In an embodiment of the present invention, the suspension insulator installation step is preferably configured to connect and replace both ends of a new suspension insulator between the armbar and the human clamp.

In an embodiment of the present invention, the overhead wire support release step is preferably configured to first remove the indirect live wire tensioner between the iron and the overhead wire, and then sequentially remove the tension chain.

In an embodiment of the present invention, the step of releasing the jumper wire support is preferably configured to remove the jumper wire fixing bracket between the iron and the jumper wire.

The suspension insulator replacement method of the indirect live wire method according to an embodiment of the present invention allows the operator to change to the indirect live wire method using a smart stick and tip tool when replacing the suspension insulator already installed between the electric pole and the overhead wire with a new suspension insulator. It provides the effect of ensuring safety, and provides the effect of helping the convenience of work because a series of work processes can be defined sequentially and manually in replacement work of the indirect live line method.

Figure 1 is a flow chart for explaining the indirect live wire suspension insulator replacement method according to an embodiment of the present invention.
Figure 2 is a diagram for explaining the process of supporting a jumper wire in the indirect live wire suspension insulator replacement method according to an embodiment of the present invention.
Figures 3 and 4 are diagrams for explaining the process of supporting overhead wires in the indirect live wire suspension insulator replacement method according to an embodiment of the present invention.
Figures 5, 6, and 7 are diagrams illustrating a process for separating and dismantling an already installed suspension insulator in the indirect live wire suspension insulator replacement method according to an embodiment of the present invention.
Figures 8 and 9 are diagrams illustrating the process for installing a new suspension insulator in the indirect live wire suspension insulator replacement method according to an embodiment of the present invention.
Figures 10, 11, and 12 are diagrams for explaining the process of releasing and removing equipment supporting overhead wires in the indirect live wire suspension insulator replacement method according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached illustration drawings. In this process, the thickness of lines or sizes of components shown in the drawing may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification. In addition, the examples below do not limit the scope of the present invention, but are merely illustrative of the elements presented in the claims of the present invention, and are included in the technical idea throughout the specification of the present invention and constitute the scope of the claims. Embodiments that include elements that can be replaced as equivalents may be included in the scope of the present invention.

Referring to Figure 1, the indirect live wire suspension insulator replacement method according to an embodiment of the present invention largely consists of a jumper wire support step (a), an overhead wire support step (b), a suspension insulator separation step (c), and a suspension insulator step. It can be divided into the installation stage (D), the overhead wire support release stage (E), and the jumper wire support release stage (F). The detailed structure of each process is as follows.

The jumper wire support step (a) is a process of supporting between the complete iron 10 and the jumper wire 20 installed on the electric pole. As shown in FIG. 2, between the complete iron 10 and the jumper wire 20 This is implemented by installing a jumper wire fixing bracket 30 to support the load of the jumper wire 20. For this purpose, the jumper wire fixing fixture 30 is configured to have clamping parts 31 and 32 for coupling to the complete iron 10 and the jumper wire 20 on both sides of the upper and lower parts, respectively.

In addition, the jumper wire fixing fixture 30 is composed of a rod-shaped member in the form of a multi-joint link to freely set the support angle of the load between the complete iron 10 and the jumper wire 20. In addition, manipulation of the jumper wire fixing fixture 30 may be implemented through the use of various types of smart sticks, tip tools, and various equipment.

The overhead wire support step (b) is a process of supporting between the complete iron 10 and the overhead wire 40, between the complete iron 10 and the overhead wire 40, as shown in FIGS. 3 and 4. This is implemented by installing a toughening chain 50 and an indirect live wire tensioner 60 to support the load of the overhead wire 40.

At this time, the toughening chain 50 is installed to be firmly fixed to the complete iron 10, and the indirect live wire tensioner 60 has one end firmly fixed to the toughening chain 50 and the other end to the It is configured to be installed to be firmly fixed to the overhead wire 40. In addition, the installation operation for the tensile chain 50 and the indirect live wire tensioner 60 can be implemented through the use of various types of smart sticks, tip tools, and various equipment.

The suspension insulator separation step (c) is a process of removing the suspension insulator 80 already installed between the complete iron 10 and the human clamp 70. As shown in FIGS. 5, 6, and 7, the complete iron insulator 80 is removed. This is implemented by removing the existing suspension insulator (80), which is installed to be supported by combining both ends between (10) and the human clamp (70), to the outside.

That is, the clamp cover 71 covering the outer peripheral surface of the human clamp 70 is first removed, and then the cotter pin 72 coupled to the connection portion between the human clamp 70 and the previously installed suspension insulator 80 is removed. By separating the eye chain 73, which is installed on the rail 10 and supports the already installed suspension insulator 80, the previously installed suspension insulator 80 can be removed. In addition, the process of removing the previously installed suspension insulator 80 can be implemented through the use of various types of smart sticks, tip tools, and various equipment.

In particular, in the case where the suspension insulator 80 installed in the suspension insulator separation step (c) is a lightweight polymer suspension insulator, it would be preferable to use tongs with relatively weak gripping force, and the already installed suspension insulator 80 is a heavy material. In the case of a porcelain suspension insulator, it would be more preferable to use an insulator fork with a relatively strong gripping force to remove the already installed suspension insulator.

The suspension insulator installation step (D) is a process of replacing a new suspension insulator between the complete iron 10 and the human clamp 70. As shown in FIG. 8, the suspended insulator 10 and the human clamp 70 This is implemented by installing and replacing a new suspension insulator (80a) in between.

In other words, the suspension insulator installation step (D) can be implemented by connecting and replacing both ends of the new suspension insulator (80a) between the armbar (10) and the human clamp (70). At this time, in the work of installing a new eye chain (73a) to the complete iron (10), it will be more convenient to perform the installation work using the three-axis type chain fixing bracket (74).

In addition, in the suspension insulator installation step (D), the process of replacing the new suspension insulator (80a) and then reassembling the clamp cover 71 to the outside of the human clamp 70 as shown in FIG. It is performed additionally. In addition, the installation process of the new suspension insulator 80a can be implemented through the use of various types of smart sticks, tip tools, and various equipment.

The overhead wire support release step (e) is a process of releasing support between the complete iron 10 and the overhead wire 40, and as shown in FIG. 10, between the complete iron 10 and the overhead wire 40 This is implemented through the operation of sequentially removing the previously installed tension chain 50 and the indirect live wire tensioner 60 and lowering them to the ground.

That is, the overhead wire support release step (e) first removes the indirect live wire tensioner 60 already installed between the complete iron 10 and the overhead electric wire 40, and then It is configured to sequentially remove the installed sealing chains 50. In addition, the process of removing the toughening chain 50 and the indirect live wire tensioner 60 can be implemented through the use of various types of smart sticks, tip tools, and various equipment.

In addition, in the step (e) of releasing the overhead wire support, waterproofing work is performed on the assembly part of the clamp cover 71 covering the newly replaced suspension insulator 80a. The waterproofing work performed in this process is shown in Figure 11 As shown, by additionally performing the task of taping watertight tape to the assembly part of the clamp cover 71 using an indirect live wire taping machine 81 and an indirect live wire knife (not shown), respectively. It could be implemented.

The jumper wire support release step (b) is a process of releasing support between the complete iron 10 and the jumper wire 20. As shown in FIG. 12, the complete iron 10 and the jumper wire 20 This is implemented by removing the jumper wire fixing bracket 30 already installed therebetween and lowering it to the ground. In addition, the process of removing the jumper wire fixing bracket 30 can be implemented through the use of various types of smart sticks, tip tools, and various equipment.

Therefore, the indirect live wire suspension insulator replacement work according to the embodiment of the present invention performed through the above process involves replacing the suspension insulator 80 already installed between the electric pole and the overhead wire 40 with a new suspension insulator 80a. Therefore, it is possible to change to an indirect live wire method using various types of smart sticks, tip tools, and various equipment, thereby ensuring the safety of workers. In particular, when replacing the indirect live wire method, a series of work processes can be performed sequentially using a manual. Since it can be defined in a standardized way, it can help with the convenience of work.

10-wire 20-jumper wire
30-Jumper wire fixing bracket 31,32-Clamping part
40-Processed wire 50-Insung chain
60-Indirect live wire tensioner 70-Inhumane clamp
71-Clamp cover 72-Cotter pin
73,73a-Eye chain 74-3 axis type chain lock fixing bracket
80,80a-suspension insulator 81-taping machine for indirect live wire

Claims (8)

A jumper wire support step supporting between the iron and the jumper wire;
An overhead wire support step of supporting between the complete iron and the overhead wire;
A suspension insulator separation step of removing the suspension insulator already installed between the iron and the human clamp;
A suspension insulator installation step of replacing a new suspension insulator between the complete iron and the human clamp;
An overhead wire support release step of releasing support between the complete iron and the overhead wire; and
An indirect live wire suspension insulator replacement method comprising a jumper wire support release step of releasing the support between the complete iron and the jumper wire. In claim 1,
The jumper wire support step is an indirect live wire type suspension insulator replacement method, characterized in that it is configured to support the load of the jumper wire by installing a jumper wire fixing fixture between the iron and the jumper wire. In claim 1,
The overhead wire support step is an indirect live wire type suspension insulator replacement method, characterized in that it is configured to support the load of the overhead wire by installing a tough chain and an indirect live wire tensioner between the iron and the overhead wire. In claim 3,
The suspension insulator replacement method of the indirect live wire method, characterized in that the tensile chain is installed to be fixed to the complete iron, and the indirect live wire tensioner is configured to fix one end to the tensile chain and the other end to the overhead wire. In claim 1,
In the suspension insulator separation step, if the suspension insulator is a lightweight polymer suspension insulator, tongs with a relatively weak gripping force are used, and if the suspension insulator is a heavy porcelain suspension insulator, an insulator fork with a relatively strong gripping force is used. An indirect live wire suspension insulator replacement method, characterized in that it is configured to remove the already installed suspension insulator. In claim 1,
The suspension insulator installation step is an indirect live wire type suspension insulator replacement method, characterized in that the two ends of the new suspension insulator are connected and replaced between the iron and the human clamp. In claim 3,
The overhead wire support release step is an indirect live wire type suspension insulator replacement method, characterized in that the indirect live wire tensioner is first removed between the iron and the overhead wire, and then the tension chain is sequentially removed. In claim 1,
The jumper wire support release step is an indirect live wire type suspension insulator replacement method, characterized in that it is configured to remove the jumper wire fixing metal between the iron and the jumper wire.