KR20220166636A - Wire sagging prevention device for overhead line - Google Patents

Abstract

The present invention relates to a wire sagging preventing device of an overhead line which has a wire connection member elastically supported by a spring inside a case connected to a support structure side and connects the other end of a wire connection member to a wire side by allowing the other end of the wire connection member to protrude from the outside of the case. If a tensile force of a wire is reduced, the spring in a compressed state is stretched to pull the wire connection member, thereby having an effect of preventing wire sagging.

Description

Wire sagging prevention device for overhead line}

The present invention relates to an apparatus for preventing sagging of wires in an overhead line, and more particularly, to a apparatus for preventing sagging of wires in an overhead line by using a restoring force of a spring.

An overhead line refers to an electric line installed in the air using a steel tower or pole to transport electricity.

Wires of overhead lines must always maintain a constant ground height, but physical sagging occurs according to wire characteristics such as self-weight, modulus of elasticity, and coefficient of linear expansion.

In addition, since the deflection of the wire of the overhead line changes depending on the wire temperature, wind, current, etc., it is necessary to maintain the wire induction (the amount of deflection in the vertical direction at the lowest point of the wire) as the design value.

If the wire droops excessively due to the above factors, it will contact trees and cause a line failure. Therefore, in order to increase the ground height of the wire, equipment maintenance work such as replacing steel towers and poles and maintenance work such as adjustment of the road are being carried out. Therefore, the consumption of manpower and cost is high.

Republic of Korea Patent Registration No. 10-0904964 (Announced on June 26, 2009)

Therefore, the present invention has been made to solve the above problems, and provides a wire sagging prevention device for an overhead line that can prevent sagging of the wire by immediately compensating for the sagging of the wire in response to a change in tension of the wire. It has a purpose.

The present invention for achieving the above object is a wire sagging prevention device installed between a wire support structure and a wire, comprising: a case; a wire connection member installed through one end of the case, provided with a spring support inside the case, and formed with a ring portion connected to the wire side outside the case; A spring interposed between the spring support part and one end of the case inside the case; includes.

The case is formed by combining a first case and a second case, and the first case includes a tube body and a connection part integrally formed with the tube body and connected to the support structure side, and the second case includes the first case. It includes a tubular body coupled to the tubular body of the case, and an insertion hole formed at one end of the tubular body through which the wire connection member passes.

The wire connection member further includes a linear rod portion connecting the ring portion and the spring support portion, the rod portion passing through the insertion hole, and the rod portion being screwed to the spring support portion to be detachable.

A bearing is installed on the spring support portion of the wire connection member, and rolling members of the bearing come into rolling contact with the inner surface of the tubular body of the second case.

A spring compression member capable of pushing the spring support is installed in the first case.

The spring compression member includes a rod part formed with a male screw part screwed into a female screw hole formed on a side wall of the body of the first case, a pressing part formed at one end of the rod part to push the spring support part, and a protrusion protruding outward from the side wall. It is screwed to the male threaded portion and includes a nut for fixing the spring compression member to the side wall.

An operating end coupled to a tool is formed at an end of the rod portion of the spring compression member to rotate the spring compression member.

The connecting part of the first case includes branching parts connected to both sides of the circumference of the tube body, ends formed by combining both branching parts while extending to opposite sides of the tube body, and connection holes formed at the ends.

Coupling parts are formed around the tube body of the first case and around the tube body of the second case, and coupling parts on both sides are coupled with bolts and nuts to combine the first case and the second case.

In the second case, a linear viewing window is formed in the longitudinal direction so that the location of the spring support portion can be seen.

A tension display scale is formed along the side of the observation window.

A plurality of rainwater discharge holes are formed in the tube body of the second case.

According to the present invention as described above, as the tension of the wire decreases, the spring pulls the wire, and the sagging of the wire is immediately compensated, thereby preventing the sagging of the wire.

Therefore, there is no need to construct (or install) high heights of support structures such as steel towers or utility poles in advance in preparation for wire sagging, thereby reducing the size and weight of support structures, thereby reducing the cost of constructing (installing) support structures. there is.

In addition, there is an effect of reducing management costs by eliminating the need for replacement of support structures for wire sagging recovery or facility maintenance work and maintenance work for maintaining the retraction of wires.

1 is an installation state diagram of a wire sagging prevention device according to the present invention.
Figure 2 is a partially exploded perspective view of the wire sagging prevention device.
Figure 3 is a cross-sectional view of the wire sagging prevention device in an assembled state.
Figure 4 (a), (b) is a left side view and a front view of the first case, which is one component of the wire sagging prevention device.
Figure 5 (a), (b) is a front view and a right side view of the second case, which is one component of the wire sagging prevention device.
6 is a front view of a spring compression member, which is one component of the wire sagging prevention device.
7 is a front view of a wire connection member, which is one component of the wire sagging prevention device.

Since the present invention can make various changes and have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. The thickness of lines or the size of components shown in the accompanying drawings may be exaggerated for clarity and convenience of description.

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

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

As shown in FIG. 1, the wire sagging prevention device 100 of the overhead line according to the present invention is a suspension insulator having one end connected to the steel tower (or pole) 1 and the other end connected to the electric wire 2 ( 3) It is installed in a structure connected to.

2 and 3, the wire sagging prevention device 100 has a structure in which a spring compression member 30, a wire connection member 40, and a spring 50 are installed inside the case.

The case is divided into a first case 10 and a second case 20, and the first case 10 and the second case 20 are coupled to each other with bolts (B) and nuts (N). The first case 10 is connected to the steel tower 1, and the wire connection member 40 protruding outward of the second case 20 is connected to the suspension insulator 3 connected to the wire 2.

As shown in FIG. 4, the first case 10 has a tube body 11 having an empty space formed therein, and a connection part 12 formed by extending from one end of the tube body 11 and connected to a support structure such as a steel tower 1. ) and a plurality of coupling parts 13 formed around the other end of the tubular body 11 at equal intervals.

The tubular body 11 has a flat side wall 11a formed at an end of the connecting portion 12, a female screw hole 11b is formed in the center of the side wall 11a, and the opposite end is completely open. The spring compression member 30 is installed in the female screw hole 11b.

The connection part 12 includes two branch parts 12a connected to the end of the tube body 11, an end 12b where the two branch parts 12a are combined into one, and a connection hole 12c formed in the end 12b. include

The space between the branches 12a is large enough to rotate the spring compression member 30 or the nut 33 (see FIG. 6) by inserting a tool.

The coupling part 13 is a small plate member protruding vertically from the outer surface of the tubular body 11, and has a bolt hole 13a.

As shown in FIG. 5 , the second case 20 includes a tubular body 21 and a coupling part 23 formed at one end of the tubular body 21 .

The tube body 21 has the same shape and size as the tube body 11 of the first case 10 and a cross section perpendicular to the longitudinal direction, so that the first case 10 and the second case 20 are coupled to each other make one case.

One end of the tube body 21 is completely open, and a plurality of coupling parts 23 are formed in the vertical direction on the outer surface of the opening. The coupling part 23 is formed in the same number at a position corresponding to the coupling part 13 of the first case 10 . A bolt hole 23a is formed in the coupling part 23 .

The other end of the tube body 21 is formed in a substantially hemispherical shape, and an insertion hole 22 is formed in the center thereof. The wire connection member 40 is installed in the insertion hole 22 .

A linear observation window 24 is formed in the tube body 21 in the longitudinal direction, and a tension display scale 25 is displayed along the side of the observation window 24.

In addition, a plurality of rainwater discharge holes 26 are formed at regular intervals along the circumference of the tube body 21 .

As shown in FIG. 6, the spring compression member 30 is integrally formed with a linear rod portion 31 and one end of the rod portion 31, and has an outer cross section formed in a flat plane perpendicular to the rod portion 31. A portion 32, a male threaded portion 31a formed on the other half of the rod portion 31, and a nut 33 fastened to the male threaded portion 31a.

The male screw part 31a of the rod part 31 is inserted into and fastened to the female screw hole 11b formed in the side wall 11a of the first case 10 .

An operating end 31b in the form of a square prism or a regular hexagonal prism is formed at the end of the rod part 31 so that the spring compression member 30 can be rotated with a tool such as a socket wrench (box wrench).

As shown in FIG. 7, the wire connection member 40 has a linear rod part 41, a ring part 42 integrally formed at one end of the rod part 41, and the other end of the rod part 41. It includes a spring support 43 detachably coupled.

The outer end surface of the spring support part 43 facing the pressing part 32 of the spring compression member 30 is formed as a flat surface, and a female screw hole (not shown) is formed in the center of the other end surface to form an end of the rod part 41. can be screwed together.

A bearing 44 having a plurality of rolling members 44a is mounted on an outer circumference of the spring support 42 . The rolling member 44a is in rolling contact with the inner surface of the tube body 21 of the second case 20 to guide the linear movement of the wire connection member 40 in the forward and backward directions, and in FIG. 7, a ball-shaped rolling member ( 44a) is exemplified. As shown, the bearing 44 is manufactured in a structure without an outer ring, so that the rolling members 44a are exposed to the outside.

The spring 50 is a coil spring of a general type and has elasticity acting in a range between the general horizontal tension of the wire 2 (about 3 ton) and the maximum usable tension (about 4 to 5 ton).

The assembly and installation process of the wire sagging prevention device 100 according to the present invention will be described.

First, the rod part 31 of the spring compression member 30 is inserted into the opening of the first case 10, and the male screw part 31a is screwed into the female screw hole 11a of the side wall 11a.

At this time, the pressing part 32 of the spring compression member 30 protrudes outward from the body 11 of the first case 10, and spring compression is performed by adjusting the fastening depth of the female screw hole 11b and the male screw part 31a. The degree of protrusion of the member 30 can be adjusted.

In the second case 20, the rod part 41 of the wire connecting member 40 is inserted into the insertion hole 22 from the outside of the body 21, and the spring 50 is inserted through the opening of the body 21. After first inserting, the spring support part 43 is coupled to the end of the rod part 41. The bearing 44 is first coupled to the spring support 43.

Thereafter, the tube body 11 of the first case 10 and the tube body 21 of the second case 20 are butted against each other, and the coupling parts 13 and 23 on both sides are coupled with bolts B and nuts N. . At this time, the pressing part 32 of the spring compression member 30 pushes the spring support part 43 of the wire connecting member 40 while being inserted into the inside of the tube body 21 of the second case 20. By rotating the operating end 31b of the spring compression member 30 with a tool to further push the wire connection member 40 with the spring compression member 30 until the spring 50 is slightly compressed, the spring compression member 30 ), the wire connection member 40 and the spring 50 all maintain a state in which a predetermined compressive force acts.

Therefore, before the wire sagging prevention device 100 is installed on the overhead line, it is possible to prevent components from vibrating and colliding (rattling) inside the wire sagging prevention device 100 during transportation and handling.

Thereafter, by tightening the nut 33 to the externally protruding male screw portion 31a of the side wall 11a of the first case 10, the assembled state of the parts is maintained.

The wire sagging prevention device 100 assembled as described above is installed as shown in FIG. The connection part 12 of the first case 10 is connected to the steel tower 1 using a fastening means such as a bolt, and the hook part 42 of the wire connection member 40 protrudes outward of the second case 20. ), connect the suspension insulator (3) to which the wire (2) is connected by using a fastening means of a suitable structure.

At this time, the tension of the wire 2 pulls the wire connection member 40 to the outside of the case, so that the spring 50 is further compressed and the pressing portion 32 and the spring support portion 43 are spaced apart.

In this state, the operator unscrews the nut 33 and manipulates the control end 31b with a tool to move the spring compression member 30 toward the inside of the first case 10, thereby moving the pressing portion 32 and the spring support portion 43. ) form a sufficient gap between them. The sufficient distance refers to a distance at which the pressing part 32 and the spring support part 43 do not come into contact with each other even when the tension of the wire 2 decreases and the spring 50 is maximally extended, which means that the spring compression member 30 This is to prevent interfering with the operation of the wire connecting member 40. After securing the interval, the nut 33 is tightened again to fix the spring compression member 30.

As described above, when the pressing portion 32 of the spring compression member 30 and the spring support portion 43 of the wire connection member 40 are separated, the spring 50 is compressed only by the tension of the wire 2. will keep

On the other hand, sagging of the wire 2 is caused by a decrease in tension of the wire 2 .

However, in the state in which the wire sagging prevention device 100 according to the present invention is installed, when the tension of the wire 2 decreases, the wire 2 pulls the wire connecting member 40 and the force is reduced, and thus in a compressed state. The spring 50 is stretched by the elastic restoring force.

Therefore, the spring 50 pushes the spring support 43 and the wire connecting member 40 pulls the wire 2 while moving toward the first case 10, so that the deflection of the wire 2 is compensated in real time. As a result, sagging of the wire 2 is prevented.

As described above, since the wire sagging is prevented by the wire sagging prevention device 100 according to the present invention, it is not necessary to construct (or install) a high overhead line support structure such as a steel tower or pole in advance in preparation for wire sagging.

Accordingly, the weight and size of the support structure are reduced, and thus material costs, labor costs, and the like are reduced, thereby saving construction (installation) costs of the support structure.

In addition, there is an effect of reducing follow-up management costs by eliminating the need for replacement of support structures for wire sagging recovery or facility maintenance work and maintenance work for maintaining the relocation of wires.

On the other hand, in the installation state of the wire sagging prevention device 100, the operator can check the position of the spring support part 43 inside the second case 20 through the observation window 24 formed in the second case 20 (actually, What is observed is the bearing 44 outside the spring support 43), and thus the increase or decrease of the tension of the wire 2 can be recognized. Since the tension display scale 25 is formed on the outside of the observation window 24, the amount of increase or decrease in tension can be checked in more detail.

In addition, when it rains, rainwater is introduced into the case through the observation window 24, and the rainwater is discharged through the rainwater discharge hole 26 located at the bottom of the plurality of rainwater discharge holes 26 in the device installation state, thereby discharging the rainwater inside the device. It is designed to prevent water from pooling.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and various modifications and other equivalent embodiments will be made by those skilled in the art in the field to which the technology belongs. You will understand that it is possible. Therefore, the true technical protection scope of the present invention should be determined by the claims below.

1: Pylon 2: Wires
3: suspension insulator 10: first case
11: pipe body 12: connection part
13: coupling part 20: second case
21: tube body 22: insertion hole
23: coupling part 30: spring compression member
31: rod part 32: pressing part
33: nut 40: wire connection member
41: rod part 42: ring part
43: spring support 44: bearing
50: spring

Claims (12)

A wire sagging prevention device installed between a wire support structure and a wire,
case;
a wire connection member installed through one end of the case, provided with a spring support inside the case, and formed with a ring portion connected to the wire side outside the case;
A wire sagging prevention device for an overhead line comprising a spring interposed between the spring support part and one end of the case inside the case. The method of claim 1,
The case is formed by combining a first case and a second case, and the first case includes a tube body and a connection part integrally formed with the tube body and connected to the support structure side, and the second case includes the first case. A wire sagging prevention device for an overhead line, characterized in that it comprises a tube body coupled to the tube body of the case, and an insertion hole formed at one end of the tube body through which the wire connection member passes. The method of claim 2,
The wire connecting member further includes a linear rod portion connecting the ring portion and the spring support portion, the rod portion passing through the insertion hole, and the rod portion being screwed to the spring support portion to be detachable. Anti-sagging device. The method of claim 2,
A wire sagging prevention device for an overhead line, characterized in that a bearing is installed on the spring support of the wire connection member, and the rolling members of the bearing come into rolling contact with the inner surface of the tubular body of the second case. The method of claim 2,
The wire sagging prevention device of the overhead line, characterized in that the spring compression member capable of pushing the spring support portion is installed in the first case. The method of claim 5,
The spring compression member includes a rod part formed with a male screw part screwed into a female screw hole formed on a side wall of the body of the first case, a pressing part formed at one end of the rod part to push the spring support part, and a protrusion protruding outward from the side wall. Wire sagging prevention device of an overhead line, characterized in that it comprises a nut screwed to the male threaded portion to fix the spring compression member to the side wall. The method of claim 6,
The wire sagging prevention device of the overhead line, characterized in that the operating end coupled to the tool to rotate the spring compression member is formed at the end of the rod portion of the spring compression member. The method of claim 2,
The connection part of the first case includes a branching part connected to both sides of the circumference of the tube body, an end formed by combining both branched parts while extending to the opposite side of the tube body, and a connection hole formed at the end of the wire of the overhead line Anti-sagging device. The method of claim 2,
Each of the coupling parts is formed around the tube body of the first case and the tube body of the second case, and the coupling parts on both sides are coupled with bolts and nuts to combine the first case and the second case. wire sagging prevention device. The method of claim 2,
The wire sagging prevention device of the overhead line, characterized in that the second case is formed with a straight observation window in the longitudinal direction so that the position of the spring support can be seen. The method of claim 10,
Wire sagging prevention device of the overhead line, characterized in that the tension display scale is formed along the side of the observation window. The method of claim 2,
A wire sagging prevention device of an overhead line, characterized in that a plurality of rainwater discharge holes are formed in the body of the second case.

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