KR20240125500A - A surge arresting cut out switch - Google Patents

Abstract

The present invention relates to a surge arresting cutout switch, and more particularly, to a surge arresting cutout switch robust to lightning, comprising: a surge arresting cutout switch comprising: an insulator core part (100); an insulating fixing rod part (200) built into the insulator core part (100); a conductor joint part (300) supported by the insulating fixing rod part (200) and installed at different heights within the insulator core part (100); a lightning arrester (400) connected to the conductor joint part (300) within the insulator core part (100); One side is connected to the insulating hanger (700) and the other side is electrically connected to a part of the conductor joint (300), so that a surge arresting cutout switch is included in which a fault current due to lightning is discharged through the disconnector (500) connected to the lightning arrester (400), so that even if a momentary fault current due to lightning is applied exceeding a preset value, it can be immediately discharged to the outside through the disconnector (500) and the grounding part (600) by conducting current through the lightning arrester (400), and secondary fault current blocking is also possible through the fuse link inside the fuse holder part (900), so that a lightning-resistant lightning damage prevention function is reliably provided.

Description

{A surge arresting cut out switch} having a conductor joint formed at the bottom of a lightning arrester

The present invention relates to a surge arresting cutout switch, and more specifically, to a surge arresting cutout switch in which a lightning-resistant conductor joint is formed at the bottom of a lightning arrester.

Cutout switches (COS) are installed and operated to prevent damage to transformers and other distribution elements installed around power poles due to fault currents being applied to them from lightning, etc.

However, the conventional COS has a disadvantage in that it cannot immediately cut off the fault current when the fault current flows exceeds the preset value.

This is because, when a fault current flows, it takes time for the fuse link provided inside the COS to melt.

In other words, the conventional COS had a limitation in that it could not immediately cut off the fault current when a fault current due to lightning was applied, and eventually the specified fault current was passed through as is, so it could not fundamentally prevent damage to the transformer or surrounding components.

Therefore, conventional technology has been to install and operate lightning arresters separately to prevent damage to transformers and surrounding components from lightning.

For example, in the past, three lightning arresters, their installation guards, and three COS were installed and operated.

This ultimately resulted in the hassle of installing multiple lightning arresters and COS, excessive work hours, and, above all, serious concerns about the safety of workers.

In addition, there was also the disadvantage of lowering economic feasibility due to increased material costs, such as increased epoxy usage through each multiple installation.

KR 1499652 B1

The purpose of the present invention to overcome the problems of the prior art as described above is to provide a surge arresting cutout switch in which a lightning-resistant conductor joint is formed at the bottom of a lightning arrester so as to immediately discharge a fault current even if a momentary fault current due to lightning is applied exceeding a preset value.

A surge arresting cutout switch comprises: an insulator core part (100); an insulating fixing rod part (200) built into the insulator core part (100); a conductor joint part (300) installed at different heights inside the insulator core part (100) while being supported by the insulating fixing rod part (200); a lightning arresting unit (400) connected to the conductor joint part (300) inside the insulator core part (100); and a surge arresting cutout switch having one side connected to an insulating hanger part (700) and the other side electrically connected to a part of the conductor joint part (300) so that a fault current due to lightning is discharged through a grounding part (600) connected to a disconnector (500) connected to the lightning arresting unit (400).

In addition, the lightning arrester (400) includes a surge arresting cutout switch characterized by being formed of a ZnO element.

In addition, the lightning arrester (400) includes a surge arresting cutout switch characterized by a structure in which three ZnO elements are stacked.

In addition, the surge arresting cutout switch is characterized in that the insulator core part (100) includes a second insulator part (102) to which the disconnector (500) is connected; a first insulator part (101) extending upward with the same diameter as the second insulator part (102); and a third insulator part (103) extending downward with a diameter reduced from that of the second insulator part (102).

In addition, the lightning protection device (400) includes a surge arresting cutout switch characterized by being located inside the first insulator (101).

In addition, the insulating hanger part (700) includes a surge arresting cutout switch characterized in that it is fixed to the pole by a fixed bracket part (800).

In addition, the conductor joint (300) includes a surge arresting cutout switch characterized in that it includes a first conductor joint (301) provided on the upper end of the first insulator (101) and connected to the upper end of the lightning arrester (400); a second conductor joint (302) provided on the second insulator (102) and connected to the lower end of the lightning arrester (400); and a third conductor joint (303) provided on the third insulator (103) and connected to the fuse holder (900).

In addition, the surge arresting cutout switch is characterized in that the first conductor joint (301), the second conductor joint (302), and the third conductor joint (303) are supported by the insulating fixing rod (200).

In addition, the surge arresting cutout switch is characterized in that the length of the third conductor joint (303) is formed shorter than the length of the first conductor joint (301) or the second conductor joint (302).

According to the present invention as described above, the following effects are achieved.

First, even if a momentary fault current due to lightning exceeds the preset value, it can be immediately discharged to the outside through the grounding part (600) connected to the disconnector (500) by passing the current through the lightning arrester (400), and secondary fault current can also be blocked by the fuse link inside the fuse holder part (900), thereby reliably providing a lightning strike-resistant lightning strike damage prevention function.

Second, since the lightning arrester (400) is structured as an integral unit, the separate configuration of the lightning arrester and the disconnector is no longer required, thereby reducing the effort of the worker for each installation, the complexity of the work process, and above all, the safety accidents of the worker, thereby providing the advantage of being economical and improving safety.

Third, it has the economic effect of improving productivity because it allows work to be performed very quickly in various work environments and its structure is simple.

Figure 1 is a surge arresting cutout switch according to a preferred embodiment of the present invention.

The present invention can have various modifications and various embodiments, and specific embodiments are illustrated in the drawings and specifically described in the detailed description. However, this is not intended to limit the present invention to specific embodiments, but should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

When describing each drawing, similar reference numerals are used to refer to similar components.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only to distinguish one component from another.

For example, without departing from the scope of the present invention, the first component could be referred to as the second component, and similarly, the second component could also be referred to as the first component. The term "and/or" includes any combination of a plurality of related listed items or any item among a plurality of related listed items.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with their meaning in the context of the relevant art, and should not be interpreted in an idealized or overly formal sense, unless expressly defined in this application.

The insulator core part (100) includes a first insulator part (101), a second insulator part (102), and a third insulator part (103).

The second insulator part (102) is the central part of the insulator core part (100), the first insulator part (101) is located above the second insulator part (102), and the third insulator part (103) is located below the second insulator part (102).

Additionally, the diameter of the first insulator (101) can be formed to be larger than the diameter of the third insulator (103).

Meanwhile, an insulating fixing rod (200) is provided inside the insulator core (100).

In other words, the insulating fixing rod (200) is installed lengthwise inside the insulator core (100).

The conductor joint (300) may include a first conductor joint (301), a second conductor joint (302), and a third conductor joint (303).

The first conductor joint (301) is provided to be connected to the upper end of the insulating fixing rod (200) inside the insulator core (100).

The second conductor joint (302) can be provided inside the insulator core part (100) at the point of the second insulator part (102).

The third conductor joint (303) is provided to be connected to the lower end of the insulating fixing rod (200) inside the insulator core (100).

The conductor joint (300) may be made of a conductor through which electricity flows.

The first conductor joint (301), the second conductor joint (302), and the third conductor joint (303) can be supported by an insulating fixing rod (200) provided inside the insulator core (100).

In other words, the insulating fixing rod (200) is arranged lengthwise along the length of the insulator core (100) within the insulator core (100) to fix the positions of the first conductor joint (301), the second conductor joint (302), and the third conductor joint (303), but is insulated so that electricity does not flow.

Meanwhile, the lightning protection device (400) may include a first lightning protection element (401), a second lightning protection element (402), and a third lightning protection element (403).

The first lightning protection element (401), the second lightning protection element (402), and the third lightning protection element (403) are ZnO elements of the same type, and can be sequentially stacked vertically.

The lightning arrester (400) has a characteristic in which the resistance value is high in normal times, but when a high voltage such as lightning is applied, the resistance value becomes 0.

Therefore, when lightning strikes, a momentary high-voltage current can flow through the lightning arrester (400).

In addition, in order to secure the lightning arrester (400), it may be desirable to wrap and secure the outer surface of the lightning arrester (400) with glass fiber.

More specifically, the lightning arrester (400) can be provided inside the first insulator (101).

The lightning arrester (400) can be provided at a predetermined distance from the insulating fixing rod (200) along the length direction of the insulating fixing rod (200).

At this time, the first lightning arrester (401) is connected to the first conductor joint (301), and the third lightning arrester (403) is connected to the second conductor joint (302).

Lightning has the characteristic of being transmitted through the shortest distance through the electric wires of the pole.

Accordingly, when lightning strikes, it first flows to the first lightning arrester (401), then sequentially flows to the second lightning arrester (402) and the third lightning arrester (403), and finally flows to the grounding part (600) connected to the disconnector (500) through the second conductor joint (302), so that it can be safely discharged, thereby preventing damage to surrounding components such as the transformer.

The short-circuit breaker (500) is electrically connected to the second conductor joint (302) and connected to the insulator core (100).

The grounding part (600) is connected to the disconnector (500) to perform grounding.

Meanwhile, the short-circuit breaker (500) prevents a fault current exceeding the insulator core (100) from being reused, and if a corresponding fault current is applied through lightning, etc., it explodes by itself, thereby short-circuiting the connection between the short-circuit breaker (500) and the grounding section (600).

The worker can confirm that lightning has occurred by checking for a short circuit between the circuit breaker (500) and the grounding part (600), and then perform the replacement work with a new part.

In the lower case, the short-circuit breaker (500) is connected to the insulating hanger (700).

Additionally, the insulating hanger part (700) is fixed to the fixed bracket part (800).

The fixed bracket part (800) serves to fix the insulator core part (100), the insulating fixing rod part (200), the conductor joint part (300), the lightning arrester part (400), the disconnector part (500), the grounding part (600), and the insulating hanger part (700) to the entire body.

The insulating hanger (700) can be used to suppress electrical flow between the fixed bracket (800) and the disconnector (500).

Accordingly, when lightning strikes, it can be discharged through the grounding part (600) connected to the disconnector (500) and is not discharged through the insulating hanger part (700) and the fixed bracket part (800).

Meanwhile, the fuse holder part (900) is arranged parallel to the insulator core part (100) and is provided at a predetermined distance from the insulator core part (100).

A fuse link is provided inside the fuse holder (900) to cut out a fault current exceeding a preset value.

According to the surge arresting cutout switch according to the preferred embodiment of the present invention as described above, even if a momentary fault current due to lightning is applied in a value exceeding a preset value, the current is immediately passed through the lightning arrester (400) and is discharged primarily to the outside through the grounding part (600) connected to the disconnector (500), and secondary fault current blocking is also possible through the fuse link inside the fuse holder part (900), so that a lightning-resistant lightning damage prevention function is reliably provided.

In addition, since the surge arresting cutout switch according to a preferred embodiment of the present invention has a structure in which the lightning arrester (400) is provided as an integral unit, the separate configuration of the lightning arrester and the disconnector is not required, thereby reducing the effort of the worker due to each installation, the complexity of the work process, and above all, the safety accidents of the worker, thereby presenting the advantage of being economical and improving safety.

In addition, it has the economic effect of improving productivity by making it possible to perform work in various work environments very quickly and by having a simple structure.

100 : Aejacoa Department
101: 1st Aejabu
102: 2nd Aejabu
103: Third Aejabu
200 : Insulating fixed rod
300 : Conductor joint
301: First conductor joint
302: Second conductor joint
303: Third conductor joint
400 : Lightning arrester
401: 1st lightning protection device section
402: 2nd lightning protection device
403: Third lightning protection device section
500 : Circuit breaker
600 : Grounding
700 : Insulating hanger
800 : Fixed bracket part
900 : Fuse holder section

Claims (1)

In surge arresting cutout switches,
Aezacor (100);
Insulating fixing rod part (200) built into the above insulator core part (100);
A conductor joint (300) including first, second, and third conductor joints (301, 302, 303) installed at different heights within the insulator core part (100) while being supported by the insulating fixing rod part (200);
A lightning arrester (400) integrally connected to the conductor joint (300) within the above-mentioned insulator core portion (100);
It includes a disconnector (500) whose one side is connected to the insulating hanger (700) and whose other side is electrically connected to a part of the conductor joint (300);
The fault current due to lightning is discharged to the outside through the grounding part (600) connected to the disconnector (500) connected to the lightning arrester (400).
The above insulator core part (100) includes a second insulator part (102) to which the circuit breaker (500) is connected;
A first insulator part (101) extending upward with the same diameter as the second insulator part (102);
Including a third insulator part (103) extending downward with a diameter reduced from that of the second insulator part (102);
The above first conductor joint (301) is provided on the upper side of the first insulator (101) and connected to the upper side of the lightning arrester (400).
The second conductor joint (302) is characterized in that it is connected to the lower end of the lightning arrester (400) while being provided in the second insulator (102).
A surge arresting cutout switch with a conductor joint formed at the bottom of the lightning arrester.