KR102186000B1 - High voltage direct current type tower - Google Patents

Abstract

The present invention relates to a direct current transmission method pylon, comprising a neutral wire, a lightning arrester-integrated insulator device having one end connected to the neutral wire, and the other end connected to the pylon arm, and the arrester-integrated insulator device has a columnar shape extending in one direction. Includes a rod portion, a lightning protection element portion disposed inside the rod portion, a covering portion surrounding the outer surface of the rod portion, and a sheath portion connected to the covering portion, a plurality of which are spaced apart at regular intervals, and comprising an insulating material Characterized in that.

Description

Direct current transmission method pylon{HIGH VOLTAGE DIRECT CURRENT TYPE TOWER}

The present invention relates to a direct current transmission type pylon, and more particularly, to a direct current transmission type pylon capable of omitting an overhead branch line by allowing a neutral wire to function as an overhead branch line.

In general, when applying an ultra-high voltage direct current return conductor method, a neutral line is installed, and an overhead branch line connected to the ground is installed at the top of the pylon to protect the neutral line and the main line. This is a method of absorbing and protecting a lightning strike. In the event of a lightning failure, a lightning arrester is installed on the transmission conductor to protect the transmission line. However, in the case of a transmission line without a lightning arrester, when a lightning failure occurs, the lightning current generated by the lightning moves through the transmission conductor, and when it encounters an insulator with a resistance less than the lightning voltage, it causes insulation breakdown and passes to the iron tower. Another flashover is generated by the transmission conductor of another pylon arm through the increase in voltage as much as the multiplied by the resistance component of and insulator. At this time, the insulator is damaged or destroyed by the lightning strike, causing great damage to the operation of the transmission line. In order to prevent such damage from lightning strikes, a method of absorbing lightning strikes by installing an overhead branch line connected to the ground at the top is used, and there is a problem in that the size of the steel tower increases as well as cost increases due to the installation of the overhead branch line. Therefore, there is a need to improve this.

As a related background technology, there is Korean Laid-Open Patent Publication No. 10-2011-0070635 (title of the invention: lightning arrester and its manufacturing method, published on June 24, 2011).

The present invention has been conceived to improve the above problems, and an object of the present invention is to provide a direct current transmission method pylon capable of omitting an overhead branch line by allowing a neutral wire to function as an overhead branch line.

The direct current transmission method pylon according to an aspect of the present invention includes: a neutral wire: and a lightning arrester integrated insulator device having one end connected to the neutral wire and the other end connected to the pylon arm, and the arrester integrated insulator device extending in one direction Column-shaped rod portion to be formed; A lightning protection element part disposed inside the rod part; A covering part surrounding the outer surface of the rod part; And a shed part connected to the covering part, arranged to be spaced apart at predetermined intervals, and including an insulating material.

In the present invention, the lightning protection element portion is formed to extend from the inside of the rod portion in the same direction as the extension direction of the rod portion to be exposed to the outside of both ends of the rod portion.

In the present invention, the lightning protection element part includes a material having lightning protection performance.

In the present invention, the fatigue machine integrated insulator device includes: a first connection part connected to one end of the rod part and electrically connected to the lightning protection element part; And a second connection part connected to the other end of the rod part and electrically connected to the lightning protection element part, wherein the first connection part is arranged to be connected to the pylon arm, and the second connection part is connected to a neutral wire. Is placed.

In the present invention, the lightning protection element part is insulated below a set voltage value and is energized when the set voltage value is exceeded.

In the present invention, when a lightning strike falls on the neutral wire, the lightning current is transmitted to the pylon arm through the lightning protection element and is grounded.

In the present invention, the rod part is made of FRP (Fiber Reinforced Plastics).

A direct current transmission method pylon according to another aspect of the present invention includes: a neutral wire; A lightning arrester having one end connected to the neutral wire and the other end connected to the pylon arm; And an insulator disposed to be spaced apart from the arrester, one end connected to the neutral wire, and the other end connected to the pylon arm.

According to the present invention, since the overhead branch line can be omitted by allowing the neutral line to function as the overhead branch line, it is possible to reduce the size of the pylon while reducing the installation cost and installation time of the pylon.

According to the present invention, a function of an insulator capable of supporting a neutral wire in a steel tower and a function of a lightning arrester capable of protecting a neutral wire in the event of a lightning strike to the neutral wire can be simultaneously implemented.

According to the present invention, due to the characteristics of the lightning protection device, it is possible to insulate between the neutral wire and the pylon arm below the set voltage value, and when a lightning strike falls on the neutral wire, the lightning current can be advanced to the pylon arm and flowed to the ground of the pylon.

According to the present invention, more efficient conversion is possible when applying an existing AC transmission line to a DC transmission method, thereby maximizing transmission efficiency and reducing conversion cost.

1 is a schematic diagram of a monopole transmission tower among a direct current transmission type pylon according to an embodiment of the present invention.
2 is a schematic diagram of a 1-bipole transmission tower among a direct current transmission method pylon according to an embodiment of the present invention.
3 is a view of a lightning arrester integrated insulator device of a direct current transmission type pylon according to an embodiment of the present invention.
4 is a cross-sectional view of a lightning arrester integrated insulator device of a direct current transmission type pylon according to an embodiment of the present invention.
5 is a view showing a state in which a arrester-integrated insulator device is disposed between a pylon arm and a neutral wire in a direct current transmission method pylon according to an embodiment of the present invention.
6 is a view showing an operating state of a direct current transmission method pylon according to an embodiment of the present invention when a lightning strike falls on a neutral wire.
7 is a view showing a state in which a lightning arrester and an insulator are disposed between a tower arm and a neutral wire in a direct current transmission method pylon according to another embodiment of the present invention.
8 is a view showing an operating state of a direct current transmission method pylon according to another embodiment of the present invention when a lightning strike falls on a neutral wire.

Hereinafter, a direct current transmission method pylon according to an embodiment of the present invention will be described with reference to the accompanying drawings. In this process, thicknesses of lines or sizes of components shown in the 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 or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

1 is a schematic diagram of a monopole transmission tower among a high voltage direct current (HVDC) type pylon according to an embodiment of the present invention. Referring to FIG. 1, in the monopole transmission tower, insulator devices 100 and 200 supporting the neutral wire B1 are connected to the tower arm A1. As the insulator devices 100 and 200, a lightning arrester-insulator device 100 and a lightning arrester 210 and an insulator 220 as separate units are representative. Unexplained reference numeral B2 denotes an electric wire, and A2 denotes a pylon arm connected to the electric wire B2 by an insulator device.

2 is a schematic diagram of a 1-bipole transmission tower among a direct current transmission method pylon according to an embodiment of the present invention. Referring to FIG. 2, in the 1-bipole transmission tower, insulator devices 100 and 200 supporting the neutral wire B1 are connected to the tower arm A1. As the insulator devices 100 and 200, a lightning arrester-insulator device 100 and a lightning arrester 210 and an insulator 220 as separate units are representative. Unexplained reference numeral B2 denotes an electric wire, and A2 denotes a pylon arm connected to the electric wire B2 by an insulator device.

3 is a view of a lightning arrester-integrated insulator device of a direct current transmission type pylon according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view of a lightning arrester integrated insulator device of a direct current transmission type pylon according to an embodiment of the present invention, and FIG. 5 Is a view showing a state in which the arrester-integrated insulator device is disposed between the pylon arm and the neutral wire in the direct current transmission method pylon according to an embodiment of the present invention, and FIG. 6 is a diagram illustrating a case where a lightning strike falls on a neutral wire according to an embodiment of the present invention. It is a view showing the operating state of the direct current transmission method pylon.

3 to 6, the direct current transmission method pylon according to an embodiment of the present invention includes a neutral wire (B1), a pylon arm (A1), and a lightning arrester integrated insulator device 100. The neutral wire B1 is fixed to the pylon arm A1 by the arrester-integrated insulator device 100 and disposed above the wire B2. The arrester-integrated insulator device 100 includes a lightning protection element part 10, a rod part 20, a covering part 30, a shed part 40, a first connection part 50, and a second connection part 55. It is done by doing.

The lightning protection element part 10 is disposed inside the rod part 20. Specifically, the lightning protection element portion 10 is formed to extend in the same direction as the extension direction of the rod portion 20 (up-down direction based on FIG. 4) inside the rod portion 20. Both ends (upper and lower ends of Fig. 4) of the lightning protection element unit 10 are exposed to the outside of both ends (upper and lower ends of Fig. 4) of the rod unit 20, respectively.

In this embodiment, both ends of the lightning protection element part 10 are formed to protrude outward from both ends of the rod part 20, and the first connection part 50 and the second connection part ( 55) and electrically connected. The lightning protection element part 10 is made of a material having lightning protection performance, such as ZnO. In addition, the lightning protection element unit 10 is insulated below the set voltage value and is energized when the set voltage value is exceeded.

Accordingly, the lightning arrestor unit 10 insulates between the neutral wire B1 and the pylon arm A1 during normal operation, and transfers the lightning current C applied to the neutral wire B1 to the pylon arm A1 during a lightning strike. By flowing it to the connected ground point, it is possible to implement the lightning protection performance without shielding a separate overhead branch or installing a lightning arrester. Here, the set voltage value is a value lower than the voltage generated during lightning strike but higher than the voltage generated during normal operation, and the setter may designate an appropriate value according to the driving environment.

In the present embodiment, the lightning protection element unit 10 is illustrated as being disposed inside the rod unit 20, but is not limited thereto. That is, the lightning arrester-integrated insulator device 100 of the present embodiment is arranged from the inside to the outside in the order of the lightning protection element part 10, the rod part 20, and the covering part 30, but the rod part 20, the lightning protection element part ( 10), of course, the covering portion 30 may be arranged in the order.

The rod part 20 is formed in a cylindrical shape that extends in one direction (up and down directions based on FIG. 5 ). The rod unit 20 may be formed not only as a single cylinder, but also may be formed by combining two or more cylinders. The rod part 20 may be formed of steel to support the neutral wire (B1) in the pylon arm (A1), and is disposed between the pylon arm (A1) and the neutral wire (B1) to form the pylon arm (A1) and the neutral wire (B1). ).

The rod unit 20 may be formed of Fiber Reinforced Plastics (FRP). FRP is a plastic composite material reinforced with glass and carbon fiber, and is a high-performance, high-functional material with excellent light weight, corrosion resistance, and formability. The rod part 20 may be formed of a twisted FRP, a straight line or a mesh shape.

The covering portion 30 surrounds the outer surface of the rod portion 20 and includes an insulating material. Specifically, the covering portion 30 surrounds the outer surface of the rod portion 20 except for both ends (upper and lower ends of Fig. 4). The lightning protection element part 10 is exposed to the outside through both ends of the rod part 20 that are not surrounded by the covering part 30.

A plurality of shed portions 40 are connected to the covering portion 30 while being spaced apart at regular intervals. The shed part 40 includes an insulating material for insulation during normal operation. In the present embodiment, the shed portion 40 is specified to be made of a separate material from the covering portion 30, but is not limited thereto. Therefore, the shed part 40 may be made of the same material as the covering part 30 and formed integrally.

The first connection part 50 is connected to one end (top part of FIG. 4) of the rod part 20 and is electrically connected to the lightning protection element part 10. The second connection part 55 is connected to the other end (lower part of FIG. 4) of the rod part 20, and is electrically connected to the lightning protection element part 10.

While the first connection part 50 is arranged to be connected to the pylon arm (A1), and the second connection part 55 is arranged to be connected to the neutral wire (B1), the arrester-integrated insulator device 100 is provided with the pylon arm (A1) and the neutral wire. It is placed between (B1). The first connection part 50 and the second connection part 55 may be covered by an insulating material so that leakage current does not enter the load part 20 and/or the lightning protection element part 10.

Hereinafter, the principle of operation of the direct current transmission method pylon according to an embodiment of the present invention will be described. Referring to FIG. 5, during normal operation, while the arrester-integrated insulator device 100 is disposed between the neutral wire B1 and the pylon arm A1, the neutral wire B1 and the pylon arm A1 are insulated from each other. That is, since the lightning arrester unit 10 disposed inside the lightning arrester-integrated insulator device 100 maintains an insulation state below the set voltage value, current flows through the lightning arrester unit 10 in normal times when lightning is not generated. It cannot pass through to the pylon arm (A1) side.

As shown in FIG. 6, when the lightning strike L falls on the neutral wire B1, the lightning current C generated by the lightning strike L exceeds the set voltage value and passes through the lightning protection element 10 to the pylon arm A1. ) Side. Specifically, the lightning current C flows along the neutral line B1 and is transmitted to the pylon arm A1 through the second connection part 55, the lightning protection element part 10, and the first connection part 50. After that, the lightning current (C) reaches the ground point of the pylon.

As described above, according to the present embodiment, when a lightning strike (L) occurs, the lightning current (C) is transmitted to the ground of the pylon through the second connection part 55, the lightning protection device part 10, and the first connection part 50. Therefore, the lightning protection integrated insulator device 100 disposed between the neutral wire B1 and the pylon arm A1 can be protected while implementing the lightning protection performance. In addition, it is possible to block the neutral wire (B1) from being damaged by lightning strikes (L), and since the neutral wire (B1) serves as a function of the existing overhead branch wire, it is possible to install a DC transmission type pylon without the overhead branch wire.

7 is a view showing a state in which a lightning arrester and an insulator are disposed between the tower arm and a neutral wire in a direct current transmission method pylon according to another embodiment of the present invention, and FIG. 8 is another embodiment of the present invention when a lightning strike falls on a neutral wire. It is a view showing the operating state of the direct current transmission method pylon according to.

7 and 8, a direct current transmission method pylon according to another embodiment of the present invention includes a neutral wire (B1), a pylon arm (A1), a lightning arrester 210, and an insulator 220. The neutral wire (B1) is disposed above the wire (B2) while being fixed to the pylon arm (A1) by the insulator 220.

The arrester 210 includes a lightning protection element part 211, a lightning shed part 212, a first lightning protection connection 213, and a second lightning protection connection 214. The lightning protection element part 211 is formed to extend in the vertical direction based on FIG. 7. The lightning protection element part 211 has an upper end electrically connected to the first lightning protection connector 213 and a lower end electrically connected to the second lightning protection connection 214.

The lightning protection element part 211 may be made of a material having lightning protection performance, such as ZnO. In addition, the lightning protection element part 211 is insulated below the set voltage value, and may be energized when it exceeds the set voltage value. Accordingly, the lightning protection element part 211 insulates between the neutral wire B1 and the pylon arm A1 during normal operation, and transfers the lightning current C applied to the neutral wire B1 to the pylon arm A1 during a lightning strike. By flowing to the connected ground point, lightning protection performance can be realized without additional shielding of overhead branch lines. Here, the set voltage value is a value lower than the voltage generated during lightning strike but higher than the voltage generated during normal operation, and the setter may designate an appropriate value according to the driving environment.

In the present embodiment, the lightning protection element part 211 is illustrated as being disposed inside a rod part (a reference numeral is omitted) forming the outer shape of the lightning arrester 210, but is not limited thereto. The rod part can be formed of steel to support the neutral wire (B1) in the pylon arm (A1), and is disposed between the pylon arm (A1) and the neutral wire (B1) to make the gap between the pylon arm (A1) and the neutral wire (B1). Keep The outer surface of the rod part is surrounded by an insulating material covering part. A plurality of lightning shed parts 212 are connected to the covering part while being spaced apart at regular intervals. The lightning shed unit 212 includes an insulating material for insulation during normal operation.

The first lightning protection connector 213 is electrically connected to the upper end of the lightning protection element part 211, and the second lightning protection connector 214 is electrically connected to the lower end of the lightning protection element part 211. The first lightning protection connection part 213 is arranged to be connected to the pylon arm (A1), and the second lightning protection connection part 214 is arranged to be connected to the neutral wire (B1), while the lightning arrester 210 includes the pylon arm (A1) and the neutral wire ( It is placed between B1). The first lightning protection connector 213 and the second lightning protection connector 214 may be covered by an insulating material so that leakage current does not enter the interior of the lightning protection element part 211.

The insulator 220 includes an insulator rod part 221, an insulator shed part 222, a first insulator connector 223, and a second insulator connector 224. The insulator rod portion 221 is formed to extend in the vertical direction based on FIG. 7. The insulator rod unit 221 may be formed not only as a single cylinder, but also may be formed by combining two or more cylinders. The insulator rod part 221 may be formed of steel to support the neutral wire B1 in the pylon arm A1, and is disposed between the pylon arm A1 and the neutral wire B1 to be disposed between the pylon arm A1 and the neutral wire. Maintain the spacing of B1).

The insulator rod unit 221 may include FRP. FRP is a plastic composite material reinforced with glass and carbon fiber, and is a high-performance, high-functional material with excellent light weight, corrosion resistance, and moldability. The insulator rod portion 221 may be formed in a twisted, straight or meshed FRP. The insulator rod part 221 has an upper end connected to the first insulator connection part 223 and a lower part connected to the second insulator connection part 224. The outer surface of the insulator rod portion 221 is surrounded by an insulating material covering portion. The insulator shed unit 222 is connected to the insulator rod unit 221 while a plurality of the insulator shed units 222 are spaced apart at regular intervals. The insulator shed part 222 includes an insulating material for insulation.

The first insulator connection part 223 is connected to the upper end of the insulator rod part 221, and the second insulator connection part 224 is connected to the lower end of the insulator rod part 221. The first insulator connector 223 is disposed to be connected to the pylon arm (A1), and the second insulator connector 224 is disposed to be connected to the neutral wire (B1), while the insulator 220 includes the pylon arm (A1) and the neutral wire ( It is placed between B1). The first insulator connector 223 and the second insulator connector 224 may be covered by an insulating material.

Hereinafter, a principle of operation of a direct current transmission method pylon according to another embodiment of the present invention will be described. During normal operation, the lightning arrester 210 and the insulator 220 are disposed between the neutral wire B1 and the pylon arm A1, so that the neutral wire B1 and the pylon arm A1 are insulated. In particular, since the lightning protection element part 211 disposed inside the lightning arrester 210 maintains an insulation state below the set voltage value, current flows through the lightning protection element part 211 in normal times when lightning is not generated. It cannot go over to the A1) side.

As shown in FIG. 8, when the lightning strike L falls on the neutral line B1, the lightning current C generated by the lightning strike L exceeds the set voltage value and passes through the lightning protection element 211 to the pylon arm A1. ) Side. Specifically, the lightning current C flows along the neutral line B1 and is transmitted to the pylon arm A1 through the second lightning protection connection part 214, the lightning protection element part 211, and the first lightning protection connection part 213. After that, the lightning current (C) reaches the ground point of the pylon.

As described above, according to the present embodiment, when the lightning strike (L) occurs, the lightning current (C) is transferred to the ground of the pylon through the second lightning protection connection part 214, the lightning protection element part 211, and the first lightning protection connection part 213. Since it can flow, it is possible to block the neutral line (B1) from being damaged by the lightning strike (L) along with the implementation of the lightning protection performance. As a result, since the neutral line (B1) also functions as the existing overhead branch line, it is possible to install a direct current transmission type pylon without the overhead branch line.

The present invention has been described with reference to the embodiments shown in the drawings, but these are only exemplary, and those of ordinary skill in the art will understand that various modifications and other equivalent embodiments are possible therefrom. will be. Therefore, the true technical protection scope of the present invention should be determined by the following claims.

100: lightning arrester integrated insulator device 10: lightning protection element part
20: rod portion 30: covering portion
40: shed part 50: first connection part
55: second connection part A1: steel tower arm
B1: neutral wire

Claims (8)

Neutral: and
One end is connected to the neutral wire, the other end comprises a lightning arrester integrated insulator device connected to the tower arm,
The arrester-integrated insulator device includes: a columnar rod portion extending in one direction;
A lightning protection element part disposed inside the rod part;
A covering part surrounding the outer surface of the rod part; And
It is connected to the covering part, and a plurality of them are arranged to be spaced apart at regular intervals, including a shed part made of an insulating material,
The lightning protection element portion is formed to extend from the inside of the rod portion in the same direction as the extension direction of the rod portion to be exposed to the outside of both ends of the rod portion
The lightning protection element part is made of a material having lightning protection performance,
The lightning arrester-integrated insulator device includes: a first connection part connected to one end of the rod part and electrically connected to the lightning protection element part; And
A second connection part connected to the other end of the rod part and electrically connected to the lightning protection element part,
The first connection part is arranged to be connected to the pylon arm, and the second connection part is arranged to be connected to a neutral wire.
delete delete delete The method of claim 1,
The lightning protection element part is insulated below a set voltage value and is energized when the set voltage value is exceeded.
The method of claim 5,
When a lightning strike falls on the neutral wire, the lightning current is transmitted to the pylon arm through the lightning protection element and is grounded.
The method of claim 1,
The rod part is a direct current transmission method pylon, characterized in that comprising FRP (Fiber Reinforced Plastics).
delete

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