KR101430749B1 - Composite insulator - Google Patents

Abstract

The present invention relates to a composite insulator. In the insulator of the present invention, a shield 104 is provided on one side of the outer surface of the tube 100. First and second flanges 110 and 110 'are installed at both ends of the tube 100. The housing 120 is formed of a silicone material so as to surround the tube 100 and the shield 104. A plurality of shades 122 are formed on the outer surface of the housing 120. The shield 104 includes a body portion 106 that is seated on an outer surface of the tube 100 and a curved portion 108 that is curved outward at one end of the body portion 106. A connecting portion 109 for electrical connection with the flanges 110 and 110 'is formed at the other end of the body portion 106 opposite to the curved portion 108. A plurality of through holes 109 'are formed in the shield 104. According to the present invention having such a configuration, the configuration of the composite insulator is simplified and the manufacturing process of the composite bushing is facilitated.

Description

Composite insulator {Composite insulator}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a composite insulator. More particularly, the present invention relates to a composite insulator for mounting a shield on an outer surface of a glass fiber reinforced plastic tube to perform electric field relaxation.

Power equipment, for example, a gas insulated switchgear (GIS) is provided in a power transmission line or a power distribution line to open / close a power line in an abnormal state such as a ground fault or a short circuit as well as opening /

Composite bushings are used in such power devices, primarily to provide insulation between the ground and the enclosure of the power device connected at the top where high voltage is applied. An example of the composite bushing is shown in FIG.

According to Fig. 1, the bushing is provided with a tube 10 made of glass fiber reinforced plastic inside. The glass fiber reinforced plastic tube 10 is manufactured by a filament winding process and has a cylindrical internal structure.

On the surface of the tube 10, a housing 20 made of a polymer is provided. The housing (20) encloses the tube (10). A plurality of shades (21) protrude from the surface of the housing (20).

A center conductor 30 is provided at the center of the tube 10 and flanges 40 and 40 'made of a metal material are disposed at both ends of the tube 10 and the housing 20. A central conductor 30 is provided along the inner center of the tube 10. The center conductor 30 extends out through the flanges 40 and 40 '. Here, the tube 10, the housing 20 and the flanges 40 and 40 ', which are obtained by removing the center conductor 30, form an insulator.

In the case of the upper flange 40 in the drawing, the lower flange 40 'comes into direct contact with the central conductor 30 to have a higher potential. The lower flange 40' is in contact with the enclosure of the power device, And is mechanically connected to the tube 10 by thermocompression bonding.

A shielding portion is formed in a portion of the inner side of the insulator that is connected to the ground of the enclosure of the power device, and electric field concentration occurs at the lower side. Therefore, in order to suppress the electric field concentration, the inner shield 60, which is cylindrical, is provided inside the insulator.

However, the conventional insulator as described above has the following problems.

Generally, in a manufacturer of a power device or the like, a bushing is manufactured by purchasing the insulator, installing the inner shield 60, and attaching other components, such as a terminal and a corona ring. However, there arises a problem that the inside of the insulator is damaged in the process of installing the inner shield 60 inside the insulator.

Korean Patent No. 10-1172795 Korean Patent No. 10-1035194

SUMMARY OF THE INVENTION An object of the present invention is to provide a shield for preventing electric field concentration on an insulator from being attached to an outer surface of a tube so as not to separately perform a shield attachment work.

Another object of the present invention is to provide a shield on the outer surface of a tube of an insulator, which is connected to one flange to improve the electric field relaxation performance.

It is a further object of the present invention to provide a shield on the outer surface of a tube of the insulator so that a lot of holes are formed in the shield so as not to be damaged when the housing is formed.

According to an aspect of the present invention for achieving the above object, the present invention provides a tube having a tube having an inner space opened to both ends through the inside thereof, first and second flanges provided at both ends of the tube, A body portion mounted on an outer surface of the tube for relieving the concentration of an electric field installed on the outer surface of the tube, a curved surface portion formed to be curled outward at one end of the body portion, and a curved portion formed at the other end of the body portion opposite to the curved surface portion A shield having a plurality of through holes formed in the curved surface portion and including a connection portion electrically connected to any one of the first flange and the second flange; a plurality of shields formed to surround the tube and the shield, And a housing.

The connection portion of the shield is electrically connected to the second flange.

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A plurality of through holes are formed through the body portion and the connecting portion of the shield.

The following effects can be obtained in the composite insulator according to the present invention.

In the present invention, since the shield is provided on the outer surface of the tube constituting the insulator, it is not necessary to separately install a shield on the completed insulator, so that it is possible to prevent the insulator from being damaged in the process of manufacturing the composite bushing by using the insulator , The yield of the process for manufacturing a composite bushing is increased.

In the present invention, since the shield is connected to the flange of the metal material provided at one end of the tube, even if the size of the shield is relatively small, the flange can perform the field relaxation action together, There is also an effect.

Further, in the present invention, since many holes are formed in the shield to prevent the shield from being deformed when the material of the housing constituting the outer surface of the insulator is injected, the round of the end portion of the shield is mounted on the tube in an accurate shape So that the performance of mitigating the concentration of the electric field is maintained as designed.

In the present invention, since the distance from the center conductor to the shield increases, the inside diameter of the insulator can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional view showing a configuration of a conventional composite bushing. FIG.
2 is a longitudinal sectional view showing a configuration of a preferred embodiment of a composite insulator according to the present invention.
3 is a perspective view showing a shield constituting a composite insulator of the embodiment of the present invention.
4 is a cross-sectional view showing a configuration of a composite insulator according to an embodiment of the present invention.

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

Referring to FIG. 2 to FIG. 4, a cylindrical tube 100 is provided inside the composite insulator of the present invention. Inside the tube 100, an inner space 102 is formed to be opened to both ends of the tube 100.

The tube 100 is mainly made of glass fiber reinforced plastic. That is, glass fiber reinforced plastic (FRP) is used as a material for forming the tube 100. Of course, the tube 100 is not made of glass fiber-reinforced plastic but a nonwoven fabric and a polyester film are used as a component of a part of the tube 100. The tube 100 is generally cylindrical in shape.

The tube 100 is made to have a designed thickness by applying a glass fiber reinforced plastic to the surface of the mandrel corresponding to the shape of the inner space 102 by a predetermined thickness. Of course, the nonwoven fabric and the polyester film may be provided on the surface of the tube 100 or the like.

A shield 104 as shown in FIG. 3 is installed to be located in a part of the surface of the tube 100. The shield 104 is installed in close contact with the outer surface of the tube 100. Therefore, the inner diameter of the shield 104 is equal to or slightly smaller than the outer diameter of the tube 100. The shield 104 is made of a conductive material, and can be made of metal.

As shown in FIG. 3, the shield 104 is provided with a cylindrical body portion 106, and a curved portion 108 is provided at one end of the body portion 106. The curved portion 108 is formed to be rounded outward at an end portion of the body portion 106. When the ends of the shield 104 are sharpened, the electric field concentration may occur, so that the curved surface portion 108 is placed so that electric field concentration does not occur at the end of the shield 104.

The connecting portion 109 is formed at the other end of the body portion 106 opposite to the curved portion 108. The connection 109 is for electrical connection with the second flange 110 ', which will be described below. The connecting portion 109 may be bonded or welded to overlap with one side of the second flange 110 'at a predetermined region. In other words, the second flange 110 'is made of a metal material as long as it can be electrically connected. In the illustrated embodiment, the connecting portion 109 can be in close contact with the corresponding portion of the second flange 110 '.

A plurality of through holes 109 'are formed in the shield 104 as a whole. The through hole 109 'serves to prevent deformation of the curved surface portion 108, particularly by the pressure applied to the inside of the mold when forming the housing 120 to be described below. Therefore, though the through hole 109 'may be formed only in the curved surface portion 108, the through hole 109' is formed in the whole of the manufactured shield 104.

The shield 104 is formed by twisting a conductive metal sheet to form a net shape, and forming the mesh shape into a cylindrical shape. Of course, the shield 104 may be formed of a metal plate and a plurality of through holes may be formed in the metal plate.

First and second flanges 110 and 110 'are provided at both ends of the tube 100, respectively. The flanges 110 and 110 'are for fastening with other parts. The first and second flanges 110 and 110 'are made of metal. Both ends of a center conductor (not shown) passing through the inner space 102 of the tube 100 are supported on the first and second flanges 110 and 110 ', although not shown in the drawings.

A plurality of sheds 122 protrude from the outer surface of the housing 120 at predetermined intervals to surround the outer surface of the housing 120. The shade 122 is formed by protruding a ring-shaped outer surface of the housing 120. The sheds 122 may protrude to the same extent or protrude with a height difference. The housing 120 is made of a silicon material. The tube 120 is formed by inserting a tube 100 having flanges 110 and 110 'mounted on both ends thereof and a shield 104 mounted on one outer surface thereof into a mold and injecting silicon.

Hereinafter, the use of the composite insulator according to the present invention will be described in detail.

The insulator of the present invention becomes a part for manufacturing a composite bushing. That is, various parts such as a terminal, a corona ring and the like are added to the insulator having the above-described configuration to make a composite bushing.

The insulator of the present invention is constructed by mounting a shield 104 on the outer surface of the tube 100 made of glass fiber reinforced plastic adjacent to the second flange 110 '. The shield 104 prevents the electric field from being concentrated at a corresponding position of the internal space 102. In general, the electric field is concentrated in the vicinity of the second flange 110 '. Therefore, in the illustrated embodiment, the shield 104 (see FIG. 1) is provided on the outer surface of the tube 100, ). However, since the portion where the electric field can be concentrated differs according to the configuration of the composite bushing, the position of the shield 104 may be changed according to the configuration of the composite bushing.

Here, production of the insulator of the embodiment shown in Fig. 2 will be described. First, a mandrel is produced and a resin-impregnated glass fiber, that is, a glass fiber reinforced plastic is laminated. The glass fiber reinforced plastic is laminated by a predetermined thickness to form the tube 100 having a desired thickness.

When the tube 100 is manufactured, a shield 104 is installed on one side of the outer surface of the tube 100. Next, flanges 110 and 110 'are installed at both ends of the tube 100. At this time, the connection portion 109 of the shield 104 is connected to the second flange 110 '. The connection between the connecting portion 109 and the second flange 110 'may be performed using an adhesive, welding, or a separate mechanism. Connecting the connecting portion 109 and the second flange 110 'made of metal in this way makes it possible to relatively reduce the size of the shield 104. This is because the second flange 110 'can function together with the shield 104 to alleviate the electric field concentration.

Next, the process of forming the housing 120 is performed. The housing 120 is made of silicon, and a shade 122 protrudes from the outer surface of the housing 120. That is, the tube 100 is positioned inside the mold, and the shield 104 and the first and second flanges 110 and 110 'are mounted on the tube 100. Of course, only a part of the flanges 110 and 110 'are located in the mold and mostly located outside the mold. This is because the housing 120 is not formed on the surfaces of the flanges 110 and 110 '.

When the high pressure silicon is injected into the mold, the shield 104 receives the pressure of silicon. The body portion 106 of the shield 104 is in close contact with the outer surface of the tube 100, The presence of the through hole 109 'prevents the pressure of the silicon from being applied to the curved surface portion 108 as it is, so that the curved surface portion 108 can be pressed against the curved surface portion 108, The housing 120 can be formed without being damaged.

The insulator is formed through the above process, and the insulator is attached with an inner conductor, a corona ring, or the like to produce a composite bushing.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

For example, in the illustrated embodiments, the tube 100 is a glass fiber-reinforced plastic and the housing 120 is comprised of silicon but is not necessarily so. That is, the tube 100 may be made of various materials having similar or similar functions to the glass fiber-reinforced plastic, and the housing 120 may have the same or similar function as silicon.

When the shield 104 is installed at a position away from the flanges 110 and 110 ', the connecting portion 109 may not be provided.

100: tube 102: inner space
104: shield 106:
108: curved portion 109:
109 ': through hole 110: first flange
110 ': second flange 120: housing
122: Shade

Claims (6)

A tube having an inner space opened to both ends through the inside thereof,
First and second flanges provided at both ends of the tube,
A body portion mounted on an outer surface of the tube for relieving the concentration of an electric field installed on the outer surface of the tube, a curved surface portion formed to be curled outward at one end of the body portion, and a curved portion formed at the other end of the body portion opposite to the curved surface portion A shield having a plurality of through holes formed in the curved surface portion and including a connection portion electrically connected to one of the first flange and the second flange,
And a housing formed to surround the tube and the shield and having a plurality of shades formed around the outer surface thereof.
The composite insulator according to claim 1, wherein a connection portion of the shield is electrically connected to the second flange.
delete delete delete The composite insulator according to claim 1, wherein a plurality of through holes are formed through the body portion and the connection portion of the shield.

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