KR101240078B1 - Vacuum interrupter insulation device and method for manufacturing the same - Google Patents

Abstract

The present invention relates to a vacuum interrupter insulator and a method for manufacturing the insulator, the vacuum interrupter insulator comprising: a first adhesive layer applied to a ceramic layer of a vacuum interrupter having a ceramic layer; A first cover bonded to the first adhesive layer and surrounding the ceramic layer of the vacuum interrupter, the outer surface of which is an uneven surface; A second adhesive layer formed on an outer surface of the first cover; And a second cover that is attached to the second adhesive layer and surrounds the first cover. In addition, the method of manufacturing the insulator may include forming a first adhesive layer by applying an adhesive to a ceramic layer of a vacuum interrupter having a ceramic layer; Forming a silicon cover to cover the ceramic layer of the vacuum interrupter to be adhered to the first adhesive layer, and to form an uneven surface on an outer surface of the silicon cover; Applying an adhesive to an outer surface of the silicone cover to form a second adhesive layer; And forming an epoxy cover to adhere to the second adhesive layer while surrounding the silicon cover. According to the present invention, the current leakage of the vacuum interrupter of the vacuum breaker is prevented.

Description

Vacuum interrupter insulation device and manufacturing method thereof {VACUUM INTERRUPTER INSULATION DEVICE AND METHOD FOR MANUFACTURING THE SAME}

The present invention relates to a vacuum interrupter insulator and a method of manufacturing the same.

In general, a circuit breaker is a device that automatically stops power of a power system in order to prevent loss of the power system in the event of a failure or overload of a power system that transmits and distributes power. Circuit breakers can be classified into inlet breakers, gas breakers, air circuit breakers, magnetic circuit breakers, and vacuum circuit breakers according to the extinguishing medium.

A vacuum circuit breaker is a circuit breaker using vacuum as a medium for extinguishing media. Recently, a vacuum circuit breaker is most commonly used among medium voltage circuit breakers. The vacuum interrupter (Vacuum interrupter), which is a key component of the vacuum circuit breaker, includes an insulating container sealed to maintain a vacuum state, and a movable terminal (electrode) and a fixed terminal (electrode) each having contacts in contact with each other in the insulating container. Include.

In a vacuum circuit breaker, the load switching and breaking of the fault current are performed in a vacuum state in the vacuum interrupter, but the external insulation of the vacuum interrupter is made in various media.

As the external insulating medium of the vacuum interrupter, air, oil, SF6 gas, or the like is used. However, if the external insulating medium is air, it cannot be used where high lightning shock voltage is required because of the low insulating ability of air. There is also a risk of oil explosion if the external insulating medium is oil. If the external insulation medium is SF6 gas, it can be used in places where high lightning voltage is required and there is no risk of explosion, but it is regulated to cause environmental pollution.

Due to these problems, recently, a solid insulation method of insulating a vacuum interrupter as a solid has been used.

As an example of a solid insulation structure of a conventional vacuum interrupter, a ceramic layer is provided in an insulating container of a vacuum interrupt, and the vacuum interrupt insulating container is wrapped in an epoxy housing formed of an epoxy material, and between the epoxy housing and the ceramic layer of the insulating container. A silicone tube formed of a silicone material is inserted.

In the method of manufacturing the solid insulation structure of the vacuum interrupter, the insulating container of the vacuum interrupter is inserted into the silicon tube to surround the ceramic layer of the vacuum interrupter insulation container. Then, a vacuum interrupter in which a silicon tube is coupled is inserted into a mold having a cavity having a shape corresponding to the outer shape of the epoxy housing, and an epoxy is inserted into the mold to form an epoxy housing. Such a technique is disclosed in Korean Patent Laid-Open Publication No. 10-2004-0040721.

However, the solid insulation structure of the conventional vacuum interrupter as described above is a silicon tube due to the irregularity of the epoxy cooling conditions, the irregularity of the shrinkage rate according to the shape of the epoxy housing, the difference in the coefficient of thermal expansion between the ceramic layer and the silicon tube and the epoxy housing, etc. Not only does not the outer surface of the inner surface of the epoxy housing sufficiently contact with each other, but the deformation of the silicon tube causes a gap between the outer surface of the ceramic layer of the insulating container and the inner surface of the silicon tube. As a result, current leaks between the fixed and movable terminals between the ceramic layer and the silicon tube and between the silicon tube and the epoxy housing.

It is an object of the present invention to prevent current leakage of the vacuum interrupter of the vacuum breaker.

In order to achieve the object of the present invention as described above, the first adhesive layer applied to the ceramic layer of the vacuum interrupter provided with a ceramic layer; A first cover bonded to the first adhesive layer and surrounding the ceramic layer of the vacuum interrupter, the outer surface of which is an uneven surface; A second adhesive layer formed on an outer surface of the first cover; And a second cover which is attached to the second adhesive layer and surrounds the first cover.

In addition, in order to achieve the object of the present invention, by applying an adhesive to the ceramic layer of the vacuum interrupter provided with a ceramic layer to form a first adhesive layer; Forming a first cover to cover the ceramic layer of the vacuum interrupter to be adhered to the first adhesive layer, and to form an uneven surface on an outer surface of the first cover; Applying an adhesive to an outer surface of the first cover to form a second adhesive layer; And forming a second cover to adhere to the second adhesive layer while surrounding the first cover.

The method of manufacturing the first cover may include inserting a vacuum interrupter having a first adhesive layer into a mold, injecting a liquid material forming the first cover into the mold, and curing the liquid material. Separating the mold.

It is preferable that the inner surface of the mold is an uneven surface, and a fluorine coating film is formed on the uneven surface.

It is preferable that the said 1st, 2nd adhesive bond layer contains a silicone resin, respectively.

Preferably, the first cover is made of silicon.

It is preferable that the said 2nd cover is an epoxy material.

The present invention wraps the vacuum interrupter of the vacuum interrupter in a state in which the first cover is bonded by the first adhesive layer and surrounds the first cover in a state in which the second cover is bonded by the second adhesive layer. Not only does not a gap be formed between the 1 cover, but cracks are prevented, a gap is not formed between the first cover and the second cover, and cracks are prevented, so that a current is generated between the movable terminal and the fixed terminal of the vacuum interrupter. To prevent leakage.

In addition, since the first adhesive layer is provided on the ceramic layer forming the outer circumferential surface of the vacuum interrupter, and the first cover is attached to the first adhesive layer, the ceramic layer having the smooth surface and the first cover are firmly attached to each other. In particular, since the outer surface of the first cover is a concave-convex surface, the contact area with the second cover is widened to increase the area of the adhesive layer between the first cover and the second cover, thereby increasing the adhesive force.

In addition, since the fluorine coating film is provided on the inner surface of the mold, the first cover is well separated from the mold. When the material of the first cover is silicon, the adhesiveness with the ceramic layer is excellent, but does not fall off from the mold. However, since the fluorine coating film is provided on the inner surface of the mold, silicon is well separated from the mold.

1 is a cross-sectional view showing an embodiment of a vacuum interrupter insulator according to the present invention;
2 is a flow chart showing an embodiment of a method for manufacturing a vacuum interrupter insulator according to the present invention;
3 is a cross-sectional view illustrating the formation of a first cover using a mold in a vacuum interrupter provided with a first adhesive layer.

Hereinafter, a vacuum interrupter insulation device and a manufacturing method thereof according to the present invention will be described with reference to the accompanying drawings.

1 is a cross-sectional view showing an embodiment of a vacuum interrupter insulator according to the present invention.

As shown in FIG. 1, an embodiment of the vacuum interrupter insulator according to the present invention may include a first adhesive layer 210 applied to a ceramic layer of the vacuum interrupter 100 and a first adhesive layer 210. A first cover 220 is bonded while surrounding the ceramic layer of the vacuum interrupter 100 while being bonded. A second adhesive layer 230 is formed on an outer surface of the first cover 220, and the second cover 240 is bonded to the second adhesive layer 230 to surround the first cover 220.

The vacuum interrupter 100 of the vacuum circuit breaker 100 includes an insulating container 110 sealed to maintain a vacuum state, and a movable terminal 120 and a fixed terminal 130 each having contacts in contact with each other in the insulating container 110. It includes. The insulating container 110 has a cylindrical shape, and a ceramic layer C is provided on an outer surface of the insulating container 110. The ceramic layer C is provided over the entire outer circumferential surface of the insulating container 110. The ceramic layer C forms the outer circumferential surface of the vacuum interrupter 100.

The first adhesive layer 210 preferably comprises a silicone resin.

It is preferable that the material of the first cover 220 is silicon. The first cover 220 is cylindrical because it surrounds the ceramic layer (C). It is preferable that the uneven surface 221 is provided on the outer surface of the first cover 220. The uneven surface 221 may be formed over the entire outer surface of the first cover 220. Meanwhile, the uneven surface 221 may be formed only in a portion of the outer surface of the first cover 220. The average roughness of the uneven surface 221 is preferably 0.15 to 1.38 micrometers.

The second adhesive layer 230 is preferably formed uniformly. The second adhesive layer 230 preferably includes a silicone resin.

It is preferable that the material of the second cover 240 is epoxy. The second cover 240 preferably surrounds the entire outer circumferential surface of the first cover 220. The outer surface of the second cover 240 may be formed in a variety of shapes.

Hereinafter, an embodiment of a method for manufacturing a vacuum interrupter insulator according to the present invention will be described.

2 is a flowchart illustrating an embodiment of a method for manufacturing a vacuum interrupter insulator according to the present invention. 1 and 2, an embodiment of a method for fabricating a vacuum interrupter insulator according to the present invention will be described.

In one embodiment of the method for manufacturing a vacuum interrupter insulator according to the present invention, first, an adhesive is applied to a ceramic layer of a vacuum interrupter 100 provided with a ceramic layer C to form a first adhesive layer 210. The first adhesive layer 210 preferably comprises a silicone resin.

The first cover 220 is formed to surround the ceramic layer C of the vacuum interrupter 100 and to be adhered to the first adhesive layer 210. In this case, the first cover 220 is formed such that the uneven surface 221 is formed on the outer surface of the first cover 220. The first cover 220 is preferably made of silicon. The first cover 220 made of a silicon material is called a silicon cover.

The first cover 220 is preferably formed by a mold. The process in which the first cover 220 is formed by a mold is as follows.

First, a mold is produced. The mold is preferably composed of two parts or three or more parts. As shown in FIG. 3, it is preferable that an uneven surface 311 is provided on an inner surface of the mold 300 and a coating film is formed on the uneven surface 311 of the mold. The coating film is preferably a fluorine coating film.

The vacuum interrupter 100 having the first adhesive layer 210 is inserted into and fixed to the mold 300. The liquid material forming the first cover 220 is injected into the mold 300. The liquid material is preferably liquid silicon rubber (LSR), which is silicon.

The liquid material injected into the mold 300 is cured. After curing the liquid material injected into the mold 300, the mold 300 is separated to separate the cured material from the mold 300.

The molded body separated from the mold 300 becomes a first cover 220 surrounding the vacuum interrupter 100, and the first cover 220 is a first adhesive layer 210 formed on an outer circumferential surface of the vacuum interrupter 100. ) Is attached. The outer surface of the first cover 220 is an uneven surface 221 by the uneven surface 311 of the mold 300. Since the fluorine coating film is provided on the inner surface of the mold 300, the first cover 220 is well separated from the mold 300.

The mold 300 may be made of a material such as aluminum or cast iron. Meanwhile, the mold 300 may be made of Teflon material. When the mold 300 is made of Teflon material, the coating film may be excluded.

An adhesive is applied to the outer surface of the first cover 220 to form a second adhesive layer 230. The first adhesive layer 210 preferably comprises a silicone resin.

The second cover 240 is formed to surround the first cover 220 and be bonded to the second adhesive layer 230. The second cover 240 is preferably epoxy material. The second cover 240 made of an epoxy material is called an epoxy cover.

The second cover 240 may be formed in a mold as in the method of forming the first cover 220. In addition, the second cover 240 may be formed by injection and then attached to the second adhesive layer 230 while surrounding the first cover 220.

Since the outer surface of the first cover 220 is an uneven surface 221, the contact area between the first cover 220 and the second cover 240 is widened.

Hereinafter, the operation and effects of the vacuum interrupter insulator according to the present invention and the manufacturing method of the insulator will be described.

The present invention wraps the vacuum interrupter 100 of the vacuum circuit breaker in a state where the first cover 220 is bonded by the first adhesive layer 210 and the second cover 240 is bonded by the second adhesive layer 230. Since the first cover 220 is wrapped in a closed state, a gap is not formed between the outer surface of the vacuum interrupter 100 and the first cover 220, the crack is prevented, and the first cover 220 and the second cover are prevented. Since the gap is not formed between the 240 and the crack is prevented, the current is prevented from leaking between the movable terminal 120 and the fixed terminal 130 of the vacuum interrupter 100.

In addition, since the first adhesive layer 210 is provided on the ceramic layer C forming the outer circumferential surface of the vacuum interrupter 100, and the first cover 220 is attached to the first adhesive layer 210, the ceramic layer has a smooth surface. And the first cover 220 are firmly attached to each other. Since the second adhesive layer 230 is provided on the outer surface of the first cover 220 and the second cover 240 is attached to the second adhesive layer 230, the first cover 220 and the second cover 240. Are firmly attached to each other. In particular, since the outer surface of the first cover 220 is an uneven surface 221, the contact area with the second cover 240 is widened, so that the area of the adhesive layer between the first cover 220 and the second cover 240 is wide. To increase adhesion.

In addition, in the present invention, since the coating film is provided on the inner surface of the mold 300, the first cover 220 is well separated from the mold 300. When the material of the first cover 220 is silicon, the adhesiveness with the ceramic layer is excellent, but it is hardly separated from the mold 300. However, since the coating film is provided on the inner surface of the mold 300, silicon is well separated from the mold 300.

100; Vacuum interrupter C; Ceramic layer
210; First adhesive layer 220; First cover
230; Second adhesive layer 240; Second cover

Claims (10)

A first adhesive layer applied to the ceramic layer of the vacuum interrupter provided with the ceramic layer;
A first cover made of silicon, the outer cover of which is coated on the ceramic layer of the vacuum interrupter while being bonded to the first adhesive layer and whose outer surface is an uneven surface;
A second adhesive layer formed on an outer surface of the first cover; And
A vacuum interrupter insulator comprising a second cover of epoxy material which is attached to the second adhesive layer and surrounds the first cover. The insulator of the vacuum interrupter according to claim 1, wherein the first and second adhesive layers each comprise a silicone resin. delete delete delete Forming a first adhesive layer by applying an adhesive to the ceramic layer of the vacuum interrupter provided with the ceramic layer;
Forming a silicon cover to cover the ceramic layer of the vacuum interrupter to be adhered to the first adhesive layer, and to form an uneven surface on an outer surface of the silicon cover;
Applying an adhesive to an outer surface of the silicone cover to form a second adhesive layer; And
And forming an epoxy cover to be bonded to the second adhesive layer while surrounding the silicon cover. The method of claim 6, wherein the silicone cover comprises inserting a vacuum interrupter having a first adhesive layer into the mold, injecting liquid silicone into the mold, and curing the liquid silicone to separate the mold. Vacuum interrupter insulator manufacturing method comprising a. 8. The method of claim 7, wherein an uneven surface is provided on an inner surface of the mold and a coating film is formed on the uneven surface. 10. The method of claim 8, wherein the coating film is a fluorine coating film. The method of claim 7, wherein the mold is made of Teflon material.

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