KR20090007941U - Bushing using screen of conductive polymer - Google Patents

Abstract

The present invention is applied to a plug-in type cable connector that inserts a screen into an epoxy bushing to form an equipotential between the cable conductor and the connecting portion, thereby preventing breakdown due to partial discharge in the air gap generated in the conductor connecting portion. Relates to an epoxy bushing.

The present invention provides a bushing using a conductive polymer screen that maximizes the production of a good quality epoxy bushing by insert molding using a conductive polymer screen similar to that of an epoxy bushing, thereby minimizing molding defects due to conventional metal screen applications. .

The above object of the present invention is achieved by a bushing applying a screen of a conductive polymer having a structure in which a screen formed of a conductive polymer is bonded together with a connection socket and a nut member of a copper alloy by insert molding.

Epoxy Bushings, Conductive Polymers, Screens, Insert Molding, Interface Face

Description

BUSHING USING SCREEN OF CONDUCTIVE POLYMER}

The present invention is applied to a plug-in type cable connector that inserts a screen into an epoxy bushing to form an equipotential between the cable conductor and the connecting portion, thereby preventing breakdown due to partial discharge in the air gap generated in the conductor connecting portion. The present invention relates to an epoxy bushing. More specifically, a conductive polymer screen maximizes the production of high quality epoxy bushings by insert molding using a conductive polymer screen similar to that of an epoxy bushing, thereby minimizing molding defects due to the application of existing metal screens. The bushing is applied.

In general, gas insulated switchgear (GIS) has excellent insulation and extinguishing characteristics by embedding breakers, disconnectors, ground breakers, instrument transformers, current transformers, main buses, and lightning arresters, which are the main equipment of substations, in a grounded metal enclosure. It is known as a key device of substations that fill the power system by filling SF ₆ gas.

The gas insulated switchgear is a device that protects the power system by opening and closing the line under abnormal conditions such as grounding and short circuits as well as opening and closing of the transmission and substation lines in a normal state. It has advantages such as operation and maintenance check and harmony with environment.

Inside the gas insulated switchgear, as illustrated in FIG. 1, an epoxy bushing 10 assembled by fastening bolts B / T to the housing G / H of the gas insulated switchgear is connected to the bushing, and a cable ( It is composed of a plug-in connector 20 composed of a stress cone 21 to secure the terminal insulation of the CB.

The technology proposed by the present invention belongs to the technical category of the epoxy bushing 10 for the gas switch.

As shown in FIG. 2, the conventional epoxy bushing 10 is connected to the connection socket 12 of copper alloy material which is formed by binding to the front end of the epoxy housing 11 and to the interface surface 11a of the epoxy housing 11. Metallic material to block partial discharge in the gap generated between the stress cone 21 of the plug-in connector 20 and the conductor of the cable CB at the front end thereof and the multi-ram 25 that is bound to the connection socket 12. The screen 15 is insert molded to form an integral structure with the epoxy housing 11.

In other words, the metal screen 15 is to cover the uneven surface of the conductor to alleviate the sudden voltage difference, and also to cover the pores generated in direct contact with the conductor and the insulator to create a conductorization By discharging the discharge, safety accidents are prevented by destroying the insulation layer due to lack of insulation during long-term use.

In other words, the metal screen 15 coupled to the inside of the epoxy bushing 10 by insert molding forms an equipotential between the conductor and the connection part of the cable CB according to use so that there is no discharge phenomenon due to the gap of the conductor connection part. It has a function.

However, the conventional screen 15 is processed as metal and is bonded by insert molding in an epoxy resin.

Therefore, in order to overcome the disadvantages of molding coupling between dissimilar materials, the screen 15 processes multiple stages of bending and binding holes and is molded into the epoxy housing 11 and the mold.

As a result, the metal screen 15 is easy to increase the time and cost according to the processing of a single member before molding the finished product of the epoxy bushing 10, the molding conditions and the molding operation is easy due to the insert molding of the dissimilar material metal And, eventually, a manufacturing cost of the epoxy bushing 10, which is a finished product, is increased.

The present invention has superior bonding performance and material flow performance compared to the conventional insert molding of screens made of metal by using polymer conductive rubber having similar molding characteristics according to the manufacture of epoxy bushings applied to plug-in connectors for gas insulated switchgear. This provides an epoxy bushing for plug-in connectors for gas insulated switchgear that maximizes formability and eliminates the combination of electrical performance in the process of use, maximizing product reliability.

In particular, it is not necessary to process to increase the binding force as in the prior art, thereby reducing the manufacturing cost and minimizing the defective rate.

In order to achieve the above object, the present invention is formed by forming a screen with a conductive polymer rubber having good moldability, and combining the epoxy housing with an epoxy housing and insert molding while extending up to the front end of the stress cone of the plug-in connector. It is characterized by maximizing life extension and formability by preventing dielectric breakdown by blocking partial discharge caused by air gap between multi-ram in front of stress cone and interface surface of epoxy housing.

In addition, the epoxy bushing of the present invention is characterized by simplifying the manufacturing process by manufacturing the screen of the conductive rubber by integral molding with the epoxy housing in the mold together with the connection socket and the insert nut of the copper alloy material.

As described in detail above, the present invention is a molding condition of the epoxy bushing applied to the plug-in connector for gas insulated switchgear insert molding of the conventional metal screen using a polymer conductive rubber similar in properties to the epoxy resin Compared to the bonding portion and the flow performance of the material is superior compared to the maximized formability, minimizing the manufacturing failure rate, it is possible to ensure economic efficiency by reducing the manufacturing cost.

Hereinafter, with reference to the accompanying drawings for a characteristic technology of the present invention will be described in detail.

That is, the bushing to which the screen of the conductive polymer of the present invention is applied, as shown in FIGS. 3 to 7,

The connection socket 12 and the nut member 13 of the copper alloy material to the epoxy housing 11 and the screen 30 of the conductive polymer are insert-molded with one side connected to the outer peripheral surface of the connection socket 12.

The conductive polymer screen 30 is integrally formed with an induction part 32 which is bent and extended by insert molding along the interface 31a of the front surface and the interface face 11a of the epoxy housing 11.

In other words, the stress cone 21 of the plug-in connector 20 which is connected to the connection socket 12 of the copper alloy material and the interface surface 11a of the epoxy housing 11, which is formed by binding the front end of the epoxy housing 11. And the induction part of the polymer screen 30 is connected to the conductor of the cable CB at the front end thereof to block partial discharge caused by the air gap between the multi-rams 25 which are connected to the connection socket 12. Insert molding along 11a) forms an integral structure with the epoxy housing 11.

At this time, the connection portion 31 is formed in the epoxy housing 11 in the through-hole 33 of a predetermined interval in order to increase the coupling force when insert molding.

In addition, the polymer screen 30 has a taper in which the guide portion 32 extends to an inclined portion that extends toward the rear end for ease of demolding from a core of a conventional mold (not shown), and at the same time, the inner circumferential surface thereof is narrowed in overall thickness. It is molded into the face 34.

The present invention is to place the connection socket 12 and the nut member 13 of the copper alloy material processed in the same manner as in the prior art and the polymer screen 30 manufactured by separate molding as described above in a mold (not shown) and epoxy The epoxy bushing 10 of the present invention is manufactured by integrally molding the epoxy housing 11 with the resin.

Therefore, the epoxy bushing 10 of the plug-in connector for a gas insulated switchgear according to the present invention has the polymer screen 30 integrally molded with a conductive rubber, so that the heterogeneity caused by the housing 11 is minimized, resulting in excellent bonding performance and defects in electrical performance. Prevented,

In addition, the through hole 33 penetrates the connection portion 31 at a predetermined interval to provide a solid binding molding with the epoxy resin.

In addition, the structure of the screen 30 of the conductive polymer may be mass-produced by using a mold that can be mass-produced in a mold, thereby mass-producing by minimizing a defect rate, thereby reducing the manufacturing cost of the epoxy bushing of the finished product by reducing the part price.

1 is a cross-sectional view showing the structure of a plug-in connector for a gas insulated switchgear.

2 is a cross-sectional view of an embodiment of the epoxy bushing of FIG. 1.

Figure 3 is a cross-sectional view before connection of the plug-in connector according to the use of the present invention.

Figure 4 is a cross-sectional explanatory view after connection of the plug-in connector according to the use of the present invention.

FIG. 5 is an enlarged view of an “F” part excerpt of FIG. 4. FIG.

6 is a perspective view of a polymer screen applied to the present invention.

7 is a longitudinal cross-sectional view of FIG. 6;

** Explanation of symbols for main parts of drawings **

10: bushing 11: epoxy housing

11a: interface face 20: plug-in connector

21: stress cone 30: conductive polymer screen

31: connection part 32: induction part

33: through hole 34: tapered surface

Claims (3)

Epoxy resin has a structure in which the connection socket and nut member of the copper alloy material and the interface surface connected to the outer circumferential surface of the connection socket and the stress cone of the plug-in connector are connected to the screen formed of a conductive polymer along the periphery by insert molding. Bushing to which a screen of conductive polymer is applied. The method of claim 1, The conductive polymer screen is integrally formed with an induction portion that is bent and extended along the interface surface of the epoxy housing to be formed and the front connection portion connected to the connection socket, and the induction portion extends to an inclined portion that extends toward the rear end. At the same time, the inner circumferential surface is formed into a tapered surface whose overall thickness is narrowed, and the bushing is applied to the screen of the conductive polymer, characterized in that it is bonded to the epoxy housing by insert molding. The method according to claim 1 or 2, The screen of the conductive polymer is a bushing applying the screen of the conductive polymer, characterized in that to form a through-hole at a predetermined interval to the connection portion of the front surface in order to increase the molding bonding force with the epoxy housing and combined by insert molding.

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