KR102281619B1 - cable join device of distribution line - Google Patents

Abstract

The present invention relates to a cable connection structure of overhead power distribution lines which makes connection and separation of lines relatively convenient and stably maintains an electrical contact, wherein the lines are to input an extra high voltage to a transformer for transformation for long-distance power distribution of electricity, thereby preventing electrical-short, short circuit, spark, and electric shock accidents and the like.

Description

Cable join device of distribution line

The present invention relates to a cable connection structure of an overhead distribution line in the field of distribution technology, and more particularly, it is relatively easy to combine and disconnect a line for inputting an extra high voltage to a transformer for long-distance distribution of electricity, and the electrical contact is easy. It relates to a cable connection structure of an overhead distribution line that is maintained stably and prevents the occurrence of short circuits, short circuits, sparks, and electric shock accidents.

In general, electricity generated at a voltage of about 20,000V in power plants, including thermal power plants, hydroelectric power plants, and nuclear power plants, is boosted to an ultra-high voltage (154 KV or 345 KV) suitable for transmission, and the boosted electricity is primary through the extra-high voltage line. transmitted to the substation.

The primary substation lowers the distributed ultra-high voltage electricity to the extra high voltage of 22.9 KV and distributes it to the secondary substations located near large-capacity customers or to each customer including factories along the distribution line.

Electricity distributed from the primary substation or secondary substation is distributed so that it is supplied to the power receiving facilities of each customer through the distribution system composed of overhead distribution lines and underground distribution lines, and is supplied to special high voltage consumers, high voltage consumers and general consumers through various corresponding transformers. is distributed

It is installed on the transformer and the extra-high voltage line (cable) for long-distance distribution is connected to or drawn out from the transformer. do.

As a technology related to the cable connection structure of an overhead distribution line according to the prior art, there is a "bushing mounted on the high-voltage side and the low-voltage side of a pole transformer" according to Patent Registration No. 10-388853 (June 12, 2003).

1 is a configuration diagram of a cable connection structure of an overhead distribution line according to an embodiment of the prior art.

Hereinafter, when described in detail with reference to the accompanying drawings, a central hole 11 is penetrated in the center of an insulator or bushing 10 that is fixedly installed on a part of the transformer 100 and connects the outside and the inside in an insulated state. is formed

A central conductor 30 is installed through the central hole 11, and one end is electrically connected to the inside of the transformer 100, and the other end is a transformer outgoing wire or lead-in connector 50 of an extra-high voltage dedicated line for remote distribution. ) is installed.

A transformer for converting the input voltage and the output voltage level is installed inside the transformer 100 , and each end of the conductor wound around the transformer is electrically connected to one end of the central conductor 30 .

Since an extra high voltage of 22.9 KV flows inside the transformer 100, an electric insulating oil that insulates so as not to cause a short circuit is built-in.

Since the electrical insulating oil is a liquid, it may leak to the outside of the transformer 100 through the central hole 11 of the bushing 10. A packing 70 is installed between (10) to block leakage of insulating oil.

The transformer lead-in connector 50 of the extra-high voltage dedicated line for long-distance distribution has a groove formed in the center for smooth and accurate contact with the extra-high voltage cable.

The transformer lead-in connector 50 of the extra-high voltage line for distribution according to the prior art can draw or lead in the extra-high voltage from the transformer 100 by making electrical contact while fixing the extra-high voltage line through a groove formed in the center.

However, the cable connection structure 50 of the overhead distribution line according to the prior art has a problem in that it is difficult and time-consuming to insert the extra-high voltage line into the groove formed in the center.

On the other hand, in the prior art, since the connection state with the extra-high voltage cable deteriorates over time, there is a problem that a short circuit, a short circuit, a spark, and an electric shock accident may occur.

In addition, the prior art had problems such as difficult, inconvenient, time-consuming, and difficult to maintain and detach and attach between the lead-in connector 50 and the extra-high voltage line.

Therefore, it is necessary to develop a technology that is easy to attach and detach between the special high voltage line for distribution and the lead-in connector of the transformer, so maintenance is easy and the contact state is maintained stably so that short circuits, short circuits, sparks and electric shock accidents do not occur.

Patent Registration No. 10-388853 (2003.06.12.)

The present invention was invented to solve the above problems, and its purpose is to easily couple the extra-high voltage line to the lead-in connector of the transformer while maintaining a stable electrical contact state and easy separation for maintenance. It is to provide a lead-in connector of

The characteristic configuration of the present invention for achieving the above object is to insert the central conductor in contact with the transformer at one end of the extra-high voltage transformer into the through hole of the insulator to fix it in a closed state, and to contact the other end of the central conductor. A cable connection structure for a distribution line, comprising: a guide tube formed to protrude downwardly from the center of a bottom surface; a receiving groove formed in the center to insert an extra-high voltage line; a body having a plurality of screw grooves formed on the upper surface; A lower fixing plate that is elastically installed through a lower spring in the lower portion of the receiving groove, a connecting bar connected to the central conductor is installed to protrude from the bottom, and a connecting pin that electrically contacts the core wire of the extra-high voltage line is formed to protrude from the upper surface ; an upper fixing plate elastically installed via an upper spring on the upper portion of the receiving groove to be pressed while in contact with the upper circumferential surface of the extra-high pressure line; an upper plate fixedly installed on the upper part of the body through a fixing bolt to elastically support the upper spring; an anti-sag rod installed to protrude upward from the upper surface of the upper plate; a fixing string connected and installed between the upper end of the anti-sag rod and the extra-high voltage line; and a driving motor for rotating the take-up wheel installed on the upper end of the anti-sag rod so that the fixing string is wound.

As described above, the present invention provides easy coupling between the extra-high voltage line and the lead-in connector, stable electrical contact, and prevention of sagging of the extra-high voltage line. It has the advantage of easy maintenance because it does not cause an electric shock accident and is easy to separate.

1 is a schematic diagram showing a cable connection structure of an overhead distribution line according to an embodiment of the prior art.
2 is an exploded perspective view illustrating a cable connection structure of an overhead distribution line according to an embodiment of the present invention;
3 is an exploded cross-sectional view showing a cable connection structure of an overhead distribution line according to an embodiment of the present invention.
4 is a cross-sectional view showing an assembly state of a cable connection structure of an overhead distribution line according to an embodiment of the present invention.
5 is a front view showing a cable connection structure of an overhead distribution line according to an embodiment of the present invention.

Since the present invention can apply various transformations and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all transformations, equivalents and substitutes included in the spirit and scope of the present invention.

In describing the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

2 is an exploded perspective view showing a cable connection structure of an overhead distribution line according to an embodiment of the present invention, and FIG. 3 is an exploded cross-sectional view showing a cable connection structure of an overhead distribution line according to an embodiment of the present invention, FIG. 4 is a cross-sectional view showing an assembly state of a cable connection structure of an overhead distribution line according to an embodiment of the present invention, and FIG. 5 is a front view showing a cable connection structure of an overhead distribution line according to an embodiment of the present invention.

Hereinafter, when described in detail with reference to the accompanying drawings, the cable connection structure of the overhead distribution line is obtained by inserting the central conductor 30 in contact with the transformer and one end of the extra-high voltage transformer 100 into the through hole of the insulator 10 . It is fixed in a closed state and is installed in contact with the other end of the central conductor 30, and the configuration is the body 200, the lower fixing plate 210, the upper fixing plate 240, the upper plate 230, and preventing sagging. It is largely divided into a rod 270 .

The body 200 has a configuration capable of supporting the load applied from the state in which the extra-high pressure line 300 of a sufficiently long length is connected, and the guide tube 201 is formed to protrude downward on the bottom surface thereof, and the extra-high pressure line 300 is formed in the center thereof. A receiving groove 203 into which the line 300 is inserted and fixed is formed, and a plurality of screw grooves 204 are formed on the upper surface.

The receiving groove 203 is a rectangular three-dimensional space area with both side ends open, and is configured to be in contact with the inserted extra-high voltage line 300 over a large area.

The width and height of the region formed by the accommodating groove 203 are the same as the diameter of the extra-high voltage line 300, and the length is 3 to 6 times the width, but preferably 5 times the width.

A lower fixing plate 210 for fixing the lower surface of the extra-high voltage line 300 is inserted in the receiving groove 203 , and the upper surface center of the lower fixing plate 210 is connected to the extra-high voltage line 300 . The lower connection pin 211 in electrical contact is formed to protrude upward.

A connecting bar 212 inserted into the guide pipe 201 is installed to protrude from the lower surface of the lower fixing plate 210, and the lower end of the connecting bar 210 is electrically connected to the central conductor 30, The lower fixing plate 210 is elastically installed via a lower spring 220 .

The upper fixing plate 240 is to fix the upper surface of the extra-high voltage line 300, and the lower surface has an arc shape with a central portion facing upward and both ends facing downward so as to stably fix the extra-high voltage line 300. is formed, and a plurality of guide holes 241 into which a guide pin 232 to be described later is inserted is formed.

In addition, the upper spring 250 is elastically installed on the upper surface of the upper fixing plate 240 .

A top plate 230 is installed on the upper portion of the upper fixing plate 240, and a plurality of fixing holes 231 are formed in the top plate 230 to correspond to the screw grooves 204 formed in the body 200, A guide pin 232 inserted into the guide hole 241 is formed to protrude downward from the bottom surface.

In addition, a plurality of fixing bolts 260 are provided to firmly fix the upper plate 230 .

A pair of anti-sag rods 270 are installed on the upper surface of the upper plate 230 to protrude upward, and a fixing string 280 is installed between the upper end of the anti-sag rod 270 and the extra-high voltage line 300 . A winding wheel 291 on which a fixing string 280 is wound is installed on the upper end of the anti-sag rod 270 , and the winding wheel 291 is installed on the driving motor 290 .

The present invention configured as described above will be described in detail as follows.

First, the extra-high voltage line 300 for distributing electricity of 22.9 KV is generally composed of only the core wire 302 through which the extra-high voltage electricity flows without including the covering 301 for insulation, and recently the covering 301 is used. trend that includes

When connecting the extra high voltage line 300 , it is inserted into the receiving groove 203 formed in the upper portion of the body 200 .

The upper plate 230 is installed on the upper portion of the body 200 to prevent the flow of the extra-high voltage line 300 .

In this state, by inserting the fixing bolt 260 into the fixing hole 231 formed in the top plate 230 and rotating the fixing bolt 260, the top plate 230 is screwed into the screw groove 204. to be firmly fixed.

When the upper plate 230 is firmly fixed, the lower spring 220 is compressed by the lower fixing plate 210 and the upper spring 250 is compressed by the upper fixing plate 240 at the same time.

At this time, the lower connection pin 211 formed on the lower fixing plate 210 cuts the covering 301 of the extra-high voltage line 300 and enters into electrical contact with the core wire 302 , and at the same time makes contact by the elastic force of the lower spring 220 . maintained stable for a long time.

On the other hand, the upper fixing plate 240 is pressed by the elastic force of the upper spring 250, and at this time, the guide pin 232 formed on the upper plate 230 is inserted into the guide hole 241 formed on the upper fixing plate 240. Therefore, the upper fixing plate 240 is stably moved in a state in which the flow is prevented.

In addition, since the extra-high voltage line 300 is connected to the anti-sag rod 270 through the fixing string 280, sagging is prevented, and when the extra-high voltage line 300 is sagging when maintaining the installed state for a long period of time, The driving motor 290 is operated to rotate the take-up wheel 291 , and by pulling the fixing string 280 , the deflection of the extra-high voltage line 300 is corrected.

On the other hand, when the extra high voltage line 300 is separated, the upper plate 230 is removed after the plurality of fixing bolts 260 are removed, the lower fixing plate 210 and the extra high voltage line ( 300) moves upward, and can be easily separated.

According to the present invention as described above, the fixing and separation of the extra-high voltage line is simple and easy, and at the same time, since the transformer once installed is maintained for a relatively long time, the electrical contact state is stably maintained during installation.

100: extra high voltage transformer 200: body
201: guide tube 203: receiving groove
204: screw groove 210: lower fixing plate
211: lower connecting pin 212: connecting bar
220: lower spring 230: upper plate
231: fixing hole 240: upper fixing plate
260: fixing bolt 270: anti-sag rod
280: fixing string 290: driving motor
291: winding wheel 300: extra high voltage line

Claims (1)

An overhead distribution line installed in contact with the other end of the central conductor 30 by inserting the central conductor 30 in contact with the transformer at one end of the extra-high voltage transformer 100 into the through hole of the insulator 10 and fixing it in a closed state. In the cable connection structure of the
A guide tube 201 formed to protrude downward from the center of the bottom surface, a receiving groove 203 formed in the center to insert the extra-high voltage line 300, and a body 200 having a plurality of screw grooves 204 formed on the upper surface;
A lower spring 220 is elastically installed in the lower portion of the receiving groove 203 , and a connecting bar 212 connected to the central conductor 30 is installed to protrude from the bottom surface, and an extra high voltage line 300 is provided on the upper surface. ) of the lower fixing plate 210 in which the connecting pin 211 in electrical contact with the core wire 302 is formed to protrude;
an upper fixing plate 240 resiliently installed via an upper spring 250 on the upper portion of the receiving groove 203 to be pressed while in contact with the upper circumferential surface of the extra-high pressure line 300;
an upper plate 230 fixedly installed on the upper portion of the body 200 via a fixing bolt 260 to elastically support the upper spring 250;
an anti-sag rod 270 installed to protrude upward from the upper surface of the upper plate 230;
a fixing string 280 connected and installed between the upper end of the anti-sag rod 270 and the extra-high voltage line 300; and
The cable connection structure of the overhead distribution line, characterized in that it includes a driving motor (290) for rotating the winding wheel (291) installed on the upper end of the sagging prevention bar (270) so that the fixing string (280) is wound.

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