KR20120047478A - Cable jointing method using spiral core - Google Patents

Abstract

PURPOSE: A cable connecting method which uses a helix core is provided to improve coherence between silicon pre-mold and a power cable by directly performing a process which expands internal diameter of the silicon pre-mold and inserts the helix core into the expanded internal diameter in the connection field. CONSTITUTION: A helix core is inserted into silicon pre-mold(113) through an expanding bar. A power cable is cut. The silicon pre-mold and a connection element are inserted into one side or the other side of the power cable. A conductor of the power cable is exposed. Both ends of the conductor are connected by a conductor sleeve(112). The silicon pre-mold is arranged on the conductor sleeve. An inner surface of the silicon pre-mold is closely adhered to the power cable while unwinding the helix core.

Description

Cable connection method using spiral core {CABLE JOINTING METHOD USING SPIRAL CORE}

The present invention relates to a power cable connection method, and more particularly to a room temperature shrinkage pre-mold connection method using a spiral core.

In the intermediate connection method of the ultra-high voltage power cable, various methods are developed and implemented according to the cable type and specification.

Recently, a connection using a room temperature shrink silicone premold has been performed in the XLPE ultra high voltage cable connection method, which is mainly used as an ultra high voltage cable connection method because of the shortening of the connection time and excellent electrical characteristics.

Conventionally, the through-hole is formed in the longitudinal direction of the silicon pre-molded rubber material to insert and fix the cable. When the diameter of the cable inserted into the through-hole of the silicon pre-molded is larger than the diameter of the through-hole, It's difficult to insert it right away, so make sure the silicone premold is already expanded before you insert the cable.

An expansion member for expanding the silicon premold is inserted into the through hole of the silicon premold in advance, and the diameter of the expansion member is formed to be somewhat larger than the diameter of the silicon premold through hole, and the through hole is formed therein.

When the expansion member is inserted into the through hole of the silicon pre-molded and expanded, the cable is inserted into the through-hole of the expansion member and then the expansion member is removed.

However, it is not an easy process to insert an expansion member having an outer diameter larger than the inner diameter of the silicon premold into the silicon premold. Thus, it remains a difficult task to provide a silicon premold with the expansion member inserted.

In order to solve such a difficult problem, a product in which a expansion member is inserted into a silicon pre-mold using expansion technology has been produced and delivered as an assembly in a factory, and in the process of connecting a power cable in the field using the delivered expansion member. I just use it.

However, since the expansion member is placed in the silicon pre-mold in advance before the power cable is connected, the power cable is silicon pre-molded if the silicon pre-mold is left for a long time because the power cable is connected without being used for a long time. Even if the expansion member is removed after insertion, the elastic restoring force of the silicon premold is reduced, thereby causing a problem that the bonding force with the inserted power cable is lowered, which may result in a deterioration in the quality of the ultra-high voltage power system.

The present invention has been made to solve the above problems, to provide a connection method of a room temperature shrinkage pre-folded ultra-high voltage cable.

In addition, the purpose is to facilitate the connection of the ultra-high voltage power cable to facilitate the connection of the ultra-high voltage power cable and to improve the electrical characteristics.

Cable connection method using a spiral core according to the present invention for solving the above problems, Spiral core insertion step of inserting a spiral core wound in a spiral close to the inside of the silicon pre-molded by the extension bar; A conductor connection step of cutting the power cable, inserting the silicon premold and the connection member into one or the other power cable, exposing the conductor and connecting the conductors at both ends by a conductor sleeve; A silicon premold setting step of placing the silicon premold on the conductor sleeve; And a silicon premold adhesion step of connecting the inner surface of the silicon premold to be in close contact with the power cable side while releasing the wound core by pulling the front end of the spiral core inserted into the silicon premold. This can be done.

Here, the extension bar has a first outer diameter and has a rod-type insertion start end portion, a rod type having a second outer diameter larger than the first outer diameter and an inner diameter of a predetermined size, and being inserted while extending the inner diameter of the silicon premold. And an inclined portion having a predetermined slope formed between the insertion end and the expansion portion.

Here, the spiral core insertion step, the insertion step of inserting the insertion end of the extension bar into the inner diameter of the silicon premold; A hydraulic extraction step of connecting the rod bar to the female thread tab formed on the front end surface of the insertion end to draw the extension bar by hydraulic pressure or pneumatic pressure; A core setting step of positioning the helical core into the inner diameter of the extension during the loading step; And an extension bar detachment step in which the extension part is inserted into the silicon premold and the inner diameter of the silicon premold is expanded, and the extension bar is separated from the silicon premold while the spiral core is positioned to the end of the silicon premold. It may be made, including.

According to the configuration of the present invention described above, by providing a connection method of the room temperature shrinkage pre-folded ultra-high voltage cable, it is possible to facilitate the connection of the ultra-high voltage power cable to facilitate the connection process of the ultra-high voltage power cable and improve the electrical characteristics. do.

1 shows a process sequence of a cable connection method using a spiral core according to the present invention.
Figure 2 is a front view of the expansion device used in the cable connection method using a spiral core according to the present invention.
3 is a perspective view of an extension bar used in a cable connection method using a spiral core according to the present invention.
4 and 5 illustrate a process of expanding the inner diameter of the silicon premol according to the present invention and a process sequence for seating the helical core into the silicon premold.

Hereinafter, with reference to the accompanying drawings will be described the process sequence of the cable connection method using a spiral core according to the present invention and the structure of the extension bar used therein and the resulting effects.

1 shows a process sequence of a cable connection method using a spiral core according to the present invention.

First, both power cables 110a and 110b are cut and placed in a state where the conductor, the insulating layer 111a and the semiconductive layer 111b are exposed.

Before the connection, the cut power cables 110a and 110b include a silicon premold 113 and an external protective copper tube (not shown).

In this state, as shown in (a), the conductor sleeve 112 made of the same material connects and compresses the conductor exposed on both power cables 110a and 110b.

Thereafter, as shown in (b), the silicon premold 113 in which the spiral core 114 is embedded is set to the correct position for the connection.

In the state where the silicon premold 113 is set in place as shown in (b), as shown in (c), by holding and pulling one end of the spiral core 114 out of the silicon premold 113 by hand, It is released from the spiral core 114 on the opposite side of the pulling side.

The portion where the spiral core 114 is unwound is contracted toward the power cable 110a by the elastic restoring force of the silicon premold 113 to be in close contact with each other.

Subsequently, when the spiral core 114 is completely released and completely detached from the silicon premold 113, as shown in (d), the silicon premold 113 is contracted by the power cables 110a and 110b to be completely in close contact with each other. .

The silicone premold 113 has excellent elasticity and thus has an outer diameter of D1 before connection, and is contracted when the spiral core 114 is completely released (D1> D2).

Since the process of expanding the inner diameter of the silicon premold 113 and embedding the spiral core 114 in the expanded inner diameter is performed directly at the connection site, the silicon premold 113 that may occur when assembled at a factory or the like and left for a long time. Since the elastic restoring force is not degraded, it is closely adhered to the power cable, so that the bonding force between the silicon premold 113 and the power cable can be increased to the maximum. Will be improved.

Hereinafter, an apparatus and a process of inserting and positioning the spiral core 114 with the inner diameter of the silicon premold 113 and the expanded inner diameter will be described with reference to FIGS. 2 to 5.

Figure 2 is a front view of the expansion device used in the cable connection method using a spiral core according to the present invention.

As shown in FIG. 2, in the expansion device of the silicon premold 113 according to the present invention, a rectangular frame 211 constituting upper, lower, and side surfaces forms a basic base.

On the top of the rectangular frame 211, a cradle 213 on which the extension bar 212 is mounted, a cradle 214 on which the silicon premold 113 is mounted, and a silicon premold so as not to push the silicon premold 113 ( The jig 219 and the jig 219 to which the 113 is coupled are attached, and the silicon pre-molded support 215 to which the jig 219 is attached, and the pressure support 216 and the pressure support 216 to allow reciprocating movement by pressure on the opposite side. It includes a cylinder 221 formed on one side of, and a rod bar 220 reciprocating into the cylinder 221, the rod bar 220 is connected to a pressure not shown device. The pressure adding device may be a pneumatic device or a hydraulic device.

3 is a perspective view of an extension bar used in a cable connection method using a spiral core according to the present invention.

As shown in FIG. 3, the extension bar 212 may be made of a metal material or a synthetic resin material, and may be made of a general structural rolled steel material (SS400).

The extension bar 212 has a first outer diameter and has a cylindrical rod-type insertion start end portion 321 primarily inserted into the inner diameter of the silicon premold 113, and has a second outer diameter larger than the first outer diameter and is spiral. A core insertion portion 325 having an inner diameter of a predetermined size into which the core 323 is inserted is formed, and a cylindrical rod-type expansion portion 323 inserted to expand the inner diameter of the silicon premold 113 and is inserted. It may be made of an inclined portion 322 having a predetermined slope formed between the end 321 and the expansion portion 323.

The core inserting portion 325 may have an inner diameter into which the spiral core 114 may be inserted and may have a length proportional to the length of the spiral core 114.

A female thread tab 324 may be formed on the front end surface of the insertion end portion 321 to fasten the eye bolt 217 that may be connected to the rod bar 220.

4 and 5 illustrate a process of expanding the silicon premold and inserting a spiral core by the expansion bar and the expansion device of the silicon premold according to the present invention.

First, referring to (A), the cylinder 221 is connected to a pressure adding device (not shown) by a pressure hose, and the silicon premolding 113 is fixed to the silicon premolding holder 215 in an extended bar ( The insertion end 321 of the 212 is inserted into the silicon premold 113, and the tip of the inserted extension bar 212 is connected to the hook 218 on the rod bar 220, which is extended by the pressure adding device. It is connected by an eye bolt 217.

Next, referring to (B), the inclined portion 222 of the extension bar 212 in a state in which the extension bar 212 is moved in the right horizontal direction shown by the rod bar 220 in the state of (A) When positioned at the beginning of the silicon premold 113, the spiral core 114 is inserted.

At this time, the spiral core 114 is not completely inserted into the extension bar 212 and is positioned in a state where a part of the tip portion is exposed. This is to release the spiral core 114 in the process (c) of FIG.

Next, referring to (C), the rod bar 220 is continuously drawn by the pressure unit in the right horizontal direction as shown, and the extension bar 212 and the extension bar 212 connected to the rod bar 220 are shown. The spiral core 114 inserted therein also moves in the horizontal direction to the right. In this process, the insertion start end portion 321, the inclined portion 322, and the expansion portion 323 of the expansion bar 212 are continuously inserted into the silicon premolding 113 and the silicon premolding 113 is expanded. The inner diameter is extended by the outer diameter of the part 323.

The spiral core 114 with the tip exposed is inserted behind the extension 323 inserted into the silicon premold 113, and the spiral core 114 is loaded in the silicon premold 113 and fixed. If not, the expansion portion 323 is recontracted from the silicon premold 113 and the recontraction contracts the spiral core 114 to be in close contact with the spiral core 114.

At the point when the silicon premold 113 is in close contact with the spiral core 114, the spiral core 114 is seated inside the silicon premold 113.

Next, referring to (D), the tip of the extension bar 212 is completely detached from the silicon premold 113 by the continuation of the process (C), and the spiral core 114 is formed of the silicon premold 113. Re-shrinkage remains in the silicon premold 113.

Finally, referring to (E), when the silicon premold 113 is removed from the expansion device, the inner diameter thereof is expanded, and the silicon premold 113, which is a finished product having the spiral core 114 inserted therein, can be assembled. The silicon premold 113 can be used for connection as shown in FIG.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, As will be understood by those skilled in the art. Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

110a, 110b: power cable 111a: insulation layer
111b: semiconducting layer 112: conductor sleeve
113: silicon premold 114: spiral core
211 frame 212 extension bar
213, 214: holder 215: silicone free mold holder
216: rod bar pressure support 217: eye bolt
218: hook 219: jig
220: rod bar 221: cylinder
321: insertion end 322: inclined portion
323: extension 324: female thread tap
325: core insertion portion

Claims (3)

A spiral core insertion step of inserting a spiral core wound spirally inwardly into the silicon premold by an extension bar;
A conductor connection step of cutting the power cable, inserting the silicon premold and the connection member into one or the other power cable, exposing the conductor and connecting the conductors at both ends by a conductor sleeve;
A silicon premold setting step of placing the silicon premold on the conductor sleeve; And
A silicon premold adhesion step of connecting the inner surface of the silicon premold to be in close contact with the power cable side while releasing the wound core by pulling the front end of the spiral core inserted into the silicon premold; Cable connection method using core. The method of claim 1,
The extension bar has a first outer diameter and has a rod-type insertion start end, a second outer diameter larger than the first outer diameter and an inner diameter of a predetermined size, and an extension of a rod type inserted while extending the inner diameter of the silicon premold. And a slanted portion having a predetermined slope formed between the insertion end portion and the expansion portion. The method of claim 2,
The spiral core insertion step,
An insertion step of inserting the insertion end of the extension bar into the silicon premolded inner diameter;
A hydraulic extraction step of connecting the rod bar to the female thread tab formed on the front end surface of the insertion end to draw the extension bar by hydraulic pressure or pneumatic pressure;
A core setting step of positioning the helical core into the inner diameter of the extension during the loading step; And
An extension bar detachment step of extending the inner bar of the silicon premolding as the extension part is inserted into the silicon premolding, and extending the bar from the silicon premolding while the spiral core is positioned to an end of the silicon premolding; Cable connection method using a spiral core, including.

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