KR20160091645A - Termination connection box - Google Patents

Abstract

The present invention relates to a termination connection box of a power cable. More particularly, the termination connection box comprises an insulating tube into which the power cable is inserted, a sleeve which is formed in the exposed end of an external semiconducting layer of the power cable and releases electric field concentration, a sleeve support part which penetrates the power cable and supports the sleeve, and a cable fixing part which is formed between the sleeve support part and the power cable and fixes the power cable. So, damage to the sleeve can be prevented.

Description

Termination connection box

The present invention relates to an end connection of a power cable.

Generally, a power cable is used to power a desired location through the ground, ground, or seabed using a power-supplying conductor. It is very important to insulate the conductor from such a power cable. For this purpose, the insulation layer for inserting the conductor may be made of XLPE (Cross-linked Polyethylene) or the like as a raw material.

The power cable is connected by a joint box at intervals of several hundred meters or tens of km, and the end of the power cable is connected by a termination connection box. The termination junction box can be classified into an air termination junction box, a gas termination junction box, and an oil termination junction box, depending on the connected state of the conductor ends of the cables.

The power cable can be inserted into the terminal connection box and connected to the working line. In this case, a sleeve and an electric field relieving cone may be provided to mitigate the concentration of the electric field in the interior of the pipe.

5 is a partially enlarged cross-sectional view of a termination box according to the prior art.

5, the outer semiconductive layer 16 and the insulating layer 14 of the power cable 100 are sequentially exposed in the interior of the aerator, and the reinforcing tape 232 is formed on the outer periphery of the outer semiconductive layer 16. [ .

At this time, the sleeve 310 and the electric field relieving cone 300 may be formed of rubber or the like, and the inner diameter of the sleeve 310 and the electric field relieving cone 300 may be enlarged to fit the end of the outer semiconductive layer 16 of the power cable 100. The sleeve 310 is supported by the compression force of the sleeve 310 and further includes a sleeve supporting part 400 for supporting the sleeve 310.

However, the power cable 100 connected to the termination box can have various diameters. Therefore, it is a burden to the manufacturer to provide all the sleeve supporting portions having various diameters corresponding to the power cable 100 having the various diameters when preparing the termination junction box. . Therefore, the sleeve supporting portion can be provided so that its inner diameter is standardized and can be used universally. Therefore, when inserting the cable into the sleeve supporting portion, a predetermined distance d may be generated between the inner surface of the power cable and the inner surface of the sleeve supporting portion.

Further, when inserting the power cable into the sleeve support portion, the inner diameter of the sleeve support portion may be relatively larger than the outer diameter of the power cable to facilitate the inserting process. Thus, a space may occur between the power cable and the inner wall of the sleeve support.

When a space is formed between the inner wall of the sleeve supporting part and the outer diameter of the power cable as described above, the power cable can be pulled in one direction from the inside of the sleeve supporting part, The power cable 100 may not be maintained at a constant interface. If the interface of the sleeve 310 is not constant, the insulation performance of the termination box can be lowered.

It is an object of the present invention to provide an end connection box capable of preventing the movement of the power cable when the power cable is inserted into a sleeve support portion for supporting the sleeve in a termination connection of the power cable.

Another object of the present invention is to provide a termination box capable of preventing breakage of the sleeve by the sleeve supporting portion when the sleeve is supported by the sleeve supporting portion.

According to another aspect of the present invention, there is provided an electric power steering system comprising: an electric power cable; an electric power cable; a power cable; a power cable; a power cable; And a cable fixing part provided between the sleeve supporting part and the power cable to fix the power cable.

The cable fixing part may be provided between the sleeve supporting part and the power cable at the end of the sleeve supporting part to fix the power cable in the sleeve supporting part.

Further, the cable fixing portion may have a length longer than a distance between an end of the sleeve supporting portion and a lower end of the sleeve.

The cable fixing portion may have a thickness equal to or less than a difference between an inner diameter of the sleeve supporting portion and an outer diameter of the power cable.

The cable fixing part may include a body part having an opening through which the power cable passes, and a lid part surrounding the end of the sleeve supporting part at one end of the body part.

In addition, the sleeve is fixed to the power cable in an interference fit type, and the sleeve supporting portion extends upward from a lower end of the aptube to support the sleeve at a lower end of the sleeve.

According to the present invention, when the power cable is inserted, the movement of the power cable can be prevented by inserting the cable fixing portion inside the sleeve support portion supporting the sleeve. Whereby the interface between the sleeve and the power cable can be kept constant.

In addition, according to the present invention, when the sleeve is supported by the sleeve supporting portion, the end of the sleeve supporting portion is enclosed by the cable fixing portion, so that breakage of the sleeve by the sleeve supporting portion can be prevented.

1 is a perspective view showing an internal configuration of a power cable,
2 is a partial cross-sectional view illustrating a termination box according to one embodiment;
FIG. 3 is an enlarged view of the 'A' region of FIG. 2,
4 is a perspective view of the cable fixing portion,
5 is a partial cross-sectional view showing a configuration of a conventional terminal connection box.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like reference numerals designate like elements throughout the specification.

1 is a perspective view showing an internal configuration of a power cable 100. As shown in Fig.

Referring to FIG. 1, the power cable 100 has a conductor 10 along its center. The conductor 10 serves as a passage through which electric current flows, and may be composed of, for example, copper or aluminum. The conductor (10) is constituted by twining a plurality of element wires (11).

However, the surface of the conductor 10 is not smooth, so that the electric field may be uneven and corona discharge tends to occur partially. In addition, when a gap is formed between the surface of the conductor 10 and the insulating layer 14 described later, the insulating performance may be deteriorated. In order to solve such a problem, the outer surface of the conductor 10 is covered with a semiconductive material such as semiconductive carbon paper, and the layer formed by the semiconductive material is defined as the inner semiconductive layer 12.

The inner semiconductive layer 12 uniformizes the charge distribution on the conductive surface to make the electric field uniform, thereby improving the dielectric strength of the insulating layer 14 described later. Furthermore, the formation of a gap between the conductor 10 and the insulating layer 14 is prevented to prevent corona discharge and ionization. The inner semiconductive layer 12 also prevents penetration of the insulating layer 14 into the conductor 10 when the power cable 100 is manufactured.

An insulating layer 14 is provided on the outside of the inner semiconductive layer 12. The insulating layer 14 electrically insulates the conductor 10 from the outside. In general, the insulating layer 14 should have a high breakdown voltage, and the insulating performance must be stable for a long period of time. Furthermore, it should have low dielectric loss and resistance to heat such as heat resistance. Therefore, polyolefin resin such as polyethylene and polypropylene is used for the insulating layer 14, and a polyethylene resin is preferable. The polyethylene resin may be a crosslinked resin, and may be produced by a silane or an organic peroxide such as, for example, dicumylperoxide (DCP) as a crosslinking agent.

On the other hand, if not only the inside but also the outside of the insulating layer 14 is not shielded, a part of the electric field is absorbed by the insulating layer 14, but most of the electric field is discharged to the outside. In this case, if the electric field becomes larger than a predetermined value, the insulating layer 14 and the outer surface of the power cable 100 may be damaged by an electric field. Therefore, a semiconductive layer is provided on the outer side of the insulating layer 14 and is defined as an outer semiconductive layer 16 to distinguish it from the inner semiconductive layer 12 described above. As a result, the outer semiconductive layer 16 serves to improve the dielectric strength of the insulating layer 14 by making the distribution of the lines of electric force between the inner semiconductive layer 12 and the inner semiconductive layer 12 equal. Further, the outer semiconductive layer 16 can smooth the surface of the insulating layer 14 in the cable, thereby alleviating the electric field concentration, and preventing the corona discharge.

A shielding layer 18 made of a metal sheath or a neutral wire is provided outside the outer semiconductive layer 16 in accordance with the type of the cable. The shielding layer 18 is provided for electrical shielding and return of short-circuit current.

A jacket (20) is provided on the outer side of the power cable (100). The sheath 20 is provided on the outer side of the cable 100 to protect the internal structure of the cable 100. Therefore, the outer cover 20 is excellent in chemical resistance and mechanical strength to withstand chemicals such as weatherability, chemical substances, and the like, which can withstand various environments such as light, weather, moisture and air in various climatic conditions. Generally, it is made of PVC (Polyvinyl Chloride) or PE (Polyethylene).

Fig. 2 shows a terminal connection box connecting the power cable having the above-described configuration with a work line.

Referring to FIG. 2, the termination box 1000 has an eyelet 110.

The air pipe 110 has a predetermined space therein, and the cable 100 is inserted into the cable pipe 100 through a predetermined length as described later. The cap 110 serves to insulate and support the cable. Thus, the aerator 110 has a plurality of wrinkles or protrusions 105 along the surface to have sufficient electrical insulation strength. It is possible to increase the insulation distance by the wrinkles or protrusions and to prevent the dielectric strength from deteriorating. The cap 110 is fabricated using a hard magnetic body to maintain an appropriate level of strength while having an insulating proof force.

On the other hand, the inner semiconductive layer 12 of the cable 100 and the outer semiconductive layer 16 distribute evenly the electric lines of force having the equal potential therebetween, thereby preventing breakdown of the insulator and further preventing the electric field from being concentrated at a specific site . That is, the equipotential lines of the electric lines of force between the inner semiconductive layer 12 and the outer semiconductive layer 16 are preferably dispersed as evenly as possible.

The cable 100 penetrates through the eyelet 110 and the conductor 10 of the cable 100 protrudes through the end of the eyelet 110 by a predetermined length. The cable 100 is stripped of the components surrounding the conductor 10 inside the ape 110 and only the conductor 10 is exposed and protruded at the end of the ape 110 to be connected to the work line (not shown). That is, when the cable 100 is inserted into the aisle 110 of the termination box 1000, the cable 100 is removed from the outer semiconducting layer 16 by removing the insulating layer 14, 110). In this case, the unremoved outer semiconductive layer 16 is inserted into the eyelet 110 by a predetermined length. That is, the cable 100 is inserted into the eyelet 110 by exposing the insulating layer 14, and the outer semiconductive layer 16 is inserted into the predetermined length eyelet 110.

Meanwhile, the insulating pipe 120 may be filled in the inner pipe 110. The insulating oil 120 flows between the cable 100 and the inner wall of the pipe 110 inside the pipe 110 to electrically isolate the oil.

When the cable 100 in which the part of the outer semiconductive layer 16 is removed so as to expose the insulating layer 14 is inserted and the outer peripheral surface of the outer semiconductive layer 16 The electric field can be concentrated at the ends of the electrodes 16, This may cause breakage of the outer semiconductive layer 16 and the insulating layer 14. Therefore, the sleeve 310 and the electric field relieving cone 300 may be provided in the inner pipe 110 to reduce the concentration of the electric field of the cable 100.

The sleeve 310 and the electric field relieving cone 300 are provided along the outer circumference of the power cable 100 adjacent to the end of the outer semiconductive layer 16 of the power cable 100. The sleeve 310 and the electric field relieving cone 300 prevent an equipotential line from breaking at an end of the outer semiconductive layer 16 to alleviate an electric field that can be concentrated at the end of the outer semiconductive layer 16 .

Meanwhile, in the present embodiment, the sleeve 310 may be made of a material having elasticity such as rubber. When the sleeve 310 is mounted on the power cable 100, the inner diameter of the sleeve 310 is expanded to a predetermined size and the power cable 100 is inserted into the sleeve 310, 310) in the form of interference.

2, because the sleeve 310 is fixed to the sleeve 310 by the self weight of the sleeve 310 as described above, The sleeve 310 can be pushed downward toward the ground. Accordingly, the sleeve 310 may be provided with a sleeve support 400 for supporting the sleeve 310 to prevent the sleeve 310 from being pushed downward.

The sleeve support part 400 may be connected to the lower base of the termination box 1000 and may extend a predetermined length from the lower end of the aisle 110 to the upper side. The end of the sleeve support 400 may be overlapped with a lower end of the sleeve 310 as shown in FIG. Accordingly, the lower end of the sleeve 310 is opened and fitted to the upper end of the sleeve support portion 400, thereby fixing the sleeve 310. Further, a band 610 may be provided along the outer periphery of the sleeve 310, and taping 600 may be performed by tape or the like so as to surround the band 610.

The power cable 100 connected to the termination box 1000 may have a variety of diameters. Referring to FIG. Therefore, it is a burden to the manufacturer to provide all the sleeve supporting portions having various diameters corresponding to the power cable 100 having the various diameters when preparing the termination junction box. . Therefore, the sleeve supporting portion can be provided so that its inner diameter is standardized and can be used universally. Therefore, when inserting the cable into the sleeve support portion, a predetermined separation distance may occur between the inner diameter of the power cable and the sleeve support portion.

Further, when inserting the power cable into the sleeve support portion, the inner diameter of the sleeve support portion may be relatively larger than the outer diameter of the power cable to facilitate the inserting process. Thus, a space may occur between the power cable and the inner wall of the sleeve support.

When a space is formed between the inner wall of the sleeve supporting part and the outer diameter of the power cable as described above, the power cable can be pulled in one direction from the inside of the sleeve supporting part, The power cable 100 may not be maintained at a constant interface. If the interface of the sleeve 310 is not constant, the insulation performance of the termination box can be lowered.

Therefore, in the present invention, a cable fixing part 500 may be provided between the sleeve supporting part 400 and the power cable 100 to fix the power cable 100.

More specifically, the cable fixing part 500 is provided between the sleeve supporting part 400 and the power cable 100 at the upper end of the sleeve supporting part 400, ) Is fixed so as not to be directed toward one side.

4 is a perspective view showing the cable fixing part 500. FIG.

4, the cable fixing part 500 includes a body part 510 having an opening 530 through which the power cable 100 passes and an end part of the body part 510, And a lid 520 surrounding the end of the support 400.

The cable fixing part 500 may be composed of synthetic fibers such as Teflon, nylon, etc., and may have a substantially cylindrical shape with upper and lower portions opened.

Meanwhile, the sleeve support portion 400 may be made of metal or the like, and the sleeve 310 may be made of rubber or the like. When the sleeve 310 is supported by the sleeve supporter 400, the upper end of the sleeve supporter 400 contacts the sleeve 310 to damage the sleeve 310 . In this case, the electric field relaxation effect by the sleeve 310 is lowered.

Therefore, in the present invention, one end of the cable fixing part 500 disposed adjacent to the upper end of the sleeve supporting part 400 may have a lid 520 surrounding the upper end of the sleeve supporting part 400 . The cover 520 includes an inclined portion 522 having a predetermined inclination on the outer side and the inclined portion 522 surrounds the upper end of the sleeve support portion 400 to support the sleeve support portion 400 It is possible to prevent the sleeve 310 from being damaged.

3, the cable fixing part 500 may have a length longer than a distance between an upper end of the sleeve supporting part 400 and a lower end of the sleeve 310. [ 3, the upper end of the cable fixing part 500 covers the upper end of the sleeve supporting part 400, and the lower end of the cable fixing part 500 is connected to the sleeve (not shown) 310). ≪ / RTI >

Meanwhile, the cable fixing part 500 is provided between the sleeve supporting part 400 and the outer diameter of the power cable 100. If the thickness of the cable fixing part 500 corresponds exactly to the difference between the inner diameter of the sleeve supporting part 400 and the outer diameter of the power cable, the cable fixing part 500 is fixed to the sleeve supporting part 400, The inserting process may be difficult when inserting the inserter 100 between the inserting process. Particularly, when the reinforcing tape 232 is wrapped around the outer semiconductive layer 16 of the power cable 100, the thickness of the cable fixing part 500 should be determined in consideration of the thickness of the reinforcing tape 232 do. Therefore, in this embodiment, the thickness of the cable fixing part 500 may be determined so as to have a thickness equal to or less than the difference between the inner diameter of the sleeve supporting part 400 and the outer diameter of the power cable 100. The outer diameter of the reinforcing tape 232 provided on the outer periphery of the outer semiconductive layer 16 of the power cable 100 and the inner diameter of the sleeve support portion 400 may be determined to have a thickness equal to or less than the difference between the outer diameter of the reinforcing tape 232 and the inner diameter of the sleeve support portion 400 .

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the following claims. . It is therefore to be understood that the modified embodiments are included in the technical scope of the present invention if they basically include elements of the claims of the present invention.

10. Conductor
12. Internal semiconducting layer
14. Insulation layer
16 .. outer semiconductive layer
20. Metal sheath
100 ... power cable
110 .. Affection
300 .. Field Relief Cone
310 ... Sleeve
1000 .. Termination box

Claims (6)

An electric cable into which a power cable is inserted;
A sleeve provided at an end of the exposed outer semiconductive layer of the power cable to alleviate field concentration;
A sleeve support portion provided to penetrate the power cable to support the sleeve; And
And a cable fixing part provided between the sleeve supporting part and the power cable to fix the power cable. The method according to claim 1,
Wherein the cable securing portion is provided between the sleeve support portion and the power cable at an end of the sleeve support portion to secure the power cable within the sleeve support portion. 3. The method of claim 2,
Wherein the cable fixing portion has a length longer than a distance between an end of the sleeve supporting portion and a lower end of the sleeve. 3. The method of claim 2,
Wherein the cable fixing portion has a thickness equal to or less than a difference between an inner diameter of the sleeve supporting portion and an outer diameter of the power cable. 3. The method of claim 2,
Wherein the cable fixing portion includes a body portion having an opening through which the power cable passes, and a lid portion surrounding the end portion of the sleeve supporting portion at one end of the body portion. The method according to claim 1,
Wherein the sleeve is secured to the power cable in an interference fit manner and the sleeve support extends upward from a lower end of the aisle to support the sleeve at a lower end of the sleeve.

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