KR101482926B1 - Fastening structure of insulator for insulation joint box of ultra high voltage power cable - Google Patents

Abstract

[0001] The present invention relates to an insulating barrel fastening structure of an ultra-high voltage power cable insulated junction box, and more particularly, to an insulation barrel fastening structure of an ultra-high voltage power cable insulated fastening barrel which is more easily fastened and more stable through a fastening structure .
The insulated-tube fastening structure of the ultra-high voltage power cable insulated junction box according to the present invention is characterized in that the insulated-tube fastening structure of the ultra high-voltage power cable insulated connection housing comprises: an inner protection of an ultra-high voltage power cable insulated connection housing; a protective material of a copper material connected to the metal sheath of the ultra- Wherein at least one pop nut (POP NUT) is inserted into the outside of the insulating tube, a hole is formed in the protective pipe at a position corresponding to the pop nut, The pop nut and the hole are positioned in correspondence with each other while the insulating tube is engaged, and the washer is fitted to the pop nut side and the nut is tap-fastened.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a high-voltage power cable,

[0001] The present invention relates to an insulating barrel fastening structure of an ultra-high voltage power cable insulated junction box, and more particularly, to an insulation barrel fastening structure of an ultra-high voltage power cable insulated fastening barrel which is more easily fastened and more stable through a fastening structure .

In the case of ultra-high voltage power cable, especially underground cable, it is installed between power plant and substation. Connection of power cable is necessary every section interval according to total installation length.

Generally, the connection between the power cables is achieved by exposing the conductor embedded in the center of both power cables, connecting the conductors of both power cables through a sleeve, which is electrically connected to each other, Insulating materials made of various kinds of insulating material epoxy, insulating paper, rubber, etc. are inserted.

After the connection is completed, a protective pipe that acts like a metal sheath of the power cable is finally connected to both sides.

One of these protective pipes is connected to each other by the metal sheath of the power cable and the lead pipe is connected to the other, and the protective pipes are connected to each other.

Among the connection boxes, an intermediate connection box connecting the middle portion is provided with a normal connection box which connects only the ultra-high voltage cable and an insulation connection which is used to insulate the left and right sheaths of the cable from each other and to reduce the loss due to the sheath current, Respectively.

In the case of an insulated junction box, the protection tubes on the left and right sides and an insulator for insulating the sheaths from each other are assembled.

In the past, the insulation box was molded by using an epoxy material. However, in view of the weight and cost reduction, the molded article of the synthetic resin material is mainly used.

The thickness of the insulation tube made of synthetic resin is thin, and the thickness of the protection tube is also becoming thinner due to the rise of the raw material.

1 schematically shows an example of an insulated connection box to which an insulated-pass protection pipe is fastened.

The first protection tube 130a is inserted into the left power cable 120a and the second protection tube 130b is inserted into the right power cable 120a. The protection tube 130a, . The protective pipes 130a and 130b are made of the same material.

Between the protective pipes 130a and 130b, an insulating tube 140 for the purpose of sheath insulation is interposed and fastened.

The insulating tube 140 is made of a synthetic resin material rather than an old epoxy molded product and the protective tubes 130a and 130b are formed with holes for fastening the screws 150 and the insulating tube 140 is formed with screw taps 150) coupling the protection tubes 130a, 130b and the insulation tube 140.

However, as the insulation tube 140 is changed to a synthetic resin material rather than an epoxy molded article, its thickness is thinned and its strength is weaker than that of an epoxy molded article, so that there is a problem that the fastening strength by the screw 150 is lowered.

Also, since the synthetic resin material has screw tabs formed thereon, the problem that the screw tabs are easily distorted due to the synthetic resin material is often caused.

In addition, the problem of lowering the strength of the fastening portion of the screw 150 due to long-time power loading in the field installation also became a problem.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the related art, and various types of fastening structures have been proposed for reinforcing the fastening of the synthetic resin insulated passage protecting tube of the insulating connection box for an ultra-high voltage cable.

In addition, the installed ultra-high voltage cable is left in a state of being loaded for a long time, so that the fastening structure of the insulated passing protection pipe is strengthened to improve the reliability of the connection box.

According to an aspect of the present invention, there is provided an insulation block fastening structure for an ultra-high voltage power cable insulation connection block, comprising: an inner protection block for an ultra-high voltage power cable insulation connection block; a copper protective pipe connected to the metal sheath of the ultra- Wherein at least one pop nut is inserted in the outer side of the insulating tube, and the protection tube is provided with a hole at a position corresponding to the pop nut, And the pop nut and the hole are positioned to correspond to each other with the protection tube and the insulating tube engaged with each other, and the washer is fitted into the pop nut and the nut is tap-fastened.

Here, the length of the pop nut may be smaller than the thickness of the insulation barrel.

Here, the length of the pop nut may be equal to the thickness of the insulation barrel.

The pop nut may have a length equal to the thickness of the insulation barrel, and a pop nut head portion abutting the inner surface of the insulation barrel may be formed at one end of the pop nut.

Further, the insulation block fastening structure of the ultra-high voltage power cable insulated connection block according to the present invention is characterized in that the insulation block fastening structure of the ultra high voltage power cable insulated connection block includes an inner protection of the ultra high voltage power cable insulation connection case and a copper protective pipe connected to the metal sheath of the ultra- At least one floating pin hole is formed on the outer side of the insulating tube, one or more 'A' shaped fixing pin grooves are formed at both ends of the insulating tube, and the protective tube And a fixing pin to be fastened to the fixing pin groove is formed by soldering, and the protection tube and the insulating tube are fixed to the fixing pin, And the floating pin is engaged with the hole and the floating pinhole in a state of being engaged with each other through the pin groove .

According to the above-described structure of the present invention, various types of fastening structures are proposed for reinforcing the fastening of the synthetic resin insulated passage protective tubing of the ultra-high voltage cable insulated connection case, and a connection due to long time loading of the ultra high voltage cable The reliability of the container can be increased.

FIG. 1 is a view showing a fastening structure of an insulation-passing protection tube of a conventional ultra-high voltage cable insulation connection box.
FIG. 2 is a view showing a fastening structure of an insulation-passing protection pipe of an ultra-high voltage cable insulation connection box according to the present invention.
Fig. 3 is a first embodiment of an insulation barrel fastening structure of an ultra-high voltage power cable insulation connection box according to the present invention.
Fig. 4 is a second embodiment of an insulation barrel fastening structure of an ultra-high voltage power cable insulation connection box according to the present invention.
FIG. 5 is a third embodiment of an insulating cylinder fastening structure of an ultra-high voltage power cable insulation connecting box according to the present invention.
FIG. 6 is a fourth embodiment of an insulation barrel fastening structure of an ultra-high voltage power cable insulation connection box according to the present invention.

Hereinafter, an insulating tub fastening structure and an operation and effect of an ultra-high voltage power cable insulated connection box according to the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a view showing a fastening structure of an insulation-passing protection pipe of an ultra-high voltage cable insulation connection box according to the present invention.

A pair of protective pipes 220a and 220b as an inner protective pipe are connected to the outer circumference of the insulating tub 230 for the high voltage cable, As shown in Fig. The protective tubes 220a and 220b and the insulating tube 230 have a substantially cylindrical structure.

The protective pipes 220a and 220b are made of a metal material in consideration of mechanical strength, and are made of a copper pipe made of a copper material having excellent conductivity and a copper pipe formed by rolling a copper plate.

The insulation barrel 230 is made of an insulating material. Recently, a light and cheap synthetic resin material is used in the form of a tube.

The protective tubes 220a and 220b and the insulating tube 230 are structured to be fastened by bolts without flanges. Particularly, since the protective pipes 220a and 220b are made of metal and the insulating tube 230 is made of synthetic resin, when a synthetic resin material and a metal material are stacked and fastened by a screw and nut assembly 240 or the like, a nut or the like is fastened It is important to increase the strength of the clamping structure of the protective pipe and the insulating pipe.

3 to 6, a coupling structure of a protective tube and an insulating tube is specifically disclosed.

Fig. 3 is a first embodiment of an insulation barrel fastening structure of an ultra-high voltage power cable insulation connection box according to the present invention.

As shown in the drawing, the insulation block fastening structure of the ultra-high voltage power cable insulation connection box according to the present invention is constructed such that the left and right protection pipes 320a and 320b are aligned with the insulation barrel 330 in which the pop nut 360 is inserted, And screwed with the pop nut 360 with the screw 340 in the state of FIG.

Such a fastening structure can reinforce the mechanical strength as compared with a structure in which a screw tab is formed in an insulating cylinder itself, which is a conventional synthetic resin, and is assembled with screws or bolts.

Particularly, in the first embodiment, the length L of the pop nut 360 is smaller than the thickness T of the insulating barrel 330, and preferably the length of the insulating barrel 330 is about 1 / As shown in Fig.

The insulating cylinder 330 into which the pop nut 360 is inserted can be made higher in rigidity than when the screw tab is formed directly on the synthetic resin material and the tightening force between the insulating cylinder 330 and the protective pipes 320a and 320b can be increased .

The high-strength fastening structure of the insulating tube 330 and the protection tubes 320a and 320b can improve the connection quality of the ultra-high voltage cable insulation connection box and is very important factor in securing reliability according to long- .

Fig. 4 is a second embodiment of an insulation barrel fastening structure of an ultra-high voltage power cable insulation connection box according to the present invention.

As shown in the drawing, the insulation barrel fastening structure of the ultra-high voltage power cable insulated connection box according to the present invention is constructed such that the left and right protection pipes 420a and 420b are aligned with the insulation barrel 430 in which the pop nut 460 is inserted, The nut 440 is screwed to the pop nut 460 with the screw 440, thereby increasing the mechanical strength.

Particularly, in the second embodiment, the length L of the pop nut 460 is formed to be equal to the thickness T of the insulation barrel 430, that is, The fastening length between the screw 440 and the pop nut 460 becomes longer as compared with the first embodiment, and the mechanical fastening strength can be further reinforced.

FIG. 5 is a third embodiment of an insulating cylinder fastening structure of an ultra-high voltage power cable insulation connecting box according to the present invention.

As shown in the figure, the insulation block fastening structure of the ultra-high voltage power cable insulation connection box according to the present invention is constructed such that the left and right protection pipes 520a and 520b are aligned with the insulation barrel 530 in which the pop nuts 560 are inserted, And the screw 540 is screwed to the pop nut 560 in the state where the screw 540 is screwed to increase the mechanical strength.

Particularly, in the third embodiment, the length L of the pop nut 560 is formed to be equal to the thickness T of the insulating barrel 550, and the pop nut head 560a is protruded to the inside of the insulating barrel 550 The pop nut 560 is formed over the entire thickness T of the insulation barrel 530 so that the head portion 560a of the pop nut protrudes from the inner surface of the insulation barrel 530 and is brought into close contact therewith.

As a result, the fastening length between the screw 540 and the pop nut 560 becomes longer and the pop nut head portion 560a comes into close contact with the inner surface of the insulating cylinder 530 The head portion of the screw 540 and the pop nut head portion 560a are more firmly fastened to the insulating tube 530 and the protective pipes 520a and 520b at both ends to thereby advantageously reinforce the mechanical fastening strength relatively .

FIG. 6 is a fourth embodiment of an insulation barrel fastening structure of an ultra-high voltage power cable insulation connection box according to the present invention.

The first to third embodiments of the present invention are a fastening structure in which a fastening force with a protective pipe is increased by inserting a pop nut into an insulating cylinder, whereas the fourth embodiment of the present invention shown in Fig. .

6, a plurality of flow pinholes 650 are formed on the outer side of the insulating cylinder 630, and at least one 'A' shaped fixing pin groove 660 is formed on both ends of the insulating cylinder 630.

A fixing pin 670 is formed on the outer surface of the protective pipes 620a and 620b by silver solder at a position corresponding to the fixing pin groove 670.

In this state, the fixing pins 670 of the protective pipes 620a and 620b are inserted into the fixing pin groove 660 side of the insulating cylinder 630 in the direction of the arrow. That is, when inserting the fixing pin 670 horizontally into the fixing pin groove 660 when the insulating cylinder 630 is fastened to the protective pipes 620a and 620b and rotating the insulating cylinder 630 by a predetermined angle, The fixing pin groove 660 and the fixing pin 670 are engaged.

This state is a state in which the insulating cylinder 630 and the protective pipes 620a and 620b are engaged with each other, but there is no fastening force.

Therefore, when the insulating pin 630 and the protective pipes 620a and 620b are engaged with each other, the floating pin 640 is used to penetrate the floating pinhole 650 coinciding with the holes of the protective pipes 620a and 620b, And the protective pipes 620a and 620b. The floating pin 640 may preferably be fastened in a fit-fit manner.

The fastening force of the floating pin 640 and the floating pinhole 650 alone may cause a problem of the fastening force for the protective pipes 620a and 620b due to the fastening force of the insulating tube 630 and the protective tubes 620a and 620, 670 and the fixing pin groove 660 can only be engaged with the insulating tube 630 and the protective pipes 620a and 620b but the fastening force is too weak so that the flow pin 640, The pin 670 and the fixing pin groove 660 are configured to complement each other to enhance the fastening force of the insulating tube 630 and the protective tubes 620a and 620b.

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.

210: Insulated connection box
220a, 220b, 320a, 320b, 420a, 420b, 520a, 520b, 620a, 620b:
230, 330, 430, 530, 630: Insulation barrel 240: Screw and nut assembly
340, 440, 540: screws 350, 450, 550: washers
360, 460, 560: Pop nut 560a: Pop nut head
640: floating pin 650: floating pin hole
660: Fixing pin groove 670: Fixing pin

Claims (5)

A structure for fastening an insulation barrel of a synthetic resin material interposed between a protective pipe of a copper material and a protective pipe connected to a metal sheath of the ultra-high voltage power cable to intercept the flow of current between the protective pipes,
Wherein the insulation barrel is cylindrical and has at least one pop nut inserted therein,
Wherein a hole is formed at a position corresponding to the pop nut at the tip of the protective tube,
Wherein the pop nut and the hole are positioned in correspondence with each other and are tap-fastened by a screw in a state where the tip end portion of the protective pipe is engaged with the outside of the insulating tube. The method according to claim 1,
And the length of the pop nut is smaller than the thickness of the insulation barrel. The method according to claim 1,
And the length of the pop nut is formed to be equal to the thickness of the insulation barrel. The method according to claim 1,
The length of the pop nut is formed to be equal to the thickness of the insulating cylinder,
And the pop nut has a pop nut head portion formed at one end of the pop nut so as to abut the inner side surface of the insulating tube. A structure for fastening an insulation barrel of a synthetic resin material interposed between a protective pipe of a copper material and a protective pipe connected to a metal sheath of the ultra-high voltage power cable to intercept the flow of current between the protective pipes,
At least one floating pin hole is formed on the outer side of the insulating tube, and one or more 'A' shaped fixing pin grooves are formed on both ends of the insulating tube,
A hole through which the floating pin can be inserted is formed at a position corresponding to the floating pinhole outside the protective pipe, a fixing pin to be fastened to the fixing pin groove is formed by soldering,
Wherein the shield pin and the insulating case are fastened to each other by inserting the floating pin into the hole and the floating pin hole with the fixing pin and the fixing pin groove engaged with each other.

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