KR20190050544A - Connecting Structure of Power Cable Conductor And Connecting Method Of The Same - Google Patents

Abstract

The present invention relates to a conductor connection structure of a power cable, which reduces a connection work time and minimizes quality deviation of a connection work to minimize costs for a power cable connection work. The conductor connection structure of a power cable comprises: a pair of cable conductors; a pipe shaped sleeve member having openings of both ends into which the conductors are inserted and provided with a plurality of coupling holes; a plurality of conductive particles inputted into a holding space between ends of the pair of conductors inserted into the sleeve member to electrically connect the pair of conductors; at least one conducting bolts pressing the conductive particles inputted into the holding space to be coupled to the coupling holes of the sleeve member for electrically connecting the conductors; and fixation bolts coupled to the coupling holes of the sleeve member for fixating the conductors inserted into the sleeve member.

Description

A conductor connecting structure of a power cable and a conductor connecting method of a power cable

The present invention relates to a conductor connecting structure of a power cable and a conductor connecting method of the power cable. More particularly, the present invention relates to a conductor connecting structure of a power cable and a conductor connecting method of the power cable, which can minimize the work time of the conductor connecting work and minimize the deviation of the quality of the connecting work, .

As the conductor portion of the power cable, a copper (Cu) conductor or an aluminum (Al) conductor may be used as a conductor. Further, in many cases, a conductor portion is formed by combining a plurality of element wires for bending property or the like.

Further, in the case of a copper conductor due to the skin effect of the metal or the like at the time of current conduction, a plurality of small wires can constitute insulated single wire insulated conductors, respectively.

In the case of connecting such a power cable, conventionally, the insulating layer of each wire constituting the conductor portion is removed and the wire is assembled again, and the conductor portion of the two power cables to be connected is brought into contact with each other.

However, the method of removing the insulating layer of each of the strands constituting the conductor and collecting them again and connecting the conductor portions of both cables by the pressing method requires a long working time, and the potential quality There is a risk that it requires considerable work skill.

An object of the present invention is to provide a conductor connecting structure of a power cable capable of minimizing the work time of the connecting operation and minimizing the variation in the quality of the connecting operation and minimizing the cost of the connecting operation of the power cable.

According to an aspect of the present invention, there is provided a conductor connection structure of a power cable for connecting a conductor section composed of a plurality of strands of a power cable, the conductor connection structure comprising: a conductor section of a pair of cables; A pipe-shaped sleeve member having a plurality of coupling holes inserted into the openings at both ends of the conductor portion; A plurality of conductor particles inserted into the space between the end portions of the pair of conductor portions inserted into the sleeve member to electrically connect the pair of conductor portions; At least one bolt for bolt fastened to the fastening hole of the sleeve member to press the conductor particles inserted into the accommodating space to electrically connect the pair of conductor portions; And a fastening bolt fastened to the fastening hole of the sleeve member to fasten the conductor portion inserted into the sleeve member.

In addition, the penetration bolt and the fixing bolt may be a fracture bolt in which the head portion is broken and separated when a torque greater than a predetermined magnitude is applied.

The width of the receiving space may be smaller than the width of the threaded body portion of the bolt.

Here, the maximum width of the conductive particles may be 5% to 20% of the width of the accommodation space.

In this case, when the penetration bolt is fastened in the state that the conductor particles are inserted into the accommodation space, the penetration bolt is contacted with the end side face of the conductor portion and the conductor particles compressed by the penetration bolt, .

The conductive particles may be made of silver, copper, or an alloy thereof, or may be a metal material plated with silver, copper, or an alloy thereof.

The conductor particles may be formed by silver-plating a cut copper wire or a cut copper wire.

Here, the sleeve member may be made of tin-plated copper or tin-plated copper alloy.

In this case, the fastening bolt and the bolt for bolting may be made of brass or brass alloy.

In addition, a plurality of bolt-in fastening holes for fastening the bolt to the sleeve may be formed at predetermined intervals along the circumferential direction at the center of the sleeve member.

A plurality of fastening holes for fastening the plurality of fastening bolts may be spaced apart from the central portion of the sleeve member.

Here, the insertion hole may be inserted in the tub tightening hole to limit the insertion depth of the conductor portion in the process of inserting the conductor portion into the sleeve of the conductor portion.

In this case, the barrel-dedicated fastening hole may be formed at a symmetrical position with respect to the center of the sleeve member so that the insertion jig can pass through the center of the sleeve member.

The insertion jig may include a head portion having a diameter larger than an inner diameter of the coupling hole formed in the sleeve member, and a through portion extending in a bar shape in the head portion to penetrate the sleeve member.

The length of the penetrating portion may be larger than the outer diameter of the sleeve member.

According to another aspect of the present invention, there is provided a method of manufacturing an insertion jig, the method comprising: inserting an insertion jig through a central portion fastening hole of a pipe-shaped sleeve member having a plurality of fastening holes; Inserting a conductor portion into both ends of the sleeve member until the insertion depth is limited by the insertion jig; A conductive particle injecting step of removing the insertion jig after the conductor section inserting step and injecting a plurality of conductor particles into a receiving space between the conductor portion end portions inserted into the sleeve member; Fixing a conductor portion by fastening a fastening bolt to the sleeve member; And a sleeve bolt is fastened to the sleeve member to reduce the voids of the conductor particles charged in the step of injecting the conductive particles and to electrically connect ends of the pair of conductor portions inserted into the sleeve member through the compressed conductor particles And a conductor-energizing step of connecting the conductor to the power cable.

The insertion jig mounting step may be performed such that the insertion jig penetrates the sleeve member via the central portion of the sleeve member.

Here, the step of injecting conductive particles may be carried out using at least one central joint hole of the central joint hole connected to the conductive particle accommodating space as a conductor particle input port, and the central joint hole except the conductive particle input hole may be formed by fastening a bolt Lt; / RTI >

In this case, the bolt for passing through which the conductor is energized in the step of energizing the conductor may be brought into contact with the end of the conductor and the conductor particles.

The securing bolt and the bolt for bolting are breaker bolts. In the step of securing the conductor and the step of energizing the conductor, the securing bolt and the bolt are not exposed to the outer circumferential surface of the sleeve member. The head portion of the bolt can be broken and fastened.

Further, in order to solve the above problems, the present invention can provide a conductor connection structure of a power cable connected by the conductor connecting method of the power cable described above.

According to the conductor connection structure of the power cable according to the present invention, the working time of the connection work can be significantly shortened as compared with the conventional method of peeling and pressing the wire-wound insulated conductor.

Further, according to the conductor connection structure of the power cable according to the present invention, when inserting the conductor portion of each cable into the sleeve member for the conductor connection of the power cable, the insertion jig for limiting the insertion depth of the conductor portion is used The efficiency of the conductor connecting work of the power cable can be improved.

Further, according to the conductor connection structure of the power cable according to the present invention, since the breakage bolts are used in connecting the conductor portion of the power cable, the skill of the operation is not required, and the operation cost can be greatly reduced.

According to the conductor connection structure of the power cable according to the present invention, the conductor particles are inserted into the space in the center of the sleeve between the cut surfaces of the conductor portions of both cables, and the gap inside the charged conductor particles is reduced The cut surfaces of both conductor portions are electrically connected to each other. Therefore, scattering of the conductive material generated in the process of peeling off the insulating portion of the elementary wire does not occur, and the stability can be improved in terms of quality.

1 shows a cross-sectional view of a power cable connectable by a conductor connection structure of a power cable according to the present invention.
2 shows a partially cutaway perspective view of a conductor connection structure of a power cable according to the present invention.
3 is a perspective view of a sleeve member constituting a conductor connection structure of a power cable according to the present invention.
4 shows a cross-sectional view of a sleeve member constituting a conductor connection structure of a power cable according to the present invention.
Figs. 5 to 11 illustrate a connection process of a conductor connection structure of a power cable according to the present invention.
Fig. 12 shows a perspective view of a conductor connection structure of a power cable according to the present invention having completed connection.
13 shows a state in which a corona shield is mounted on a conductor connection structure of a power cable according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail. 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, a power cable 100 that can be connected by the connection structure of the power cable 100 according to the present invention includes a conductor portion 10, an inner semiconductive layer 20 surrounding the conductor portion 10, An insulating layer 30 surrounding the inner semiconductive layer 20, an outer semiconductive layer 40 surrounding the insulating layer 30, and a metal sheath or a neutral wire surrounding the outer semiconductive layer 40, A shielding layer 50 for the return path of a short-circuit current, a sheath 60 surrounding the shielding layer 50, and the like.

The conductor portion 10 may be formed of a single wire made of copper, aluminum, preferably copper, or a twisted wire associated with a plurality of wires. The diameter of the conductor 10, the diameter of the wire 11 constituting the twisted wire Diameter, and the like may be different depending on the transmission voltage of the power cable 100, the use thereof, etc., and may be appropriately selected by a person skilled in the art.

Each of the strands 11 constituting the conductor portion 10 is insulated to reduce the conductor resistance due to the skin effect, thereby maximizing the power transmission amount.

Conventionally, when connecting such a wire-insulated power cable 100, the insulation of the wire is removed and the conductor portion 10 of both cables is used as a compression method. However, the present invention is not limited to the sleeve member 200 A method of inserting conductor particles mp into a center portion of a space between conductor end portions and then tightening a bolt 310 to electrically connect both cables Can be applied. This will be described in detail with reference to FIG.

The inner semiconductive layer 20 constituting the power cable 100 is disposed between the conductor portion 10 and the insulation layer 30 to prevent interlayer delamination between the conductor portion 10 and the insulation layer 30 Eliminates the air layer induced, and alleviates the local electric field concentration. On the other hand, the outer semiconductive layer 40 functions to uniformly apply an electric field to the insulating layer 30, to alleviate local field concentration, and to protect the cable insulation layer from the outside.

Typically, the inner semiconductive layer 20 and the outer semiconductive layer 40 are formed by dispersing conductive particles such as carbon black, carbon nanotubes, carbon nanoplate, and graphite in a base resin, and a crosslinking agent, an antioxidant, Is formed by extrusion of a further added semiconducting composition.

Here, the base resin may be a series of olefin resins similar to the base resin of the insulating composition forming the insulating layer 30 for the interlayer adhesion between the semiconductive layer 20, 40 and the insulating layer 30 .

The insulating layer 30 may be, for example, a polyolefin resin such as polyethylene or polypropylene as a base resin, and may preferably be formed by extrusion of an insulating composition comprising a polyethylene resin as a base resin.

The polyethylene resin may be an ultra low density polyethylene (ULDPE), a low density polyethylene (LDPE), a linear low density polyethylene (LLDPE), a medium density polyethylene (MDPE), a high density polyethylene (HDPE) Cables are rapidly replacing cross-linked polyethylene (XLPE) insulated cables.

The jacket layer 20 may be made of any one of polyethylene, polyvinyl chloride, and polyurethane.

In the connection structure of the power cable for connecting the conductor portion 10 composed of a plurality of strands of the power cable 100 according to the present invention, the conductor portion 10 of the pair of cables, the conductor portion 10, The sleeve member 200 is inserted into openings at both ends of the sleeve member 200 and has a plurality of fastening holes. The sleeve member 200 is inserted into a space between the ends of the pair of conductor portions 10 inserted into the sleeve member 200 A plurality of conductor particles (mp) for electrically connecting the pair of conductor portions to each other, a plurality of conductor particles (mp) for electrically connecting the pair of conductor portions to the pair of conductor portions, At least one bolt for tightening the bolt 310 and a fastening bolt 330 fastened to the fastening hole of the sleeve member 200 for fastening the conductor portion 10 inserted into the sleeve member Constituted by .

1, the power cable 100 that can be connected by the connection structure of the power cable 100 according to the present invention includes a conductor portion 10, an inner semiconductive layer 20 surrounding the conductor portion 10, An insulating layer 30 surrounding the inner semiconductive layer 20, an outer semiconductive layer 40 surrounding the insulating layer 30, and a metal sheath or a neutral wire surrounding the outer semiconductive layer 40, A shielding layer 50 for the return path of a short-circuit current, a sheath 60 surrounding the shielding layer 50, and the like.

A power cable conductor connecting apparatus for connecting a pair of conductors 10 composed of a plurality of small wires of the power cable 100 according to the present invention is a pipe type having open ends at both ends and is provided at predetermined intervals along the circumferential direction A sleeve member (200) having a plurality of fixing holes (230) formed therein and a coupling hole (210) formed at predetermined intervals along the circumferential direction between the plurality of fixing holes, At least one bolt (310) for tightening the hole (230) to electrically connect the pair of conductors, at least one bolt (310) for fastening the conductor to be fastened to the fastening hole (230) And a plurality of conductor particles (mp) accommodated in the sleeve member 200 and electrically connecting the pair of conductors 10 to each other, It may be configured to also.

As shown in FIG. 2, the power cable 100 according to the present invention may include a sleeve member 200 to which a conductor portion 10 of a connected cable is inserted and fixed.

The sleeve member 200 is a metal member having excellent openability in the form of a pipe having both ends opened and formed with a plurality of fastening holes. For example, the sleeve member 200 may be made of tin-plated copper or a tin-plated copper alloy material.

The sleeve member 200 may be provided with fastening holes for fastening a plurality of bolts. Specifically, the sleeve member has a plurality of fastening holes formed at predetermined intervals along the circumferential direction and a plurality of fastening holes formed at predetermined intervals along the circumferential direction between the plurality of fastening holes.

The coupling hole formed at the center of the sleeve member 200 among the plurality of coupling holes formed in the sleeve member 200 shown in FIG. 3 is inserted into both ends of the sleeve member 200, The bolts 310 for pressurizing the conductor particles mp injected into the accommodating space formed between the conductor portions 10 to electrically connect the conductor portions 10 to each other, (210).

3, a plurality of fastening holes formed in the sleeve member 200, other than the central portion of the sleeve member 200, (230) for fixing the conductor unit (10) and the sleeve member (200) by fastening the flange (330).

When the fastening bolts 330 are fastened to the fixing fastening holes 230, the fastening portions of the conductor portions 10 are plastically deformed or penetrated to move the conductor portions 10 in the longitudinal direction of the sleeve member 200 Can be blocked.

3 may be formed at a position corresponding to a space for accommodating the conductive particles mp in the central portion of the sleeve member 200. The through- Therefore, a plurality of the coupling holes 210 may be formed at predetermined intervals along the circumference of the center of the sleeve member 200.

Each of the fixing holes 230 is also formed at a predetermined interval along the circumference of each position at a predetermined position in the longitudinal direction of the sleeve member 200 in a region other than the central portion of the sleeve member 200 As shown in FIGS. 3 and 4, the adjacent fastening holes may be staggered in the lengthwise direction of the sleeve member 200. This is so that the fixing effect of the fixing bolts 330 is dispersed throughout the conductor portion 10 so that the compression effect of the conductive particles mp by the bolt 310 is not concentrated in a specific region.

The bolt 310 may include a head portion to which a tool torque is applied and a body portion having a thread formed thereon. The head portion is a region where the head portion is broken when the fastening is completed, and the body portion enters the sleeve member and is fastened when the fastening is completed.

Specifically, the bolt 310 is provided with a head portion which is broken and separated when a torque of a predetermined magnitude or more is applied, and includes a body portion formed below the head portion including a thread, And a lower end. At this time, the diameter of the body portion may be equal to or greater than the maximum diameter of the lower end portion.

As described later, the lower end of the bolt 310 limits the insertion depth of the pair of conductors inside the sleeve member 200 to separate the end portions of the two conductor portions, .

Therefore, the width of the accommodation space is set to be smaller than the width of the threaded body portion of the bolt 310 by the diameter of the lower end portion, preferably the maximum diameter of the lower end portion, When the bolt 310 is fastened, the bolt 310 is press-fitted into the side faces of the end portions of the both conductor portions and is compressed by the bolt for passing, .

As shown in FIG. 4, each bolt fastening hole is formed with a thread so that the fastening force can be adjusted according to the fastening depth of the bolt 310 and fastening bolt 330. As will be described later, the penetration bolt 310 and the fixing bolt 330 may be composed of a fracture bolt in which the head portion is broken when a force of a predetermined magnitude or more is applied.

The reason why the bolt 310 and the fixing bolts 330 are formed of the breaking bolts is that the connection structure of the power cable 100 according to the present invention should be accommodated in the connection box as will be described later, A corona shield or the like must be mounted on the outside of the structure and it is difficult for the bolt head or the like to protrude from the surface of the sleeve member 200 constituting the power cable 100 because of the prevention of field concentration.

The bolt (310) and the fixing bolt (330) may be made of brass.

Figs. 5 to 11 show the connection process of the connection structure of the power cable 100 according to the present invention.

A method of connecting a conductor of a power cable according to the present invention includes a step (S100) of inserting an inserting jig through a central portion fastening hole of a pipe-shaped sleeve member having a plurality of fastening holes, (S200) of inserting a conductor portion into both ends of the sleeve member until it is restricted, removing the insertion jig and inserting a plurality of conductor particles into a receiving space between the end portions of the conductor portions inserted into the sleeve member (S400) of fixing the conductor portion by fastening the fastening bolt to the sleeve member (S400); and a step of fastening the conductor bolt to the sleeve member to insert the conductor particle The ends of the pair of conductor portions inserted into the sleeve member through the compressed conductor particles are electrically It may include a conductor portion energizing step (S500) for connecting.

The connecting structure of the power cable 100 according to the present invention is a method of connecting the conductor portion 10 of the cable to be connected inserted into the sleeve member 200 directly to the conductor portion 10 are inserted into the receiving space S between both ends, and then the bolts 310 are fastened inward to connect the cables by reducing the gap between the conductive particles mp. The method of directly contacting the conductor portion 10 of the cable is not easy to achieve uniform surface contact of the end portion of the conductor portion 10 and therefore the resistance is inevitably increased and the method of peeling off the insulating film and then compressing it requires much more time do.

However, in the power cable 100 according to the present invention, the conductor portions 10 of the two power cables 100 are inserted into the sleeve member 200 and then the fixing bolts 330 are fastened to the conductor portions 10 The conductor particles mp are injected into the spaces between both ends of the conductor portions 10 of the cables after the fixing of the conductor portion 10 is completed and then the bolts 310 are tightened to form conductor particles mp, And the conductor particles (mp) can complete the electrical connection between both ends of the conductor portion 10 of the cable to be connected, and the connection of the power cable 100 can be completed. A process of forming the connection structure of the power cable 100 according to the present invention will be described.

5 and 6 illustrate a state in which the insertion jig mounting step S100 for inserting the insertion jig through the central joint hole 210 of the sleeve member having a plurality of fastening holes is performed, (S200) of inserting the conductor portion 10 into both ends of the sleeve member 200 until the insertion depth is limited by the inserting depth of the sleeve member 200. As shown in FIG.

As shown in FIGS. 5 and 6, the insertion jig 600 is temporarily mounted on at least one of the coupling holes 210 of the plurality of tubular coupling holes 210 formed at the center of the sleeve member 200 (S100), a conductive portion inserting step (S200) of inserting the conductor portion 10 of the cable to be connected into the sleeve member 200 may be performed.

The coupling hole 210 formed in the central portion of the sleeve member 200 among the plurality of coupling holes formed in the sleeve member 200 is inserted into the coupling hole 210 of the sleeve member 200, A bolt 310 for tightening the bolt 310 for pressurizing the conductor particles mp injected into the accommodating space formed between the conductor portions 10 in a state of being inserted at both ends and electrically connecting the conductor portions 10, And the insertion jig 600 is a temporary connection structure for limiting the insertion depth of the conductor portion in the process of inserting the conductor portion 10 of the cable to be connected into the sleeve member 200.

The insertion jig 600 may include a head portion 610 and a penetrating portion 630 so as to penetrate through the center of the sleeve member 200. The insertion jig 600 includes a head portion 610 having a diameter larger than an inner diameter of the coupling hole 210 formed in the sleeve member 200 and a head portion 610 extending through the sleeve portion 200, And a through-hole 630 extending in a bar shape. Preferably, the length of the penetrating portion is larger than the outer diameter of the sleeve member 200.

Therefore, the head portion 610 prevents the insertion jig 600 from escaping from the insertion jig 600 while the penetration portion 630 is inserted into the sleeve member 200 It is possible to limit the insertion depth of the connection portion of the cable to be connected.

When the conductor portion 10 of the cable to be connected is inserted in a state where the penetrating portion 630 of the insertion jig 600 is inserted into only a part of the inside of the sleeve member 200, It is preferable that the insertion jig 600 is installed to penetrate through the center of the sleeve member 200 in order to solve such a problem that the penetrating part 630 is broken or bent.

Also, for this purpose, the sleeve coupling hole 210 may be formed at a symmetrical position with respect to the center of the sleeve member.

When the conductor portion 10 of the cable to be connected is inserted into both ends of the sleeve member in a state where the insertion jig 600 is inserted and inserted into the coupling hole 210 of the sleeve member 200, It is not necessary to separately manage the inserting position of the conductor portion 10, so that workability can be improved.

5 and 6, after the inserting jig 600 has been inserted with the inserting depth of the inside of the sleeve member 200 of the conductor part 10 being limited, the inserting jig 600 Once removed, the receiving space S may be formed within the central portion of the sleeve member 200, as shown in FIG.

8, when the insertion of the conductor portions 10 is completed, a plurality of bolts 310 and fixing bolts 330 (not shown) for insertion of conductive particles, except for at least one bolt- Can be temporarily fastened to the respective fastening holes. Here, the temporary fastening means that the weak fastening state in which the bolt head is not broken is assumed to be a temporarily fastened state.

The reason for temporarily fastening the fastening bolt 330 in a state where the conductor portion 10 is inserted into the sleeve member 200 is that when the fastening of the head portion of the fastening bolt 330 is performed, The plastic deformation of the conductor portion 10 due to the deformation of the conductor portion 10 may occur and the conductor strands may flow into the accommodation space S to cause the introduction and interference of the conductor particles mp.

The reason why the bolt 310 is temporarily fastened to the bolt 310 is that the conductor particles mp introduced into the accommodation space S are pressed by the bolt And the main fastening of the method of breaking the head portion of the penetration bolt 310 can be delayed later.

Then, as shown in Fig. 9, a conductive particle injecting step (S300) of injecting conductor particles (mp) into the accommodation space S may be performed. The maximum width of the conductor particles mp is 5 to 20% of the width of the accommodation space S in order to prevent interference or jamming during the charging process and to evenly fill the entire accommodation space S. It is preferable to satisfy it.

For example, the conductive particles (mp) may be made of silver, copper, or an alloy thereof, or may be formed of a material that is plated with silver, copper, or an alloy thereof A method of finely cutting the metal wire by a method of constituting the conductor particles (mp) can be used.

Therefore, the conductor particles (mp) may be copper, silver, copper alloy, silver alloy, silver-plated copper, silver-plated copper alloy, silver-plated copper alloy, The alloy plating may be made of various materials such as an alloy. Further, the material of the plurality of conductor particles (mp) may be composed of copper or an alloy thereof, or may be composed of various combinations of metal if plated with silver, copper or an alloy thereof.

10, when the introduction of the conductive particles mp is completed, it is preferable that the main fastening bolts 330 temporarily fastened before the main tightening of the bolt 310 is performed Do.

10, the fixing bolt 330 is inserted into the sleeve member 200 and the conductor portion 10 by a method of plastic deformation or penetration of the conductor of the conductor portion 10 during the main fastening process. (S400) may be performed.

That is, when the conductor bolts (mp) are inserted into the sleeve member 200, the fixing bolts 330 are inserted into the fixing bolt holes 230 before tightening the bolt 310 It is preferable to fasten. This is to prevent the conductor portion 10 from being pushed back by the pressure applied in the main tightening process of the bolt 310 and to strengthen the contact state of the end portion side of the conductor portion 10 and the conductor particles mp to be.

The conductor particles (mp) may be composed of small metal particles of metal, etc., and in a simple injected state, a large amount of voids may exist between the particles. 11, when the fastening of the fastening bolts 330 is completed, the tightening of the bolt 310 is completed, the pores between the conductor particles mp are reduced or eliminated, The contact area between the particles and the contact area between the conductor particles and the side surface of the end portion of the conductor portion 10 is widened, so that the contact resistance can be reduced. In this case, since the sleeve member 200 and the conductor portion 10 are fixed by the fixing bolts 330, they may not be pushed back in the process of tightening the bolt 310.

In the past, when connecting an insulated wire cable, a method of removing the insulating sheath of each wire and pressing the insulated wire was used. In the case of the power cable 100 connection structure according to the present invention, however, Since the cross section of the power cable 100 to be connected is electrically connected, work for removing the insulating layer is not required, and workability can be improved.

11, in the state where the fastening bolt 330 is fully engaged, the bolt 310 is fastened to the bolt hole 210 used as the inlet of the conductor particle mp, as shown in FIG. And the tightening can be performed so that the head portion of the bolt 310 is broken as shown in FIG.

In a state where the conductor unit 10 is fixed to the sleeve member 200 by a conductor fixing step S400 for fixing the conductor unit 10 by fastening the fastening bolts 330 to the sleeve member 200, The tightening bolt 310 is fastened to the sleeve member 200 to reduce the voids of the conductor particles injected in the conductive particle injecting step S300 to compress the conductor particles, A conductive portion energizing step (S500) for electrically connecting the end portion of the conductor portion may be performed.

In the conductor-energizing step S500, the bolt S200 to be fastened can be brought into contact with both ends of the conductor portions and the conductor particles.

Specifically, when the bolt 310 is tightly coupled in the conductor-energizing step S500, the bolt 310 penetrates into the sleeve member 200, And the body portion of the bolt 100 having a larger diameter than the distance between the conductor ends (the width of the accommodating space) can be brought into contact with the ends (faces) of the pair of conductors 10 have. Therefore, the conduction path can be diversified by connecting the conduit end (surface) together with the compressed conductor particles by making the direct connection between the bolt and the conductor end via the penetration bolts 310.

11, the penetration bolt 310 has a body portion (threaded portion) formed between the lower end portion and the head portion, and the diameter of the body portion is smaller than the diameter of the bolt 310 ) Of the lower end portion. Such a shape can be realized by a method in which the shape of the lower end of the bolt 310 is hemispherical.

As described above, when the fastening bolts 330 are tightly fastened, the end portions of the pair of conductor portions are filled with the conductor particles mp in an accommodation space S formed by a predetermined distance from the ends of the bolts. The pair of conductor portions 10 can be fixed to the sleeve member 200 and can be energized by the compressed conductor particles and the bolt for passing.

Fig. 12 shows a perspective view of the connection structure of the power cable 100 according to the present invention. Fig. 13 shows a state in which the corona shield is attached to the connection structure of the power cable 100 according to the present invention.

12, the connection structure of the connected power cable 100 is such that both the fixing bolts 330 and the head portions of the bolt 310 are broken to protrude outside the sleeve member 200 The connection can be completed. A corona shield 500 is formed so as to surround the sleeve member 200. The conductor connection portion formed by the sleeve member and the like and the corona shield are electrically connected to each other by a metal wire 600 to form an equipotential, It is possible to prevent the occurrence of an accident.

As shown in Fig. 13, the connection structure of the power cable 100 equipped with the corona shield may have a smooth surface without steps or the like.

In this way, when the power cable 100 is connected, the working time can be greatly shortened, and the effect of minimizing the variation in the contact quality of the connection part due to the worker's skill can be obtained.

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.

100: Power cable
200: Sleeve member
310: Transmission bolt
330: Fixing bolt
600: Insert jig

Claims (21)

A conductor connecting structure of a power cable for connecting a conductor section composed of a plurality of small wires of a power cable,
A conductor portion of a pair of cables;
A pipe-shaped sleeve member having a plurality of coupling holes inserted into the openings at both ends of the conductor portion;
A plurality of conductor particles inserted into the space between the end portions of the pair of conductor portions inserted into the sleeve member to electrically connect the pair of conductor portions;
At least one bolt for bolt fastened to the fastening hole of the sleeve member to press the conductor particles inserted into the accommodating space to electrically connect the pair of conductor portions; And
And a fastening bolt fastened to the fastening hole of the sleeve member to fasten the conductor portion inserted into the sleeve member. The method according to claim 1,
Wherein the penetration bolt and the fixing bolt are broken bolts that are broken when the torque is applied to the bolt and the fixing bolt. The method according to claim 1,
Wherein the width of the accommodating space is smaller than the width of the threaded body of the bolt. The method according to claim 1,
Wherein a maximum width of the conductor particles is 5% to 20% of a width of the accommodating space. The method according to claim 1,
When the penetration bolt is fastened in the state that the conductor particles are inserted into the accommodation space, the penetration bolt is contacted with the end faces of the conductor portions and the conductor particles compressed by the penetration bolts and having reduced voids Conductor connection structure of power cable. The method according to claim 1,
Wherein the conductor particles are made of silver, copper or an alloy thereof, or plated with silver, copper or an alloy thereof. The method according to claim 6,
Wherein the conductor particles are formed by silver-plating a cut copper wire or a cut copper wire. The method according to claim 1,
Wherein the sleeve member is made of tin-plated copper or tin-plated copper alloy. The method according to claim 1,
Wherein the fixing bolt and the bolt for bolt are made of brass or brass alloy. The method according to claim 1,
Wherein a plurality of bolt-on fastening holes for fastening the bolt to the sleeve are formed at a predetermined interval along the circumferential direction at a central portion of the sleeve member. 11. The method of claim 10,
Wherein a plurality of fastening holes for fastening a plurality of fastening bolts are formed spaced apart from each other in a region other than a central portion of the sleeve member. 11. The method of claim 10,
Wherein an insertion jig for limiting the insertion depth of the conductor portion is inserted in the tubular fastening hole during the insertion of the conductor portion into the sleeve of the conductor portion. 13. The method of claim 12,
Wherein the through hole is formed at a symmetrical position with respect to the center of the sleeve member so that the insertion jig can pass through the center of the sleeve member. 13. The method of claim 12,
Wherein the insertion jig includes a head portion having a diameter larger than an inner diameter of the coupling hole formed in the sleeve member and a through portion extending in a bar shape in the head portion to penetrate the sleeve member. Connection structure. 15. The method of claim 14,
And the length of the penetrating portion is larger than the outer diameter of the sleeve member. An insertion jig mounting step of inserting the insertion jig through a central portion fastening hole of a pipe-shaped sleeve member having a plurality of fastening holes;
Inserting a conductor portion into both ends of the sleeve member until the insertion depth is limited by the insertion jig;
A conductive particle injecting step of removing the insertion jig after the conductor section inserting step and injecting a plurality of conductor particles into a receiving space between the conductor portion end portions inserted into the sleeve member;
Fixing a conductor portion by fastening a fastening bolt to the sleeve member; And
A conductive member for electrically connecting end portions of the pair of conductor portions inserted into the sleeve member through the compressed conductor particles, compressing a gap between the sleeve member and the sleeve member, And an energizing step for energizing the power cable. 17. The method of claim 16,
Wherein the insertion jig mounting step is performed such that the insertion jig passes through the sleeve member via a central portion of the sleeve member. 17. The method of claim 16,
The conductive particle injecting step is carried out using at least one central hole for at least one of center hole holes connected to the conductor particle accommodating space as a conductor particle input port. The central hole for coupling other than the conductive particle input hole is formed in a state And the conductor is connected to the power cable. 17. The method of claim 16,
And a bolt for bolt fastened in the conductive part energizing step is brought into contact with the end of both the conductor part and the conductor particle. 17. The method of claim 16,
Wherein the fixing bolt and the bolt for breaking the bolt are breaking bolts, and the fixing step and the conductive part energizing step are performed by fixing the fixing bolt and the bolt to the outer circumferential surface of the sleeve member, And the head portion is broken and fastened. A conductor connecting structure of a power cable connected by a conductor connecting method of a power cable according to any one of claims 16 to 20.

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