KR20190098610A - 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 working time of a conductor connection work, minimizes a deviation of quality of the connection work, and minimizes a cost of the connection work of the power cable, and a conductor connection method of a power cable. The conductor connection structure of a power cable comprises: a pair of conductor units of cables; a pipe-shaped sleeve member having a plurality of coupling holes; a plurality of conductor particles for electrically connecting the pair of conductor units; at least one current carrying bolt coupled to the coupling hole of the sleeve member; and a fixing bolt coupled to the coupling hole of the sleeve member.

Description

Connecting Structure of Power Cable Conductor And Connecting Method Of The Same}

The present invention relates to a conductor connecting structure of a power cable, a conductor connecting method of a power cable, and a power cable conductor connecting device. More specifically, the present invention reduces the working time of the conductor connection work and minimizes the deviation of the quality of the connection work, the conductor connection structure of the power cable and the conductor connection method of the power cable that can minimize the cost of the power cable connection work It is about.

The conductor portion of the power cable may be a copper (Cu) conductor or an aluminum (Al) conductor. In addition, the conductor portion is often formed by associating a plurality of element wires for bending characteristics and the like.

In addition, in the case of the copper conductor, the elementary insulated conductor part in which a plurality of element wires are insulated from each other may be formed in consideration of the skin effect of the metal and the like when the current is applied.

In the case of connecting such a power cable, conventionally, the insulation layer of each wire constituting the conductor portion is removed and collected again to bring the conductor portions of both connected power cables into contact with each other, and then a crimping method is used.

However, the method of connecting the conductor parts of both cables by removing the insulating layers of the respective wires constituting the conductor part and reassembling them by crimping method takes a long working time and the potential quality due to the scattering of the conductive material during the stripping of the insulating layer. There is a problem that there is a risk and requires considerable work proficiency.

The present invention provides a conductor connection structure of a power cable and a conductor connection method of a power cable that can reduce the working time of the conductor connection work and minimize the variation of the quality of the connection work, thereby minimizing the cost of the power cable connection work. The task to be solved.

In order to solve the above problems, the present invention provides a conductor connection structure of a power cable for connecting a conductor portion composed of a plurality of element wires of a power cable, comprising: a conductor portion of a pair of cables; A sleeve member having a pipe shape, each of the conductor parts being inserted into openings at both ends and having a plurality of fastening holes; A plurality of conductor particles introduced into a receiving space between ends of the pair of conductor portions inserted into the sleeve member to electrically connect the pair of conductor portions; At least one electricity supply bolt fastened to a fastening hole of the sleeve member to pressurize the conductor particles introduced into the accommodation space to electrically connect the pair of conductor parts; And a fixing bolt fastened to a fastening hole of the sleeve member to fix the conductor portion inserted into the sleeve member, wherein a side of an end of at least one conductor portion of the pair of conductor portions is formed in the conductor portion. A conductor connecting structure of a power cable can be provided which is not perpendicular to the direction of insertion into the sleeve member.

In addition, the side surfaces of the pair of conductor parts may be configured as inclined surfaces, respectively.

In addition, the side surfaces of the pair of conductor parts may be configured to have a symmetrical inclined surface, and the tip of the side surfaces of the pair of conductor parts may be spaced apart from each other in the sleeve member.

Here, the maximum width of the conductive particles may have a size of 5% to 20% of the minimum distance between the tip of the side of the conductor portion inserted into the sleeve member.

In addition, when the conductive bolt is fastened in the state in which the conductive particles are put into the accommodation space, the conductive bolts may be pressed together by the end sides of both conductor portions and the conductive bolts to be in contact with the conductive particles having reduced voids. Can be.

The conductor 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.

In addition, the conductor particles may be formed by silver plating a cut copper wire or a cut copper wire.

The sleeve member may be made of tin plated copper or tin plated copper alloy.

In addition, the fixing bolt and the energizing bolt may be made of brass or brass alloy material.

In addition, a plurality of power supply fastening holes to which a plurality of power supply bolts are fastened may be formed at predetermined intervals along the circumferential direction at the center of the sleeve member.

In addition, a plurality of fixing fastening holes to which a plurality of fixing bolts are fastened may be spaced apart from the central portion of the sleeve member.

In addition, in order to solve the above problems, the present invention provides a conductor portion insertion step of inserting a conductor portion of a pair of power cables each having an end side surface formed of an inclined surface into openings at both ends of a pipe-type sleeve member having a plurality of fastening holes. ; A conductor particle input step of introducing a plurality of conductor particles into a receiving space between ends of both conductor parts in the sleeve member; A conductor part fixing step of fixing the conductor part by fastening a fastening bolt to the sleeve member; And tightening a current-carrying bolt to the sleeve member to reduce the voids of the conductor particles introduced in the conductor particle feeding step, and electrically connect the ends of the pair of conductor parts inserted into the sleeve member through the compressed conductor particles. It can provide a conductor connection method of the power cable comprising a; conducting the conductive portion.

The inserting of the conductor part may limit the insertion depth of both conductor parts by inserting both conductor parts in a state in which at least one current-carrying bolt is temporarily fastened to the sleeve member before inserting both conductor parts through both ends of the sleeve member. At the same time, the receiving space may be formed by separating end portions of the both conductor parts.

In the inserting of the conductor part, the insertion depth of both conductor parts may be inserted by inserting the both conductor parts in the state where the insertion jig is inserted through the center fastening hole of the sleeve member before inserting the both conductor parts through the both ends of the sleeve member. At the same time, the receiving space may be formed by spaced apart from both ends of the conductor part.

The insertion jig may be inserted to penetrate through the center of the sleeve member.

In addition, the conductor part inserting step may be performed such that the side surfaces of the pair of conductor parts are symmetrical inclined surfaces, and the leading ends of the side surfaces of the pair of conductor parts are disposed to be spaced apart from each other in the sleeve member. Can be.

Here, at least one current-carrying bolt fastened in the conduction step of the conductor part may be performed to be in contact with both the end of the conductor part and the conductor particles.

The fixing bolt and the energizing bolt may be broken bolts, and the fixing of the conductor part and the energizing step of the conductor part may include fixing bolts so that the fixing bolts and the electricity supply bolts are not exposed to the outer circumferential surface of the sleeve member. The head part of the electricity supply bolt can be broken and fastened.

According to the conductor connecting structure of the power cable according to the present invention, the working time of the connecting work can be greatly shortened as compared with the conventional method of stripping and crimping a wire conductor insulated.

In addition, according to the conductor connection structure of the power cable according to the present invention, since the broken bolt is used to connect the conductor portion of the power cable, the work cost can be greatly reduced because it does not require the skill of the work.

Further, according to the conductor connecting structure of the power cable according to the present invention, the conductor particles are introduced into the sleeve center receiving space between the cut surfaces of the conductor portions of both cables, and the voids inside the conductor particles introduced using the energizing bolts as fastening means are reduced. In order to electrically connect the cut surfaces of both conductor parts, the scattering of the conductive material generated in the process of stripping the insulation of the wire may not occur, and thus stability may be improved in quality.

Moreover, according to the conductor connection structure of the power cable which concerns on this invention, the edge part of the conductor part of a pair of power cable connected in the sleeve member is comprised by the inclined surface, etc., and the area of the conductor part edge part which contact | connects a conductor particle is increased and connected. The resistance of the site can be minimized.

1 shows a cross-sectional view of a power cable connectable by the conductor connection structure of the power cable according to the present invention.
Figure 2 shows a partially cutaway perspective view of the conductor connection structure of a power cable according to the invention.
3 shows a perspective view of the sleeve member constituting the conductor connecting structure of the power cable according to the present invention.
Fig. 4 shows a cross-sectional view of the sleeve member constituting the conductor connecting structure of the power cable according to the present invention.
5 to 14 show the connection process of the conductor connection structure of the power cable according to the present invention.
Fig. 15 shows a perspective view of the conductor connection structure of the power cable according to the present invention with the connection completed.
Fig. 16 shows a state where 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 invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosure may be made thorough and complete, and to fully convey the spirit of the present invention to those skilled in the art. Like numbers refer to like elements throughout.

1 shows a cross-sectional view of a power cable connectable by a conductor connection structure of a power cable according to the invention, and FIG. 2 shows a partial cutaway perspective view of the conductor connection structure of the power cable according to the invention.

The power cable as shown in FIG. 1 is laid for power supply, and the connection can be performed at predetermined intervals. In order to connect the power cables at predetermined intervals, the connection of the conductor portion of the power cables must be preceded.

Conventionally, although the insulation layer of each wire constituting the conductor portion of the power cable is removed and assembled again, the conductor portions of both power cables to be connected are brought into contact with each other, and a crimping method is used. The method of connecting the conductor parts of both cables by removing the insulating layer and reassembling it by crimping method has a long working time, has a potential quality risk due to scattering of conductive material during stripping of the insulating layer, and requires considerable working skill. In order to solve the problem, the present invention provides a conductor connection structure of the power cable shown in FIG.

As shown in FIG. 1, the power cable 100 connectable by the connection structure 400 of the power cable according to the present invention includes a conductor portion 10 and an inner semiconducting layer 20 surrounding the conductor portion 10. ), The insulating layer 30 surrounding the inner semiconducting layer 20, the outer semiconducting layer 40 surrounding the insulating layer 30, the outer semiconducting layer 40, and made of a metal sheath or a neutral wire for electrical shielding and It may include a shielding layer 50 for returning the short-circuit current, the outer shell 60 surrounding the shielding layer 50 and the like.

The conductor part 10 may be formed of a stranded wire in which a single wire or a plurality of conductor wires made of copper, aluminum, and preferably copper are associated with each other, and the diameter of the conductor part 10 and the stranded wire 11 constituting the stranded wire. The standard including the diameter may be different according to the transmission voltage, the use, and the like of the power cable 100 including the same, and may be appropriately selected by a person skilled in the art.

Each wire 11 constituting the conductor part 10 is insulated from each other to maximize the amount of power transmission by reducing conductor resistance due to the skin effect.

In the related art, when the wire insulated power cable 100 is connected, the insulation of the wire is removed and the conductor portion 10 of both cables is used as a crimping method. The conductor portion 10 of the cable to be connected in the () and the conductor particle (mp) is injected into the center of the core and then tightening the electricity supply bolt 310 can be electrically connected to both cables. Detailed description thereof will be described below with reference to FIG. 2.

The inner semiconducting layer 20 constituting the power cable 100 is disposed between the conductor portion 10 and the insulating layer 30 to lift the interlayers of the conductor portion 10 and the insulating layer 30. It removes the air layer that induces and alleviates local electric field concentration. On the other hand, the outer semiconducting layer 40 performs a function of applying an even electric field to the insulating layer 30, localized electric field concentration mitigation and protecting the cable insulating layer from the outside.

In general, the inner semiconducting layer 20 and the outer semiconducting layer 40 have conductive particles such as carbon black, carbon nanotubes, carbon nanoplates, graphite, and the like dispersed in a base resin, and a crosslinking agent, an antioxidant, a scorch inhibitor, and the like. It is formed by extrusion of the additionally added semiconducting composition.

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

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

The polyethylene resin may be applied to ultra low density polyethylene (ULDPE), low density polyethylene (LDPE), linear low density polyethylene (LLDPE), medium density polyethylene (MDPE), high density polyethylene (HDPE) and the like, in the case of a high-pressure cable Cables are quickly being replaced by crosslinked polyethylene (XLPE) insulated cables.

The outer shell 60 provided at the outermost portion of the cable may be made of any one of polyethylene, polyvinyl chloride, and polyurethane.

Specifically, the present invention provides a conductor connection structure of a power cable for connecting a conductor portion 10 composed of a plurality of element wires of a power cable, comprising: a conductor portion 10 of a pair of cables; A sleeve member 200 having a pipe shape, each of the conductor parts being inserted into openings at both ends and having a plurality of fastening holes; A plurality of conductor particles (mp) introduced into the receiving space between the ends of the pair of conductor portions 10 inserted into the sleeve member 200 to electrically connect the pair of conductor portions; At least one electricity supply bolt 310 fastened to a fastening hole of the sleeve member 200 in order to pressurize the conductor particles (mp) introduced into the accommodation space to electrically connect the pair of conductor parts 10; And a fixing bolt 330 fastened to the fastening hole of the sleeve member to fix the conductor portion 10 inserted into the sleeve member 200. The side surface of the end of the at least one conductor portion 10 may provide a conductor connection structure of the power cable, characterized in that it is not perpendicular to the insertion direction of the sleeve member 200 of the conductor portion.

As shown in FIG. 1, the power cable 100 connectable by the connection structure 400 of the power cable according to the present invention includes a conductor portion 10 and an inner semiconducting layer 20 surrounding the conductor portion 10. ), The insulating layer 30 surrounding the inner semiconducting layer 20, the outer semiconducting layer 40 surrounding the insulating layer 30, the outer semiconducting layer 40, and made of a metal sheath or a neutral wire for electrical shielding and It may include a shielding layer 50 for returning the short-circuit current, the outer shell 60 surrounding the shielding layer 50 and the like.

As shown in FIG. 2, the power cable conductor connection structure 400 according to the present invention may include a sleeve member 200 into which both conductor portions 10 of the cable to be connected are inserted and fixed.

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

In addition, the sleeve member 200 may be provided with a fastening hole for fastening the plurality of bolts. Specifically, the sleeve member includes a plurality of fastening holes formed at predetermined intervals along the circumferential direction and a fastening hole for energization formed at predetermined intervals along the circumferential direction between the plurality of fastening holes.

Among the plurality of fastening holes formed in the sleeve member 200 illustrated in FIG. 3, the fastening holes formed at the center of the sleeve member 200 are inserted into both ends of the sleeve member 200 by connecting the conductor portion 10 of the cable to be connected. Power supply fastening hole for fastening the conductive particles 310 to electrically connect the two conductor parts 10 by pressing the conductor particles (mp) introduced into the receiving space formed between the two conductor parts 10 in the closed state. (210).

3, the fastening hole formed outside the center of the sleeve member 200 among the plurality of fastening holes formed in the sleeve member 200 has a fixing bolt in a state in which the conductor portion 10 of the cable to be connected is inserted. A fastening hole 230 for fastening the 330 to fix the conductor part 10 and the sleeve member 200.

When the fixing bolt 330 is fastened to the fixing fastening hole 230, the conductor part 10 may be plastically deformed or penetrated so that the movement of the conductor part 10 in the longitudinal direction of the sleeve member 200 is performed. Can be blocked.

The electricity supply fastening hole 210 to which the electricity supply bolt 310 shown in FIG. 3 is fastened may be formed at a position corresponding to the conductor particle (mp) receiving space at the center of the sleeve member 200. Accordingly, the plurality of fastening holes 210 may be formed at predetermined intervals along the circumference of the central portion of the sleeve member 200.

In addition, each fixing fastening hole 230 is also formed in a region other than the center of the sleeve member 200 at predetermined intervals along the circumference of each position at a predetermined interval in the longitudinal direction of the sleeve member 200. 3 and 4, adjacent fastening holes may be staggered in the longitudinal direction of the sleeve member 200. This is to disperse the fixing effect of the fixing bolt 330 to the entire conductor portion 10, so that the compression effect of the conductor particles (mp) by the energizing bolt 310 is not concentrated in a specific region.

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

The reason for configuring the electricity supply bolt 310 and the fixing bolt 330 as a break bolt is as described later, the connection structure 400 of the power cable according to the present invention should be accommodated in the junction box, the connection Corona shield or the like should be mounted on the outside of the structure, and the reason is that it is difficult for the bolt head or the like to protrude to the surface of the sleeve member 200 constituting the power cable 100 for reasons such as electric field concentration prevention.

5 to 14 show the connection process of the conductor connection structure of the power cable according to the present invention.

In the conductor connecting method of the power cable according to the present invention, a conductor part inserting step (S100) for inserting a conductor part of a pair of power cables into an opening at both ends of a pipe-shaped sleeve member having a plurality of fastening holes (S100), inside the sleeve member Conductor particle input step (S200) for injecting a plurality of conductor particles into the receiving space between the both ends of the conductor portion, the conductor part fixing step (S300) for fixing the conductor portion by fastening the fastening bolt to the sleeve member, and the sleeve The conductor part energizing step of fastening the conductive bolt to the member to reduce the voids of the conductive particles introduced into the conductor particle step, and electrically connecting the ends of the pair of conductor parts inserted into the sleeve member through the compressed conductor particles. It is possible to provide a method for connecting a conductor of a power cable including (S400).

The power cable conductor connection structure 400 according to the present invention is not a method of directly connecting the conductor portion 10 of the connection target cable inserted into the sleeve member 200 to electrically connect the conductor particles (mp). The cable is connected by inserting the receiving space S between both ends of the part 10 and then tightening the energizing bolt 310 inward to reduce the air gap between the conductor particles mp. In the method of directly contacting the conductor portion 10 of the cable, the uniform surface contact of the ends of the conductor portion 10 is not easy, so the resistance must be increased, and the method of peeling the insulating film and then crimping takes much more work time. do.

However, in the power cable conductor connection structure 400 according to the present invention, after inserting the conductor portions 10 of both power cables 100 into the sleeve member 200, respectively, the fastening bolt 330 is fastened to the conductor portion. After fixing the conductor 10 and fixing the conductor portion 10, the conductor particles (mp) are injected into the spaces between the both ends of the conductor portion 10 of both cables, and then the conductive bolt 310 is fastened to the conductor particles ( The gaps between the mps are minimized, and the conductor particles (mp) may complete the electrical connection between the both ends of the conductor portion 10 of the cable to be connected, thereby completing the connection of the power cable 100. A process of forming the power cable conductor connection structure 400 according to the present invention will be described.

5 and 6 perform a conductor part inserting step (S100) of inserting a conductor part of a pair of power cables into openings at both ends of a pipe-shaped sleeve member 200 having a plurality of fastening holes 210 and 230. An example of the process is shown.

As illustrated in FIGS. 5 and 6, the electricity supply bolt 310 may be temporarily provided in at least one electricity supply fastening hole 210 of the plurality of electricity supply fastening holes 210 formed at the center of the sleeve member 200. The conductor part inserting step S100 of inserting the conductor part 10 of the connection object cable into the sleeve member 200 in the fastened state may be performed.

The end side surface of the conductor portion 10 of the power cable connected through the conductor connection structure of the power cable according to the invention is characterized in that it is configured not to be perpendicular to the insertion direction into the sleeve member 200.

As a specific example, in the embodiment shown in Figs. 5 and 6, the side of the conductor portion inserted into the sleeve member 200 is not perpendicular to the insertion direction of the sleeve member, but consists of an inclined surface and furthermore the pair of The side of the end of the conductor portion may consist of a symmetric inclined surface. I'll explain more about this later.

The conductor part inserting step (S100) may be performed by inserting each conductor part 10 into the sleeve member 200, as shown in FIGS. 5 and 6.

In this case, the conductor part 10 is connected to the sleeve member 200 in a state in which the bolt for the electricity transmission 310 is partially protruded into the receiving space of the sleeve member 200 to the at least one electricity supply fastening hole 210. When inserted into the inside, the inner end of the electricity supply bolt 310 may serve as a stopper. That is, in the conductor part inserting step (S100), the at least one current-carrying bolt 310 is temporarily fastened to the sleeve member 200 to limit the insertion depth of both conductor parts and at the same time to separate the ends of the conductor parts from the accommodation space. Can be formed.

When the conductor part inserted into the sleeve member 200 is formed of a symmetrical inclined surface, the part of the conductor part that is locked by the temporary fastening current-carrying bolt 310 of each conductor part is blocked at the insertion depth is the tip most protruding in the insertion direction. Can be.

That is, as will be described later, since the conductive particles (mp) will be injected through the fastening holes for energization formed in the upper portion of the sleeve member, the receiving space formed by the inclined surface (10s) of each conductor portion 10 is upward direction It can be in the form of widening.

In the embodiment shown in FIGS. 5 to 6, the side of the end of the conductor portion is shown as being configured as a planar symmetrical inclined surface, for example, configured not to be perpendicular to the insertion direction of the sleeve member of the conductor portion, but the sleeve As long as the contact area between the conductor portion and the conductor particles is increased so as not to be perpendicular to the insertion direction of the member, the side shape of the end portion of the conductor portion may be configured in various shapes. For example, it may include a curved shape.

7 illustrates a state in which the conductor part insertion step S100 is completed.

As shown in FIG. 7, the receiving space formed between the ends of each conductor portion 10 may have an inverted triangle in cross section, and the tip of each conductor portion 10 may be pretightened. The depth of insertion may be limited by the dedicated bolt 310.

The reason why the end side of the conductor portion 10 is formed as an inclined surface as shown in FIG. 7 so as not to be perpendicular to the insertion direction into the sleeve member 200 is the contact with the conductive particles introduced into the receiving space. This is to improve the area.

In the embodiment shown in FIGS. 5 to 7, the side of the conductor portion inserted into the sleeve member 200 is not perpendicular to the insertion direction of the sleeve member, but constitutes an inclined surface and furthermore, the end of the pair of conductor portions. The side is composed of a symmetrical inclined surface (10S) so that the cross section of the receiving space (S) to be a triangle, and when the conductive particles (mp) is put into the receiving space to fasten the bolt for electricity, the compressed conductor particles (mp) The area of the conductor portion 10 that can be in contact with can be increased.

8 to 10 show another example of a process of inserting a conductor portion (S100) for inserting conductor portions of a pair of power cables into openings at both ends of a pipe-shaped sleeve member having a plurality of fastening holes. . Descriptions duplicated with those described with reference to FIGS. 5 through 7 will be omitted.

Unlike the conductor part inserting step S100 shown in FIGS. 5 to 7, the conductor part inserting step S100 shown in FIGS. 8 to 10 limits the insertion depth of the conductor part 10 by using a bolt for energization. Rather than using a separate insertion jig 600 to limit the insertion depth of the conductor portion 10.

The insertion jig 600 is a conductor part insertion depth limiting means temporarily mounted on the sleeve member 200, and the insertion jig mounting step S50 may be performed before the conductor part 10 is inserted.

8 and 9 illustrate the insertion jig 600 in a state in which an insertion jig mounting step S50 of inserting an insertion jig through a central fastening hole 210 of a pipe-type sleeve member having a plurality of fastening holes is performed. It shows a process in which the conductor portion insertion step (S100) for inserting the conductor portion 10 to both ends of the sleeve member 200 until the insertion depth is limited by.

As shown in FIGS. 8 and 9, the insertion jig 600 is temporarily mounted in at least one of the fastening holes 210 of the plurality of energizing fastening holes 210 formed in the center of the sleeve member 200. In the step S50, the conductor part inserting step S100 of inserting the conductor part 10 of the connection object cable into the sleeve member 200 may be performed.

The insertion jig 600 may include a head part 610 and a through part 630 so that the insertion jig 600 may be installed through the center of the sleeve member 200. The insertion jig 600 has a head portion 610 having a diameter larger than the inner diameter of the fastening hole 210 for electricity delivery formed in the sleeve member 200 and the head portion 200 to penetrate the sleeve member 200. ) May be provided with a through portion 630 extending in the form of a bar. In addition, the length of the through part may be configured to be larger than the outer diameter of the sleeve member 200.

Therefore, the head part 610 is prevented from exiting in a state where the insertion jig 600 is mounted to the fastening hole 210 for the electricity supply, and the through part 630 is inserted into the sleeve member 200. It can serve to limit the insertion depth of the connecting portion of the cable to be connected.

In addition, for this purpose, the electrical fastening hole 210 may be formed at a symmetrical position with respect to the center of the sleeve member.

As described above, when the conductor jig 10 of the connection target cable is inserted into both ends of the sleeve member in a state where the insertion jig 600 is inserted and mounted in the fastening hole 210 for power supply of the sleeve member 200, the operator Since it is not necessary to separately manage the insertion position of the conductor portion 10, the workability can be improved.

As shown in FIG. 10, when the insertion jig 600 is removed after the insertion is completed in a state where the insertion depth inside the sleeve member 200 of both conductor parts 10 is limited by the insertion jig 600, An accommodating space S may be formed inside a central portion of the sleeve member 200. In the illustrated embodiment of FIG. 10, an accommodating space formed between ends of each conductor part 10 has an inverted triangle in cross section. It may be configured in the form, the front end of each conductor portion 10 may be in a state in which the insertion depth is limited by the insertion jig removed.

When the insertion of both conductor parts 10 is completed, as shown in FIG. 11, the plurality of fixing bolts 330 may be temporarily fastened. Here, the temporary fastening refers to a weak fastening state in which the bolt head is not broken as a temporary fastening state.

The reason for temporarily tightening the fixing bolt 330 in the state in which the conductor part 10 is inserted into the sleeve member 200 is that the fixing bolt 330 is performed when the main fastening of the head of the fixing bolt 330 is broken. This is because plastic deformation of the conductor part 10 is generated, and the conductor element wires are introduced into the accommodation space S, so that the input and interference of the conductor particles mp may occur.

In addition, as shown in FIG. 11, at least one fastening hole of the plurality of fastening holes 210 for energization is left for the input of the conductor particles mp, and the remaining energizing bolts 310 are also conductive particles (mp). In order to prevent the loss of the conductor particles (mp) during the injection of the) may be temporarily fastened to the remaining fastening holes for electricity.

Here, the reason for temporarily tightening the energizing bolt 310 is to maximize the effect of compressing by pressing the conductor particles (mp) injected into the receiving space (S) with the bolt for energizing, as will be described later, This fastening in the manner in which the head portion of 310 is broken can be pushed back.

And, as shown in Figure 12, the conductor particle input step (S200) for injecting the conductor particles (mp) in the accommodation space (S) can be performed. The maximum width of the conductor particles (mp) is the size of 5% to 20% of the minimum width of the containing space (S) in order to prevent interference or jams in the input process and to be evenly filled in the entire receiving space (S). It is desirable to satisfy. In the end, it means that the conductor particles (mp) can be configured in the size of 5% to 20% of the minimum distance between the inclined side edges of the symmetrical form of each conductor portion.

The conductor particles (mp) may be made of a metal material having good electrical conductivity. For example, the conductor particles (mp) may be made of silver, copper, or an alloy thereof, or may be plated with silver, copper, or an alloy thereof. It may be made of a metal material, a method of finely cutting the metal wire may be used as a method for configuring the conductor particles (mp).

Therefore, the conductor particles (mp) are copper, silver, copper alloy, silver alloy, silver plated copper, silver alloy plated copper, silver plated copper alloy, silver alloy plated copper alloy, copper plating silver, copper alloy plating silver, copper plating silver alloy, copper Alloy plating may be made of various materials such as alloys. In addition, 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 as long as it is a metal material plated with silver, copper, or an alloy thereof.

As shown in FIG. 13, when the input of the conductive particles (mp) is completed, it is possible to fasten the current-carrying bolts 310 to the fastening holes 210 used as the inlets for the conductive particles (mp). As shown in FIG. 14, the fastening may be performed such that the head portions of the fixing bolt 330 and the electricity feeding bolt 310 are broken.

As shown in FIG. 14, the fixing bolt 330 fixes the sleeve member 200 and the conductor part 10 by a method of plastically deforming or penetrating the conductor of the conductor part 10 in the present fastening process. In the state in which the conductor part fixing step S300 and the conductor part 10 are fixed to the sleeve member 200, the conductive particle 310 is fastened to the sleeve member 200 by fastening the conductive bolt 310 to the conductor particle feeding step S200. The conductive part conducting step (S400) of reducing the air gap of the conductive particles introduced in the compression and electrically connecting the inclined side of the end of the pair of conductor portions 10 inserted into the sleeve member through the compressed conductor particles It may be performed sequentially.

Here, the conductor part fixing step (S300) performed by the main fastening of the fixing bolt 330, which was temporarily fastened before the conductor part energizing step (S400) for fastening the energizing bolt 310, is performed first. It is preferable.

That is, in the state in which the conductor particle (mp) is injected into the sleeve member 200, the fixing bolt 330 is seen in the fixing fastening hole 230 before the fastening of the electricity supply bolt 310. It is desirable to fasten. This is to prevent the conductor portion 10 from being pushed back by the pressure applied during the main fastening process of the electricity supply bolt 310, and to strengthen the contact state between the end side of the conductor portion 10 and the conductor particles (mp). to be.

The conductor particles (mp) may be made of a metal material, may be made of small metal particles, or the like, and in a simple injected state, a significant portion of the voids may exist between the particles. However, as shown in FIG. 14, when the fastening of the energizing bolt 310 is completed while the fastening of the fixing bolt 330 is completed, the gap between the conductor particles mp is reduced or removed and the conductor is reduced. Since the contact area between particles and the contact area between the conductor particles and the inclined side surface of the end portion of the conductor portion 10 are widened, the contact resistance can be reduced. In this case, since the sleeve member 200 and the conductor part 10 are fixed by the fixing bolt 330, the sleeve member 200 and the conductor part 10 may not be pushed back in the process of fastening the energizing bolt 310.

Conventionally, in the case of connecting an insulated wire cable, a method of removing the insulation coating of each wire and compressing the wire is used. However, in the case of the power cable conductor connection structure 400 according to the present invention, the conductor particles (mp) Since the end surface of the power cable 100 to be connected is electrically connected, the workability can be improved since a separate insulation layer is not required, and further, the end side of the conductor part is perpendicular to the insertion direction of the conductor part. It is possible to further reduce conductor resistance by forming an inclined surface or the like, thereby reducing the contact area between the conductor particles and each conductor portion.

In addition, at least one of the energizing bolts 310 is main fastened to be in direct contact with the end of the conductor part 10 so that the conductor part and the conductor part are electrically connected to each other via a non-conducting bolt. It is also preferable to diversify.

In the embodiment shown in FIG. 14, the energizing bolt electrically connected with each conductor portion may be an energizing bolt mounted at the stopper position in the embodiment shown in FIGS. 5 to 7.

Figure 15 shows a perspective view of the connection structure 400 of the power cable according to the present invention the connection is completed, Figure 16 shows a state in which the corona shield is mounted on the connection structure 400 of the power cable according to the present invention.

As shown in FIG. 15, in the connection structure 400 of the completed power cable, both the fixing bolts 330 and the heads of the electricity supply bolts 310 are broken so that they do not protrude out of the sleeve member 200. So that the connection can be completed. In addition, the corona shield 500 is formed to surround the sleeve member 200, the conductor connecting portion formed by the sleeve member or the like and the corona shield is energized with each other by the metal wire 600 or the like to form an equipotential, such as corona discharge Can prevent accidents.

As shown in FIG. 16, the connection structure 400 of the power cable equipped with the corona shield may have a smooth surface without a step.

In this way, when connecting the power cable 100, the working time can be significantly shortened, it is possible to obtain the effect of minimizing the variation in the contact quality of the connection site due to the skill difference of the operator.

Although the present specification has been described with reference to preferred embodiments of the invention, those skilled in the art may variously modify and change the invention without departing from the spirit and scope of the invention as set forth in the claims set forth below. Could be done. Therefore, it should be seen that all modifications included in the technical scope of the present invention are basically included in the scope of the claims of the present invention.

100: power cable
10: conductor part
200: sleeve member
400: power cable conductor connection structure

Claims (18)

In the conductor connection structure of a power cable for connecting the conductor part which consists of several wire | wire of a power cable,
A conductor portion of a pair of cables;
A sleeve member having a pipe shape, each of the conductor parts being inserted into openings at both ends and having a plurality of fastening holes;
A plurality of conductor particles introduced into a receiving space between ends of the pair of conductor portions inserted into the sleeve member to electrically connect the pair of conductor portions;
At least one electricity supply bolt fastened to a fastening hole of the sleeve member to pressurize the conductor particles introduced into the accommodation space to electrically connect the pair of conductor parts; And,
And a fixing bolt fastened to a fastening hole of the sleeve member to fix the conductor portion inserted into the sleeve member.
And a side surface of an end portion of at least one conductor portion of the pair of conductor portions is not perpendicular to an insertion direction into the sleeve member of the conductor portion. The method of claim 1,
And a side surface of each end portion of the pair of conductors is configured as an inclined surface, respectively. The method of claim 2,
Side surfaces of the pair of conductor portions are configured as symmetrical inclined surfaces, and tip ends of the side portions of the pair of conductor portions are arranged to be spaced apart from each other in the sleeve member. . The method of claim 3,
And the maximum width of the conductor particles has a size of 5% to 20% of the minimum distance between the tips of the side surfaces of the conductor portions inserted into the sleeve member. The method of claim 1,
When the conductive bolt is fastened in the state in which the conductive particles are inserted into the receiving space, the conductive bolts are in contact with the conductive particles compressed by the end side of both conductor parts and the conductive bolts to reduce the voids. Conductor connection structure of power cable. The method of claim 1,
The conductor particle is a conductor connection structure of a power cable, characterized in that composed of silver, copper or an alloy material thereof, or a metal material plated with silver, copper or an alloy material thereof. The method of claim 6,
The conductor particle is a conductor connection structure of a power cable, characterized in that the conductor is composed of silver plated cut copper wire or cut copper wire. The method of claim 1,
And the sleeve member is made of tin plated copper or tin plated copper alloy. The method of claim 1,
The fixing bolt and the electricity supply bolt are conductor connection structure of the power cable, characterized in that the brass or brass alloy material. The method of claim 1,
And a plurality of power supply fastening holes for fastening the plurality of power supply bolts are formed at predetermined intervals along the circumferential direction at a central portion of the sleeve member. The method of claim 10,
And a plurality of fastening holes for fastening the plurality of fastening bolts to be spaced apart from the central portion of the sleeve member. A conductor portion inserting step of inserting conductor portions of a pair of power cables each having side ends formed in an inclined surface into openings at both ends of a pipe-type sleeve member having a plurality of fastening holes;
A conductor particle input step of introducing a plurality of conductor particles into a receiving space between ends of both conductor parts in the sleeve member;
A conductor part fixing step of fixing the conductor part by fastening a fastening bolt to the sleeve member; And,
A conductor for fastening a current-carrying bolt to the sleeve member to reduce the voids of the conductor particles introduced in the conductor particle feeding step, and electrically connect the ends of the pair of conductor parts inserted into the sleeve member through the compressed conductor particles. A secondary conduction step; conductor connecting method of a power cable comprising a. The method of claim 12,
The inserting of the conductor part may include inserting both conductor parts while temporarily tightening at least one current-carrying bolt to the sleeve member before inserting the both conductor parts through both ends of the sleeve member, thereby limiting the insertion depth of both conductor parts. And at the same time, spaced apart from each end of the conductor part to form the accommodation space. The method of claim 12,
The conductor part inserting step limits the insertion depth of both conductor parts by inserting both conductor parts in the state where the insertion jig is inserted through the center fastening hole of the sleeve member before inserting the both conductor parts through both ends of the sleeve member. And at the same time as spaced apart from the ends of the conductor portion to form the receiving space. The method of claim 14,
And the insertion jig is inserted to penetrate through the center of the sleeve member. The method of claim 12,
The conductor part inserting step may be performed such that the side surfaces of the pair of conductor parts are symmetrical inclined surfaces, and the leading ends of the side surfaces of the pair of conductor parts are arranged to be spaced apart in the sleeve member. A conductor connecting method of a power cable, characterized in that. The method of claim 16,
And at least one current-carrying bolt fastened in the conduction step of the conductor part is performed to be in contact with both ends of the conductor part and the conductor particles. The method of claim 12,
The fixing bolt and the energizing bolt are broken bolts, and the conductor part fixing step and the conductor part energizing step are conducted with the fixing bolt and the electricity supply so that the fixing bolt and the electricity supply bolt are not exposed to the outer circumferential surface of the sleeve member. A method for connecting a conductor of a power cable, characterized by breaking and fastening the head of the bolt.

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