JP2023106844A - Power wiring path - Google Patents

Abstract

To provide a power wiring path capable of easily performing waterproof processing between a power cable and a power cable termination connection part.SOLUTION: A power wiring path 8 comprises a power cable 1, a power cable termination connection part 2, and a shrinkable tube 6. The power cable 1 includes a central conductor 11, an insulation layer 12, a shield layer 13 consisting of a plurality of shield wires 131 and a sheath 14 and is stripped stepwise in such a manner that the central conductor 11 and the insulation layer 12 are exposed from the sheath 14 and the shield layer 13. The power cable termination connection part 2 includes: a cable holder 3 including an insertion hole 20 in which the central conductor 11 and the insulation layer 12 are inserted; and a tubular member 4 which is fixed to an end of the cable holder 3 and in which the sheath 14 is stored. The shrinkable tube 6 covers an outer peripheral surface 14a of the sheath 14 exposed from the tubular member 4, is adhered to an outer peripheral surface 422a of the tubular member 4 and forms a waterproof structure which prevents infiltration of water from a gap between the tubular member 4 and the sheath 14.SELECTED DRAWING: Figure 2

Description

The present invention relates to power wiring lines used, for example, in rail vehicles.

Conventionally, for example, a power cable for transmitting electric power in a railway vehicle includes a central conductor, an insulating layer covering the outer periphery of the central conductor, a shielding layer composed of a plurality of shield wires arranged so as to surround the outer periphery of the insulating layer, and a shielding wire. and a sheath covering the perimeter of the layer. The end portion of the power cable is step-stripped so that the central conductor and the insulating layer are exposed from the shielding layer and the sheath, and the step-stripped end portion of the power cable is an insulation made of a polymer-based material. It is connected to a termination connection using a body.

The polymer connecting portion for a power cable described in Patent Document 1 includes a polymer insulator tube having a cable insertion hole into which the step-stripped end of the power cable is inserted, a protective metal fitting that protects the rear end side of the polymer insulator pipe, and a protective metal fitting. and a waterproofing part that seals between the power cable and the power cable. The waterproof part is formed by winding a resin tape such as polyethylene tape or epoxy tape with an adhesive layer having good water resistance.

JP 2016-116281 A

When a resin tape is wound to form a waterproof portion as described in Patent Document 1, the resin tape must be manually wound many times around the outer periphery of the power cable, which is time-consuming. It takes

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a power distribution line that facilitates waterproofing between a power cable and a power cable terminal connection.

An object of the present invention is to solve the above problems by providing a power cable for transmitting power, a power cable termination connection to which the end of the power cable is connected, and a shrinkable tube disposed around the outer periphery of the power cable. The power cable comprises a central conductor, an insulating layer covering the outer circumference of the central conductor, a shielding layer composed of a plurality of shield wires arranged so as to surround the outer circumference of the insulating layer, and the shielding layer. a sheath that covers an outer periphery, and the end portion is stripped so that the central conductor and the insulating layer are exposed from the sheath and the shielding layer, and the power cable termination portion is exposed from the sheath. a cable holder provided with an insertion hole into which the central conductor and the insulating layer are inserted; and a metallic tubular member fixed to an end of the cable holder and accommodating the sheath, The shrinkable tube covers the outer peripheral surface of the sheath exposed from the tubular member and adheres closely to the outer peripheral surface of the tubular member to form a waterproof structure that prevents water from entering through a gap between the tubular member and the sheath. provide power wiring paths.

ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to perform waterproofing easily between the power cable and the power cable termination connection part in a power distribution line.

1 is a configuration diagram showing a power wiring path according to an embodiment of the present invention; FIG. FIG. 4 is a cross-sectional view showing the power cable termination connection on the first railcar side with the power cable and one end of the shrink tube. 3 is a cross-sectional view of the power cable and the shrinkable tube along line AA of FIG. 2; FIG. (a) is a perspective view showing a tubular member of a power cable. (b) is a perspective cross-sectional view of the tubular member taken along line BB of (a).

[Embodiment]
A power wiring path according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4. FIG. FIG. 1 is a configuration diagram showing a power distribution line for a railway vehicle according to an embodiment of the present invention.

This power distribution line 8 relays power between first and second railcars 91 and 92 connected by a coupler (not shown). It has a pair of power cable termination connections 2, 2 connected to the ends thereof, respectively, and a shrinkable tube 6 that covers the outer periphery of the power cable 1 between the power cable termination connections 2, 2. In FIG. 1, for the sake of convenience, a part of the shrinkable tube 6 is broken to show the power cable 1 inside it. The power cable 1 is a crossover cable suspended between the first and second railcars 91 and 92 .

Power cable termination connections 2, 2 are installed on the roofs of first and second railcars 91, 92, respectively. A first exterior cover 912 is attached on the roof 911 of the first railcar 91 . The power cable termination connection portion 2 on the first railway vehicle 91 side is arranged inside the first exterior cover 912 , and the power cable 1 and the shrinkable tube 6 are inserted into the insertion hole 912 a provided in the first exterior cover 912 . is inserted.

Similarly, a second exterior cover 922 is attached on the roof 921 of the second railway vehicle 92, and the power cable termination connection portion 2 on the side of the second railway vehicle 92 is attached to the second exterior cover 922. , and the power cable 1 and the shrinkable tube 6 are inserted through an insertion hole 922 a provided in the second exterior cover 922 . Between the first outer cover 912 and the second outer cover 922 , the power cable 1 is entirely covered with the shrinkable tube 6 .

FIG. 2 is a cross-sectional view showing the power cable terminal connection 2 on the side of the first railcar 91 together with one end of the power cable 1 and shrinkable tube 6 . FIG. 3 is a cross-sectional view of the power cable 1 and shrinkable tube 6 taken along line AA of FIG. Although not shown, the power cable termination connection portion 2 on the side of the second railroad vehicle 92 is also configured in the same manner.

The power cable 1 transmits power to a power supply target, and as shown in FIG. , a shielding layer 13 composed of a plurality of shielding wires 131 arranged so as to surround the outer periphery of the insulating layer 12 , and a sheath 14 covering the outer periphery of the shielding layer 13 . In this embodiment, an inner semiconducting layer 15 is provided between the central conductor 11 and the insulating layer 12 , and an outer semiconducting layer 16 is provided between the insulating layer 12 and the shield layer 13 . A pressure winding tape 17 is spirally wound around the outer periphery of the shielding layer 13, and the outside thereof is covered with a sheath 14.例文帳に追加

As the wire 111 of the central conductor 11, a wire made of a highly conductive metal such as a tinned annealed copper wire can be used. The central conductor 11 transmits a high voltage of, for example, 7000V or higher. The insulating layer 12 is formed by extruding a material such as ethylene propylene rubber, vinyl chloride, crosslinked polyethylene, silicone rubber, fluorine-based material, or the like. The sheath 14 is formed, for example, by extruding rubber such as natural rubber, butyl rubber, halogenated butyl rubber, non-halogenated polyolefin elastomer, etc. to which a cross-linking agent or the like is added. The shield wire 131 is made of a wire material such as a tin-plated annealed copper wire, for example, and is helically wound horizontally.

The inner semi-conductive layer 15 and the outer semi-conductive layer 16 are provided to alleviate the concentration of the electric field, and are mainly made of a polymer-based material, and are extruded to have conductivity by dispersing conductive powder. It is formed by molding. A belt-like body made of plastic or rayon, for example, can be used as the pressing tape 17 .

The power cable 1 is stripped at the end to be connected to the power cable terminal connection 2, and each layer is exposed step by step. Specifically, the sheath 14 and the pressing tape 17 are partially removed to expose the plurality of shield wires 131, the outer semi-conductive layer 16 is partially removed to expose the insulating layer 12, and the insulating layer 12 is exposed. 12 and part of the inner semiconducting layer 15 are removed to expose the central conductor 11 .

A compression terminal 10 is attached to the central conductor 11 exposed from the insulating layer 12 . The compression terminal 10 has a cylindrical crimped portion 101 which is crimped so as to compress the center conductor 11 and a flat connecting portion 102 provided integrally with the crimped portion 101 . A housing hole 101 a for housing the central conductor 11 is formed in the crimped portion 101 . A device connection hole 102 a is formed at the tip of the connection portion 102 .

A connection portion 102 of the compression terminal 10 is connected to the terminal 90 by a nut 100 inside the power cable termination connection portion 2 . The terminal 90 has a tapered bushing 901 and a conductor 902 exposed from the bushing 901 . A male thread 902 a is formed at the tip of the conductor 902 .

The power cable termination connection part 2 includes a cable holder 3 provided with an insertion hole 20 into which the central conductor 11 and the insulating layer 12 of the power cable 1 exposed from the sheath 14 and the shielding layer 13 are inserted; It comprises a metallic tubular member 4 fixed to the end, an insulating plug 51 for connecting the compression terminal 10 to the conductor 902 of the terminal 90, and a protective cap 52 for protecting the insulating plug 51.

The insulating plug 51 includes a molded insulator 511, a high-voltage electrode 512 provided at one end of the insulator 511, and a voltage detection electrode 513 provided at the other end of the insulator 511. . The high-voltage electrode 512 is formed with a countersunk hole 512a corresponding to the shape of the nut 100 and a female thread 512b into which the male thread 902a of the conductor 902 is screwed. The voltage detection electrode 513 is formed with a tool fitting hole 513a into which the tip of a tool such as a socket wrench is fitted. The insulator 511 is integrally molded with the high-voltage electrode 512 and the voltage detection electrode 513 .

The protective cap 52 is made of a semi-conductive rubber material and is formed in a bottomed cylindrical shape integrally having a disk-shaped bottom wall 521 and a cylindrical side wall 522 . A bottom wall 521 covers the insulating plug 51 . The side wall 522 has an annular convex portion 522 a formed on the inner peripheral surface thereof for fixing to the cable holder 3 .

The cable holder 3 has an insertion hole 20 at its center, a holding cylinder portion 3A that holds the central conductor 11 and the insulating layer 12 of the power cable 1, and a connection portion between the compression terminal 10 and the conductor 902 of the terminal 90. It has a connection tube portion 3B that accommodates the . In this embodiment, the axial direction of the connection tube portion 3B is perpendicular to the axial direction of the holding tube portion 3A, and the cable holder 3 is formed in a T shape. Hereinafter, in the axial direction (horizontal direction in FIG. 1) of the holding tube portion 3A, the connecting tube portion 3B side is referred to as the front end side, and the opposite side (the tubular member 4 side) is referred to as the rear end side.

The cable holder 3 includes an insulator 30 made of a polymer-based material and first to third semi-conductors 31 made of a polymer-based material to which conductivity is imparted by dispersing a conductivity-imparting agent. ∼33. The insulator 30 is provided over the holding tube portion 3A and the connection tube portion 3B, and is provided around the insertion hole 20 in the holding tube portion 3A. Further, the insulator 30 in the connecting tube portion 3B is formed with a bushing insertion hole 301 into which the bushing 901 is inserted and an insulation plug insertion hole 302 into which the insulation plug 51 is inserted. The first to third semi-conductors 31 to 33 are provided integrally with the insulator 30 and relax the electric field around the power cable 1 . Further, the third semi-conductor 33 has a shielding function of suppressing leakage of the electric field around the power cable 1 to the outside.

Examples of polymer-based materials for the insulator 30 and the first to third semi-conductors 31 to 33 in the cable holder 3 include silicone rubber, ethylene propylene rubber (EPM), ethylene propylene diene rubber (EPDM), and the like. can be done. As the conductivity-imparting agent, for example, conductive fine powder such as carbon black can be used.

The first to third semi-conductors 31 to 33 are pre-injection-molded bodies prior to forming the insulator 30 . The first semi-conductor 31 surrounds the compression terminal 10 from the distal end of the holding tube portion 3A to the connection tube portion 3B. The first semiconductor body 31 accommodates a terminal insertion hole 311 into which the compression terminal 10 is inserted together with a part of the longitudinal direction of the central conductor 11 and the insulating layer 12, and a part of each of the bushing 901 and the insulating plug 51. A receiving hole 312 is formed to The second semi-conductor 32 is arranged closer to the rear end side of the holding tube portion 3A than the first semi-conductor 31 is.

The insertion hole 20 includes a small-diameter hole portion 21 having an inner diameter corresponding to the outer diameter of the insulating layer 12 of the power cable 1 , a large-diameter hole portion 23 provided at the end on the rear end side, and a large-diameter hole portion 23 extending from the small-diameter hole portion 21 . It is formed by a tapered hole portion 22 whose inner diameter gradually increases toward the diameter hole portion 23 . The small-diameter hole portion 21 is formed of a first semi-conductor 31 at a portion on the front end side and a second semi-conductor 32 on a portion at the rear end side. A small-diameter hole 21 is formed by the insulator 30 between the first semiconductor 31 and the second semiconductor 32 .

The third semi-conductor 33 includes a cylindrical portion 331 covering the insulator 30 around the insertion hole 20 in a part of the tip side of the holding cylinder portion 3A including the outer circumference of the first semi-conductor 31, and a cylindrical portion It integrally has first and second protruding pieces 332 and 333 projecting radially outward from an outer peripheral surface 331a of 331, and an outer shell portion 334 forming the outer shell of the connecting tube portion 3B. The outer shell portion 334 is formed with an annular concave portion 334a with which the convex portion 522a formed on the side wall 522 of the protective cap 52 is engaged.

A ground wire 71 is connected to the first projecting portion 332 . The ground wire 71 has a ground wire body 711 made of an insulated wire whose core wire is covered with an insulator, and a ground terminal 712 attached to the tip of the ground wire body 711 . The ground terminal 712 is attached to the first protruding portion 332 by a bolt 72 and a nut (not shown) screwed onto the bolt 72 .

The tubular member 4 is fixed to the end of the cable holder 3 on the rear end side, allows the central conductor 11 and the insulating layer 12 of the power cable 1 to pass therethrough, and accommodates part of the shield layer 13 and the sheath 14 . . The tubular member 4 is made of a highly conductive metal such as brass or an aluminum alloy. The plurality of shield wires 131 of the shield layer 13 are led out from the sheath 14 inside the tubular member 4 and folded back around the outer periphery of the sheath 14, and are routed from between the outer peripheral surface 14a of the sheath 14 and the inner peripheral surface 4a of the tubular member 4. It is led out to the outside of the tubular member 4 .

FIG. 4(a) is a perspective view showing the tubular member 4. FIG. FIG. 4(b) is a perspective cross-sectional view of the tubular member 4 taken along line BB of FIG. 4(a). The tubular member 4 integrally has an embedded portion 41 embedded in the cable holder 3 and a cylindrical portion 42 exposed from the cable holder 3 . The tubular member 4 is fixed to the cable holder 3 by embedding the embedded portion 41 in the insulator 30 of the cable holder 3 .

The embedding portion 41 has a cylindrical shape, and through holes 410 are formed at a plurality of locations (four locations in the present embodiment) in the circumferential direction, the through holes 410 penetrating the embedding portion 41 in the axial direction. The insulator 30 enters the plurality of through holes 410 . The embedded portion 41 is embedded in the insulator 30 in a portion corresponding to a portion of the tapered hole portion 22 of the insertion hole 20 and the outer peripheral side of the large diameter hole portion 23 .

The embedded portion 41 and the cylindrical portion 42 are aligned in the axial direction along the longitudinal direction of the power cable 1 inside the tubular member 4 . The cylindrical portion 42 further has a large diameter portion 421 and a small diameter portion 422 having different outer diameters. The large diameter portion 421 is formed continuously with the embedded portion 41 . The small-diameter portion 422 has an outer diameter smaller than that of the large-diameter portion 421 and is formed continuously from the end portion of the large-diameter portion 421 opposite to the embedding portion 41 .

Approximately the entire outer peripheral surface 422 a of the small diameter portion 422 of the tubular member 4 is covered with the shrinkable tube 6 . The shrinkable tube 6 may cover a part of the outer peripheral surface 422a on the side of the opening from which the sheath 14 is led out in the axial direction of the small-diameter portion 422 . In other words, it is sufficient that the outer peripheral surface 422 a of at least a portion of the small diameter portion 422 in the axial direction is covered with the shrinkable tube 6 .

The inner peripheral surface 4a of the tubular member 4 includes a large-diameter inner peripheral surface 4b in which the plurality of shield wires 131 and the sheath 14 are accommodated, a small-diameter inner peripheral surface 4c having an inner diameter smaller than that of the large-diameter inner peripheral surface 4b, It has a partially conical tapered surface 4d between the large-diameter inner peripheral surface 4b and the small-diameter inner peripheral surface 4c. The central conductor 11 and the insulating layer 12 exposed from the sheath 14 are inserted inside the small-diameter inner peripheral surface 4c and the tapered surface 4d.

The embedded portion 41 is formed to have a smaller outer diameter than the large diameter portion 421 and the small diameter portion 422 of the cylindrical portion 42 . The thickness T ₂ of the small diameter portion 422 is formed thinner than the thickness T ₁ of the large diameter portion 421 and the thickness T ₀ of the embedded portion 41 . An outer peripheral surface 421a of the large diameter portion 421 is not covered with the insulator 30 of the cable holder 3 and is exposed to the outside. The insulator 30 of the cable holder 3 is in close contact with the outer peripheral surface 41a of the embedded portion 41 and the axial end surface 421b of the large diameter portion 421 on the embedded portion 41 side.

Further, the cylindrical portion 42 of the tubular member 4 is provided with a ground wire connection portion 401 to which the ground wire 73 is connected and a shield wire connection portion 402 to which the plurality of shield wires 131 are connected. The ground wire connecting portion 401 is provided at a portion not covered with the shrinkable tube 6 , and the shield wire connecting portion 402 is provided at a portion covered with the shrinkable tube 6 . In the present embodiment, the ground wire connection portion 401 is provided at one circumferential location on the large diameter portion 421 , and the shield wire connection portions 402 are provided at a plurality of circumferential locations on the small diameter portion 422 . The ground wire connection portion 401 is part of the large diameter portion 421 and the shield wire connection portion 402 is part of the small diameter portion 422 .

As shown in FIG. 2 , connection terminals 74 are attached to the distal ends of the plurality of shield wires 131 . In this embodiment, the number of shield wires 131 in the shield layer 13 is 20, and ten of these shield wires 131 are electrically connected to the tubular member 4 by two connection terminals 74 . That is, in this embodiment, the tubular member 4 is provided with two shield wire connection portions 402, and these shield wire connection portions 402 are provided at positions separated by 180° in the circumferential direction of the small diameter portion 422. . The shrinkable tube 6 covers the twenty shield wires 131 led out from the tubular member 4 together with the two connection terminals 74 .

The two connection terminals 74 are connected to the shield wire connection portion 402 by bolts 75, respectively. The shield wire connecting portion 402 is formed with a threaded hole 402a into which the bolt 75 is screwed. In this embodiment, the screw hole 402a radially penetrates the small diameter portion 422 . However, the screw hole 402a does not have to pass through the small-diameter portion 422 . A peripheral portion of the opening of the screw hole 402a on the outer peripheral surface 422a of the small diameter portion 422 is a flat surface 402b perpendicular to the central axis of the screw hole 402a so that the connection of the connection terminal 74 by tightening the bolt 75 can be securely performed. It has become.

The ground wire 73 has a ground wire body 731 made of an insulated wire whose core wire is covered with an insulator, and a ground terminal 732 attached to the tip of the ground wire body 731 . The ground wire connection portion 401 has a screw hole 401a into which a bolt 76 for connecting a ground terminal 732 is screwed. is formed as A peripheral portion of the opening of the screw hole 401a on the outer peripheral surface 421a of the large diameter portion 421 is a flat surface perpendicular to the central axis of the screw hole 401a so that the ground terminal 732 can be securely connected by tightening the bolt 76. 401b.

The shrinkable tube 6 is a heat-shrinkable tube that shrinks in the radial direction when heated, and has a tubular base layer 61 and an adhesive layer 62 provided inside the base layer 61 . The base layer 61 is made of a resin material that shrinks when heated, such as polyolefin or fluoropolymer. The adhesive layer 62 is made of a hot-melt adhesive, and more specifically, made of polyolefin such as polyethylene, thermoplastic polyester, ethylene-vinyl acetate copolymer, polyamide, or the like.

The shrinkable tube 6 covers the outer peripheral surface 14a of the sheath 14 exposed from the tubular member 4 and adheres closely to the outer peripheral surface 422a of the small-diameter portion 422 of the tubular member 4 to prevent water from flowing out from the gap between the tubular member 4 and the sheath 14. It forms a waterproof structure that prevents infiltration. 1, the shrinkable tube 6 has a power cable termination connection 2 connected to one end of the power cable 1 and a power cable termination connection connected to the other end of the power cable 1. The entire power cable 1 between the part 2 is covered.

In this embodiment, the shrinkable tube 6 is shrunk by heating over the entire longitudinal direction, but this is not the only option. and the second exterior cover 922, the shrinkable tube 6 may not be shrunk. In addition, the adhesive layer 62 may not be provided inside the base layer 61 in portions that are not related to waterproofness.

(Actions and effects of the embodiment)
According to the embodiment described above, the following actions and effects are obtained.

(1) The shrinkable tube 6 covers the outer peripheral surface 14a of the sheath 14 exposed from the tubular member 4 and adheres closely to the outer peripheral surface 422a of the small-diameter portion 422 of the tubular member 4, so that the shrinkable tube 6 is compressed from the gap between the tubular member 4 and the sheath 14. Since a waterproof structure is formed to prevent the intrusion of water, there is no need to wrap a resin tape like the one described in Patent Document 1, for example, and the waterproofing between the power cable 1 and the power cable termination connection part 2 can be easily performed.

(2) Since the ground wire connecting portion 401 is provided at a portion not covered with the shrinkable tube 6, the work of connecting the ground wire 73 can be easily performed, and even if the ground wire 73 is broken, for example, The line 73 can be replaced quickly.

(3) The tubular member 4 has a large diameter portion 421 provided with a ground wire connection portion 401 to which the ground wire 73 is connected, and a plurality of shield wire connection portions 402 provided in a small diameter portion 422 . It is possible to reduce the outer diameter of the shrinkable tube 6 at the outer periphery of the , and to ensure a sufficient current capacity of the large-diameter portion 421 in which a relatively large current is likely to occur. Further, the ground terminal 732 can be firmly connected by the bolt 76 by increasing the screw depth of the screw hole 401 a of the ground wire connection portion 401 . Furthermore, by forming the screw hole 401a so as not to penetrate the tubular member 4, waterproofness can be improved.

(4) The plurality of shield wires 131 are led out of the sheath 14 inside the tubular member 4, folded back at the end of the sheath 14 and led out of the tubular member 4, so that the tubular member 4 can be reduced in size and weight. However, the wiring work of the shield wire 131 can be easily performed.

(Summary of embodiment)
Next, technical ideas understood from the embodiments described above will be described with reference to the reference numerals and the like in the embodiments. However, each reference numeral in the following description does not limit the constituent elements in the claims to the members and the like specifically shown in the embodiment.

[1] A power cable (1) for transmitting power, a power cable termination connection (2) to which the end of the power cable (1) is connected, and a contraction arranged around the outer circumference of the power cable (1) a tube (6), the power cable (1) includes a central conductor (11), an insulating layer (12) covering the outer circumference of the central conductor (11), and an outer circumference of the insulating layer (12). and a sheath (14) covering the outer periphery of the shield layer (13), and the sheath (14) and The central conductor (11) and the insulating layer (12) are step-stripped from the shield layer (13), and the power cable termination (2) is exposed from the sheath (14). A cable holder (3) provided with an insertion hole (20) into which the central conductor (11) and the insulating layer (12) are inserted; and a sheath fixed to the end of the cable holder (3). (14), and the shrinkable tube (6) covers the outer peripheral surface (14a) of the sheath (14) exposed from the tubular member (4). A power wiring that is in close contact with the outer peripheral surface (422a) of the tubular member (4) to form a waterproof structure that prevents water from entering through a gap between the tubular member (4) and the sheath (14). Road (8).

[2] The plurality of shield wires (131) are led out from the sheath (14) inside the tubular member (4), and the plurality of shield wires (131) are provided in the tubular member (4). A shield wire connection part (402) to be connected and a ground wire connection part (401) to which a ground wire is connected are provided, and the shield wire connection part (402) is covered with the shrinkable tube (6). The power wiring path (8) according to the above [1], wherein the ground wire connecting portion (401) is provided at a portion not covered with the shrinkable tube (6).

[3] The tubular member (4) includes an embedded portion (41) embedded in the cable holder (3) and a large diameter portion (421) formed continuously from the embedded portion (41). and a small diameter portion (422) having an outer diameter smaller than that of the large diameter portion (421), the large diameter portion (421) being provided with the ground wire connection portion (401), The power wiring line (8) according to [2] above, wherein (422) is provided with a plurality of said shield wire connections (131).

[4] The plurality of shield wires (131) extend from between the outer peripheral surface (14a) of the sheath (14) and the inner peripheral surface (4a) of the tubular member (4) to the outside of the tubular member (4). The power wiring path (8) according to the above [2] or [3], which is derived from

[5] Terminals (75) are attached to the distal ends of the plurality of shield wires (131), and the shrinkable tube (6) extends from the plurality of shield wires (131) led out from the tubular member (4). ) together with the terminal (75), and the shield wire connection portion (402) is formed with a screw hole (402a) into which a bolt (76) for connecting the terminal (75) is screwed. A power wiring path (8) according to [4].

[6] Both ends of the power cable (1) are connected to the power cable termination connection (2), and the shrinkable tube (6) is connected to one end of the power cable (1). the entire power cable (1) between the power cable termination connection (2) connected to the power cable (1) and the power cable termination connection (2) connected to the other end of the power cable (1) A power wiring line (8) according to any one of the above [1] to [5], which is covered.

Although the embodiments of the present invention have been described above, the embodiments described above do not limit the invention according to the scope of claims. Also, it should be noted that not all combinations of features described in the embodiments are essential to the means for solving the problems of the invention.

DESCRIPTION OF SYMBOLS 1... Power cable 11... Central conductor 12... Insulating layer 13... Shielding layer 131... Shield wire 14... Sheath 2... Power cable termination connection part 20... Insertion hole 3... Cable holder 4... Tubular member 401... Ground wire connection part 401a Screw hole 402 Shield wire connecting portion 402a Screw hole 41 Embedded portion 421 Large diameter portion 422 Small diameter portion 4a Inner peripheral surface 6 Shrinkable tube 73 Ground wire 75 Connection terminal 76 Bolt 8 power wireway

Claims (6)

A power cable for transmitting power, a power cable termination connection to which the end of the power cable is connected, and a shrinkable tube disposed around the power cable,
The power cable includes a central conductor, an insulating layer covering the outer circumference of the central conductor, a shielding layer composed of a plurality of shield wires arranged so as to surround the outer circumference of the insulating layer, and a sheath covering the outer circumference of the shielding layer. and is stepped off at the end so that the central conductor and the insulating layer are exposed from the sheath and the shielding layer,
The power cable termination connection portion includes a cable holder provided with an insertion hole into which the central conductor and the insulating layer exposed from the sheath are inserted, and a cable holder fixed to an end portion of the cable holder to accommodate the sheath. and a metallic tubular member for
The shrinkable tube covers the outer peripheral surface of the sheath exposed from the tubular member and adheres closely to the outer peripheral surface of the tubular member to provide a waterproof structure that prevents water from entering through a gap between the tubular member and the sheath. forming,
power wiring. The plurality of shield wires are led out from the sheath inside the tubular member,
The tubular member is provided with a shield wire connection portion to which the plurality of shield wires are connected and a ground wire connection portion to which a ground wire is connected,
The shield wire connecting portion is provided at a portion covered with the shrinkable tube,
wherein the ground wire connecting portion is provided at a portion not covered by the shrinkable tube;
2. The power wiring line of claim 1. The tubular member integrally includes an embedded portion embedded in the cable holder, a large-diameter portion continuously formed with the embedded portion, and a small-diameter portion having an outer diameter smaller than that of the large-diameter portion. have
The large-diameter portion is provided with the ground wire connection portion,
A plurality of the shield wire connection portions are provided in the small diameter portion,
3. A power wiring line according to claim 2. The plurality of shield wires are led out of the tubular member from between the outer peripheral surface of the sheath and the inner peripheral surface of the tubular member,
4. A power distribution line according to claim 2 or 3. Terminals are attached to tip portions of the plurality of shield wires,
The shrinkable tube covers the plurality of shield wires led out from the tubular member together with the terminal,
A threaded hole into which a bolt for connecting the terminal is screwed is formed in the shield wire connecting portion,
5. A power wiring line according to claim 4. Both ends of the power cable are respectively connected to the power cable termination connection,
The shrinkable tube is positioned between the power cable termination connected to one end of the power cable and the power cable termination connected to the other end of the power cable. covering the entire
6. A power distribution line according to any one of claims 1-5.

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