JP2014050223A - Terminal connection part of coaxial cable for power - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a terminal connection part of a coaxial cable for power, which has stable insulation characteristics and allows improvement of workability during construction.SOLUTION: A terminal connection part of a coaxial cable for power includes: a first conductor connection part electrically connected to an inner conductor; a second conductor connection part electrically connected to an outer conductor; an insulation part which is formed integrally with the first conductor connection part and the second conductor connection part so as to surround outer peripheral surfaces of the first conductor connection part and the second conductor connection part and has a cable terminal reception part for mounting therein a cable terminal part of the coaxial cable for power and is made of a hard insulating material; and a shielding layer formed on an outer surface of the insulation part and is configured so that the cable terminal part to which a first electric field limiting component for controlling an electric field between the inner conductor and the outer conductor and a second electric field limiting component for controlling an electric field between the outer conductor and the cable shielding layer are attached is mounted in the cable terminal reception part.

Description

  The present invention relates to a terminal connection portion of a power coaxial cable.

  Conventionally, as a terminal connection portion (terminal connection portion, intermediate connection portion, etc.) of a power coaxial cable, a terminal connection box for a coaxial CV cable (see Patent Document 1), a connection portion of a power DC coaxial cable (see Patent Document 2) ), And connection techniques such as a submarine cable connection method (see Patent Document 3).

The configuration of the power coaxial cable is shown in FIG. As shown in FIG. 1, in the power coaxial cable 20, at least an inner conductor 21a, an inner insulator 21c, an outer conductor 22a, an outer insulator 22c, a cable shielding layer 23, and a vinyl sheath 25 are formed concentrically from the center. It has the structure made.
The terminal of such a power coaxial cable 20 is provided with a terminal connection portion (terminal connection portion, intermediate connection portion, etc.) so as to send power to each of the inner conductor 21a and the outer conductor 22a.
For example, Patent Document 1 discloses a cylinder in which a conductor lead bar and an inner conductor of a coaxial cable for electric power (main conductor in Patent Document 1) are connected in a soot tube filled with insulating oil, and the bottom metal fitting of the soot tube is cut off. A terminal connection portion (termination connection portion) of a power coaxial cable is disclosed in which an outer conductor lead terminal arranged in a cylindrical assembly is connected to an outer conductor of a power coaxial cable.
Further, for example, Patent Documents 2 and 3 disclose a connection technology (straight line connection portion) between power coaxial cables as a terminal connection portion (intermediate connection portion) of the power coaxial cable.

JP 2008-312303 A JP 2007-325442 A JP 2001-112139 A

However, in the terminal connection part (terminal connection part) of the conventional power coaxial cable as disclosed in Patent Document 1, an insulating part for insulating the connection part with the inner conductor of the power coaxial cable (Patent Document) The structure is complicated, for example, an insulating part (insulating oil in Patent Document 1) is provided separately to insulate a connecting part between the insulating oil and the external conductor. In addition, since the construction is performed locally, the insulation characteristics vary depending on the operator, and a long time is required for the construction.
Further, in the case of an air termination connection portion among the terminal connection portions of a conventional power coaxial cable, the internal conductor is connected by a conductor lead bar as in the air termination connection portion (box) of Patent Document 1. That is, since it is not a slip-on system, it is not easy to insert and remove the cable. In addition, the cable processing length is long, so construction time is required. In addition, because of the capacitor type (paper winding), the construction time becomes long, and there is a variation by the installer.
Other conventional techniques for the terminal connection part of the coaxial cable for electric power include a tape winding system connection part and a mold system connection part described in Patent Documents 2 and 3, but there are similar problems.

That is, in the terminal connection part of the coaxial cable for electric power described in the conventional patent documents 1 to 3, there are the following problems (1) to (4).
(1) Since the structure is complicated, the performance is not stable.
(2) It takes construction time due to the complicated structure.
(3) Capacitor cone, tape winding mold method and extrusion mold method require high skill in construction.
(4) Since it is not a slip-on system, it is not easy to insert and remove the cable. In particular, in the tape winding type connection part and the extrusion mold type connection part that performs crosslinking by heating and the entire integration, it is necessary to replace all parts at the time of disassembly.

  The objective of this invention is providing the terminal connection part of the coaxial cable for electric power which can improve the workability | operativity at the time of construction while having the stable insulation characteristic.

The terminal connection part of the power coaxial cable according to the present invention is an electric power coaxial cable in which at least an inner conductor, an inner insulator, an outer conductor, an outer insulator, and a cable shielding layer are concentrically formed in order from the center. A terminal connection,
A first conductor connecting portion electrically connected to the inner conductor;
A second conductor connection portion electrically connected to the outer conductor;
The power coaxial cable is formed integrally with the first conductor connecting portion and the second conductor connecting portion so as to surround outer peripheral surfaces of the first conductor connecting portion and the second conductor connecting portion. An insulating part made of a hard insulating material having a cable terminal receiving part for mounting the cable terminal part of
A shielding layer formed on the outer surface of the insulating part,
The first electric field relaxation component for controlling the electric field between the inner conductor and the outer conductor, and the second electric field relaxation component for controlling the electric field between the outer conductor and the cable shielding layer are attached. A cable terminal portion is attached to the cable terminal receiving portion.

  According to the present invention, the terminal portion of the power coaxial cable is simply mounted in the insulating unit in which the first conductor connecting portion, the second conductor connecting portion, the insulating portion, and the shielding layer are integrally formed. Therefore, it is possible to realize a terminal connection portion of a power coaxial cable that has stable insulation characteristics and can improve workability during construction.

It is sectional drawing which shows the structure of the coaxial cable for electric power. It is a figure which shows the terminal connection part of the coaxial cable for electric power which concerns on embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 2 is a diagram illustrating a terminal connection portion of the power coaxial cable according to the embodiment. In the following description, in FIG. 2, the upper side is referred to as the front end side, and the lower side is referred to as the rear end side.
The terminal connection portion 1 of the power coaxial cable shown in FIG. 2 is a gas termination connection portion for connecting the power coaxial cable 20 to a power device such as a gas insulated switchgear or a transformer.
As shown in FIG. 2, the terminal connection portion 1 of the power coaxial cable is configured by mounting the power coaxial cable 20 and the power single-core cable 40 on the insulating unit 10.
Here, the power single-core cable in the present application is for distinguishing from the power coaxial cable, and includes a so-called triplex cable (for example, a CVT cable).

  As shown in FIG. 1, the power coaxial cable 20 includes, in order from the center, an internal conductor 21a, an internal semiconductive layer 21b for internal insulation, an internal insulator 21c, an external semiconductive layer 21d for internal insulation, an external conductor 22a, an external conductor An internal semiconductive layer 22b for insulation, an external insulator 22c, an external semiconductive layer 22d for external insulation, a cable shielding layer 23, a pressing tape 24, and a cable sheath 25 (here, vinyl sheath) are formed concentrically. .

The power coaxial cable 20 is a so-called high voltage coaxial cable in which an inner insulator 21c and an outer insulator 22c are made of crosslinked polyethylene.
A current with a first voltage (for example, 66 kV) flows through the inner conductor 21a, and a current with a second voltage (for example, 11 kV) flows through the outer conductor 22a to transmit power. The first voltage applied to the inner conductor 21a is higher than the second voltage applied to the outer conductor 22a. Further, the cable shielding layer 23 is set to the ground potential.

  The power single-core cable 40 includes, in order from the center, a cable conductor 41, an internal semiconductive layer (not shown), an insulating layer 42, an external semiconductive layer 43, a cable shielding layer 44, a pressing tape (not shown), and a cable sheath 45. (In this case, vinyl sheath) and the like. The power single-core cable 40 is a CV cable for 11 kV, for example, in which the insulating layer 42 is made of crosslinked polyethylene. One end of the power single-core cable 40 is connected to the insulating unit 10, and the other end is connected to a power device such as a gas-insulated switchgear or a transformer or an air terminal connection (11 kV side).

  The ends of the coaxial cable for power 20 and the single-core cable for power 40 are stepped to a predetermined length to expose each layer, and a connecting part such as a stress cone or a compression device is attached to produce a terminal portion of the cable. .

The insulating unit 10 includes a conductor lead bar 11, a buried electrode 12, an insulating portion 13, a shielding layer 14 and the like.
Further, the insulating unit 10 has a mounting flange 15 at a lower end portion of a bushing head portion 13c to be described later, and this mounting flange 15 is attached to a power device installation plate 70 via a sealing material (not shown) such as an O-ring. By tightening the bolts, the bushing head 13c is disposed in an airtight state in a state where the bushing head 13c is disposed inside the power device.

The insulating part 13 is a hollow molded body made of a hard insulating material such as an epoxy resin. The insulating part 13 includes a coaxial cable terminal receiving part 13a for mounting the terminal part of the power coaxial cable 20, a single core cable terminal receiving part 13b for mounting the terminal of the power single cable 40, and a power device. It has a bushing head 13c to be placed inside.
In FIG. 2, the single-core cable terminal receiving portion 13b is formed at a portion branched from the portion where the coaxial cable terminal receiving portion 13a is formed. The bushing head portion 13c is formed on the distal end side of the portion where the coaxial cable terminal receiving portion 13a is formed, and has a shape in which a cylindrical portion and a truncated cone portion are continuously provided.

The conductor lead bar 11 is made of a metal material suitable for energization such as a copper alloy. A conductor insertion portion 11 a for electrically connecting the inner conductor 21 a of the power coaxial cable 20 is formed at the rear end portion of the conductor lead bar 11.
The conductor lead-out bar 11 is embedded in the insulating portion 13 so that the conductor insertion portion 11a and the coaxial cable end receiving portion 13a of the insulating portion 13 are connected to each other and the distal end portion 11b penetrates the insulating portion 13 and is exposed to the outside. Is done. The leading end portion 11b of the conductor lead bar 11 is connected to a conductor portion (not shown) in the power device.

The embedded electrode 12 is made of a metal material suitable for energization such as a copper alloy. The embedded electrode 12 is embedded in the insulating portion 13 so as to connect the coaxial cable terminal receiving portion 13a and the single-core cable terminal receiving portion 13b.
The conductor lead bar 11, the embedded electrode 12, and the insulating portion 13 are integrally formed by molding an epoxy resin.

The shielding layer 14 of the insulating unit 10 is a conductive layer formed on the outer surface of the insulating portion 13. When the shielding layer 14 is grounded, the outer surface of the insulating unit 10 is held at the ground potential. Thereby, the electric field stress in the insulating part 13 is relieved and external leakage of the electric field is prevented.
The shielding layer 14 is formed, for example, by applying a conductive paint to the outer surface of the insulating portion 13. In the case where the shielding layer 14 is formed by applying a conductive paint, the shielding layer 14 can be easily formed, so that the degree of freedom in designing the shape of the insulating portion 13 is increased.

  The shielding layer 14 of the insulating unit 10 and the cable shielding layer 23 of the power coaxial cable 20 or the cable shielding layer 44 of the power single-core cable 40 are cut off by providing an edge cut portion. By providing this edge cut portion, the cable shielding layers 23 and 44 can be protected from an open / close surge or a lightning surge of the power equipment.

The edge cut portion may be formed by an insulating tube made of epoxy resin, but as shown in FIG. 2, the shielding layer 14 is not formed on the end portions 13d and 13e of the insulating portion 13 (the conductive paint is not applied here). Thus, one end portion 13 d of the insulating portion 13 becomes an edge cutting portion for cutting the cable shielding layer 23 (here, the metal fitting flange 342) and the shielding layer 14 of the power coaxial cable 20. In addition, the other end 13e of the insulating portion 13 includes a cable shielding layer 44 (here, the cable protection metal fitting 53 that is in contact with the compression device 52) of the power single-core cable 40 and an edge cutting portion that cuts off the shielding layer 14. Become.
This eliminates the need for an insulating cylinder for edge cutting, reduces the number of parts, improves workability during assembly, and eliminates the need for an insulating cylinder, so that it can be compactly formed in the longitudinal direction as a terminal connection part, and cable processing Since the length is short, it is more preferable.

  The terminal portion of the power coaxial cable 20 that has been subjected to the step stripping process and to which a predetermined connection component is attached is attached to the coaxial cable terminal receiving portion 13a in a slip-on manner. Thereby, the power coaxial cable 20 can be easily connected to the insulating unit 10, and the construction time can be shortened.

Specifically, a conductive conductor connection sleeve 31 suitable for energization made of, for example, copper, aluminum, copper alloy, or aluminum alloy is provided on the inner conductor 21a at the stepped end of the power coaxial cable 20. Installed by compression. A conductor contact (for example, a multi-ram band) for allowing the terminal portion of the power coaxial cable 20 to be inserted into and removed from the insulating unit 10 is disposed on the outer periphery of the conductor connection sleeve 31. It is attached to the insertion portion 11a so as to be insertable / removable (slip-on method).
Thus, when the power coaxial cable 20 is attached to the insulating unit 10 by the slip-on method, the cable processing length can be shortened and the cable can be easily attached and detached, so that the construction time can be greatly reduced.

  A first electric field relaxation component 32 for controlling the electric field between the inner conductor 21 a and the outer conductor 22 a is attached to the outer peripheral surface of the inner insulator 21 c of the power coaxial cable 20. Here, the first electric field relaxation component 32 includes a first stress cone 321 and a first compression device CU1. The first compression device CU1 presses the first stress cone 321 from the rear end side, and here is configured by a pressing metal 322, a spring 323, and a pressing metal pipe 324.

  A first stress cone 321 is attached to the outer peripheral surface of a portion extending from the internal insulator 21c to the external semiconductive layer 21d for internal insulation. The first stress cone 321 includes an insulating portion on the tip side made of an insulating rubber material (for example, ethylene propylene rubber (EP rubber) or silicone rubber) and a semiconductive rubber material (for example, semiconductive ethylene). A semiconductive portion on the rear end side made of propylene rubber (EP rubber) or silicone rubber). The insulator portion and the semiconductor portion are integrally formed by molding. The distal end portion (insulator portion) of the first stress cone 321 has a shape corresponding to the coaxial cable terminal receiving portion 13a of the insulating portion 13 (here, a tapered shape). The tip of the semiconductive portion has a bell mouth shape having a circular arc cross section in order to reduce the electric field.

A push fitting 322 is disposed on the rear end side of the first stress cone 321. The front end portion of the press fitting 322 is formed in a trumpet shape whose inner diameter increases toward the front end side corresponding to the outer peripheral surface on the rear end side of the first stress cone 321 (the outer peripheral surface of the semiconductive portion). The
A plurality of recesses for accommodating a coiled spring 323 are provided on the circumference at the rear end portion of the press fitting 322, and the springs 323 are respectively disposed in the recesses, and a press fitting pipe 324 is provided at the rear end side of the spring 323. Be placed. A partition piece 324a projecting radially inward is formed in the vicinity of the distal end portion of the pressing metal pipe 324, and the rear end portion of the spring 323 is supported by the partition piece 324a.

  The rear end portion of the pressing metal pipe 324 extends to the rear end portion of the embedded electrode 12. The flange surface of the rear end portion of the pressing metal pipe 324 is brought into contact with the rear end surface (stepped portion) of the embedded electrode 12 and fixed by a plurality of bolts V1, whereby the first stress cone 321 is insulated from the insulating portion 13. It is fixed in a pressed state on the inner peripheral surface of the (coaxial cable terminal receiving portion 13a). The pressing metal pipe 324 is electrically connected to the embedded electrode 12. Further, the inner diameter of the first stress cone 321 is formed smaller than the outer diameter of the cable (the outer diameter of the internal insulator 21c).

  An outer conductor connecting component 33 is attached to the outer peripheral surface of the outer conductor 22 a of the power coaxial cable 20. The external conductor connecting component 33 includes a conductive external conductor fixing metal fitting 331 and an external conductor fixing ring 332 that are suitable for energization made of, for example, copper, aluminum, copper alloy, or aluminum alloy.

The outer conductor fixing metal fitting 331 is formed in a hollow truncated cone shape whose diameter is reduced toward the rear end side. The outer conductor fixing metal fitting 331 is arranged on the inner periphery on the rear end side of the partition piece 324a of the pressing metal pipe 324, and is a multi-surface contact type conductor contactor (here, multiram) arranged on the outer peripheral surface of the outer conductor fixing metal fitting 331. It is electrically connected to the presser fitting pipe 324 through a band (not shown).
The outer conductor 22a is disposed along the tapered outer surface on the rear end side of the outer conductor fixing bracket 331, and the outer conductor fixing ring 332 is fitted from the outside to be fixed to the outer conductor fixing bracket 331 with a plurality of bolts V2. As a result, the outer conductor fixing ring 332 is fixed to the outer conductor fixing metal fitting 331. The outer conductor 22a is nipped and fixed while being pressed by the outer conductor fixing metal fitting 331 (first fixing member) and the outer conductor fixing ring 332 (second fixing member). The outer conductor 22a is electrically connected to the embedded electrode 12 via the outer conductor fixing metal fitting 331 and the pressing metal pipe 324.

  When the external conductor 22a and the embedded electrode 12 are electrically connected, soldering or welding is not performed, so that the external conductor 22a and the external conductor connecting component 33 can be easily separated during disassembly. Further, the external conductor connecting component 33 can be reused.

  A second electric field relaxation component 34 for controlling the electric field between the outer conductor 22 a and the cable shielding layer 23 is attached to the outer peripheral surface of the outer insulator 22 c of the power coaxial cable 20. Here, the second electric field relaxation component 34 includes a second stress cone 341 and a second compression device CU2. The second compression device CU <b> 2 presses the second stress cone 341 from the rear end side, and here is constituted by a pressing metal flange 342.

  A second stress cone 341 is attached to the outer peripheral surface of the portion extending from the external insulator 22c to the external insulating external semiconductive layer 22d. A stopper 35 is interposed between the second stress cone 341 and the rear end portion of the first compression device CU1 (here, the metal fitting pipe 324). The second stress cone 341 has substantially the same configuration as the first stress cone 321, although the shape is different. That is, the second stress cone 341 has an insulator portion on the front end side and a semi-conductor portion on the rear end side, and the outer periphery of the tip portion (insulator portion) of the second stress cone 341 It has a shape corresponding to the rear end (here, a tapered shape). The tip of the semiconductive portion of the second stress cone 341 has a bell mouth shape whose tip is arc-shaped in cross section in order to relax the electric field.

  On the rear end side of the second stress cone 341, a pressing metal flange 342 is disposed. The second stress cone 341 is fixed in a state of being pressed against the inner peripheral surface of the insulating portion 13 by bringing the front end surface of the pressing metal flange 342 into contact with the rear end surface of the insulating portion 13 and fixing with the bolt V3. . In addition, the inner diameter of the second stress cone 341 is smaller than the outer diameter of the cable (the outer diameter of the external insulator 22c), and the second stress cone 341 and the power coaxial cable 20 are securely in close contact due to the difference in diameter.

The cable shielding layer 23 of the power coaxial cable 20 is connected to the pressing metal flange 342. The cable shielding layer 23 is connected to the ground potential through the presser flange 342.
A protective metal fitting 61 is attached to the rear end side of the pressing metal flange 342, and an anticorrosion layer 62 is formed from the rear end portion of the protective metal fitting 61 to the cable sheath 25 of the power coaxial cable 20.

Further, the terminal portion of the power single-core cable 40 subjected to the stripping process is attached to the single-core cable terminal receiving portion 13b. Specifically, a connecting component 50 including a stress cone 51, a compression device 52 (here, a type having a shaft), and the like is attached to the distal end portion of the power single-core cable 40. The cable conductor 41 and the embedded electrode 12 are electrically connected by connecting the terminal portion of the power single-core cable 40 to which the connection component 50 is attached to the single-core cable terminal receiving portion 13b (inserted in FIG. 2). Is done. Further, the cable shielding layer 44 of the power single-core cable 40 is connected to the ground potential via, for example, the compression device 52 and the cable protection fitting 53.
Note that the configuration of the terminal portion of the power single-core cable 40 may be a known connection method, and is not limited to that described in the present embodiment.

  As described above, the terminal connection portion 1 of the power coaxial cable according to the embodiment includes the conductor lead bar 11 (first conductor connection portion) electrically connected to the inner conductor 21a of the power coaxial cable 20; The embedded electrode 12 (second conductor connecting portion) electrically connected to the outer conductor 22a of the power coaxial cable 20 and the conductor extraction rod so as to surround the outer surfaces of the conductor extraction rod 11 and the embedded electrode 12 11 and the embedded electrode 12, and an insulating portion 13 made of a hard insulating material having a coaxial cable terminal receiving portion 13 a for mounting the cable terminal portion of the power coaxial cable 20. And a shielding layer 14 formed on the outer surface (insulating unit 10). The first electric field relaxation component 32 for controlling the electric field between the inner conductor 21a and the outer conductor 22a, and the second electric field relaxation component 34 for controlling the electric field between the outer conductor 22a and the cable shielding layer 23 are provided. The attached cable terminal portion is attached to the coaxial cable terminal receiving portion 13a (so-called inner cone type).

  Conventionally, there is no inner cone type as in this embodiment as a power coaxial cable terminal connecting portion, but the terminal connecting portion 1 of the power coaxial cable is a conductor lead bar 11 (first conductor connecting portion). A simple configuration in which the terminal portion of the power coaxial cable 20 is mounted in the insulating unit 10 in which the embedded electrode 12 (second conductor connecting portion), the insulating portion 13, and the shielding layer 14 are integrally formed. Have In the case of an epoxy cast product, the insulation unit 10 can confirm an insulation performance by performing an electrical test in a factory. Therefore, the terminal connection part 1 of the coaxial cable for electric power using the insulation unit 10 has a stable insulation performance compared with the case where an insulation part is formed at the time of field construction like the past, and workability at the time of construction. Can be significantly improved.

  Further, in the terminal connection portion 1 of the power coaxial cable, the inner conductor 21a of the power coaxial cable 20 and the conductor lead bar 11 (first conductor connection portion) are electrically connected in a sealed space in the insulating unit 10. In addition, the outer conductor 22a of the power coaxial cable 20 and the cable conductor 41 of the power single-core cable 40 are electrically connected via the embedded electrode 12 (second conductor connection portion).

  A portion where the inner conductor 21a of the power coaxial cable 20 and the conductor lead bar 11 are connected is a first high voltage portion, and the outer conductor 22a of the power coaxial cable 20 and the cable conductor 41 of the power single-core cable 40 are connected. The part to be connected becomes the second high-pressure part. All of the first high-voltage part and the second high-voltage part are covered with the insulating part 13 of the insulating unit 10 and are insulated from the outside. A first voltage is applied to the first high voltage section, and a second voltage is applied to the second high voltage section. In the embodiment, a voltage of 66 kV is applied to the first high voltage part, and a voltage of 11 kV is applied to the second high voltage part.

As described above, the terminal connection portion 1 of the power coaxial cable has a completely sealed structure in which the high voltage portion and the charging portion are covered with the shielding layer 14 and is not exposed, so that it is effective for human injury (electric shock) and fire due to contact. Can be prevented and safety is excellent.
Moreover, in the terminal connection part 1 of the power coaxial cable, the slip-on method is adopted among the inner cone types, so that the terminal of the power coaxial cable can be inserted / removed. And can be easily inserted and removed.

As mentioned above, the invention made by the present inventor has been specifically described based on the embodiment. However, the present invention is not limited to the above embodiment, and can be changed without departing from the gist thereof.
For example, the power single-core cable 40 may be attached to the insulating unit 10 as an outer cone type. In the outer cone type, for example, the terminal portion of the power single-core cable is not an inner cone type stress cone but an inner cone type as shown in FIGS. 1 to 6 of Japanese Patent Application Laid-Open No. 2007-151298. This is a known insulation method in which a rubber block (rubber unit) including a semiconductive layer, an insulating layer, and an external shielding layer is insulated by attaching it to the outer periphery of the protruding portion of the insulating unit (epoxy unit). In the embodiment, when the terminal portion of the power single-core cable 40 is formed of an outer cone type, a protrusion to which a rubber block (rubber unit) is attached instead of the single-core cable terminal receiving portion 13b of the insulating unit 13 is used. Part (corresponding to 5c of JP2007-151298A), the embedded electrode 12 is exposed in a round bar shape from the protruding portion, and a rubber block is formed on the outer periphery where the exposed embedded electrode and the cable conductor 41 are connected. (Rubber unit) is mounted (not shown).

  Further, for example, in the embodiment, the case where the tip end portion 11b of the conductor lead bar 11 is applied to a gas termination connection portion connected to a power device has been described. It can also be applied to the middle termination connection.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 Terminal connection part of electric power coaxial cable 10 Insulation unit 11 Conductor extraction rod (1st conductor connection part)
12 Embedded electrode (second conductor connection part)
13 Insulating part 14 Shielding layer 15 Mounting flange 20 Power coaxial cable 21a Internal conductor 21b Internal semiconductive layer 21c for internal insulation Internal insulator 21d External semiconductive layer 22a for internal insulation External conductor 22b Internal semiconductive layer 22c for external insulation External Insulator 22d External semiconductive layer 23 for external insulation Cable shield layer 24 Press tape 25 Cable sheath 31 Conductor connection sleeve 32 First electric field relaxation component 321 First stress cone CU1 First compression device 322 Press fitting 323 Spring 324 Press Metal pipe 33 External conductor connection part 331 External conductor fixing metal part 332 External conductor fixing ring 34 Second electric field relaxation part 341 Second stress cone CU2 Second compression device 342 Press metal flange 35 Stopper 40 Power single-core cable 50 Connection Part 51 Stress Co 52 compressor 53 cable protection bracket

Claims (7)

In order from the center, at least an inner conductor, an inner insulator, an outer conductor, an outer insulator, and a terminal connection portion of a coaxial cable for power formed by concentrically forming a cable shielding layer,
A first conductor connecting portion electrically connected to the inner conductor;
A second conductor connection portion electrically connected to the outer conductor;
The power coaxial cable is formed integrally with the first conductor connecting portion and the second conductor connecting portion so as to surround outer peripheral surfaces of the first conductor connecting portion and the second conductor connecting portion. An insulating part made of a hard insulating material having a cable terminal receiving part for mounting the cable terminal part of
A shielding layer formed on the outer surface of the insulating part,
The first electric field relaxation component for controlling the electric field between the inner conductor and the outer conductor, and the second electric field relaxation component for controlling the electric field between the outer conductor and the cable shielding layer are attached. The terminal connection part of the coaxial cable for electric power characterized by the cable terminal part being mounted | worn with the said cable terminal receiving part. The first electric field relaxation component includes a first stress cone made of rubber and a first pressing device disposed on a rear end side of the first stress cone.
The second electric field relaxation component includes a second stress cone made of rubber and a second pressing device disposed on a rear end side of the second stress cone. The terminal connection part of the coaxial cable for electric power of description.   The first voltage is applied to the first conductor connection portion, and a second voltage lower than the first voltage is applied to the second conductor connection portion. Or the terminal connection part of the coaxial cable for electric power of 2.   4. The terminal connection portion of the power coaxial cable according to claim 1, wherein the insulating portion is made of an epoxy resin. 5. The second conductor connection portion has a first fixing member and a second fixing member,
5. The electric power according to claim 1, wherein the outer conductor is sandwiched and fixed while being pressed by the first fixing member and the second fixing member. 6. Coaxial cable terminal connection. The first pressing device includes a pressing metal, a plurality of springs arranged in a plurality of recesses on the rear end side of the pressing metal, and a pressing metal pipe arranged on the rear end side of the spring,
Provided with a partition piece projecting radially inward in the vicinity of the tip of the pressing metal pipe, supporting the spring by the tip surface of the partition piece,
6. The terminal connection portion of the power coaxial cable according to claim 5, wherein the first fixing member is disposed on an inner periphery of the pressing metal pipe on a rear end side of the partition piece.   The terminal connection part of the coaxial cable for electric power according to any one of claims 1 to 6, wherein the inner conductor is connected to the first conductor connection part so as to be insertable / removable by a slip-on method.

Images