JP3006333B2 - Termination connection for power cable with built-in optical fiber unit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power cable terminating connection, and more particularly to an optical fiber unit built-in type in which an optical fiber unit for pulling down from a high voltage section is built in a common insulator with the power cable terminating section. The present invention relates to a power cable termination connection.

[0002]

2. Description of the Related Art When transmitting an optical signal from a high voltage section to a low voltage section at a power cable terminal connection section, this can be realized by pulling down an optical fiber from a high voltage section. It is difficult to maintain and it is extremely difficult to put it to practical use. In other words, under such conditions, since a high voltage is applied to the optical fiber, it enters during use due to the presence of an air layer between the sheath reinforcing layer and the core wire and the low insulation strength of the sheath reinforcing layer itself. There is a possibility that the air layer flashes due to the generated moisture, the optical fiber is damaged due to the deterioration of the jacket reinforcing layer, or the surface of the jacket reinforcing layer flashes due to the carbonization phenomenon of the jacket reinforcing layer.

Under such a problem, an optical fiber is housed in a porcelain tube separate from a power cable terminal connection portion, and insulating oil, compound, gas and the like are sealed therein and the optical fiber is removed from a high voltage portion. Has been implemented in some cases. In this case, in order to obtain higher reliability, a method is employed in which the optical fiber is cut off at the upper and lower portions of the insulator tube, and light is transmitted through a glass plate also serving as a seal.

[0004] On the other hand, recently, an optical electric field sensor or a magnetic field sensor is attached to a power cable terminal connection portion, and is often used for various purposes. One example is the determination of an accident section, which is applied to determine whether an accident has occurred on an underground line or an overhead line.
In this case, since it is difficult to pull down the optical fiber from the high voltage portion, it is common to attach these sensors to a lower metal fitting located on the ground side of the power cable terminal connection (porcelain tube).

[0005]

However, according to the conventional pulling-down structure of the optical fiber at the power cable terminal connection, the optical fiber is housed in a porcelain separate from the power cable terminal connection. There is a disadvantage that the entire structure including the terminal connection part becomes large and requires a large space, and the cost increases.

[0006] Further, when determining an accident section, since a sensor is attached to the lower metal fitting of the power cable terminal connection, an accident in the terminal connection may be determined as an overhead line, and the accuracy of the determination is high. Is bad.

Accordingly, an object of the present invention is to improve the withstand voltage characteristic of an optical fiber without increasing the size of the entire structure and increase the cost, and at the same time, to improve the accuracy of judging an accident section. It provides a cable termination connection.

[0008]

SUMMARY OF THE INVENTION In view of the above problems, the present invention improves the withstand voltage characteristic of an optical fiber without increasing the size of the entire structure and the cost, and at the same time, improves the accuracy of determining an accident section. For this reason, a power cable termination type power cable built-in type power cable termination connection portion provided with one or a plurality of optical fiber units disposed and supported by an upper fitting and a lower fitting in an insulator tube of the power cable termination connection portion. To provide.

The optical fiber unit comprises: first and second optical connectors supported by an upper fitting and a lower fitting; and an optical fiber linearly provided between the first and second optical connectors. , Covering the outer periphery of the optical fiber,
And a molded resin body applied to the second optical connector.

The first optical connector is connected to a sensor for detecting current and voltage of a power cable, and the second optical connector is connected to a measuring instrument. This sensor is
An optical magnetic field sensor and an electric field sensor are arranged on the outer periphery of the conductor extraction rod.

[0011]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a terminal connecting portion for a power cable with a built-in optical fiber unit according to the present invention.

FIG. 1 shows a sectional structure of an embodiment of the present invention. The power cable termination connection includes a power cable 22 having a reinforcing insulation 23 and a power cable 2.
2, a conductor extraction rod 6 connected to the conductor 25 exposed from the stripped portion, an insulator tube 13 surrounding the connection between the power cable 22 and the conductor extraction rod 6, and an upper fitting for hermetically supporting the conductor extraction rod 6. 11, a lower metal fitting 14 for hermetically supporting the power cable 22, and an insulating oil 2 contained in the insulator tube 13.
4, an optical fiber unit 12, both ends of which are supported by an upper metal fitting 11 and a lower metal fitting 14, and arranged linearly inside a porcelain tube 13.

The upper bracket 11 is surrounded by the corona shield 7 and is provided with an optical magnetic field sensor 19 on the conductor lead bar 6 and an optical electric field sensor 20 outside the corona shield 7. The optical electric field sensor 20 is provided with a protective cover 21 integrated with the corona shield 7.

The optical fiber unit 12 penetrates through the upper fitting 11 and the lower fitting 14 through a packing seal, and both ends penetrating the upper fitting 11 and the lower fitting 11 by the upper optical unit fixing part 10 and the lower optical unit fixing part 15. The upper optical connector 9 is fixed to the lower metal fitting 14, the upper optical connector 9 is connected to the upper end, and the lower optical connector 16 surrounded by the protective cover 17 is connected to the lower end.
An optical magnetic field sensor 19 and an optical electric field sensor 20 are connected to the upper optical connector 9 via an optical fiber 8, and a measuring instrument (not shown) is connected to the lower optical connector 16 via an optical fiber 18. It is connected. That is, optical signals from the two sensors are transmitted to the measuring device via the optical fiber unit 12.

The fixing of the optical fiber unit 12 to the upper metal fitting 11 and the lower metal fitting 14 is performed by using an insulator tube 13.
In consideration of the length tolerance and the thermal expansion and contraction of the optical fiber unit 12, only one of the upper optical unit fixing portion 10 and the lower optical unit fixing portion 15 is fixed, and the other is slidable in the axial direction to some extent. It is desirable to perform from. The optical fiber unit 1 built in the insulator tube 13
The number 2 is not limited to one, and a plurality may be arranged in the circumferential direction of the power cable 22.

FIG. 2 shows an example of an optical fiber unit applied to the present invention. In this optical fiber unit 12, an optical receptacle (optical connector) 1 integrated with a protective tube 2 is connected to both ends of an optical fiber (an optical fiber core wire having no tension member or jacket), and both optical receptacles 1 are connected. It is formed by integrally molding a circular rod-shaped epoxy resin 4 so as to cover and between the two protective tubes 2. The outer circumference of the optical fiber 3 may be housed in the insulator tube 13 without being covered with the epoxy resin.

In the above configuration, the optical magnetic field sensor 1
9 or an optical signal output from the optical electric field sensor 20 is transmitted to the upper optical connector 9 via the optical fiber 8 of the upper metal fitting 11, and then transmitted to the lower optical connector 16 via the optical fiber unit 12. You. The optical signal transmitted to the lower optical connector 16 is transmitted via an optical fiber 18 to a measuring device, where an accident section is determined.

As described above, according to the present invention, an optical fiber unit is built in a porcelain tube of a power cable terminal connection,
By attaching a sensor for determining an accident section to the upper bracket, it is possible to improve the withstand voltage characteristics of the optical fiber unit without complicating the entire structure, and reduce the installation space and reduce costs while determining the accident section. Accuracy can be improved.

In the above embodiment, the example of the aerial terminal connection portion for the power cable is shown. However, the present invention is not limited to this. By reviewing a part of the structure, another terminal connection portion (for example, , In oil, SF ₆ gas in terminal connection). Moreover, it is also possible to apply to the extraction of the optical signal from the high-voltage section even with equipment such as GIS other than the cable. In the above embodiment, the optical fiber is covered with an epoxy resin or the like and provided in a straight line.
It is also possible to provide an optical fiber without a coating in a curved manner according to the space in the insulator tube.

[0020]

As described above, according to the terminal connection portion for a power cable with a built-in optical fiber according to the present invention, the power cable terminal connection portion is linearly supported by the upper metal fitting and the lower metal fitting in the insulator tube. Since one or more optical fiber units are arranged, it is possible to improve the withstand voltage characteristic of the optical fiber without increasing the size of the entire structure and to increase the cost, and also to improve the accuracy of determining an accident section. Can be.

[Brief description of the drawings]

FIG. 1 is a sectional view showing an embodiment of the present invention.

FIG. 2 is a sectional view showing an optical fiber unit according to one embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Optical receptacle 2 Protective cylinder 3 Optical fiber 4 Epoxy resin 6 Conductor lead-out bar 7 Corona shield 8 Optical fiber 9 Upper optical connector 10 Upper optical unit fixing part 11 Upper metal fitting 12 Optical fiber unit 13 Insulator tube 14 Lower metal fitting 15 Lower optical unit fixing part Reference Signs List 16 lower optical connector 17 protective cover 18 optical fiber 19 optical magnetic field sensor 20 optical electric field sensor 21 protective cover 22 power cable 23 reinforcing insulation 24 insulating oil 25 conductor

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-5-40205 (JP, A) JP-A-64-54369 (JP, A) JP-A-61-169434 (JP, U) 19778 (JP, B2) Jiko 1-27393 (JP, Y2) (58) Fields investigated (Int. Cl. ⁷ , DB name) H02G 15/00-15/196

Claims (3)

(57) [Claims] 1. A conductor lead bar connected to a conductor exposed from a stepped portion of a power cable is supported by an upper metal fitting provided at one end of a porcelain tube, and the power supply rod is provided by a lower metal fitting provided at the other end of the porcelain tube. A terminal connection portion of a power cable supporting an outer peripheral portion of a non-stripped portion of the cable and accommodating the stepped portion of the power cable insulated and reinforced by a reinforced insulating portion in the porcelain tube; is supported at both ends by the lower bracket, one disposed within the porcelain bushing, or made by providing a plurality of optical fiber unit, the optical fiber unit
Is supported by the upper fitting and the lower fitting.
First and second optical connectors, and the first and second optical connectors
Optical fiber linearly installed between the optical connectors
The first and second optical cores cover the outer circumference of the optical fiber.
Composed of a molded resin body applied to the connector
A terminal connection section for a power cable with a built-in optical fiber unit, characterized in that: 2. The power cable according to claim 1, wherein the first optical connector is connected to the power cable.
2. The terminal connection section for a power cable with a built-in optical fiber unit according to claim 1 , wherein the second optical connector is connected to a sensor for detecting current and voltage of the optical fiber unit , and the second optical connector is connected to a measuring instrument . 3. The sensor is mounted on the outer periphery of the conductor pull-out bar.
The terminal connection section for an optical fiber unit built-in type power cable according to claim 2, which is an optical magnetic field sensor and an electric field sensor arranged .