JP3261108B2 - Bushing for cable termination - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cable terminal bushing for connecting a power cable such as a CV cable used in a terminal box in gas or a terminal box in oil.

[0002]

2. Description of the Related Art A CV cable used as an underground electric line or the like is connected to equipment such as a substation via a cable terminal bushing such as a gas terminal connection box. In this bushing for terminating a cable, the conductor 1a at the end of the CV cable 1 is connected to the lower end of the conductor pull-out rod 8 in the inner hole of the sheath 2 made of epoxy resin as shown in FIG. The upper end of the conductor pull-out rod 8 pulled out from the device is connected to the device. The CV cable 1 is inserted into the inner hole from below the sleeve 2 with the conductor 1a protruding from the end. Also, the CV cable 1 has
A pre-molded insulator 5 made of a spindle-shaped cylindrical EP rubber is closely fitted in advance, and the pre-molded insulator 5 is inserted into the inner hole from below the sleeve 2 to form a tapered shaft surface 5a formed on the upper portion. Is pressed against the tapered hole surface 2a formed in the inner hole of the sleeve 2 so that the connection portion between the CV cable 1 and the conductor lead rod 8 is covered with the insulator without any gap. The pre-mold insulator 5 is pressed by a spring of the pre-mold insulator pressing device 6.

[0003] At the upper end of the sleeve 2 is a CV cable 1
In order to alleviate the electric field at the connection portion between the wire and the conductor pull-out rod 8 so that the electric stress is not concentrated, the upper shield metal fitting 11 is used.
Is embedded. The upper shield fitting 11 is a cylindrical body made of aluminum, and the lower end part is the shield fitting body 1.
1a, a screw hole 11b is formed at the upper end, and the screw hole 11b is embedded so as to be exposed at the upper end surface of the sleeve 2. And this upper shield fitting 1
By screwing a bolt through the upper fitting 9 to the first screw hole 11b, the upper fitting 9 is attached to the upper end surface of the sleeve 2 so that the upper shield fitting 11 is electrically connected to the conductor lead rod 8. ing.

[0004] A lower shield fitting 12 for reducing the electric field is also embedded in the lower end of the sleeve 2. Similarly to the upper shield fitting 11, the lower shield fitting 12 is a cylindrical body made of aluminum. The upper end part forms the shield fitting body 12a, and the lower end part has a screw hole 12b formed therein. Is embedded so as to be exposed at the lower end surface of the sleeve 2. Then, a bolt is screwed into the screw hole 12b of the lower shield fitting 12 via the lower fitting 7, thereby attaching the lower fitting 7 to the lower end surface of the sleeve 2, and pressing the lower shield fitting 12 with the pre-molded insulator. The device 6 is connected to the external semiconductive layer 1b of the CV cable 1.

[0005]

However, the upper shield metal fitting 11 and the lower shield metal fitting 12 of the above-mentioned conventional sleeve 2 are used.
However, since it is necessary to cut out a columnar aluminum material and form it into a long cylindrical body, there is a problem that the material is expensive and processing is troublesome, resulting in high cost.

The reason that expensive aluminum materials are used for the upper shield metal fitting 11 and the lower shield metal fitting 12 is that when epoxy resin is cast for embedding them in the sleeve 2,
If other inexpensive metals, such as brass, are used, cracks may occur in the epoxy resin due to curing strain, and the airtightness inside the sleeve 2 may be deteriorated. In addition, the upper shield metal fitting 11 and the lower shield metal fitting 12 are exposed only on the upper and lower end surfaces of the sleeve 2 in FIG. 7, but may also be exposed on the inner peripheral surface of the inner hole. In case,
If a casting is used for the upper shield fitting 11 and the lower shield fitting 12, the airtightness is reduced due to minute gaps in the casting, so that the aluminum material has to be cut out by cutting.

In the case of a large cable terminal bushing for high voltage, the upper shield metal fitting 11 and the lower shield metal fitting 12 also become large, so that it becomes difficult to cut each of them as an integral object. In the case of the shield fitting 11, as shown in FIG. 8, the annular shield fitting body 11a and the mounting fitting 11c having the same annular and screw hole 11b are separately formed by cutting, and between them. In some cases, a cylindrical metal tube 11d joined by welding and connected is used. However, such a large upper shield metal fitting 11 causes a large hardening strain to be applied to the metal cylinder 11d at the time of casting the epoxy resin. There has been a problem that cracks are liable to occur and airtightness cannot be avoided.

The present invention has been made in order to cope with such a situation, and has been made by connecting a shield metal body of a shield metal fitting to be embedded in a sleeve and a mounting metal with a metal net or a plurality of metal rods. Another object of the present invention is to provide a bushing for terminating a cable that does not cause cracks or the like in a sleeve tube even when an inexpensive metal material is used.

[0009]

In order to solve the above-mentioned problems, a first aspect of the present invention is to provide a metal conductor lead rod attached to a front end of a sleeve made of an insulator, and to have an inner hole of the sleeve. The conductor at the terminal end of the power cable inserted from the rear is connected to the power cable, and a pre-molded insulator closely fitted to the power cable is inserted from the rear into the inner hole of the sleeve, and the tapered shaft surface on the front side is inserted into the sleeve. In a cable terminal bushing pressed and brought into close contact with a tapered hole surface of a pipe inner hole, a metal ring-shaped mounting bracket or a plurality of metal mounting brackets formed with a screw hole or a bolt is formed by a screw hole. A part of the sleeve is exposed at the end face of the sleeve, or a bolt part projects from the end face of the sleeve, and is embedded in the end of the sleeve. An annular metal shield fitting surrounding the body is embedded And, between the mounting member and the shield fitting body in the sleeve, it is characterized in that annularly arranged metal rod which connects between the embedded.

According to the first aspect of the present invention, the mounting fitting embedded in the end of the sleeve and the shield metal body embedded in the interior of the sleeve are connected by the internal and external communication members. Also at this time, the epoxy resin or the like can freely move between the inside and the outside through the holes, gaps, gaps and the like of the inside and outside communication members, and hardening distortion is hardly applied to the inside and outside communication members. For this reason, cracks and the like do not occur in the sleeve, and airtightness can be ensured, so that the production yield can be increased. In addition, there is no possibility that welding, brazing, or the like between the inner / outer communication member and the mounting bracket or the shield bracket main body may be removed due to hardening distortion. Further, since inexpensive materials such as brass can be used instead of aluminum, the cost of the sleeve can be reduced. If an appropriate number of thin metal rods are used, the weight can be reduced compared to a cylindrical body made of an aluminum material even if an inexpensive material such as brass is used.

[0011]

Embodiments of the present invention will be described below with reference to the drawings.

1 to 6 show one embodiment of the present invention. FIG. 1 is a partial longitudinal sectional perspective view of a sleeve, FIG. 2 is an assembled perspective view of an upper shield fitting, and FIG. 3 is an upper shield. 4 is an assembled perspective view of the lower shield metal fitting, FIG. 5 is an overall perspective view of the lower shield metal fitting, and FIG. 6 is a partial longitudinal sectional front view of a cable terminal bushing.
Components having the same functions as those of the conventional example shown in FIG. 7 are denoted by the same reference numerals.

In this embodiment, a case will be described in which the CV cable 1 is connected to a sleeve 2 used for a cable terminal bushing of a terminal connection box in gas. However, the power cable may be of another type, and the bushing for terminating the cable is not limited to the one used for the gas termination junction box.

This bushing for terminating a cable uses a sleeve 2 made of a cylindrical body made of epoxy resin as shown in FIG. The sleeve 2 has a tapered hole surface 2a whose inner diameter becomes larger toward the lower part substantially at the center of the inner hole, and an upper shield metal part 3 and a lower shield metal part 4 are embedded in an upper end part and a lower end part, respectively.

As shown in FIG. 2, the upper shield fitting 3 includes a shield fitting body 3a, a mounting fitting 3b, and a wire mesh tube 3c.
It is composed of The shield metal body 3a is formed by winding a wire such as brass or copper into a coil, and further forming the coil in an annular shape. The mounting bracket 3b is composed of six small columnar components such as brass and copper, and has a screw hole 3d opened at the upper end thereof. Wire mesh cylinder 3c
Is made of a wire mesh in which a number of gaps are formed by alternately knitting wires such as brass or copper, or forming a large number of slits in a plate material and expanding the slits on both sides, and forming this into a cylindrical shape. As shown in FIG. 3, the upper shield metal fitting 3 inserts the lower end of the wire mesh tube 3c into the annular inner periphery of the shield metal body 3a, and connects and fixes it by soldering. It is formed by arranging six mounting brackets 3b around the circumference at equal intervals and connecting and fixing them by soldering. In addition,
It is not necessary to solder all six mounting brackets 3b to the wire netting cylinder 3c.
May be embedded at the time of casting.

As shown in FIG. 4, the lower shield fitting 4 includes a shield fitting body 4a, a mounting fitting 4b, and a metal rod 4c.
It is composed of The shield fitting main body 4a is a part obtained by cutting out brass, copper, or the like in an annular shape, and has rounded corners to reduce the electric field to form a radius. The mounting bracket 4b is also
Although it is an annular component such as brass or copper, as shown in FIG. 1, a plurality of screw holes 4d are formed in the lower end surface. The metal rod 4c is eight rod materials such as brass and copper. As shown in FIG. 5, the lower shield metal fitting 4 inserts the lower end of each metal rod 4c into holes formed at equal intervals in the annular upper end surface of the mounting metal fitting 4b, and connects and fixes them by soldering or welding. At the same time, the upper ends of the metal rods 4c are inserted into holes formed at equal intervals in the annular lower end surface of the shield fitting main body 4a, and connected and fixed by soldering or welding.

The upper shield fitting 3 and the lower shield fitting 4 are disposed at the upper end and the lower end of a casting mold for the sleeve 2 respectively. In addition, the wire mesh tube 3 of the upper shield fitting 3
When all the mounting brackets 3b have not been soldered to c, the remaining mounting brackets 3b are arranged at predetermined positions on the inner periphery of the wire mesh tube 3c. Then, the sleeve 2 is completed by injecting an epoxy resin into the mold and curing the resin. At this time, the epoxy resin injected into the mold freely flows into and out of the upper shield fitting 3 through many gaps of the wire mesh tube 3c of the upper shield fitting 3 and moves. Through the gap between the eight metal rods 4c, the metal can freely flow into and out of the lower shield fitting 4 and move. Therefore, even when the epoxy resin is cured, the curing distortion does not apply an excessive force to the wire mesh tube 3c or the metal rod 4c, so that the soldering or welding does not come off. In addition, since there is no possibility that the epoxy resin cracks due to the curing strain, the airtightness of the sleeve 2 does not deteriorate.

As shown in FIG. 6, an end of the CV cable 1 is inserted into the inner hole of the sleeve 2 from below. C
The V cable 1 is a power cable in which the periphery of a conductor 1a is covered with a crosslinked polyethylene insulator, an external semiconductive layer 1b, and a metal shielding layer, and the periphery is further covered with a vinyl sheath.
In the CV cable 1, the vinyl sheath, the metal shielding layer, and the outer semiconductive layer 1b at the terminal end facing upward are peeled off, and the conductor 1a is projected from the upper end of the crosslinked polyethylene insulator. Further, the pre-molded insulator 5 is closely fitted to the cross-linked polyethylene insulator exposed at the end of the CV cable 1 in advance. Pre-mold insulator 5
Is a spindle-shaped cylindrical EP rubber, the upper side of which is made of an insulating rubber portion, and the lower side of which is made of a semiconductive rubber portion so as to reduce the electric field together with the lower shield fitting 4. A tapered shaft surface 5 a is formed on the outer peripheral surface on the upper side of the pre-mold insulator 5. Before fitting the pre-molded insulator 5 to the outside, the lower metal fitting 7 to which the pre-molded insulator pressing device 6 is attached is also passed through the CV cable 1.

First, the CV cable 1 is composed of the conductor 1 at the upper end.
a is made to protrude upward from the inner hole of the sleeve 2, inserted into the lower end of the conductor pull-out rod 8, and connected and fixed by caulking.
Next, the upper fitting 9 is placed on the upper end surface of the sleeve 2 and bolts are screwed into the screw holes 3d of the mounting fitting 3b of the upper shield fitting 3 from above. Then, the upper end of the inner hole of the cannula 2 is closed by the upper metal fitting 9, and only the conductor extraction rod 8 protrudes upward from the central through hole of the upper metal fitting 9. Thus, the shield metal body 3a of the upper shield metal 3 is electrically connected to the conductor lead rod 8 via the upper metal 9.

The pre-molded insulator 5 fitted to the cross-linked polyethylene insulator of the CV cable 1 is inserted from below into the inner hole of the sleeve 2 with the CV cable 1.
Then, first, the lower metal fitting 7 is lifted up to the lower end surface of the sleeve 2, and bolts are screwed from below into the screw holes 4 d of the mounting metal fitting 4 b in the lower shield metal fitting 4. Then, by adjusting the spring pressure of the pre-mold insulator pressing device 6 of the lower metal fitting 7, the pre-mold insulator 5 is lifted upward and pressed. Then, the tapered shaft surface 5a on the upper side of the pre-molded insulator 5 is pressed against the tapered hole surface 2a of the inner hole of the sleeve 2 so as to be in close contact with no gap. Further, the pre-mold insulator pressing device 6 is connected to the external semiconductive layer 1b of the CV cable 1 and is also electrically connected to the shield fitting main body 4a of the lower shield fitting 4 via the lower fitting 7. Become.

According to the bushing for cable termination having the above-described structure, the upper shield fitting 3 and the lower shield fitting 4 are embedded in the sleeve 2 as in the prior art, so that the electric field at the connection portion of the CV cable 1 is reduced. Can be. Further, the upper shield fitting 3 and the lower shield fitting 4 are connected between the shield fitting bodies 3a, 4a and the mounting fittings 3b, 4b by a wire mesh tube 3c.
And the metal rod 4c, the epoxy resin passes through the gap between the wire mesh tube 3c and the gap between the metal rods 4c even when the epoxy resin of the sleeve 2 is cast. The inside and outside of the resin are freely moved back and forth, so that the resin does not turn around badly, and no excessive force is applied due to hardening distortion to cause cracks. In addition, there is no possibility that the soldering or welding of the connection portions of the wire mesh tube 3c and the metal rod 4c may be removed, and the production yield of the sleeve 2 can be increased. Further, since hardening distortion can be avoided in this way, inexpensive metal materials other than aluminum, such as brass and copper, can be used for the upper shield metal fittings 3 and the lower shield metal fittings 4. Cost can be reduced.

In the present embodiment, the upper shield fitting 3 using the wire mesh tube 3c is disposed at the upper end of the sleeve 2 and the lower shielding fitting 4 using the metal rod 4c is disposed at the lower end. May be reversed, and the type may be unified to either the wire mesh cylinder 3c or the metal rod 4c. In addition, depending on the type of the bushing for terminating the cable, only one of the upper shield fitting 3 and the lower shield fitting 4 can be used for the sleeve 2. Furthermore, in this embodiment, the case where the wire netting cylinder 3c and the metal rod 4c are connected and fixed by soldering or welding has been described. However, this connecting means is optional, and is not necessarily fixed if it is electrically connected. Is also good.

Further, in the present embodiment, two types of the upper shield fitting 3 using the wire mesh tube 3c and the lower shield fitting 4 using the metal rod 4c are shown. Whatever the inside and outside communication members made of metal that makes the inside and outside of the upper shield metal fitting 3 and the lower shield metal fitting 4 communicate with each other, a punching material having a large number of holes formed in a cylindrical shape, It can also be used. Further, the shield metal bodies 3a and 4a are not limited to the structure as in the present embodiment, but may have any structure such as a pipe formed in a ring shape.

Further, in this embodiment, the case where the screw holes 3d, 4d are provided in the mounting members 3b, 4b of the upper shield metal member 3 and the lower shield metal member 4 has been described, but these screw holes 3d, 4d are used instead. A bolt portion of an external thread may be provided so as to protrude from the end surface of the sleeve 2.

Furthermore, in the present embodiment, the sleeve 2 made of epoxy resin is used. However, any other material having a high insulating property and capable of embedding the upper shield fitting 3 and the lower shield fitting 4 during molding is used. Any one can be used. Also, the pre-mold insulator 5 is not limited to the EP rubber, and may be made of an appropriate material. Further, the means for connecting the conductor 1a of the CV cable 1 to the conductor pull-out rod 8 is not limited to caulking as in the present embodiment, but is also optional such as being fixedly connected using a wedge or detachably connected using a multi-contact. Means can be used.

[0026]

As is apparent from the above description, according to the bushing for terminating a cable of the present invention, the space between the mounting bracket embedded in the end of the sleeve and the shield metal body embedded in the back of the bushing is provided. Since the inner and outer communication members to be connected are hardly affected by the curing distortion of the epoxy resin or the like, it is possible to prevent the hermeticity of the sleeve from being deteriorated, and to use a cheap material such as brass for the shield metal to reduce the cost of the sleeve. It will be possible to down.

[Brief description of the drawings]

FIG. 1, showing an embodiment of the present invention, is a partial longitudinal sectional perspective view of a sleeve.

FIG. 2, showing an embodiment of the present invention, is an assembled perspective view of an upper shield fitting.

FIG. 3, showing one embodiment of the present invention, is an overall perspective view of an upper shield fitting.

FIG. 4 shows one embodiment of the present invention, and is an assembled perspective view of a lower shield fitting.

FIG. 5, showing one embodiment of the present invention, is an overall perspective view of a lower shield fitting.

FIG. 6, showing an embodiment of the present invention, is a partial longitudinal sectional front view of a cable terminal bushing.

FIG. 7 shows a conventional example, and is a partial longitudinal sectional front view of a cable termination bushing.

FIG. 8 shows a conventional example, and is an assembled perspective view of an upper shield fitting.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 CV cable 1a Conductor 2 Sleeve 2a Tapered hole surface 3 Upper shield fitting 3a Shield fitting main body 3b Mounting fitting 3c Wire mesh tube 3d Screw hole 4 Lower shield fitting 4a Shield fitting main body 4b Mounting fitting 4c Metal rod 4d Screw hole 5 Pre-mold insulation Body 5a Tapered shaft surface 6 Pre-mold insulator pressing device 8 Conductor withdrawal rod

Continuation of front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H02G 15/06

Claims (1)

(57) [Claims] 1. A conductor at a terminal end of a power cable inserted from the rear into an inner hole of a sleeve, which is connected to a metal conductor lead rod attached to a front end of a sleeve made of an insulator.
A cable end in which a pre-molded insulator closely fitted to the power cable is inserted into the inner hole of the sleeve from the rear, and a tapered shaft surface on the front side is pressed against and tightly attached to the tapered hole surface of the inner hole of the sleeve. In the bushing, a metal annular mounting bracket or a plurality of metal mounting brackets formed with a screw hole or a bolt portion exposes the screw hole portion to the end surface of the sleeve, or covers the bolt portion. An annular metal shield fitting body surrounding the inner hole of the sleeve is embedded in the end of the sleeve, protruding from the end face of the pipe, and embedded in the end of the sleeve. A bushing for terminating a cable, wherein a metal rod arranged in an annular shape is connected between a mounting fitting and a shield fitting main body in a sleeve, and is connected therebetween.