KR100853813B1 - Jumping apparatus - Google Patents

Abstract

(Problem) Provided is a jumper device capable of maintaining the depth of the jumper wire in a simple configuration.

(Solution means) A jumper device for connecting a transmission line L installed through internal built-in insulator devices 1a and 1b respectively provided on the left and right sides of the arm A of the transmission line pylon. One end of the jumper wire J of the jumper device is mounted and supported by jumper support devices 2a and 2b provided on the tip end side of the built-in insulator devices 1a and 1b, respectively.

Jumper

Description

Jumper device {JUMPING APPARATUS}

1 is a schematic configuration diagram showing an embodiment of a jumper device according to the present invention.

2 is an enlarged cross-sectional view of one mounting bracket portion.

3 is a schematic configuration diagram showing another embodiment of the jumper device according to the present invention.

FIG. 4 is an enlarged view of the mounting bracket 3a portion in FIG. 3.

5 is a schematic configuration diagram of still another embodiment of a jumper device according to the present invention.

6 is an explanatory diagram showing a relationship between a jumper device and a clearance.

* Explanation of symbols for the main parts of the drawings

A: Arm L: Power Transmission Line

J: jumper wire 1a, 1b: built-in insulator device

2a, 2b: jumper support device 3a, 3b: mounting bracket

4a, 4b: mounting bracket C: clearance

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a jumper device and to a jumper device in which the depth of the jumper wire is made small while the jumper support device does not come into contact with the built-in insulator device or does not fall within the insulation distance thereof.

The jumper device is provided with a jumper support device in built-in insulator devices provided on each of the left and right sides of the arm of a transmission line steel tower (hereinafter referred to as a "steel tower"), and a rigid horizontal member at the bottom of the jumper support device. V) and at the same time, a jumper wire is attached to the horizontal member (for example, publication No. 60-51725, etc.).

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However, the above-mentioned conventional jumper device using a rigid horizontal member has a drawback of increasing the size of the apparatus and increasing the cost since the rigid horizontal member is used.

In the state where the jumper wire is directly installed by the jumper support device, the jumper support device is installed so that the distance from the arm is minimized. Therefore, the insulator side of the jumper support device is built in according to the arrangement of the transmission line. There is a structure approaching the insulator device. In this case, there is a fear that the jumper support device may come into contact with the built-in insulator device when it is installed or when the jumper wire swings by wind.

Also, in a jumper device in which a jumper wire is directly installed as a jumper support device, depending on the arrangement of the power transmission line, the insulator device side of the jumper support device may enter the insulation distance of the insulator device, that is, the clearance. have. Referring again to FIG. 6, when the jumper support device 2 'supports the jumper depth of the jumper wire J so as to be the minimum required, the clearance C as the jumper support device 2' becomes close to horizontal. ) There is a risk of getting inside. If the jumper support device 2 'enters into the clearance C, this results in impairing the insulation function of the built-in insulator device.

Therefore, this invention is made | formed in order to solve the said fault, The objective is to provide the jumper apparatus which made it possible to maintain the depth of a jumper wire in a simple structure.

Another object of the present invention is to provide a jumper device in which the jumper support device is not in contact with the built-in insulator device.

It is still another object of the present invention to provide a jumper device in which the jumper support device does not enter the clearance of the built-in insulator device.

In order to achieve the above object, according to the present invention, a jumper device for connecting the transmission line installed through the built-in insulator device respectively provided on the left and right sides of the arm of the steel tower, the jumper wire of the jumper device is one end of the built-in insulator device There is provided a jumper device characterized in that the support is installed by a jumper support device provided on each side. At this time, the jumper wire is gripped at the bottom of the jumper support device, and the jumper wire is suspended while the tension is maintained on the jumper wire by the left and right jumper support devices, and the jumper wire secures the insulation gap with the steel tower member. It is supported in a state.

In the present invention, the jumper support device corresponds to a situation in which the built-in insulator device side of the jumper support device approaches the built-in insulator device, and the jumper support device is provided such that the tip end side of the built-in insulator device moves away from the built-in insulator device. It is preferable to bend in the direction because it can effectively prevent the jumper support device from contacting the built-in insulator device.

In addition, in the present invention, as the device corresponding to the situation described with reference to Fig. 6, the jumper supporting device is separated from the built-in insulator device so that the tip end side of the built-in insulator device can secure the insulation distance of the built-in insulator device. It is preferable to bend in the direction.

EMBODIMENT OF THE INVENTION Hereinafter, although embodiment of this invention is described based on drawing, this invention is not limited to these embodiment.

1 is a schematic configuration diagram showing an embodiment of a jumper device according to the present invention, wherein built-in insulator devices 1a and 1b are provided on both sides of an arm A provided in an unillustrated steel tower, respectively. Power transmission lines L and L are respectively provided at the leading end portions (ends opposite to arm A) of (1a and 1b).

The jumper wire J extends the power transmission line L, and is provided below the arm A. As shown in FIG. Thus, this jumper wire J is supported at both ends by the jumper support devices 2a and 2b at the lower ends of the jumper support devices 2a and 2b, respectively, and is substantially horizontal between the lower ends of the support devices 2a and 2b. It is very much in place.

The jumper support device 2a, 2b is supported so that rotation of the jumper support device 2a, 2b may be prevented from interfering with the mounting brackets 3a, 3b at the distal ends of the built-in insulator devices 1a, 1b, respectively. In addition, jumper wires J are configured to be installed at the other ends of the jumper supporting devices 2a and 2b so that rotation of the jumper wires J is not hindered through the mounting brackets 4a and 4b. 2 is an enlarged view of a portion of the mounting bracket 4b.

In this way, since the jumper wires J are almost horizontally installed and held by the pair of jumper support devices 2a and 2b, the depth of the jumper wires J becomes small, so that the upper and lower arm gaps can be made smaller. At the same time, since the horizontal vibration amount of the jumper wire J is also suppressed by installing the jumper wire J, the steel tower itself can be miniaturized.

FIG. 3 is a schematic configuration diagram showing another embodiment of the jumper device according to the present invention, and is the same as that of FIG. 1 except for the installation structure of the jumper support device 2a in the mounting bracket 3a portion.

FIG. 4 is an enlarged view of the mounting bracket 3a portion in FIG. 3. As can be seen from FIG. 4, the mounting portion of the jumper support device 2a to the mounting bracket 3a is formed to bend in a direction away from the built-in insulator device 1a.

As described above, when the jumper support devices 2a and 2b are separated from the built-in insulator devices 1a and 1b, the jumper support devices 2a and 2b are built-in insulator even if the jumper wire J is shaken by wind or the like. There is no fear of contacting the devices 1a, 1b.

FIG. 5: is a schematic block diagram of further another embodiment which concerns on this invention in the case where there are multiple jumper wires, and abbreviate | omits the right axis part of the arm A provided in the steel tower which is not shown in figure. Again, the omitted part is configured in the same shape.

The arm A is provided with a built-in insulator device 1a, and a power transmission line L is provided at the front end portion (end of the side opposite to the arm A) of the built-in insulator device 1a.

The jumper wire J extends the power transmission line L, and is installed below the arm A. FIG. Therefore, this jumper wire J is supported by the jumper support device 2a and is installed substantially horizontally. As can be seen in FIG. 5, each jumper wire J is supported in a state in which contact between the jumper wires can be avoided by the spacer S, and the jumper support device 2a is located above the plurality of jumper wires. Is holding a jumper wire.

One end of the jumper support device 2a is supported so that rotation is not prevented through the mounting bracket 3a at the distal end portion of the built-in insulator device 1a. Moreover, the jumper wire J is comprised so that the rotation of the jumper support apparatus 2a may not be interrupted via the mounting bracket 4a at the other end part. In this embodiment, the jumper support device 2a is formed to bend in a direction far away from the built-in insulator device 1a. That is, the jumper support device 2a is formed to be bent largely so as not to enter the clearance C which is the insulation distance of the built-in insulator device 1a.

As described above, when the jumper support device 2a is far from the built-in insulator device 1a, the insulation performance of the built-in insulator device 1a can be maintained in a predetermined state. Moreover, even if the jumper wire J vibrates by wind or the like, there is no fear that the jumper support device 2a contacts the built-in insulator device 1a.

Moreover, in the above example, the jumper wire J is composed of one strand of conductor, but when the power transmission line L is made of a polyconductor, it is composed of a polyconductor. In the above example, the jumper wire J and the power transmission line L are integrated, but when the power transmission line L is supported by the compression clamp, the jumper wire J and the power transmission line L become separate bodies.

In the jumper device according to the present invention, since the jumper wires are installed by the jumper support devices provided at the front end side of the built-in insulator device respectively, the jumper wires are supported by a pair of jumper support devices from the arm. Since the distance of is supported by the minimum installation, the depth of the jumper wire becomes small, the upper and lower arm gaps can be reduced, and the amount of lateral vibration of the jumper wire J is also suppressed. The tower itself can be miniaturized.

In the jumper device according to the present invention, the jumper support device is bent in the direction away from the built-in insulator device because the jumper support device is bent so that the distance from the arm and the jumper wire are set to the minimum necessary. Even when rocking by wind, it is possible to effectively prevent the jumper support device from contacting the built-in insulator device.

Further, in the jumper device according to the present invention, the jumper support device is bent in a direction far away from the built-in insulator device so that the front end side of the built-in insulator device can secure the insulation distance of the built-in insulator device. The jumper support device does not enter the clearance and the jumper support device effectively prevents the insulator from touching the built-in insulator even when it is laid so that the distance from the arm is at the minimum required or when the jumper wire swings due to wind. can do.

Claims (6)

A jumper device for connecting a transmission line installed through built-in insulator devices respectively provided on the left and right sides of the arm of a transmission line steel tower, The jumper wire of the jumper device, one end is gripped at the lower end of the jumper support device respectively provided on the front end side of the built-in insulator device, the jumper wire is suspended while the tension is maintained on the jumper wire by the left and right jumper support device, A jumper device, characterized in that a jumper wire is supported in a state of securing an insulating gap with a steel tower member. The method of claim 1, The jumper device is characterized in that the jumper wire is horizontally supported between the lower ends of the left and right jumper support devices. The method of claim 1, A jumper device comprising: a plurality of jumper wires upward and downward, and supported by a jumper support device in a state capable of avoiding contact between a plurality of jumper wires. The method of claim 3, wherein A jumper device, wherein a jumper support device grips an upper jumper wire among the plurality of jumper wires. The method of claim 2, The jumper support device is a jumper device, characterized in that the front end side of the built-in insulator device is bent in a direction away from the built-in insulator device. The method of claim 5, And the jumper support device is bent in a direction away from the built-in insulator device so that the distal end side of the built-in insulator device can secure the insulation distance of the built-in insulator device.

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