KR100952479B1 - Breakdown position detection apparatus for power transmission/power distribution cable line - Google Patents

Abstract

The present invention provides a ferromagnetic shield for the transmission line. The ferromagnetic shield includes a cylindrical shield body having a hollow in which a transmission line is located, and an eddy current loss formed in the shield body so as to be radially disposed along a longitudinal axis of the through hole and about a center axis of the shield body. And an eddy current loss generating member installed in the eddy current loss generating member installation portion. In addition, the present invention also provides a ball sensor having the ferromagnetic shield. Therefore, the present invention can be mounted directly on the line through which a large current flows.

Description

Ferromagnetic shield for transmission line and ball sensor with same {BREAKDOWN POSITION DETECTION APPARATUS FOR POWER TRANSMISSION / POWER DISTRIBUTION CABLE LINE}

The present invention relates to a ferromagnetic shield for a transmission line and a ball sensor having the same, and more particularly to a ferromagnetic shield for a transmission line and a ball sensor having the same can be mounted directly on the line flowing a large current.

In general, the transmission line is a power facility for supplying electric power generated by the power plant to substations through substations. In the modern society, accidents of transmission facilities are directly connected to long-term power supply interruptions and have a significant social impact. Get mad.

For example, the voltage of the transmission line is operated at ultra high voltage such as 154kV, 345kV, 765kV. Therefore, in recent years, in order to monitor the operation state of the transmission line operated at the ultra-high voltage, it is required to develop equipment installed directly on the transmission line to monitor the state of the transmission line.

The monitoring method for monitoring the operation status of a conventional transmission line is a method of directly visiting a site where a transmission line is installed at regular intervals by a site operator, and diagnosing a local sensor such as a wind speed sensor or a camera installed in the transmission tower. It is divided into methods.

Therefore, in the related art, rather than remotely monitoring the power transmission line, the power transmission line is monitored by only visiting the position where the power transmission line is installed or using only the monitoring using the local sensor.

That is, conventionally, it was difficult to directly install an electronic circuit for monitoring a transmission line directly on the transmission line.

In recent years, the US USI's "power donut" has been developed that can be installed directly on the transmission line, but electronic equipment for monitoring and diagnosing such transmission line should form a gap over a certain distance from the transmission line, and also There is a problem that a monitoring diagnosis system of a certain size or more should be installed on the transmission line to burden the line.

The present invention has been made to solve the above problems, the first object of the present invention is to provide a magnetic field shield for a transmission line and a ball sensor having the same can be installed directly on the outer surface of the transmission line.

The second object of the present invention is to provide a magnetic field shield for a transmission line and a ball sensor having the same, which can easily shield the large current flowing in the line by causing eddy currents on the surface of the line when an abnormal state occurs in the transmission line. In providing.

In order to achieve the above object, a ferromagnetic shield for a transmission line of the present invention is a cylindrical shield body having a hollow in which the transmission line is located, and along the longitudinal direction of the through hole and radially based on the center axis of the shield body. And an eddy current loss generating member installed in the shield body, and an eddy current loss generating member installed in the eddy current loss generating member.

Here, the eddy current loss generating member installation portion is preferably a plurality of through holes penetrating from one side of the shield body to the other side.

The eddy current loss generating member may be a plurality of conductors, and each of the conductors may be inserted into each of the through holes.

In addition, the shield body is preferably composed of a plurality of bodies that are separated and coupled to be symmetrical with each other based on the central axis.

In order to achieve the above object, a ball sensor for a transmission line having a ferromagnetic shield for a transmission line of the present invention has a spherical sensor body having a fitting hole through which one side and the other side are inserted and into which the transmission line is fitted, and the inside of the line body. A connection member formed at a predetermined interval, a connection member having a predetermined interval, a connection member connecting the partition walls to each other and communicating with the fitting hole, and having a line hole into which the transmission line is fitted, and installed inside the connection member of the power transmission line. It includes a ferromagnetic shield for shielding the flow path of the magnetic flux along the direction perpendicular to.

Here, the ferromagnetic shield is a cylindrical shield body having a hollow surrounding the transmission line, the shield body along the longitudinal direction of the shield body and disposed radially with respect to the center axis of the shield body It is preferable to have an eddy current loss generating member installation portion formed and an eddy current loss generating member provided in the eddy current loss generating member installation portion.

In addition, the eddy current loss generating member installation portion is a plurality of through holes penetrating from one side of the shield body to the other side, the eddy current loss generating member is a plurality of conductors, each of the conductors is fitted into each of the through holes It is preferable to be.

In addition, the sensor body is divided into a plurality of the central axis of the sensor body so that the connection member is separated and coupled to each other, the shielding body is a plurality of bodies that are separated and coupled to be symmetrical to each other based on the central axis. It is desirable to make.

The present invention has the effect of downsizing the device to be installed directly on the outer surface of the transmission line.

In addition, the present invention has an effect that can easily shield the large current flowing in the line by causing an eddy current loss in the surface of the line when an abnormal state occurs in the transmission line.

In other words, the present invention can be installed directly on the equipment with high current flow such as power transmission line to monitor the condition, and is always exposed to danger and is a conventional high current equipment that is easily damaged or causes metabolism by small external disturbances. It is possible to install directly in the system, and it has the effect of enabling the development of automation equipment to monitor the equipment in real time.

Hereinafter, a ferromagnetic shield for a transmission line and a ball sensor for a transmission line having the same will be described with reference to the accompanying drawings.

In addition, since the ferromagnetic shield for the transmission line of the present invention is provided in the ball sensor for the transmission line of the present invention, it will be described in addition to the description of the ball sensor.

1 is a partially cutaway perspective view illustrating a ball sensor for a transmission line having a ferromagnetic shield for a transmission line of the present invention. Figure 2 is an exploded perspective view showing a ferromagnetic shield for the transmission line of the present invention. Figure 3 is a trial showing a ferromagnetic shield for the transmission line of the present invention.

First, referring to Figures 1 to 3, the configuration of the ball sensor for the transmission line having a ferromagnetic shield for the transmission line of the present invention.

The ball sensor 100 has a spherical sensor body 110.

The sensor body 110 has a fitting hole 111 penetrating through one side and the other side thereof to which the power transmission line 10 is fitted. Here, the fitting hole 111 serves as an inlet and an outlet of the power transmission line 10.

A connection member 120 is installed inside the sensor body 110 to fix the transmission line 10.

The connection member 120 is connected to the fitting hole 111 by connecting a set of partition walls 121 and the partition walls 121 which are installed at a predetermined interval to each other inside the sensor body 110. The transmission line 10 is composed of a line hole 122 is fitted.

Vents 121a are formed in the partition 121 to expose the inside of the connection member 120 to the outside thereof.

A ferromagnetic shield 200 is provided inside the connection member 120 to shield the flow path of the magnetic flux of the power transmission line 10 along a right angle.

On the other hand, the sensor body 110 may be divided into a plurality of the central axis (c1) of the sensor body 110 so that the connection member 120 is separated and coupled to each other. Preferably, the sensor body 110 is divided into a pair.

Next, a configuration of the ferromagnetic shield 200 will be described with reference to FIGS. 2 and 3.

The ferromagnetic shield 200 is a cylindrical shield body 210 having a hollow 211, along the longitudinal direction of the shield body 210 and the central axis c1 of the shield body 210 An eddy current loss generating member installation unit 220 formed in the shield body 210 so as to be disposed radially with respect to the eddy current loss generating member installation unit 220 and an eddy current loss generating member 230 installed in the eddy current loss generating member installation unit 220. do.
Here, as shown in FIG. 1, the hollow 211 is fitted with a line hole 122 into which the power transmission line 10 is fitted.
In addition, the center axis c1 of the sensor body 110 is the same as the center axis c1 of the shield body 210.
Here, the diameter of the shield body 210 is made of 80mm, the inner diameter of 40mm, the length is 130mm may be formed in a small size.

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The eddy current loss generating member 220 is a plurality of through holes penetrating from one side of the shield body 210 to the other side, the eddy current loss generating member 230 is a plurality of conductors, each of the conductors It is fitted into each of the through holes.

The conductors may be rectangular rods having a certain length. Preferably the conductor may be an aluminum rod.

The eddy current loss generating member 230 may have a size of 14 × 5 × 174 (mm).

On the other hand, the shield body 210 may be composed of a plurality of bodies that are separated and coupled to be symmetrical to each other based on the central axis (c1). Preferably the sensor body is divided into a set of bodies.

Accordingly, the shield body 210 divided into a pair may be fitted to the inside of the connection member 120.

Next, the operation and effects of the ferromagnetic field shield for the transmission line of the present invention having the configuration as described above and the ball sensor for the transmission line having the same.

Ball sensor 100 as shown in Figure 1 is installed is fitted on the power transmission line (10). The ball sensor 100 may be installed in plurality at a predetermined distance from each other on the power transmission line 10.

When the power transmission line 10 is fitted into the track groove 122 of the connection member 120 through the fitting hole 111, the power transmission line 10 is a ferromagnetic shield (installed inside the connection member 120) ( 200).

After the ball sensor 100 is installed in the power transmission line 10 as described above, when a predetermined current or more flows in the power transmission line 10, the ball sensor 10 may detect the current flowing in real time. Although not shown in the figure, the ball sensor 100 is provided with a solar sensor is driven by solar heat, the current sensor can be operated by this drive. The current sensor can transmit a signal wirelessly to a station through a controller when an abnormal current occurs.

As described above, when an abnormal current occurs in the transmission line 10, for example, a current flowing in the transmission line 10 is 2000 amps, a magnetic field generated by an accident current of 70 kA and a lightning current of 25 kA (300 kHz) is strong. The system shield 200 may shield it.

That is, the eddy current loss generating members 230, which are conductors installed in the shield body 210, may be installed in a direction along the transmission line 100 to break the direction of the magnetic flux of the transmission line 10 at a right angle. .

Therefore, the ferromagnetic field may be shielded by heat loss due to eddy current loss at the portion where the shield body 210 is installed.

In addition, between the eddy current loss generating members 230 according to the present invention can be heated to a predetermined temperature by the eddy current loss, which is heat exhausted through the vents 121a formed in the partitions 121, The conductor eddy current loss generating members 230 can be easily cooled.

Therefore, the ferromagnetic shield 200 of the present invention can shield the electromagnetic waves generated from the inside, that is, the transmission line 10 and the outside thereof, to reduce the magnetic field of the energized current, in particular accident current, and with the transmission line Insulation can be ensured.

1 is a partially cutaway perspective view illustrating a ball sensor for a transmission line having a ferromagnetic shield for a transmission line of the present invention.

Figure 2 is an exploded perspective view showing a ferromagnetic shield for the transmission line of the present invention.

Figure 3 is a perspective view showing a ferromagnetic shield for the transmission line of the present invention.

** Description of symbols for the main parts of the drawing **

100: ball sensor 110: sensor body

120 connection member 121 partition wall

121a: vent 122: track hole

200: magnetic field shield 210: shield body

220: eddy current loss generating member 230: eddy current loss generating member

Claims (9)

A cylindrical shield body having a hollow in which the transmission line is located; An eddy current loss generating member installed along the longitudinal direction of the shield body and formed on the shield body so as to be disposed radially with respect to the center axis of the shield body; And A magnetic field shield for a transmission line including an eddy current loss generating member installed in the eddy current loss generating member installation portion. The method of claim 1, The eddy current loss generating member installation portion is a ferromagnetic shield for a transmission line, characterized in that a plurality of through holes penetrating from one side of the shield body to the other side. 3. The method of claim 2, The eddy current loss generating member is a plurality of conductors, each of the conductors are ferromagnetic shield for the transmission line, characterized in that installed in each of the through holes. The method of claim 1, The shielding body is a ferromagnetic shield for a transmission line, characterized in that consisting of a plurality of bodies separated and coupled to be symmetrical with respect to the center axis line. A spherical sensor body formed with a fitting hole through which one side and the other side of the power transmission line are fitted; A connection member installed inside the sensor body and having a pair of partition walls having a predetermined interval and a line hole connecting the partition walls to each other and communicating with the fitting hole to insert the transmission line; And Ball sensor having a ferromagnetic shield for the transmission line is installed in the connection member and comprises a ferromagnetic shield for shielding the direction of the magnetic flux of the transmission line in a right angle. The method of claim 5, The ferromagnetic shield is formed on the shield body so as to have a cylindrical shield body having a hollow surrounding the transmission line, and radially disposed along the longitudinal axis of the shield body and the center axis of the shield body. And a eddy current loss generating member installed in the eddy current loss generating member installing portion, and a eddy current loss generating member installed in the eddy current loss generating member installing portion. The method of claim 6, The eddy current loss generating member installation portion is a plurality of through holes penetrating from one side of the shield body to the other side, The eddy current loss generating member is a plurality of conductors, each of the conductors is a ball sensor having a ferromagnetic shield for the transmission line, characterized in that the insertion is installed in each of the through holes. The method of claim 6, The sensor body is divided into a plurality of the central axis of the sensor body so that the connection member is separated and coupled to each other, The shielding body is a ball sensor having a ferromagnetic shield for the transmission line, characterized in that consisting of a plurality of bodies separated and coupled to be symmetrical to each other based on the central axis. The method of claim 6, The partition walls have a ball sensor having a ferromagnetic shield for the transmission line, characterized in that the ventilation holes are further formed to expose the eddy current loss generating member to the outside.

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