KR102358958B1 - the symmetric conical antenna for the radiation electromagnetic wave detection of the columnar transformer - Google Patents

Abstract

The present invention relates to a symmetric cone-shaped antenna for detection of electromagnetic waves radiated from a pole transformer, comprising: an upper cone-shaped body (210) formed so that a cross section becomes narrower from the maximum diameter part to the upper part and the lower part thereof, wherein the ratio of a length from the maximum diameter part to the upper end and the length from the maximum diameter part to the lower end is 1:5-10; a lower cone-shaped body (220) formed symmetrically with the upper cone-shaped body (210); a coaxial cable (230) connected to a lower part of the lower cone-shaped body (220); and a sphere (240) provided on an upper part of the upper cone-shaped body (210) and partially exposed to the outside. Accordingly, it is possible to provide a broadband antenna for detection of radiated electromagnetic waves, which satisfies return loss of -10 dB on the basis of radiated electromagnetic wave analysis through pole transformer modeling and actually measured data. Therefore, electromagnetic waves radiated due to partial discharge of a pole transformer can be measured.

Description

The symmetric conical antenna for the radiation electromagnetic wave detection of the columnar transformer

The present invention relates to a symmetrical conical antenna for detecting radiated electromagnetic waves of a pole transformer, and more particularly, to a symmetrical conical antenna for detecting radiated electromagnetic waves of a pole transformer for detecting radiated electromagnetic waves due to partial discharge of a pole transformer.

A pole transformer, one of the power energy supply facilities, is a facility that supplies electricity to consumers by reducing the high voltage used in the distribution system to a low voltage.

Such a pole transformer is usually provided with windings and iron cores in order to reduce high voltage to low voltage with a designed turns ratio, and these windings and iron cores are built in a tank filled with insulating oil. It prevents penetration and deterioration of dielectric strength, and at the same time plays a role in dissipating heat generated from the iron core or winding through convection and radiation of oil.

1 shows a general pole transformer, the pole transformer 100 has a box-shaped enclosure 110 constituting a body in appearance, a lid 120 for sealing it, and a high-pressure power supplied from the outside is applied as a winding. A high-pressure bushing (130, or “primary bushing”) installed through the lid 120 as a connection member to It includes a low pressure bushing (140, or "secondary bushing") that is

At this time, since the inside of the enclosure 110 of the pole transformer 100 is filled with insulating oil to cool the heat generated during transformation, complete insulation must always be built inside the pole transformer for stable operation of the pole transformer.

Therefore, insulation diagnosis inside the pole transformer is absolutely required, and there are ultrasonic, thermal imaging, and wireless load system methods as shown in FIG. 2 as methods currently used for insulation diagnosis of pole transformers. There was a problem in that it was impossible to identify faults by the system and to clearly detect and determine faults due to the external environment.

On the other hand, since it is known that most of the insulation breakdown accidents go through a partial discharge process, the most effective detection method for diagnosing insulation of a pole transformer is to detect a partial discharge.

A typical example of such a partial discharge detection method is the radiation electromagnetic wave method. The radiation electromagnetic wave method measures electromagnetic waves emitted when an abnormality occurs in a power device using an antenna, so it has the advantage of enabling high-sensitivity broadband detection and online monitoring. .

However, although the radiation electromagnetic wave method has been applied to and studied for transmission-grade gas insulated switchgear (GIS) and power transformers, there are few cases of using radiation electromagnetic waves for partial discharge and insulation improvement of pole-phase transformers. It is judged that this is due to the fact that the external structure is composed of a cylindrical shape sealed with iron, making it difficult to measure the radiated electromagnetic waves generated from the outside, and that it is usually installed on a telephone pole and the installation position is about 10 m high.

Therefore, in case of using partial discharge to detect the internal failure of the pole transformer, it is suitable for the frequency band of the electromagnetic wave radiated inside the pole transformer, and the high-sensitivity diagnosis that can measure the radiated electromagnetic wave in that band at a distance of at least 10m A sensor, that is, a broadband antenna with high sensitivity is required.

Korean Patent Registration No. 10-1642765 Korean Patent No. 10-1045651

The present invention was invented in response to the above requirements, and provides a broadband antenna for detecting radiated electromagnetic waves that satisfies the return loss of -10 dB based on the analysis of radiated electromagnetic waves through modeling of the pole transformer and the data actually measured, thereby partially discharging the pole transformer. An object of the present invention is to provide a symmetrical conical antenna for detecting radiated electromagnetic waves of a pole transformer that can measure radiated electromagnetic waves.

A feature of the present invention for achieving the above object is that the cross section is formed to become narrower from the maximum diameter portion toward the upper and lower portions, respectively, and the ratio of the length from the maximum diameter portion to the top and the length from the maximum diameter portion to the bottom is 1: 5 ~ 10 man upper conical body; a lower conical body formed symmetrically with the upper conical body; a coaxial cable connected to the lower part of the lower conical body; It is provided on the upper portion of the upper conical body and a portion of which is exposed to the outside; to provide a symmetrical conical antenna for detecting radiation electromagnetic waves of a pole transformer comprising a.

According to the present invention configured as described above, by providing an antenna in consideration of the installation height of the pole transformer and the frequency band of the radiated electromagnetic wave, the radiated electromagnetic wave radiated to the outside of the pole-phase transformer due to partial discharge inside the pole-phase transformer with high sensitivity and broadband characteristics It can be detected so that the reliability of fault diagnosis can be increased, and thus, the type of failure of the pole-phase transformer can be checked, thereby facilitating maintenance of the pole-phase transformer.

1 is a view showing the structure of a conventional pole transformer.
2 is a view showing a method for diagnosing insulation of a conventional pole transformer.
3 is a view showing an embodiment of a symmetrical conical antenna for detecting radiation electromagnetic waves of a pole transformer according to the present invention.
4 is a graph showing an antenna return loss of a symmetrical conical antenna for detecting radiated electromagnetic waves of a pole transformer according to the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 3, the symmetrical conical antenna for detecting radiated electromagnetic waves of a pole transformer according to the present invention is formed such that the cross section becomes narrower from the maximum diameter portion toward the upper and lower portions, respectively, the length from the maximum diameter portion to the upper end, and the maximum diameter portion from the bottom An upper conical body 210 having a length ratio of 1: 5 to 10; A lower conical body 220 formed symmetrically with the upper conical body 210; a coaxial cable 230 connected to the lower conical body 220; It is provided on the upper portion of the upper conical body 210 and a part of the sphere 240 is exposed to the outside; is configured to include.

And the outer side of the upper/lower conical body 210 is covered with a cover 250 made of Teflon, and the side is formed in a cylindrical shape as a whole. etc., have excellent electrical characteristics.

The cover 250 uses a dielectric constant of 2ε so that the upper/lower conical bodies 210 and 220 maintain the bipole shape and the characteristics of the broadband antenna do not decrease.

And, since the upper/lower conical bodies 210 and 220 are parts serving as radiators, they are formed of a conductive metal material.

The sphere 240 is also formed of a conductive metal material and has a dielectric constant of 2.2ε.

The antenna of the present invention configured as described above exhibits high-sensitivity performance having a return loss characteristic of -10 dB or less so that electromagnetic waves generated inside the pole-phase transformer can be measured from the outside of the pole-phase transformer, and has a broadband characteristic in the range of 1 to 7 GHz, especially It has reliable broadband characteristics in 1.5 - 2.9GHz and 3.9-5.2Hz bands.

A detailed embodiment of the antenna according to the present invention will be described below.

3 shows the structure and coordinate system of a broadband antenna according to the present invention.

=140 mm이다. The length of the upper/lower conical bodies 210 and 220, that is, the height of the radiator

= 140 mm.

=70 mm,

=2 mm,

=20 mm,

=49 mm,

=2 mm이다. The antenna, which has a structure in which two conical bodies 210 and 220 are connected up and down, is composed of a perfect conductor (PEC),

=70 mm,

=2 mm,

= 20 mm,

=49 mm,

=2 mm.

It has a structure in which power is fed to the upper conical body 210 through the lower conical body 220 .

As shown in FIG. 4 , the antenna for detecting radiated electromagnetic waves of a pole transformer according to the present invention configured as described above has broadband characteristics in the range of 1 to 7 GHz, and is particularly reliable in the bands of 1.5 - 2.9 GHz and 3.9 - 5.2 Hz.

Normally, when partial discharge is started with various variables (electrode shape, filler type, etc.) inside the pole transformer being different, radiated electromagnetic waves with high electric field strength are emitted in the 0.1 ~ 4.0 GHz band range depending on the type of variable. It can be seen that the antenna of the present invention can detect the radiation electromagnetic wave of the above-described pole transformer.

On the other hand, the antenna of the present invention described above can be used as a sensor and antenna useful for building a fault diagnosis system of a distribution class power facility. It can contribute to the prevention of social problems and other ripple effects caused by accidents and breakdowns of distribution-class power facilities can be suppressed.

In addition, it can be used as a diagnostic sensor for transmission and distribution facilities with a similar frequency band of radiated electromagnetic waves generated when a fault occurs, contributing to the improvement of the reliability of fault detection in power facilities. It can be used as a useful sensor for insulation diagnosis below, and contributes to the establishment of an effective power distribution diagnosis system to reduce the cost of power facility diagnosis, reduce the number of distribution power facility maintenance, and reduce distribution power facility maintenance and repair costs can lead

210: upper conical body 220: lower conical body
230: coaxial cable 240: body
250: cover

Claims (4)

The upper conical body 210 is formed so that the cross section becomes narrower toward the upper and lower portions from the maximum diameter portion, and the ratio of the length from the maximum diameter portion to the top and the length from the maximum diameter portion to the bottom is 1: 5 to 10;
a lower conical body 220 formed symmetrically with the upper conical body 210;
a coaxial cable 230 connected to the lower conical body 220;
In the configuration including the sphere 240 provided on the upper portion of the upper conical body 210 is exposed to the outside;
The outer side of the upper/lower conical body 210, 220 is covered with a cover 250 made of Teflon, and the side is formed in a cylindrical shape as a whole, and the Teflon has a dielectric constant of 2ε. Symmetrical conical antenna for detecting radiated electromagnetic waves.
delete The method of claim 1,
The sphere 240 has a symmetrical conical antenna for detecting radiation electromagnetic waves of a pole transformer, characterized in that the dielectric constant is 2.2ε.
The method of claim 1,
In the upper/lower conical bodies 210 and 220, respectively, the radius of the maximum diameter portion

=70 mm, top length at maximum diameter

=20 mm, bottom length at maximum diameter

=49 mm, feeding length between the upper/lower conical body (210, 220)

A symmetrical conical antenna for detecting radiated electromagnetic waves of a pole transformer, characterized in that =2 mm.

Images