KR100679086B1 - A spacer for ultra high voltage power device having wideband ultra high frequency partial discharge diagnosis sensor in it - Google Patents

Abstract

 The present invention relates to a spacer for ultra-high voltage power equipment having a built-in broadband ultra-high frequency partial discharge diagnostic sensor, and more particularly, by simplifying the structure of the gas insulated switchgear by inserting a sensor for detecting the partial discharge in the spacer. The present invention relates to a spacer for an ultrahigh voltage power device that enables detection of a discharge.

Spacer, Field Relaxation Means, Electromagnetic Wave Sensing Means

Description

Spacer for ultra high voltage power device having wideband ultra high frequency partial discharge diagnosis sensor in it}

1 is a cross-sectional view showing a conventional opening and closing device equipped with a spacer

2 is a front sectional view of a spacer according to the present invention;

3 is a side sectional view of a spacer according to the present invention;

4 is a configuration diagram of a discharge diagnosis system of a power device

5 is a cross-sectional perspective view of a spacer according to the present invention;

6 is a coupling diagram showing a state in which the spacer is coupled to the container

7 is a cross-sectional view showing a state in which the spacer is coupled to the container

The present invention relates to a spacer for ultra-high voltage power equipment having a built-in wideband ultra-high frequency partial discharge diagnostic sensor, and more particularly, to provide a simple and precise structure of a gas insulated switchgear by incorporating a sensor for detecting a partial discharge in the spacer. The present invention relates to a spacer for an ultrahigh voltage power device that enables detection of partial discharge.

Gas Insulation Switchgear (GIS) is used for substations in substations inside and outside the premises.It is a device that protects the system appropriately by safely opening and closing lines in abnormal conditions such as accidents and short circuits under normal operating conditions. say.

1 shows an internal configuration diagram of a conventional gas insulated switchgear, in which a container 8 sealed with a spacer 1 is filled with insulating gas SF6, and the container 8 has a conductor 2. The circuit breaker 7 connected to (3) is provided. Here, when an abnormality occurs in the power system to which the gas insulated switchgear is connected, when the current is cut off by the breaker 7, a high temperature arc 7b is generated in the breaker 7a, and the insulation gas 4 is decomposed. do. The insulation gas 4 is generally SF6, and when the high temperature arc is generated, the insulation gas is in a dissociated state of S and F, or ions. After the arc 7b is extinguished, dissociated S and F or ions recombine again, and most of them return to the stable SF6.

The spacer installed in the metal insulation switchgear configured and operated as described above is made of an insulating material such as epoxy, and when the partial discharge occurs inside the GIS, the radiated electromagnetic wave is leaked to the outside through the spacer to detect the electromagnetic wave in the spacer. After attaching the sensor and detecting the electromagnetic wave generated inside the GIS, the noise included in the detected signal is removed to diagnose the abnormality such as corona occurrence or deterioration of the GIS, and to estimate the time for repair or replacement. .

However, this conventional method may cause a malfunction when there is a strong electromagnetic wave generation source near the GIS.

In particular, since the GIS system is applied to a high-voltage power equipment, malfunctions may be caused by equipment or devices that generate strong electromagnetic waves, such as high voltage transformers, insulators, switchgear, and transmission lines in the vicinity.

As an invention to solve such a problem, there is a Republic of Korea Patent Application No. 10-2003-60868 "electromagnetic shielding means for gas insulated switchgear and discharge diagnosis system having the same".

The patent consists of a band-shaped metallic first shielding agent having a width sufficient to surround a GIS spacer, a metallic shielding material in which an epoxy resin and a metallic second shielding material are sequentially laminated, and fastening means for fastening both ends of the metallic shielding material. It is.

The present invention having such a configuration surrounds the first shielding agent and the second shielding agent, which are electromagnetic shielding means, in the GIS spacer to block external electromagnetic waves from penetrating into the GIS system.

However, the conventional invention has the following problems.

First, when a separate shielding means is wrapped in the spacer, the shielding means directly exposed to the outside for a long time is deformed due to the external temperature change and snow and boiling, so that the shielding means is strongly coupled with the spacer at first, Over time, the bond loosens, allowing air or moisture to enter the spacer.

The moisture and air introduced in this way affects the decomposition of the insulating gas by the arc, making it difficult to disassemble and recombine the insulating gas, thereby causing the insulation performance of the insulating gas or the performance degradation of the current interruption.

Second, the conventional device has to be manufactured separately from the spacer and the shielding device, and the manufacturing process is complicated, and there is a problem in that cost increases in terms of manufacturing and maintenance, such as a separate manpower for preventing the shielding device from loosening. .

The present invention has been made to solve the above problems, and an object of the present invention is to provide a spacer for an ultra-high voltage power device which is not affected by external environmental conditions and has no deterioration in insulation performance or current blocking performance of an insulating gas. will be.

Another object of the present invention is to provide a spacer for an ultra-high voltage power device by manufacturing a spacer including the shielding device in the same process, there is no need to produce a shielding device, and requires little extra manpower to maintain it.

In order to achieve the above object, the power device spacer 20 according to the present invention will be described with reference to the drawings shown in FIGS. 2, 3, and 5.

The power device spacer includes a conductor support part 30 for supporting the conductor 11 passing through the inside of the container,

It is composed of a body 40 having a constant curvature and surrounding the conductor support portion 30 and a container contact portion 50 extending outward from the body and coupled to the container.

The conductor support part 30 forms a circular hole and supports the conductor 11 made of a cylindrical rod therein.

The body 40 is connected to the container contact portion 50 with a constant curvature while surrounding the circular hole-shaped conductor support portion 30, the material is made of epoxy. However, the material of the body 40 is not limited to epoxy only, and deformation does not occur even at a high temperature and may be used as long as it is an insulating material.

The container contact portion 50 extends outward from the body 40 and is a plate surrounding the body in a circular shape with a predetermined thickness. The container contact portion 50 is provided with a plurality of bolt holes 51 formed at equal intervals along the circumference, and each of the bolt holes 51 is separated by the same distance from the center of the body 40.

Between the container contact portion 50 and the bolt hole 51, the electric field relaxation means 52 is formed around the center of the body 40 to form a round ring. The field relaxing water stage 52 is made by twisting several copper, so that the cross-sectional area of the field relaxing means 52 is constant along the circumference.

In this case, the electric field relaxing means 52 does not cause partial electric field concentration inside the spacer 20, and serves to have a uniform electric field distribution while reducing the electric field distribution means. 52 is provided in the spacer with a uniform cross-sectional area and a constant distance from the center of the spacer as described above.

Therefore, when the electric field relaxing means has a non-uniform cross-sectional area or when one of the electric field relaxing means is broken, local electric field concentration may occur locally at the specific part.

Between the electric field relaxing means 52 and the bolt hole 51 is provided with an electromagnetic wave sensing means 53 surrounding the electric field relaxing means 52 at regular intervals from the electric field relaxing means 52.

The electromagnetic wave sensing means 53 is formed in the shape of two semicircular loops and surrounds the electric field relaxing means 53. The ends 54 of the two electromagnetic wave sensing means 53 are bent, and the bent ends 54 face outwards. The two bent ends 54 face each other, and one end of the end 54 is provided with a signal transmission terminal 55 connecting the two bent ends.

The signal transmission terminal 55 is attached to the outer surface of the spacer 20, the binding unit 56 is provided so that the terminal can be connected to the outside.

4 is a configuration diagram of a power device discharge diagnosis system, wherein the binding unit 56 is connected to an external detection unit 57 to connect a signal detected by the electromagnetic wave detection means to the detection unit 57. The detection unit 57 is connected to the central control room 58, through which it is configured to be always diagnosed and monitored remotely ON-LINE.

Referring to the electromagnetic wave detection means of the components having such a basic configuration in detail as follows.

The electromagnetic wave sensing means 53 uses a material of silver or copper having a high conductivity of the conductor so as to accurately detect electromagnetic waves generated therein. In addition, since the electromagnetic wave sensing means 53 serves as a kind of current detection device, the electromagnetic wave detection means 53 forms a loop, whereby the signal can be accurately detected from any direction of the circumference.

The loop-shaped electromagnetic wave sensing means 53 operates as a capacitive coupler of a conductor (antenna) -dielectric (spacer) -conductor (field mitigating means), whereby the capacitance with the field releasing means 52 is maximized. The area of the electromagnetic wave sensing means 53 should be reduced in order to reduce it, and the distance from the field mitigating means 52 should be increased to the maximum.

Therefore, in order to make the spacer 20 equipped with the actual electromagnetic wave sensing means 53, the thickness of the conductive wire should be made the thinnest in the range that the characteristics of the electromagnetic wave sensing means 53 do not change, and the electromagnetic wave sensing means 53 is It should be properly positioned between the field relaxation means 52 and the bolt hole 51. Since the electromagnetic wave sensing means 53 is in the form of a loop, its length is determined by the length R from the center of the spacer 20 to the electromagnetic wave sensing means 53 and the rotation angle at which the loop is formed.

이다.That is, the length L of the electromagnetic wave sensing means 53 is

to be.

In addition, the distance between the electromagnetic wave sensing means 53 and the electric field relaxing means 52 is determined by the distance from the center of the spacer 20 to the electromagnetic wave sensing means 53. Since the size of the electric field relaxing means 52 is determined at the time of manufacturing the spacer 20, the R is adjusted so as to reduce the capacitance with the electromagnetic wave sensing means 53 as much as possible, and the electromagnetic wave sensing means 53 is provided by the bolt hole 51. ) Should be arranged so that the characteristics of

As a result of obtaining the optimal value through computer simulation, when the length of the electromagnetic wave sensing means 53 is 488 mm, the thickness of the electromagnetic wave sensing means 53 is 6 mm, and the separation distance between the electromagnetic wave sensing means 53 and the electric field relaxing means 52 is 12 mm is considered to be preferable.

However, the dimensions are not determined but may be changed as the use environment such as the dimensions of the body and the strength of the current changes.

The electromagnetic wave detection means 53 can detect a signal having a low frequency component of several MHz to several hundred MHz bands generated by partial discharge due to internal voids or external scratches, insulation deterioration of the spacer during GIS operation, and the like. In order to ensure that it has a frequency band between 200MHz and 2000MHz.

The installation and operation of the spacer for the ultra-voltage power device according to the present invention having such a configuration will be described below with reference to FIGS. 4, 6, and 7.

After bolting the spacer 20 to one side of the container 10 through the bolt hole 51 formed in the container contacting part 50 of the spacer 20, the conductor 11 penetrates the inside of the container to the conductor support part 30. ) So that the conductor 11 can be supported by the spacer 20. In the same way, the spacer 20 is bolted to the other side of the container, and then the conductor 11 is inserted into the conductor support part 30.

Subsequently, an insulating gas made of SF 6 is filled into the sealed container by the spacer to insulate the power devices inside the container 10. This makes it possible to partition the container into several spaces.

Thereafter, the signal transmission terminal 55 formed at one end of the spacer 20 is connected to the detection unit 57 by a lead wire. At this time, the detection unit 57 is connected to the central control room 58, it is possible to determine whether the partial discharge occurs in real time on the ON-LINE.

Electromagnetic waves are generated when partial discharge occurs due to loosening of bolts, poor contact, inflow of metallic foreign substances, voids inside spacers, etc.

The electromagnetic wave generated as described above moves along the metal conductor forming the outer wall of the container 10, and the electromagnetic wave moving along the metal conductor is radiated to the outside through the spacer 20. However, the electromagnetic wave is significantly weakened by the electric field relaxing means 52, the weakened electromagnetic wave is sensed by the electromagnetic wave sensing means (53). The electromagnetic wave detection means 53 for detecting the electromagnetic wave transmits the detection signal to the detection unit 57 via the signal transmission terminal 55, and the signal sent to the detection unit 57 is transmitted from the central control room 58. Diagnose the presence of partial discharge. Accordingly, it is possible to always detect and diagnose the abnormality of the power equipment online.

According to the present invention having the above-described configuration, the following effects can be achieved.                     

First, since the electromagnetic wave sensing means is placed inside the spacer, deformation is difficult to occur due to external environmental influences, and thus there is no change in the electromagnetic wave sensing performance even when used for a long time.

Secondly, as the spacer with the electromagnetic wave sensing means is produced, the production and manufacturing process is simplified compared to the production of the electromagnetic wave sensing means, thereby reducing the cost.

Third, since the electromagnetic wave sensing means is built in the spacer, when the spacer is aged, the whole of the electromagnetic wave sensing means may be replaced at once, and the maintenance cost of the electromagnetic wave sensing means is almost insignificant.

Claims (5)

In the spacer for ultra-high voltage power equipment for sealing a container filled with insulating gas and fixing the conductor in the center thereof, It consists of a body having a conductor support for supporting the conductor, and a container contact portion extending outwardly from the body and in contact with the container, The container contact portion is a spacer for ultra-high voltage power equipment for partial discharge detection, characterized in that the electromagnetic wave detection means for detecting the electromagnetic waves generated in the interior of the container is built-in The method of claim 1, The electromagnetic wave detection means is a spacer for ultra high voltage power equipment for partial discharge detection, characterized in that consisting of two semi-circular loop shape delete The method according to claim 1 or 2, Spacer for ultra-high voltage power device for partial discharge detection, characterized in that the electromagnetic field sensing means surrounding the center of the body at a predetermined distance apart from the electromagnetic wave sensing means further comprises a spacer. The method of claim 4, wherein The electric field relaxation means is a spacer for ultra-high voltage power equipment for partial discharge detection, characterized in that the same cross-sectional area along the circumference

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