KR101415405B1 - A combined voltage current transformer - Google Patents

Abstract

The present invention relates to a metering outfit comprising: an enclosure in which three metering voltage transformers and three metering current transformers are installed, and which is filled with insulating oil; three insulator bushings and one grounding bushing that are exposed and protrude on the top surface of the enclosure. The insulator bushing is composed of a bottom support fixated to pass through the enclosure and come in contact with the insulating oil filling the enclosure, an insulator fixed at the bottom support, a bushing terminal fixed at the insulator, a packing interposed between the bushing terminal and the insulator, and a conductive wire connecting the bushing terminal to the voltage transformer and a current transformer, wherein the inner and outer surfaces of the insulator and the packing are coated with carbon black and the inner and outer surfaces of the bottom support are coated with carbon black to a portion in contact with the insulating oil when the bottom support is installed, whereby zero potential is maintained at the inner and outer surfaces of the insulator bushing. According to the present invention, carbon black coating is carried out on the inner surface and an outer bottom portion of the insulator bushing and a coil which is not divided is wound around an iron core so that hardly can partial discharge occur in the metering outfit. Thus, damage to insulator can be prevented and a longer lifespan can be obtained.

Description

[0001] A combined voltage current transformer [0002]

More particularly, the present invention relates to a transformer current transformer for a meter, and more particularly, to a carbon black coating on the entire inner surface of an insulator bushing, and a carbon black coating on an outer surface of the outer surface of the insulator in contact with insulating oil, To a transformer current transformer for an instrument.

Generally, a transformer transformer for a meter is a part of a power transformer installed in a common enclosure with a potentiometer (PT) and a current transformer (CT: Current Transformer) It is a device for easily measuring the amount of electric power such as a voltage current by winding primary and secondary coils in a predetermined ratio to an iron core like a transformer so as to easily measure it by converting it into a predetermined voltage current.

The meter transformer (PT) is a device that changes the voltage to the low voltage necessary for the meter or relay. The meter current transformer is a device that transforms the current of the high-voltage / high-current circuit to the small current necessary for the meter or relay. And an inflow type for charging.

A number of prior art related thereto are disclosed, for example, in Published Unexamined Patent Application No. 2009-0004289 and No. 0452103.

However, although the instrument transformer current transformer and the instrument current transformer are used together, there is a possibility that the partial discharge easily occurs and the damage is likely to occur.

Here, the partial discharge is a kind of discharge phenomenon, which is an incomplete dielectric breakdown phenomenon that does not interfere with the gap between the solid insulator, the gas drop of the liquid insulator, the contact interface of the different kind of insulator, and the peak of the metal surface.

For example, corona discharge, surface discharge, void discharge, and the like are the main causes of the deterioration of insulation.

When such a partial discharge is caused, it is required to minimize it because heat, impact of charged particles, and chemical action by molecules and ions damage the surrounding solid insulator.

However, in the conventional transformer for a meter, the technical structure that solves this problem is not disclosed.

1, the conventional transformer for a meter has a structure in which one iron core 10 is wound in a form in which the coil 20 is divided into four parts. Therefore, in the transformer for a part for connecting the divided coils 20 There is a phenomenon that a corona is generated in (A) and a partial discharge is induced.

Therefore, Applicant has started to develop the technology by introducing the concept of making the bushing around the bushing so that discharge does not occur. In order to confirm the related prior arts more specifically, No. SR2013-0001233) As a result, according to the report dated April 05, 2013, Japanese Patent Registration No. 4634826, Domestic Patent Publication No. 2011-0111643 and Domestic Registration No. 1045651 were confirmed as peripheral technologies.

However, the concept of electrification for preventing discharge is not shown in these prior arts, so that it can be confirmed through the report that it has technical advancement.

Thus, although the transformer current transformer related to the present invention is already a mature industrial field, it has been recognized that an improved technique for improving the local function or performance is still required.

The present invention is based on consideration of the above-described prior art peripheral technology as described above, and is produced by necessity of improvement. The carbon black coating is applied so that the inner and outer surfaces of the insulator bushing constituting the transformer transformer for a meter can be converted to zero potential, And a transformer current transformer for a meter which prevents damage of an insulator by eliminating a discharge and achieves longevity improvement.

Further, in the present invention, when constructing a transformer for a meter, the iron core is divided into four coils, and by using a special type of insulating paper without winding, one coil can be wound on one iron core in such a form that one coil is not divided, Another object of the present invention is to provide a transformer transformer for a meter which prevents damage to an insulator and achieves longevity.

In order to achieve the above-mentioned object, the present invention provides a three-phase transformer, a three-phase current transformer, and an enclosure filled with insulating oil; A transformer current transformer for gauges including three insulator bushings and one ground bushing protruded and fixed to the upper surface of the enclosure; The insulator bushing includes an insulator fixed to the bottom of the lower housing complex, a bushing terminal fixed to the insulator, a packing interposed between the bushing terminal and the insulator, a bushing terminal And a conductive line connecting the transformer and the current transformer, wherein the inner and outer surfaces and the packing of the insulator are entirely carbon black-coated, and the inner and outer surfaces of the lower cladding layer are covered with the insulating oil Is coated with carbon black so as to maintain the zero electric potential on the inner and outer surfaces of the insulator bushing.

At this time, the instrument transformer is characterized in that a coil not divided into one iron core is wound, and an insulating resin surrounding the coil is formed continuously, vertically, horizontally and vertically with a predetermined pattern.

The epoxy resin is also characterized by being formed in a diamond shape.

In addition, the insulating paper is heated at a temperature of 120 占 폚 to 10 占 폚 in a state of wrapping the coil so that the epoxy resin completely insulates and coils the coil.

According to the present invention, carbon black coating is performed on the inner surface and the outer lower end of the insulator bushing, and the coil is wound on one iron core without dividing the coil using an epoxy-coated insulating paper. It is possible to prevent damage to the insulator and to achieve longevity improvement.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing an example of winding a coil of a transformer incorporated in a conventional transformer for a meter; FIG.
2 is an exemplary perspective view of a transformer transformer for a meter according to the present invention.
3 is an exemplary view showing an insulator bushing of a transformer transformer for a meter according to the present invention.
4 is an exemplary view showing an example of winding a transformer coil of a transformer transformer for a meter according to the present invention.
Fig. 5 is an illustration of an insulating paper used for insulation during winding of the coil of Fig. 4;

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

As shown in FIG. 2, the transformer transformer for a meter according to the present invention includes an enclosure 100.

The enclosure 100 includes a transformer 200 and a bushing terminal 110 having a transformer 200 and a bushing terminal 110 connected to the transformer 200. The transformer 200 includes a transformer 200, 120 are provided.

Here, the bushing terminal 110 is a kind of input terminal and is a component of the insulator 120, but will be described separately for convenience of explanation. The high voltage flowing on the high-voltage line is supplied to the transformer 200 and the current transformer (Not shown).

As described above, the transformer 200 is a means for converting a high voltage drawn through the bushing terminal 110 to a low voltage and outputting the converted voltage. The current transformer 200 has an amount of current flowing through the bushing terminal 110 And outputting a signal corresponding to the signal.

In addition, the inside of the enclosure 100 is filled with an insulating material, and an insulating material is preferably used as the insulating material. In addition, nitrogen gas or compressed dry air may be filled as an insulating material.

In addition, a ground bushing 130 is provided on the upper surface of the enclosure 100.

Accordingly, the transformer transformer for a meter described in the present invention has three insulator bushings 120, three transformer 200 for meters, and three transformers for meters (not shown).

Particularly, in the present invention, the coil winding structure of the insulator 120 and the transformer 200 for a meter is improved in order to prevent partial discharge by a corona or the like.

3, the insulator 120 according to the present invention includes an insulator 124 fixed to the lower housing complex 122, a lower insulator 122 fixed to the insulator 124, And includes a packing 126 interposed therebetween, and the bushing terminal 110 is seated and fixed with the packing 126 interposed therebetween.

The conductive line L is connected to the bushing terminal 110 and the conductive line L is connected to the transformer 200 and the current transformer through the insulator 124.

However, in order to solve the partial discharge itself, the insulator 124 is formed so as not to generate a potential difference between the inside and the outside of the insulator 124. That is, the insulator 124 is made of a ceramic material, A carbon black coating is applied to make it a zero potential.

In the case of a metallic material, since the inner surface and the outer surface of the insulator 124 are coated with carbon black, the inner and outer surfaces of the insulator 124 are exposed to the equipotential So that the potential difference is not generated, thereby preventing the partial discharge.

That is, this is derived from the Gauss law (∇, E = ρ / ε ₀ ), where ρ = 0 in the conductor. In other words, since the same amount of positive and negative charges are around, the net charge density in the conductor becomes zero, and only on the surface of the net charge, which is one of the basic laws of electromagnetism.

In this case, the carbon black coated on the inner and outer surfaces of the insulator 124 must be connected to each other so that the conductive body as a whole can be formed, and the above-described equipotential surface can be formed accordingly.

Further, in the present invention, since the lower housing complex 122, which is the means for supporting and fixing the insulator 124, is also fixed to the housing 100, It is preferable that a lower end portion of the coating layer 122 is completely coated with carbon black to form the coating surface 128.

In this case, it is not necessary to limit the thickness of the coating, and it is necessary to uniformly coat the inside and the outside in order to form an equipotential surface.

For this purpose, the carbon black coating is most preferably immersed, but it is also possible to use various methods such as spraying and evaporation.

However, the length of the coating surface 128 should be limited, and the length of contact with the insulating oil (not shown) filled in the enclosure 100 should be maintained when the lower compartment 122 is installed.

Thus, the insulating property is increased, and partial discharge can be prevented.

4 and 5, in the present invention, the iron core 210 and the coil 230 constituting the transformer 200 are connected to one bobbin 220 surrounding the iron core 210 The coil 230 has a form in which it is wound all at once without being divided.

This is for eliminating the partial discharge generated at the contact when the coil 230 is divided into four parts as in the prior art. If the known insulating paper is used, the risk of the partial discharge can not be excluded. Therefore, in the present invention, ) Is used.

The insulation paper 240 according to the present invention has a function of fixing the position of the coil 230 wrapped around the bobbin 220 while inserting the insulation paper 240 so as not to generate a partial discharge. The epoxy resin 242 is diamond-shaped and has a shape that is continuously formed up, down, left, and right so as to have a predetermined pattern.

The outer side of the coil 230 is wound with the insulating paper 240 so as to be in contact with the surface coated with the epoxy resin 242 while the coil 230 is wound around the bobbin 220, The epoxy 230 is firmly fixed while the epoxy resin 242 melts, and at the same time, the adhesion with the insulating paper 240 is improved, thereby maximizing the insulation property.

In the case of the epoxy resin 242, the melting point is about 150-240 and the softening point is about 60-70 on the average. However, in the present invention, This is because it must be heated only to the extent that it is ductile and not sticky.

As described above, in the transformer transformer for a meter according to the present invention, carbon black coating is applied to the inside and the outside of the insulator 120 having the highest possibility of partial discharge, and at the same time, To form a zero potential across the inside and the outside of the insulator bushing 120, thereby completely eliminating the possibility of partial discharge, thereby achieving insulation protection and longevity.

It is also possible to switch the winding form of the coil 230 to a single type and completely cut off the coil 230 from the outer side of the coil 230 in order to completely cut off the partial discharge easily caused in the winding portion of the coil 230 of the transformer 200 having the transforming function. It is possible to completely block the partial discharge phenomenon by firmly fixing and insulating the coil 230 by using the insulating paper 240 coated with the diamond-like epoxy resin 242. [

100: enclosure 110: bushing terminal
120: insulator bushing 130: grounding bushing
200: Transformer

Claims (4)

Three meter transformers, three meter current transformers and an insulation-filled enclosure; A transformer current transformer for gauges including three insulator bushings and one ground bushing protruded and fixed to the upper surface of the enclosure;
The insulator bushing includes an insulator fixed to the bottom of the lower housing complex, a bushing terminal fixed to the insulator, a packing interposed between the bushing terminal and the insulator, a bushing terminal And a conductive wire connecting the transformer and the current transformer,
The inner surface of the insulator and the packing are entirely carbon black coated,
The outer surface of the lower cladding layer is carbon black coated to a portion where the lower cladding layer is in contact with the insulating oil at the time of installing the lower cladding layer,
And the zero potential is maintained at the inner and outer surfaces of the insulator bushing. The method of claim 1,
Wherein the instrument transformer is formed by winding an unseparated coil on one iron core and continuously forming an epoxy resin on the insulating paper surrounding the coil in a predetermined pattern up, down, left, and right. The method of claim 2,
Wherein the epoxy resin is a diamond-like pattern. The method of claim 2,
Wherein the insulating paper is heated to a temperature of 120 占 폚 to 10 占 폚 in a state of wrapping the coil so that the epoxy resin completely insulates and insulates the coil.

Images