KR200492985Y1 - Adapter of measuring for leakage current of trasnformer bushing - Google Patents

Abstract

The present invention relates to an adapter for measuring leakage current of a transformer bushing, wherein the adapter for measuring leakage current of a transformer bushing according to an embodiment of the present invention includes a connector for connecting to a coaxial cable; A conductor connection part for electrically connecting each of the lead terminal and the bushing tab terminal of the connector; An inner housing for assembling the connector at one end and inserting and receiving the conductor connection part into a hollow; And an outer housing for sealing by maintaining the received state of the inner housing.

Description

Adapter for measuring leakage current of transformer bushing{ADAPTER OF MEASURING FOR LEAKAGE CURRENT OF TRASNFORMER BUSHING}

The present invention relates to an adapter for measuring leakage current of a transformer bushing, and specifically, an adapter having a connector connected to a coaxial cable, a conductor connection part connecting the connector lead terminal and the bushing tap terminal, and an overvoltage protection element to suppress the occurrence of overvoltage. By constituting, not only suppressing external noise, but also increasing the gripping force of the bushing tap terminal, and to suppress the occurrence of overvoltage, to an adapter for measuring leakage current of a transformer bushing.

In recent years, as the transformer preventive diagnosis system is gradually widespread, it is being studied as an element technology for diagnosing the leakage current of the transformer.

1 is a view showing an adapter connected to a conventional transformer bushing. The adapter connected to the bushing tap terminal 1 of a conventional transformer is composed of a connection part 2a and a connection line 2b.

The connection part 2a of the transformer bushing is formed in a'V'-shaped plate structure with elasticity, and if it loses its elasticity due to the point contact type, there is a concern that the transformer to be protected may be burned.

The connection line 2b is a wire that connects the adapter and the diagnostic device. Since it is a general wire without shielding performance, it is susceptible to external noise. For example, a minute leakage current of about 10 mA flows through the connection line 2b from the primary bushing of the 154 kV peripheral voltage device. Here, the leakage current has a large change in the measured value due to external noise. In addition, the connection line 2b is manufactured according to different standards for each manufacturer since the installation standards for each adapter manufacturer are not unified.

Accordingly, the adapter connected to the conventional transformer bushing needs to have a shielding function to prevent the influence of external noise and to provide a standardized connection wire.

Meanwhile, in Korean Patent No. 1,654,382, a technique for measuring leakage current by being connected to a test tap of a transformer bushing has been proposed.

Korean Patent Registration No. 10-1654382 (Registered on August 30, 2016)

Data Reliability Analysis of Preventive Diagnosis System, Journal of the Korean Institute of Electrical Engineers, Vol. 54P, No. 2, June 2005

The purpose of the present invention is to construct an adapter having a connector connected to a coaxial cable, a conductor connection part connecting the connector lead terminal and the bushing tap terminal, and an overvoltage protection element that suppresses the occurrence of overvoltage, thereby suppressing external noise as well as the bushing tap. It is to provide an adapter for measuring the leakage current of a transformer bushing to increase the gripping power of the terminal and suppress the occurrence of overvoltage.

An adapter for measuring leakage current of a transformer bushing according to an embodiment of the present invention includes a connector for connecting to a coaxial cable; A conductor connection part for electrically connecting each of the lead terminal and the bushing tab terminal of the connector; An inner housing for assembling the connector at one end and inserting and receiving the conductor connection part into a hollow; And an outer housing for sealing by maintaining the received state of the inner housing.

For the connector, the N-type connector standard can be applied.

In order to electrically connect the bushing tab terminal, the conductor connection portion may include a pinch connection portion in which a side surface is divided by forming one or more gaps at an end thereof in a longitudinal direction.

The conductor connection portion may be electrically connected to the lead terminal of the connector through soldering.

The inner housing may be an insulating material, and the conductor connection part may be a metal material.

The inner housing may assemble the connector by inserting portions that abut each other with the connector on both sides of the connector fixing ring.

The adapter for measuring leakage current of a transformer bushing according to an embodiment of the present invention may further include an overvoltage protection device for suppressing overvoltage between the inner housing and the outer housing.

In the adapter for measuring leakage current of a transformer bushing according to an embodiment of the present invention, the conductor connection part has a connection groove in which a side portion is open, and the inner housing has a first through hole formed at a side thereof, and the The outer housing may have a second through hole formed on a side surface thereof, and the connection groove, the first through hole, and the second through hole may face each other and form one passage in a vertical direction.

The first through hole may be filled with an insulating material.

The present invention configures an adapter including a connector connected to a coaxial cable, a conductor connection part connecting the connector lead terminal and the bushing tap terminal, and an overvoltage protection element that suppresses the occurrence of overvoltage, thereby suppressing external noise and It can increase the gripping power and suppress the occurrence of overvoltage.

In addition, the present invention can protect the circuit by conducting the overvoltage to the ground through the overvoltage protection element even when the circuit at the rear end of the adapter is separated.

Further, according to the present invention, the standard of the adapter lead can be applied universally by using the adapter lead wire as a coaxial cable.

1 is a view showing an adapter connected to a conventional transformer bushing,
2A is an exploded perspective view showing an adapter for measuring leakage current of a transformer bushing according to an embodiment of the present invention,
2B is a view showing a case where the adapter of FIG. 2A is used for a transformer bushing;
3 is a diagram illustrating the function of the overvoltage protection device of FIG. 2B.

In order to fully understand the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those with average knowledge in the art. Accordingly, the shape of the element in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same member may be indicated by the same reference numeral. Detailed descriptions of known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

2A is an exploded perspective view showing an adapter for measuring leakage current of a transformer bushing according to an embodiment of the present invention, and FIG. 2B is a view showing a case in which the adapter of FIG. 2A is used for a transformer bushing.

2A and 2B, an adapter for measuring leakage current of a transformer bushing according to an embodiment of the present invention (100, hereinafter referred to as "adapter") is a transformer bushing 10, which is one of the diagnostic techniques of a transformer. ) Can be used to diagnose leakage current.

The adapter 100 includes a connector 101, a connector fixing ring 103, an inner housing 105, a conductor connection 107, an outer housing 109, an insulating member 111, an overvoltage protection element 113, and a fixed Includes bolt 115.

The connector 101 can be connected to the coaxial cable 20 having a shielding function by applying an N-type connector structure as a standard. Here, the coaxial cable 20 is a lead wire connected to the rear end of the adapter 100 and is connected to a transformer bushing diagnostic device (not shown).

As described above, since the connector 101 applies an N-type connector structure, the influence of external noise can be reduced by using the coaxial cable 20 as a leader line of the same standard regardless of the manufacturer.

The connector 101 is provided with a connector lead terminal 101a on the opposite side to which the coaxial cable 20 is connected. The connector lead terminal 101a is a terminal made of a metal material that is electrically connected to the center conductor of the coaxial cable 20.

The connector lead terminal 101a has one end connected to the center conductor of the coaxial cable 20 and the other end electrically connected to the conductor connection part 107 to be described later. At this time, the connector lead terminal 101a is connected to the conductor connection portion 107 by soldering.

The connector 101 is assembled with the inner housing 105 via a ring type connector fixing ring 103 having a predetermined width w and thickness d. That is, portions of the connector 101 and the inner housing 105 abutting each other are assembled by being fitted to both sides of the connector fixing ring 103, respectively. In this case, the connector lead terminal 101a is inserted into the conductor connecting portion 107 installed in the inner housing 105.

The inner diameter of the connector fixing ring 103 may be the same as the outer diameter of the abutting portion of the connector 101 and the inner housing 105. In this case, the connector fixing ring 103 may be made of an elastic material (eg, rubber, etc.) that can be assembled by force-fitting into a contact portion between the connector 101 and the inner housing 105.

In addition, it is preferable that the connector 101 and the inner housing 105 abut each other are assembled with the width w of the connector fixing ring 103 divided. At this time, when the connector 101 is fitted into the connector fixing ring 103, a fixing ring support portion 101b for preventing more than half of the connector fixing ring 103 from being fitted into the connector fixing ring 103 may be formed. Here, the fixing ring support part 101b may be formed around the connector 101 at the same height as the thickness d of the connector fixing ring 103.

The inner housing 105 is a pipe-shaped housing formed corresponding to the length of the adapter 100, and a metal conductor connection portion 107 is inserted into the hollow to be accommodated. At this time, the connector lead terminal 101a is located in the hollow of the conductor connection portion 107.

In the inner housing 105, a first through hole 105a for interconnecting the connector lead terminal 101a and the conductor connection portion 107 by soldering is formed on the side surface. Here, the soldering treatment of the connector lead terminal 101a and the conductor connection portion 107 can be performed before/after assembling the outer housing 109.

The inner housing 105 is formed of an insulating material to form a structure surrounding the conductor connecting portion 107 to block the flow path of the leakage current from the conductor connecting portion 107 to the outer housing 109. This can improve the reliability of diagnosis of leakage current for the transformer bushing 10.

The conductor connection part 107 has a shape of a pipe inserted into the hollow of the inner housing 105 and is a member made of a metal material that electrically interconnects the connector lead terminal 101a and the bushing tab terminal 11. Here, the bushing tab terminal 11 is a terminal made of a metal material that is inserted into the bushing connection portion 12 formed on one side of the transformer bushing 10.

First, the conductor connection portion 107 has a connection groove 107a whose side portion is open to face the first through hole 105a formed on the side surface of the inner housing 105.

Next, when the conductor connection portion 107 is inserted into the bushing tap terminal 11 of the transformer bushing 10, the side of the bushing tap terminal 11 is exposed to the bushing tap terminal 11 for surface contact rather than point contact. It is provided with a pinch connection (107b) forming a surrounding structure. The pinched connection portion 107b has a structure in which the side surface is divided by forming one or more gaps in the longitudinal direction at the end of the conductor connection portion 107.

When the bushing tab terminal 11 is inserted in the pinched connection portion 107b, the bushing tab terminal 11 is inserted while a gap is opened from the beginning of the insertion. The pinching connection 107b can improve the gripping force of the bushing tab terminal 11 due to the property of recovering to its original state when the gap is opened.

Additionally, the fitting connection portion 107b may further include a structure (eg, irregularities, grooves, locking projections) for increasing the gripping force on the contact portion with the bushing tab terminal 11.

The outer housing 109 forms an inner space for accommodating the inner housing 105. That is, the outer housing 109 forms an inner space corresponding to the outer shape of the inner housing 105, so that the inner housing 105 can be accommodated without going through a process of separately adjusting the assembly alignment of the inner housing 105. have.

After receiving the inner housing 105, the worm housing 109 seals the inner housing 105 so that it does not deviate from the outside. That is, in the outer housing 109, when the inner housing 105 is inserted, a hole in which only the bushing tab terminal 11 can be inserted is formed at the front end, so that the inner housing 105 does not escape to the outside, and the connector 101 at the rear end. ) Or the connector fixing ring 103 and finally hermetically welded and sealed.

Here, the outer housing 109 is a guide portion for guiding the insertion path so that the bushing tab terminal 11 is easily inserted into the fitting connection portion 107b of the conductor connection portion 107 in the portion into which the bushing tab terminal 11 is inserted ( Not shown) is formed.

The outer housing 109 has a second through hole 109a formed on its side at a point opposite to the first through hole 105a of the inner housing 105.

As described above, after the assembly of the adapter 100 is completed, the connector lead terminal 101a and the conductor connection portion 107 have the second through hole 109a, the first through hole 105a, and the connection groove 107a. Can be connected by soldering.

The first through hole 105a is filled by the insulating member 111 after soldering of the connector lead terminal 101a and the conductor connection portion 107 is completed.

The second through hole 109a is fastened by the fixing bolt 115 after the overvoltage protection element 113 is inserted.

The overvoltage protection element 113 is inserted between the inner housing 105 and the outer housing 109, and the voltage generated when the rear end of the adapter 100 is disconnected or opened during operation of the transformer is immediately converted to ground. It prevents burnout of the transformer bushing 10 by allowing it to flow to suppress the occurrence of overvoltage.

The overvoltage protection device 113 is fixed by a fixing bolt 115 and has a secondary protection structure that is connected to the ground when a high voltage occurs.

As described above, the adapter 100 can be assembled as follows.

In the inner housing 105, a connector 101 is assembled on one side by a connector fixing ring 103, and a conductor connecting portion 107 is inserted and received on the other side. At this time, the connector lead terminal 101a and the conductor connection portion 107 may be connected to each other through soldering. However, the connector lead terminal 101a and the conductor connection portion 107 may be connected to each other through soldering after the inner housing 105 is inserted and received in the outer housing 109. Thereafter, the inner housing 105 is inserted into and received in the outer housing 109. At this time, the overvoltage protection device 113 is installed by being inserted between the inner housing 105 and the outer housing 109. In addition, the first through hole 105a of the inner housing 105 is filled by the insulating member 111, and the second through hole 109a of the outer housing 109 is filled by the fixing bolt 115.

The connection groove 107a of the conductor connection part 107, the first through hole 105a of the inner housing 105, and the second through hole 109a of the outer housing 109 face each other, and one passage in the vertical direction To form. Accordingly, the connector lead terminal 101a and the conductor connection portion 107 may be connected through a soldering treatment even after the assembly of the adapter 100 is completed.

Meanwhile, the center conductor of the coaxial cable 20, the connector lead terminal 101a, and the bushing tab terminal 11 are preferably positioned on a virtual straight line passing through the center of the adapter 100. In addition, the adapter 100 forms an electrical line leading to the center conductor of the coaxial cable 20, the connector lead terminal 101a, the conductor connection portion 107, and the bushing tab terminal 11.

3 is a diagram illustrating the function of the overvoltage protection device of FIG. 2B.

When the transformer is in normal operation, the leakage current of the transformer bushing 10 is analyzed through the transformer bushing diagnostic device 120 at the rear end of the adapter 100 and flows to the ground (see Fig. 3 (a)).

When the circuit is disconnected at the rear end of the adapter 100, the leakage current of the transformer bushing 10 becomes '0', but an overvoltage occurs and may progress due to burnout of the transformer bushing 10 [Fig. b) see].

When the overvoltage protection element 113 is provided when the circuit is separated at the rear end of the adapter 100, the leakage current of the transformer bushing 10 conducts a current to the ground through the overvoltage protection element 113 to generate an overvoltage. By suppressing the burnout of the transformer bushing 10 can be prevented [see Fig. 3 (c)].

The embodiments of the present invention described above are merely exemplary, and those of ordinary skill in the art to which the present invention belongs will appreciate that various modifications and other equivalent embodiments are possible. Therefore, it will be understood that the present invention is not limited to the form mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. In addition, the present invention is to be understood as including the spirit of the present invention as defined by the appended claims and all modifications, equivalents and substitutes within the scope thereof.

10: transformer bushing 11: bushing tap terminal
20: coaxial cable 100: adapter
101: connector 101a: connector lead terminal
101b: fixing ring support 103: connector fixing ring
105: inner housing 105a: first through hole
107: conductor connection part 107a: connection groove
107b: pinched connection 109: outer housing
109a: second through hole 111: insulating member
113: overvoltage protection device 115: fixing bolt

Claims (9)

A connector for connecting to a coaxial cable;
A conductor connection part for electrically connecting each of the lead terminal and the bushing tab terminal of the connector;
An inner housing for assembling the connector at one end and inserting and receiving the conductor connection part into a hollow; And
An outer housing for sealing by maintaining the received state of the inner housing;
Adapter for measuring leakage current of the transformer bushing comprising a.
The method of claim 1,
The connector is an adapter for measuring leakage current of a transformer bushing that applies the N-type connector standard.
The method of claim 1,
The conductor connection part,
An adapter for measuring leakage current of a transformer bushing, comprising a pinch connection portion in which a side surface is divided by forming one or more gaps at an end to electrically connect the bushing tab terminal.
The method of claim 1,
The conductor connection part,
Adapter for measuring leakage current of a transformer bushing that is electrically connected to the lead terminal of the connector through soldering.
The method of claim 1,
The inner housing is an insulating material, and the conductor connection portion is an adapter for measuring leakage current of a transformer bushing of a metal material.
The method of claim 1,
The inner housing,
An adapter for measuring leakage current of a transformer bushing for assembling the connector by inserting the connector and the part in contact with each other on both sides of a connector fixing ring.
The method of claim 1,
Adapter for measuring leakage current of the transformer bushing further comprising; an overvoltage protection element for suppressing overvoltage between the inner housing and the outer housing.
The method of claim 1,
The conductor connection part has a connection groove in which a side portion is open, the inner housing has a first through hole formed at the side, and the outer housing has a second through hole formed at the side,
The connection groove, the first through hole, and the second through hole are opposed to each other, and an adapter for measuring leakage current of a transformer bushing forming a passage in a vertical direction.
The method of claim 8,
The first through hole is an adapter for measuring leakage current of a transformer bushing filled with an insulating material.

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