KR20210051887A - Apparatus and method for detecting secondary failure of MOF - Google Patents

Abstract

The present invention provides an apparatus and method for detecting a secondary failure of an metering out fit (MOF) that puts a load on a secondary side of the MOF, and determines whether a failure occurs on the secondary side of the MOF based on the magnitude of a current changed by an input load. The apparatus for detecting the secondary failure of an MOF for determining whether a failure has occurred on the secondary side of a current transformer included in the MOF according to an embodiment of the present invention comprises: a current sensor for measuring a current flowing through the secondary side of the current transformer; an input load setting part for setting the input or cut-off of an input load installed in parallel to the secondary terminal of the current transformer and a line; and a determination part for determining whether a failure occurs in the secondary side of the current transformer based on the magnitude of the current measured from the current sensor according to the input or cut-off of the input load.

Description

Apparatus and method for detecting secondary failure of MOF in instrument transformer

The present invention relates to an apparatus and method for detecting secondary-side failure of an instrument transformer, and more specifically, a load is put on the secondary side of the instrument transformer, and based on the magnitude of the current fluctuating by the applied load, the second of the instrument transformer It relates to a secondary-side failure detection apparatus and method of an instrument transformer for determining whether a vehicle-side failure occurs.

Measure the voltage and current using a metering out fit (MOF) combined with a potential transformer (PT) and a current transformer (CT), and use the measured voltage and current. The amount of power used by the high-pressure consumer is being measured.

Therefore, since the accuracy of the instrument transformer has a direct effect on the amount of power used, it is important to periodically check the accuracy and failure of the instrument transformer.

Mainly, the failure of the instrument transformer is caused by an error or failure of the instrument transformer inside the instrument transformer, or the secondary winding of the current transformer deviates from the support and a ground fault occurs in contact with the internal coil or steel enclosure.

When a ground fault occurs in the secondary winding of an instrument current transformer, the current converted to the secondary decreases according to the degree of the fault, resulting in an increase in the current error, and the increase in the current error causes the electricity bill to be less than the amount used. Is generated, and indirect costs and electric disasters due to the under-metering of electricity bills are caused.

However, when a ground fault occurs in the secondary winding of the instrument current transformer, the fault current within the secondary side maximum value is discharged to the ground fault point, so the protective relay does not operate and has no apparent signs of a ground fault. There is a problem that it is difficult to judge.

The present invention is to solve the above-described problem, an instrument that puts a load on the secondary side of an instrument transformer, and determines whether or not a failure of the secondary side of the instrument transformer occurs based on the magnitude of the current fluctuating by the applied burden. It is an object of the present invention to provide an apparatus and method for detecting a secondary side failure of a transformer.

In addition to the technical problems of the present invention mentioned above, other features and advantages of the present invention will be described below or will be clearly understood by those of ordinary skill in the art from such technology and description.

A secondary-side failure detection device of an instrument transformer for determining whether a secondary side failure of a current transformer included in an instrument transformer according to an embodiment of the present invention has occurred in order to achieve the above-described object, includes a current flowing through the secondary side of the current transformer. Based on the current sensor to be measured, the input load setting unit that sets the input or cutoff of the input load installed in parallel on the secondary line of the current transformer, and the magnitude of the current measured from the current sensor according to the input or cutoff of the input burden. It may include a determination unit that determines whether a failure of the secondary side of the furnace current transformer has occurred.

In addition, the secondary side failure detection method of the instrument transformer for determining whether a secondary side failure of the current transformer included in the instrument transformer according to an embodiment of the present invention has occurred in order to achieve the object described above is based on the current flowing through the secondary side of the current transformer. A fault occurs in the secondary side of the current transformer based on the measuring step, the step of inputting the input load installed in parallel on the secondary terminal of the current transformer and the line, and the magnitude of the current measured according to the input or interruption of the input load. It may include the step of determining whether or not.

The apparatus and method for detecting secondary-side failure of an instrument transformer according to an embodiment of the present invention may determine whether a secondary-side failure of the instrument transformer has occurred.

Further, by using only the secondary side line without contacting the primary side line of the meter transformer to which the high voltage is applied, it is possible to safely determine the secondary side failure of the meter transformer.

In addition, by determining whether a failure has occurred without separating the instrument transformer from the system, a power outage operation can be avoided.

In addition, other features and advantages of the present invention may be newly recognized through embodiments of the present invention.

1 is a view showing an equivalent circuit diagram of a secondary-side fault detection apparatus of an instrument transformer according to an embodiment of the present invention.
2 is a diagram showing an equivalent circuit diagram of a fault detection apparatus according to an embodiment of the present invention.
3 is a circuit diagram of an apparatus for detecting a failure when a failure does not occur according to an exemplary embodiment of the present invention.
4 is a circuit diagram of a failure detection apparatus when a failure occurs according to an embodiment of the present invention.
5 is a diagram illustrating a method for detecting a secondary side failure of an instrument transformer according to an embodiment of the present invention.

In order to clearly describe the present invention, parts irrelevant to the description have been omitted, and the same reference numerals are attached to the same or similar components throughout the specification.

Although not defined differently, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms defined in a commonly used dictionary are additionally interpreted as having a meaning consistent with the related technical literature and the presently disclosed content, and are not interpreted in an ideal or very formal meaning unless defined.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein.

1 is a diagram showing an equivalent circuit diagram of a secondary-side fault detection apparatus of an instrument transformer according to an embodiment of the present invention.

1 is a diagram illustrating only a current transformer, which is a specific object of the present invention, although the transformer for an instrument includes a plurality of transformers for an instrument and a current transformer for an instrument.

Referring to FIG. 1, the fault detection system 1000 of an instrument transformer according to an embodiment of the present invention includes a current transformer 100, a load 200, and a secondary-side fault detection device 300 (hereinafter, a fault detection device) of the instrument transformer. ) Can be included.

The current transformer 100 is included in an instrument transformer, and can convert a large current supplied from a power source into a low current of a predetermined ratio. For example, a large current may flow through the primary side of the current transformer 100, and a low current converted at a constant rate may flow through the secondary side. Here, according to the winding ratio in which the coil is wound on the primary side and the secondary side of the current transformer 100, it may be converted into a current of a predetermined ratio.

The load 200 may be connected to the secondary side of the current transformer 100 to apply a rated load to the current transformer 100.

Here, when a ground fault occurs at the primary side of the current transformer 100, since the primary voltage (eg, 22,900V) contacts the ground fault point, a very large fault current may flow to the ground fault point. When a very large fault current flows to the ground fault point, it is determined that a fault has occurred in the primary side of the current transformer 100 and the protection relay can be operated.

On the other hand, when a ground fault occurs at the secondary side of the current transformer 100, a fault current within the secondary maximum value flows to the ground fault point, and thus the protection relay does not operate, and only error fluctuations may occur.

Accordingly, the failure detection device 300 according to an embodiment of the present invention checks the rate of change of the secondary current according to the change in the load impedance within the rated load of the instrument transformer, Ground fault on the car side can be judged.

The failure detection device 300 according to an embodiment of the present invention does not contact the primary side line of the current transformer 100 to which a high voltage is applied, and uses only the current fluctuation of the secondary side to safely prevent power failure. Secondary side failure can be judged.

2 is a diagram showing an equivalent circuit diagram of a fault detection apparatus according to an embodiment of the present invention.

Referring to FIG. 2, a failure detection apparatus 300 according to an embodiment of the present invention may include a current sensor 310, an input load setting unit 320, and a determination unit 330.

The current sensor 310 is installed on the secondary side of the current transformer 100 to measure the current flowing through the secondary side of the current transformer 100. For example, the current sensor 310 may measure the current flowing through the secondary side of the current transformer 100 at regular intervals, or measure the current flowing through the secondary side of the current transformer 100 by a signal transmitted from the inside or outside.

The input load setting unit 320 may set the input or cut off of the input load 322 installed in parallel on the secondary terminal of the current transformer 100 and the line. Here, the input burden 322 may be input within the rated burden (eg, 25VA, 1Ω).

For example, the input load setting unit 320 may block the input load 322 and insert it when a failure of the secondary side of the current transformer 100 is detected.

The determination unit 330 may determine whether a failure of the secondary side of the current transformer 100 occurs based on the magnitude of the current flowing through the secondary side of the current transformer 100 as the input load 322 is applied.

Specifically, the determination unit 330 compares the magnitude of the current before and after the input burden 322 is applied, and when the difference in the magnitude of the current before and after the input burden 322 is input is greater than or equal to a predetermined value, the secondary side of the current transformer 100 It can be determined that a failure has occurred in the system. Here, the determination unit 330 may receive the magnitude of the current before and after the input load 322 is input from the current sensor 310.

For example, when a ground fault does not occur on the secondary side of the current transformer 100, when the input load 322 is input by the setting of the input load setting unit 320, the magnitude of the current on the secondary side of the current transformer 100 is increased. It may not change. That is, since the current on the secondary side of the current transformer 100 is determined based on the ratio with the primary side, the magnitude of the current flowing through the secondary side of the current transformer 100 even if the input burden 322 is input and shorted May be similar to the magnitude of the current flowing through the secondary side of the current transformer 100 before the input burden 322 is input. Accordingly, the determination unit 330 may determine that the difference in the magnitude of the current before and after the input burden 322 is input is less than a predetermined value, and the difference in the magnitude of the current before and after the input burden 322 is input is less than a predetermined value. , It can be determined that a failure has not occurred in the secondary side of the current transformer 100.

On the other hand, when a ground fault occurs on the secondary side of the current transformer 100, when the input load 322 is input by the setting of the input load setting unit 320, the magnitude of the current on the secondary side of the current transformer 100 varies greatly. Can be. That is, when a ground fault occurs on the secondary side of the current transformer 100, most of the current flowing through the secondary side of the current transformer 100 may flow to the point where the ground fault occurs. At this time, when the input burden 322 is input and shorted, the current flowing to the point where the ground fault occurs may flow separately to the input burden 322 and the point where the ground fault occurs. For example, it is assumed that a ground fault occurs on the secondary side of the current transformer 100 and a current of 6A flows at the point where the ground fault occurs. At this time, when the input burden 322 is input, the point at which the input burden 322 is put may be shorted, and the current of 6A flowing at the point where the ground fault occurs is 3A to the input burden 322, and the ground fault occurs. At the point where this occurs, it can flow by dividing by 3A. According to this, the difference in the magnitude of the current before and after the input load 322 is applied may be 3A.

That is, when a ground fault occurs on the secondary side of the current transformer 100, the determination unit 322 may determine that the difference in the magnitude of the current before and after the input burden 322 is input is greater than or equal to a predetermined value, and the input burden 322 Since the difference in the magnitude of the current before and after the input is greater than or equal to a predetermined value, it can be determined that a failure has occurred in the secondary side of the current transformer 100.

Accordingly, the failure detection device 300 varies the load within the rated load of the current transformer 100 of the instrument transformer, and checks the rate of change of the secondary current of the current transformer 100 according to the change of the load. It is possible to determine whether or not a failure on the secondary side has occurred.

3 is a circuit diagram of an apparatus for detecting a failure when a failure does not occur according to an exemplary embodiment of the present invention.

Referring to FIG. 3, the input burden setting unit 320 may be set to input the input burden 322. Here, the current source can be assumed to be a current transformer. When the input load 322 is applied to the secondary side of the current transformer 100, the magnitude of the secondary current of the current transformer 100 may be changed by the input load 322.

The current sensor 310 may measure the secondary current of the current transformer 100 before the input load 322 is applied and transmit it to the determination unit 330, and 2 of the current transformer 100 after the input load 322 is applied. The vehicle-side current may be measured and transmitted to the determination unit 330.

The determination unit 330 may compare the secondary current of the current transformer 100 before the input load 322 is applied and the secondary current of the current transformer 100 after the input load 322 is applied.

When a ground fault does not occur on the secondary side of the current transformer 100, a difference in the magnitude of the secondary current of the current transformer 100 before and after the input load 322 is applied may be less than a predetermined value. That is, since the current on the secondary side of the current transformer 100 is determined based on the ratio with the primary side, the magnitude of the current flowing through the secondary side of the current transformer 100 even if the input burden 322 is input and shorted The magnitude of the current flowing through the secondary side of the current transformer 100 may not change significantly before the input load 322 is applied. Accordingly, when a ground fault does not occur on the secondary side of the current transformer 100, the determination unit 330 determines that the difference in the magnitude of the secondary current of the current transformer 100 before and after the input burden 322 is input is less than a predetermined value. It can be judged as. In addition, when the difference in the magnitude of the current before and after the input load 322 is input is less than a predetermined value, the determination unit 330 may determine that a failure has not occurred in the secondary side of the current transformer 100.

4 is a circuit diagram of a failure detection apparatus when a failure occurs according to an embodiment of the present invention.

Referring to FIG. 4, the input burden setting unit 320 may be set to input the input burden 322. Here, the current source can be assumed to be a current transformer. When the input load 322 is applied to the secondary side of the current transformer 100, the magnitude of the secondary current of the current transformer 100 may be changed by the input load 322.

The current sensor 310 may measure the secondary current of the current transformer 100 before the input load 322 is applied and transmit it to the determination unit 330, and 2 of the current transformer 100 after the input load 322 is applied. The vehicle-side current may be measured and transmitted to the determination unit 330.

The determination unit 330 may compare the secondary current of the current transformer 100 before the input load 322 is applied and the secondary current of the current transformer 100 after the input load 322 is applied.

When a ground fault occurs on the secondary side of the current transformer 100, a difference in the magnitude of the secondary current of the current transformer 100 before and after the input load 322 is applied may be greater than or equal to a predetermined value. That is, when a ground fault occurs on the secondary side of the current transformer 100, most of the current flowing through the secondary side of the current transformer 100 may flow to the point where the ground fault occurs. At this time, when the input burden 322 is input and shorted, the current flowing to the point where the ground fault occurs may be divided and flow at the point where the input burden 322 and the ground fault occur. For this reason, the magnitude of the current flowing through the secondary side of the current transformer 100 may vary greatly.

Accordingly, when a ground fault occurs on the secondary side of the current transformer 100, the determination unit 330 determines that the difference in the magnitude of the secondary current of the current transformer 100 before and after the input burden 322 is input is greater than or equal to a predetermined value. can do. In addition, when the difference in the magnitude of the current before and after the input burden 322 is input is greater than or equal to a predetermined value, the determination unit 330 may determine that a failure has occurred in the secondary side of the current transformer 100.

5 is a diagram illustrating a method of detecting a secondary side failure of an instrument transformer according to an embodiment of the present invention.

Referring to FIG. 5, the input burden setting unit 320 may set the input burden to be input to the secondary side of the current transformer 100 (S100 ). Here, the current sensor 310 may measure the current of the secondary side of the current transformer 100 before the input load is applied to the secondary side of the current transformer 100. In addition, the current sensor 310 may measure the current at the secondary side of the current transformer 100 after an input load is put into the secondary side of the current transformer 100.

The determination unit 330 may compare the magnitude of the current before and after the input burden 322 is input (S200). The determination unit 330 may calculate a difference between the current magnitude by receiving the magnitude of the current measured before the input burden 322 is input from the current sensor 310 and the magnitude of the current measured after the input burden 322 is input. .

As a result of comparing the magnitude of the current before and after the input burden 322 is input, it may be determined whether the difference in size before and after the input burden 322 is input is greater than or equal to a predetermined value (S300).

When the difference in the magnitude of the current before and after the input burden 322 is input is greater than or equal to a predetermined value, the determination unit 330 may determine that a failure has occurred in the secondary side of the current transformer 100 (S400). When a ground fault occurs on the secondary side of the current transformer 100, most of the current flowing through the secondary side of the current transformer 100 may flow to the point where the ground fault occurs. At this time, when the input burden 322 is input, the current flowing to the point where the ground fault occurs may be divided and flow between the point where the input burden 322 is put and the point where the ground fault occurs. Accordingly, the difference between the current before and after the input burden 322 is applied may be large, and thus, the difference between the current before and after the input burden 322 is applied may be greater than or equal to a predetermined value. Accordingly, the determination unit 330 may determine that a failure has occurred in the secondary side of the current transformer 100 when the difference between the current before and after the input load 322 is input is greater than or equal to a predetermined value.

On the other hand, as a result of comparing the magnitude of the current before and after the input burden 322 is input, when the difference in size before and after the input burden 322 is input is not more than a predetermined value, the determination unit 330 is It may be determined that a failure has not occurred on the vehicle side (S500). When a ground fault does not occur on the secondary side of the current transformer 100, a current fluctuated by the primary side may flow through the secondary side of the current transformer 100. At this time, even if the input burden 322 is applied, the current on the secondary side of the current transformer 100 may not be significantly changed. Accordingly, the difference between the current before and after the input burden 322 is applied may appear small, and thus, the difference between the current before and after the input burden 322 is applied may be less than a predetermined value. Accordingly, the determination unit 330 may determine that a failure has not occurred in the secondary side of the current transformer 100 when the difference between the current before and after the input load 322 is input is less than a predetermined value.

As described above, according to an embodiment of the present invention, a load is applied to the secondary side of the instrument transformer, and based on the magnitude of the current fluctuating by the applied load, the instrument transformer determines whether or not a failure occurs on the secondary side of the instrument transformer. It is possible to realize an apparatus and method for detecting a fault in the secondary side of a transformer.

Those skilled in the art to which the present invention pertains, since the present invention may be implemented in other specific forms without changing the technical spirit or essential features thereof, the embodiments described above are illustrative in all respects and should be understood as non-limiting. Only do it. The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. .

100: current transformer
200: burden
300: fault detection device
310: current sensor
320: input burden setting unit
330: judgment unit

Claims (12)

In the secondary side failure detection device of the instrument transformer for determining whether a secondary side failure of the current transformer included in the instrument transformer,
A current sensor measuring a current flowing through the secondary side of the current transformer;
An input load setting unit for setting the input or cut-off of the input load installed in parallel on the secondary side line of the current transformer;
Secondary-side failure detection device of an instrument transformer comprising a determination unit that determines whether or not a failure of the secondary side of the current transformer has occurred based on the magnitude of the current measured by the current sensor according to the input or cut-off of the input burden.
The method of claim 1,
The current sensor measures the current flowing through the secondary side of the current transformer before the input load is applied, and measures the current flowing through the secondary side of the current transformer after the input load is applied.
The method of claim 1,
The determination unit 2 of the meter transformer for comparing the magnitude of the current flowing to the secondary side of the current transformer before and after the input burden is applied, and calculating a difference in magnitude of the current flowing through the secondary side of the current transformer before and after the input burden is applied. Vehicle-side failure detection device.
The method of claim 3,
The determination unit determines that a failure has occurred in the secondary side of the current transformer when the difference in magnitude of the current flowing through the secondary side of the current transformer before and after the input of the input burden is greater than or equal to a predetermined value.
The method of claim 1,
When a fault occurs in the secondary side of the current transformer, current flows to the point where the fault occurs,
When the input burden is applied, the current is divided and flows between the point where the input burden is applied and the point where the failure occurs, so that the difference in magnitude of the current flowing in the secondary side of the current transformer before and after the input of the input burden is greater than a certain value. Secondary fault detection device for instrument transformers.
The method of claim 3,
The determination unit determines that a failure has not occurred in the secondary side of the current transformer when the difference in the magnitude of the current flowing through the secondary side of the current transformer before and after the input of the input burden is less than a certain value .
In the secondary side failure detection method of an instrument transformer for determining whether a secondary side failure of a current transformer included in an instrument transformer has occurred, the method comprising:
Measuring a current flowing through the secondary side of the current transformer;
Inputting an input load installed in parallel to the secondary terminal of the current transformer and the line;
And determining whether or not a failure of the secondary side of the current transformer has occurred based on the magnitude of the current measured according to the input or cut-off of the input burden.
The method of claim 7,
Measuring the current flowing through the secondary side of the current transformer,
A secondary-side failure detection method of an instrument transformer for measuring the current flowing through the secondary side of the current transformer before the input load is applied, and measuring the current flowing through the secondary side of the current transformer after the input load is applied.
The method of claim 7,
The step of determining whether a failure of the secondary side of the current transformer has occurred,
Secondary fault detection of an instrument transformer that compares the magnitude of the current flowing through the secondary side of the current transformer before and after the input burden is applied, and calculates the difference in magnitude of the current flowing through the secondary side of the current transformer before and after the input burden is applied. Way.
The method of claim 7,
The step of determining whether a failure of the secondary side of the current transformer has occurred,
A secondary-side failure detection method of an instrument transformer for determining that a failure has occurred in the secondary side of the current transformer when the difference in magnitude of the current flowing through the secondary side of the current transformer before and after the input burden is greater than or equal to a predetermined value.
The method of claim 7,
When a fault occurs in the secondary side of the current transformer, current flows to the point where the fault occurs,
When the input burden is applied, the current is divided and flows between the point where the input burden is applied and the point where the failure occurs, so that the difference in magnitude of the current flowing in the secondary side of the current transformer before and after the input of the input burden is greater than a certain value. The secondary side fault detection method of the instrument transformer used.
The method of claim 7,
The step of determining whether a failure of the secondary side of the current transformer has occurred,
When the difference in the magnitude of the current flowing through the secondary side of the current transformer before and after the input burden is less than a predetermined value, the secondary side failure detection method of an instrument transformer for determining that a failure has not occurred in the secondary side of the current transformer.

Images