KR0146148B1 - Input circuit of 3phase overcurrent relay - Google Patents

Abstract

The present invention relates to an input circuit of a three-phase overcurrent relay and a method for monitoring the same. In the conventional input circuit of a three-phase overcurrent relay, an image split current occurs when the three-phase alternating current is unbalanced, but it is incomplete to be judged as a failure of the input circuit. In addition, there was a problem that it is difficult to judge the input circuit as a fault only by the image split current.

In order to solve this problem, the present invention compares the difference between the image current obtained by the sum of the three-phase input currents and the image current obtained through the adder to determine whether the input circuit is faulty, thereby making it possible to determine the failure of the input circuit more reliably. It is to be able to monitor whether or not.

Description

Input circuit of three-phase overcurrent relay and its monitoring method

1 is an input circuit diagram of a conventional three-phase overcurrent relay.

2 shows the use of a typical three-phase overcurrent relay.

3 is an input circuit diagram of the three-phase overcurrent relay of the present invention.

4 is a signal flow diagram of the input circuit monitoring method of the three-phase overcurrent relay of the present invention.

* Explanation of symbols for main parts of the drawings

1: auxiliary current transformer 2: filter part

3,7: Sample and hold part 4: Analog / digital converter part

5 microprocessor 6 adder

10: peripheral current machine

The present invention relates to a three-phase overcurrent relay, and more particularly, to an input circuit and a monitoring method of the three-phase overcurrent relay to determine whether the relay operates normally by determining the abnormality of the input circuit using the image split current.

1 is a configuration diagram of an input circuit of a conventional three-phase overcurrent relay, and as shown therein, an auxiliary current transformer 1 for determining current values for three-phase input currents ia, ib, and ic, and the auxiliary current transformer 1 The filter unit 2 for filtering the current value determined in, the sample and hold unit 3 for sampling and maintaining the current value filtered by the filter unit 2, and the sampled value in the sample and hold unit 3. It consists of an analog / digital conversion section 4 for converting to a digital signal, and a microprocessor 5 for calculating a three-phase current converted into a digital signal by the analog / digital conversion section 4 and monitoring whether there is a failure. .

In the input circuit of the conventional three-phase overcurrent relay configured as described above, the three-phase overcurrent relay is applied to protect the overcurrent by receiving the three-phase current to be protected through the peripheral current transformer 10 as shown in FIG.

That is, when the three-phase current (Ia, Ib, Ic) is input to the peripheral current transformer 10, the peripheral current transformer 10 determines the current value (ia, ib, ic) of the three-phase current to the three-phase overcurrent relay Will be authorized.

At this time, the current value (ia, ib, ic) determined by the peripheral current transformer 10 is high, the current value (ia, ib, ic) is a secondary current by the secondary current transformer (1).

The current value determined in this way is filtered by the filter portion 2, and each filtered current value is applied to the sample and hold portion 3 so as to be sampled and maintained.

At this time, the analog / digital conversion unit 4 converts the three-phase current value sampled above into a digital signal and applies it to the microprocessor 5, and the microprocessor 5 converts the three-phase current to the following equation (1). Calculate using to find the image split current (Io).

At this time, if the three-phase current is balanced, the image split current Io does not exist and the image split current Io becomes o. Therefore, the microprocessor 5 determines that the input circuit is normal, and if the three-phase current is unbalanced, Since the image split current Io is generated, the microprocessor 5 can determine that the input circuit is a failure.

However, the input circuit of the conventional three-phase overcurrent relay described above is not only incomplete to determine the input circuit as a failure due to the generation of the image split current (Io) when the three-phase current is unbalanced, the input circuit only by the image split current (Io) There was a problem that is difficult to judge as a malfunction.

In order to solve this problem, the present invention obtains the image split current (Io) obtained by software and the image split current (Io ') through an adder, and then compares the difference between the two image split currents (Io) (Io'). Created an input circuit of the three-phase overcurrent relay to determine whether the circuit failure and the monitoring method thereof, will be described in detail with reference to the accompanying drawings.

3 is an input circuit diagram of the three-phase overcurrent relay of the present invention. As shown therein, an auxiliary current transformer 1 for determining current values for three-phase input currents ia, ib, and ic, and the auxiliary current transformer 1 A filter unit 2 for filtering the current value determined in step 2), a sample and hold unit 3 for sampling the signal filtered by the filter unit 2, and an adder 6 for adding each current value of the auxiliary current transformer 1. ), A sample and hold unit 7 for sampling the output signal of the adder 6, and an analog / digital conversion unit for converting each output signal of the sample and hold unit 3 and 7 into a digital signal ( 4) and the output signal of the analog / digital conversion unit 4 are processed to calculate the image split current Io (Io '), and compare the difference of the image split current Io (Io'). It consists of a microprocessor (5) to determine whether the failure.

When described in detail with reference to the accompanying drawings the effect of the present invention configured as described above are as follows.

When the three-phase input current (ia, ib, ic) is input to the auxiliary current transformer 1, the auxiliary current transformer 1 determines the current value for each current.

At this time, when the filter unit 2 filters the current value determined by the auxiliary current transformer 1 and outputs it to the sample and hold unit 3, the sample and hold unit 3 samples each current value to analog / digital conversion unit. (4).

Accordingly, the analog / digital conversion unit 4 converts the sampled current value into a digital signal and outputs it to the microprocessor 5, and the microprocessor 5 uses the following equation (2) to determine the image division current ( Calculate Io) and set ε by taking ½ of the largest current among the input three-phase currents.

On the other hand, the current value determined in the auxiliary current transformer (1) is input to the adder (6) and summed (Sum (I)), the sum (Sum (I)) value is sampled in the sample and hold unit (7) and the It is output to the analog / digital converter 4.

Therefore, when the analog / digital converter 4 converts the sampled value into a digital signal and outputs the digital signal to the microprocessor 5, the microprocessor 5 takes a value of this value and divides the value into an image split current Io '. Obtain

At this time, the microprocessor (5) compares the difference between the two image split currents (Io) and (Io '), and if the difference is greater than ε, the input circuit is judged to be a failure, and if the difference is smaller than ε, it is determined to be normal. Monitor the presence of faults.

As described above, the present invention compares the difference between the image current (Io) obtained by the sum of the respective currents by software and the image current (Io ') obtained by adding the currents by an adder to determine whether the input circuit is faulty. By doing so, it is possible to determine the failure of the input circuit more reliably.

Claims (2)

An auxiliary current transformer 1 for determining respective current values for the input currents ia, ib and ic, a filter part 2 for filtering an output signal of the auxiliary current transformer 1, and A sample and hold section 3 for sampling the output signal, an adder 6 for summing the output signals of the auxiliary current transformer 1, and a sample and hold section 7 for sampling the output signal of the adder 6; And an analog / digital conversion section 4 for converting the output signals of the sample and hold sections 3 and 7 into digital signals, and an output signal of the analog / digital converting section 4 to calculate the sample. After calculating the filter image divider current Io according to the output signal of the and hold unit 3 and the adder unit image divide current Io 'according to the output signal of the sample and hold unit 7, the difference is compared. Input circuit of a three-phase overcurrent relay, characterized in that consisting of a microprocessor (5) for determining whether or not. After calculating each current value of the input currents (ia, ib, ic), the first step of obtaining the filter part image current (Io) and the respective current values of the first step are summed in the adder (Sum (I)). A second step of obtaining a post addition image division current Io '; a third step of setting ε by taking half of the largest current among the input currents ia, ib, and ic; A method for monitoring an input circuit of a three-phase overcurrent relay comprising a fourth step of comparing a difference between the filter part image current (Io) and the adder part image current (Io ') obtained in step 2 and determining whether there is a failure. .