KR0179754B1 - Overcurrent meter - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overcurrent relay for line protection. In the related art, when a line current flowing on a wiring line is obtained, a line without compensating measurement errors occurring in a low pass filter unit, a full wave rectifier and a parallel amplifier which constitutes a line protection overcurrent relay Since current is obtained, a significant error accumulates in the line current reaching the microcomputer in the final stage, and an error occurs in the overcurrent determination, and an accurate overcurrent determination is not achieved. To eliminate the error, a low pass filter, a radio wave Since each of the rectifying unit and the parallel amplification unit must be provided with a separate fine adjustment circuit, there is another problem that the manufacturing cost increases significantly and becomes a complicated configuration. Therefore, the line protection overcurrent relay of the present invention grounds the input side of the low pass filter part, the full-wave rectifier part and the parallel amplifier part by using the first, second and third multiplexers when measuring the line current flowing through the wiring line. By calculating this and reflecting this offset voltage in the calculation of the line current, it is possible to solve the measurement error problem occurring in the low pass filter part, the full-wave rectifier part and the main multiplexer, so that the overcurrent judgment can be made accurately and the measurement error problem can be solved. A separate fine tuning circuit is not required to solve the problem, thus reducing manufacturing costs and providing a simple configuration.

Description

Overcurrent relay for line protection

1 is a block diagram of a conventional line protection overcurrent relay.

2 is a block diagram of the overcurrent relay for protecting the line of the present invention.

3 is a flow chart according to the operation of the line protection overcurrent relay in FIG.

* Explanation of symbols for main parts of the drawings

201: current detector 202: low pass filter

203: full wave rectifier 204: history amplifier

205: main multiplexer 206: microcomputer

207: blocking operation unit 208: display unit

209: setting unit 210: first self-diagnosis unit

211: second self-diagnosis unit 212: third self-diagnosis unit

MUX1: First Multiplexer MUX2: Second Multiplexer

MUX3: Third Multiplexer

The present invention relates to a technique for determining how much line current flows in a wiring line, and in particular, by reflecting a measurement error occurring inside the line current flowing in the wiring line to the calculation for obtaining the line current, The present invention relates to an overcurrent relay for line protection that can be measured accurately without errors.

1 shows a block diagram of a conventional line protection overcurrent relay, comprising: a current detector 101 for detecting a line current flowing through the wiring line LN and converting it into a detection voltage; A low pass filter 102 for removing a harmonic component included in the detection voltage of the current detector 101 to produce a detection voltage free of structural wave components; A full-wave rectifier 103 for rectifying the detected voltage of the low pass filter 102 to produce a detected voltage of direct current; A parallel amplifier 104 for amplifying the detected voltage of the full-wave rectifier 103 by 1, 2, 4, and 8 times, respectively; A main multiplexer 105 for selecting any one of four detection voltages amplified and output from the parallel amplifier 104; The selection operation of the main multiplexer 105 is controlled to obtain an optimal operation, and the operation calculates a line current with respect to any detected voltage selected by the main multiplexer 105, and determines whether the obtained line current is an overcurrent. And a microcomputer 106 for driving the shutoff operation unit 107 configured to judge and shut off the power source.

Here, reference numeral 108 denotes a display unit which displays various data related to the line current measurement and the line current obtained by the microcomputer 106, and '109' sets various initial data related to the line current measurement. It is a setting part.

The operation of the conventional line protection overcurrent relay having such a configuration will be described.

First, when a line current flowing in the wiring line LN is detected by the current transformer CT of the current detection unit 101 connected to the wiring line LN, the line current is detected by the burden resistor R. And a harmonic component, and are level-adjusted so as to be suitable for the line current measurement by the variable resistor VR1 and input to the low pass filter unit 102, which is the next stage.

The low pass filter 102, which has received the detection voltage, makes the detection voltage without harmonic components included in the detection voltage and inputs it to the full-wave rectifying section 103. The full-wave rectifying section 103 converts the detected voltage into direct current. The signal is converted into a detection voltage and input to the parallel amplifier 104.

The parallel amplifier 104 amplifies the detected voltage inputted in parallel so that the microcomputer 106 can select one when the line current is obtained to perform an optimal operation.

In other words, it is amplified by 1 times to the first amplifier (AMP1), 2 times to the second amplifier (AMP2), 4 times to the third amplifier (AMP3), 8 times to the fourth amplifier (AMP4) The detected voltages are respectively input to four input terminals of the main multiplexer 105.

The microcomputer 106 controls the selection operation of the main multiplexer 105 for optimal operation, receives and digitizes the optimum detection voltage required for the operation, and calculates the line current for the digitized detection voltage. The line current flowing through the line LN is obtained.

Subsequently, by checking whether the obtained line current is an overcurrent and driving the cutoff operation unit 107 to cut off the power supplied to the wiring line LN by determining the overcurrent, the load supplied with the power through the wiring line LN or The wiring line LN is protected.

The problem with the conventional line protection overcurrent electricity having such a configuration and operation is that the measurement error occurring in the low pass filter, the full-wave rectifier and the parallel amplifier which constitutes the line protection overcurrent relay when the line current flowing on the wiring line is obtained. Since the line current is obtained without compensation, a significant error accumulates in the line current reaching the microcomputer in the final stage, and an error occurs in the overcurrent determination, so that the accurate overcurrent judgment cannot be made. Further, in order to eliminate the error, a separate fine adjustment circuit must be provided in each of the low pass filter, the full-wave rectifier and the parallel amplification unit, thereby causing another problem that the manufacturing cost increases significantly and becomes a complicated configuration.

Therefore, the present invention was devised in view of the problems of the conventional over-current relay for line protection, and a line capable of accurate overcurrent determination by compensating measurement errors occurring in the low pass filter unit, the full-wave rectifier unit and the parallel amplifier unit. It is an object to provide a protective overcurrent relay.

The line protection overcurrent relay according to the above object includes: a current detector for detecting a line current flowing through a wiring line and converting the current into a detection voltage, and a low pass filter unit for removing harmonic components contained in the detected voltage of the current detector; A first multiplexer for grounding the input side of the low pass filter unit when a control signal is input; A full-wave rectifier for rectifying the detected voltage free from harmonic components output from the low pass filter unit and converting the detected voltage into a direct-current detection voltage; A second multiplexer for grounding the input side of the full-wave rectifying unit when a control signal is input; A parallel amplifier which amplifies the detected voltage of the direct current of the full-wave rectifier by 1, 2, 4, and 8 times, respectively; When a control signal is input, any one of a third multiplexer for grounding the input side of the parallel amplifier and four detection voltages amplified by 1, 2, 4, and 8 times by the parallel amplifier according to the input control signal. A main multiplexer for selecting one; Input control signals to the first, second, and third multiplexers to obtain offset voltages of the low pass filter, full-wave rectifier, and parallel amplifiers, and input control signals to the main multiplexers to receive an optimum detection voltage. A microcomputer that calculates the current and reflects the offset voltage to calculate the line current, determines whether the obtained line current is an overcurrent, and determines that the current is overcurrent so that the power supplied to the wiring line is cut off. It consists of.

The operation and effects of the present invention will be described in detail with reference to FIGS. 2 and 3 showing one preferred embodiment for the line protection overcurrent relay configured as described above. In this case, a detailed description of the same conventional parts will be omitted.

In the line protection overcurrent relay according to the present embodiment, as shown in FIG. 2, the low pass filter portion (A) is provided in a current detector 201 including a current transformer CT, a load resistor R, and a variable resistor VR. The input side of the 202 and the first multiplexer MUX1 are connected, the input side of the full wave rectifier 203 and the second multiplexer MUX2 are connected to the output side of the low pass filter 202, and the output side of the full wave rectifier 203. The input side of the parallel amplifier 204 and the third multiplexer MUX3 are connected to each other. The main multiplexer 205 is connected to the input side of the parallel amplifier 204 and the output side of the main multiplexer 205. The input side of the computer 206 is connected, and the microcomputer 206 is connected to the first, second, and third multiplexers MUX1-MUX3, the main multiplexer 205, the shutoff operation unit 207, and the display unit 208. Configured to control operation. The setting unit 209 is connected to the microcomputer 206.

In this configuration, the microcomputer 206 is initialized for the line current measurement (ST1). Then, when the line current flowing on the wiring line LN is detected by the current transformer CT of the current detector 201, the line current is detected by the burden resistor R of the current detector 201 to detect the detected voltage (harmonic component). And the level is adjusted by the variable resistor VR to be suitable for overcurrent measurement.

At this time, the microcomputer 206 controls the first multiplexer MUX1 by inputting a control signal to the first multiplexer MUX1 connected to the input side of the low pass filter unit 202 to control the first multiplexer MUX1. Ground the input side electrically (ST2).

That is, the input of the low pass filter unit 202 is set to zero.

The microcomputer 206 receives the voltage input from the main multiplexer 205 while the detection voltage is not input to the low pass filter unit 202, and digitizes it to calculate an offset voltage for the digitized voltage. The offset voltage of the low pass filter unit 202 is obtained, and the offset voltage is stored (ST3).

When the offset voltage of the low pass filter unit 202 is obtained as described above, the microcomputer 206 inputs a control signal to the first multiplexer MUX1 again to release the ground state of the input side of the low pass filter unit 202.

Accordingly, the low pass filter unit 202 receives the detection voltage output from the current detection unit 201 at the front end.

The low pass filter unit 202 receiving the detection voltage removes harmonic components included in the detection voltage to generate a detection voltage without harmonic components.

At this time, the microcomputer 206 controls the second multiplexer MUX2 by inputting a control signal to the second multiplexer MUX2 connected to the input side of the full-wave rectifying unit 203 to low-pass the input side of the full-wave rectifying unit 203. As in the case of the pass filter unit 202, the ground is performed (ST4).

The microcomputer 206 receives the voltage input from the main multiplexer 205 while the input side of the full wave rectifying unit 203 is grounded and the detection voltage is not input to the full wave rectifying unit 203 as described above. The offset voltage of the full-wave rectifier 203 is obtained by calculating the offset voltage, and the offset voltage of the full-wave rectifier 203 is stored (ST5).

When the offset voltage of the full-wave rectifying unit 203 is obtained as described above, the microcomputer 206 again controls the second multiplexer MUX2 to release the ground state of the input side of the full-wave rectifying unit 203.

Accordingly, the full wave rectifier 203 receives a detection voltage without harmonic components output from the low pass filter 202 at the front end.

The full-wave rectifier 203, which receives the detection voltage without harmonic components, rectifies the detection voltage to generate a DC detection voltage.

At this time, the microcomputer 206 controls the third multiplexer MUX3 by inputting a control signal to the third multiplexer MUX3 connected to the input side of the parallel amplifier 204 to control the input side of the parallel amplifier 204. Ground it (ST6).

The microcomputer 206 receives the voltage input from the main multiplexer 205 and digitizes the digital amplifier 206 while the input side of the parallel amplifier 204 is grounded and the detection voltage is not input to the parallel amplifier 204. An offset voltage is calculated for the voltage to obtain the offset voltage of the parallel amplifier 204, and the offset voltage is stored (ST7).

When the offset voltage of the parallel amplifier 204 is obtained in this manner, the microcomputer 206 again controls the third multiplexer MUX3 to release the ground state of the input side of the parallel amplifier 204.

Accordingly, the detection voltage of the DC rectified and output to the radio amplifier 203 is amplified by 1 times from the parallel amplifier 204 to the first amplifier AMP1 and twice by the second amplifier AMP2. 4 times with the third amplifier AMP3 and 8 times with the fourth amplifier AMP4.

The microcomputer 206 receives the optimum detection voltage by controlling the main multiplexer 205 so as to perform an optimal operation for obtaining a line current among the four detection voltages amplified and output from the parallel amplifier 204. .

The microcomputer 206 receiving the lowest detection voltage digitizes the detection voltage, calculates a line current with respect to the digitized detection voltage, and calculates and stores the low pass filter 202 and the full-wave rectifier 203. ) And the offset voltage of the parallel amplifier 204 are reflected in the calculation to obtain an accurate line current (ST8).

Since the offset voltages of the low pass filter unit 202, the full-wave rectifying unit 203, and the parallel amplifier unit 204 are reflected in the calculation of the line current as described above, the line current finally obtained becomes an accurate line current without measurement error.

Next, the microcomputer 206 compares whether the obtained line current is an overcurrent due to an overload with a predetermined set value, and if it is determined that it is not an overcurrent, the microcomputer 206 calculates the line current again, and if it is determined that the overcurrent is an overcurrent, the blocking operation unit ( In order to ensure accuracy without driving 207, a time limit operation for calculating the line current is performed once again (ST9, ST10, ST8).

As a result of obtaining the line current again, if it is determined that it is still an overcurrent, the blocking operation unit 207 is driven to cut off the power supplied to the wiring line LN to protect the load or the wiring line LN (ST11) (ST12). ).

As another embodiment of the present invention, as shown in FIG. 2, the first magnetic diagnostic unit 210 is provided on the output side of the current detection unit 201, and the second self-diagnosis on the output side of the low pass filter unit 202. FIG. The unit 211 is provided, and the third magnetic diagnosis unit 212 is installed at the output side of the full wave rectifying unit 203 so that the current detector 201, the low pass filter unit 202, and the full wave rectifying unit 203 operate normally. Monitor your presence at all times.

As described in detail above, the line protection overcurrent relay of the present invention uses the first, second, and third multiplexers to measure the input of the low pass filter unit, the full-wave rectifier unit, and the history amplifier unit when measuring the line current flowing through the wiring line. By measuring the offset voltage by grounding and reflecting the offset voltage in the calculation of the line current, it is possible to solve the measurement error problem in the low pass filter part, full-wave rectifier part and main multiplexer. In addition, since a separate fine adjustment circuit is not required to solve the measurement error problem, the manufacturing cost is reduced and a simple configuration is obtained.

Claims (2)

A current detector for detecting the line current flowing through the wiring line and converting the current into a detection voltage, and a low pass filter for removing harmonic components contained in the detected voltage of the current detector; A first multiplexer for grounding the input side of the low pass filter unit when a control signal is input; A full-wave rectifier for rectifying the detected voltage free from harmonic components output from the low pass filter unit and converting the detected voltage into a direct-current detection voltage; A second multiplexer for grounding the input side of the full-wave rectifying unit when a control signal is input; A parallel amplifier which amplifies the detected voltage of the direct current of the full-wave rectifier by 1, 2, 4, and 8 times, respectively; When a control signal is input, any one of a third multiplexer for grounding the input side of the parallel amplifier and four detection voltages amplified by 1, 2, 4, and 8 times by the parallel amplifier according to the input control signal. A main multiplexer for selecting one; The control signal is input to the first, second, and third multiplexers to obtain offset voltages of the low pass filter, full-wave rectifier, and parallel amplifiers. Calculates the line current by inputting and calculates the line current by reflecting the offset voltage in this operation, and determines whether the obtained line current is an overcurrent so that the power supplied to the wiring line is cut off. An overcurrent relay for line protection, comprising: a microcomputer for controlling; 2. The apparatus of claim 1, further comprising: a first self-diagnosis unit provided at the output side of the current detection unit for monitoring whether the current detection unit operates normally; and a second self-diagnosis unit installed at the output side of the low pass filter unit for monitoring the normal operation of the low pass filter unit. And a third self-diagnostic part provided on the output side of the full-wave rectifying part and monitoring whether the full-wave rectifying part operates normally.