KR100364821B1 - Apparatus for transform signal of current transformer - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to a current transformer, and more particularly, to a signal converter of a current transformer that is adapted to measure a high accuracy measured value using the current transformer. Such a signal conversion device of the current transformer according to the present invention outputs a first amplified voltage and a second amplified voltage by amplifying the first multiplexer for multiplexing the voltage of each phase measured through the current transformer, and the voltage output from the first multiplexer An amplifying unit configured to compare the output second output voltage with a preset reference voltage and determine whether to output a signal based on a comparison result, and the output first amplified voltage according to whether the comparator outputs a signal. And a second multiplexer for selecting and outputting any one of the second and second amplified voltages, and a processor for converting the output voltage of the second multiplexer to a digital value, so that an overflow of the AD conversion of the processor does not occur and operation time is increased. Is effective.

Description

Apparatus for transform signal of current transformer

TECHNICAL FIELD The present invention relates to a current transformer, and more particularly, to a signal converter of a current transformer that is adapted to measure a high accuracy measured value using the current transformer.

1 is a circuit diagram showing a signal conversion device of a conventional current transformer.

Referring to FIG. 1, a signal converter of a conventional current transformer may include a current transformer 100 measuring current and a voltage measuring part configured to output a voltage by adjusting a burden resistance value according to the magnitude of the current measured by the current transformer 100 ( 110, a multiplexer 120 multiplexing the voltage of each phase measured by the voltage measuring unit 110, an amplifier 130 amplifying the voltage output from the multiplexer 120, and the amplifier 130. The processor 140 converts the output voltage of the digital signal into a digital value.

Here, in the voltage measuring unit 110, burden resistors R ₁ , R _2, and R ₃ are respectively connected in parallel to the secondary (+) terminal and the (−) terminal of the current transformer 100, and the processor is connected to the R ₂ and R 3. Switch 1 and switch 2 which operate under the control of 140 are respectively connected. The Rf resistor for the lope filter is connected to the (+) terminal of the current transformer 100 and the input R terminal of the multiplexer 120, and the capacitor C for the lope filter together with the Rf resistor is the (−) terminal of the current transformer 100. And the R terminal of the multiplexer 120. At this time, the current transformer and the voltage measuring unit for measuring the current of each phase (R, S, T, N) may be connected to the input terminals R, S, T, N of the multiplexer 120, respectively.

The output of the multiplexer 120 is connected to the first amplifier 131 and the second amplifier 132 of the amplifier 130, and the output of each of the amplifiers 131 and 132 is connected to the processor 140.

The operation of the conventional signal conversion device configured as described above is as follows.

First, the current transformer 100 measures and outputs current of each phase (R, S, T, N). Then, the voltage measuring unit 110 adjusts the burden resistance value according to the current measured by the current transformer 100 and outputs an appropriate voltage V _r .

That is, the voltage measuring unit 110 may adjust the burden resistance value according to the magnitude of the current I _r output from the current transformer 100. As shown in FIG. 3, the current output from the current transformer 100 is I _ra. Since the secondary side current is minute if the size of the switch is small, switch 1 and switch 2 are turned off to increase the voltage (V _r ), and if the current output from the current transformer 100 has the size of I _rb , switch 1 Is ON, switch 2 is turned off, and if the current output from the current transformer 100 has the magnitude of I _rc , switch 1 and switch 2 are turned on to adjust the magnitude of voltage V _r .

Therefore, when the current output from the current transformer 100 is _Ira , the voltage V _r of the voltage measuring unit 110 is measured as in Equation 1 below.

VR = R1 × Ira

When the current output from the current transformer 100 is I _rb , the voltage V _r of the voltage measuring unit 110 is measured as in Equation 2 below.

When the current output from the current transformer 100 is I _rc , the voltage V _r of the voltage measuring unit 110 is measured as in Equation 3 below.

In this case, the switch 1 and the switch 2 of the voltage measuring unit 110 are implemented as analog switches, and are controlled by the processor 140.

The harmonics of the voltage Vr determined according to the switch operation are removed through the Lopez filter LFP including the resistor Rf and the capacitor C, and then input to the multiplexer 120.

The multiplexer 120 selects an output signal according to the control of the processor 140, and the output voltage of the multiplexer 120 is input to the first amplifier 131 and the second amplifier 132 of the amplifier 130. .

Here, the first amplifier 131 is a voltage follow with an amplification gain of 1 times, and the second amplifier 132 is composed of resistors R ₄ and R ₅ as an integer multiple of 2 times or more. The output voltages of the first amplifier 131 and the second amplifier 132 are input to the processor 140, and the processor 140 converts the output voltage of the amplifier 130 into a digital value.

At this time, the processor 140 operates to obtain a maximum gain within a range where no overflow occurs. That is, when the digitally converted value (hereinafter, abbreviated to AD value) in the processor 140 overflows, the output voltage of the second amplifier 132 is converted into a digital value. This is because overflow does not occur with the output voltage of the first amplifier 131 which is voltage-following, while the input current of the current transformer 100 is alternating current, so the second amplifier 132 is used when sampling data in the processor 140. This is because an amplification of may cause an overflow outside the AD input voltage range.

Therefore, the processor 140 converts the output voltages of the first amplifier 131 and the second amplifier 132 into digital values, respectively, and selects one AD value among them in order to obtain an appropriate AD value.

However, the conventional signal converter of the current transformer has the following problems.

First, the processor is configured to select data of the first amplifier when the AD value caused by the output voltage of the second amplifier overflows, so that it is necessary to simultaneously read the data of the first amplifier and the second amplifier to determine a valid value. There is a feeling.

Second, since the processor always needs to perform AD conversion on the output voltages of the first amplifier and the second amplifier, it takes a lot of computation time in AD conversion, and there is a problem that the error in AD conversion cannot be reduced due to the limitation of the number of data sampling. .

Accordingly, an object of the present invention has been made in view of the above-mentioned problems of the prior art, and is to provide a signal conversion device of a current transformer that can reduce the calculation time and error during AD conversion of the voltage measured by the current transformer.

1 is a circuit diagram showing a signal conversion device of a conventional current transformer.

2 is a circuit diagram showing a signal conversion device of a current transformer according to the present invention.

3 is a signal waveform diagram showing an example of an output current of a current transformer.

* Description of the symbols for the main parts of the drawings *

200: current transformer 210: voltage measurement unit

220: first multiplexer 230: amplifier 231: first amplifier 232: second amplifier 240: comparator 241: comparator 250: second multiplexer 260: processor

According to an apparatus feature of the present invention for achieving the above object, the signal conversion device of the current transformer is a first multiplexer for multiplexing the voltage of each phase measured through the current transformer, and by amplifying the voltage output from the first multiplexer An amplifier for outputting a first amplified voltage and a second amplified voltage, a comparator configured to compare the output second output voltage with a preset reference voltage, and determine whether to output a signal according to a comparison result, and a signal output of the comparator And a second multiplexer for selecting and outputting any one of the outputted first and second amplified voltages, and a processor for converting the output voltage of the second multiplexer into a digital value.

Preferably, the comparator outputs a signal when the output second amplification voltage exceeds a preset reference voltage, and does not output a signal when the output second amplification voltage is less than or equal to the reference voltage.

The second multiplexer selects and outputs the first amplified voltage when a signal is output from the comparator, and selects and outputs the second amplified voltage when a signal is not output from the comparator.

In addition, the processor receives an output signal of the comparator and senses an amplification ratio with respect to the output voltage of the second multiplexer.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a circuit diagram showing a signal conversion device of a current transformer according to the present invention.

Referring to FIG. 2, the signal conversion device of the current transformer according to the present invention includes a current transformer 200 for measuring current of each phase R, S, T, and N, and a load according to the current measured by the current transformer 200. The voltage measurer 210 outputs the voltage V _r by adjusting the resistance value, and the first multiplexer 220 multiplexes any one of the voltage V _r of each phase measured by the voltage measurer 210. And an amplifier 230 which amplifies the voltage V _r output from the first multiplexer 220 and outputs a first amplified voltage and a second amplified voltage, and among the output voltages of the amplified unit 230. 2 comparing the amplification voltage with a reference voltage that is already set, and outputting or not outputting a signal to prevent the occurrence of an overflow according to the comparison result, and according to whether or not the signal output of the comparator 240 Any one of the first amplified voltage or the second amplified voltage output from the amplifier 230 Select the output to be configured and the second multiplexer (250), the output voltage of the second multiplexer 250 to the processor 260 for conversion to a digital value.

Here, when the configuration of the voltage measuring unit 210 is described, burden resistors R ₁ , R ₂ , and R ₃ are connected to the secondary side (+) side and the (-) side of the current transformer 200 in parallel, respectively. Switches 1 and 2 are connected in series with resistors R ₂ and R ₃ . The Lopez filter acceptable resistance R _f is connected to the R ₃ (+) side and the input terminal of the first multiplexer 220, and the input of Lopez filter tolerated capacitor C, the first multiplexer 220 with the resistance R _f It is connected to the terminal and ground. The voltage measuring unit 210 is connected to the input terminals R, S, T, and N of the first multiplexer 220 together with the current transformers of the respective phases R, S, T, and N.

The amplifier 230 includes a first amplifier 231 having an amplification gain of 1 times and a second amplifier 232 having an amplification gain of 2 times or more, and a first amplifying voltage output from each of the amplifiers 231, 232. The second amplified voltages are respectively input to the second multiplexer 250.

The comparator 240 receives the second amplified voltage output from the second amplifier 232 to the non-inverting terminal (+), and inverts the terminal (−) as the reference voltage based on the divided voltages of the resistors R6 and R7. The output terminal of the comparator 241 is connected to the second multiplexer 250 and the processor 260 to transmit a signal, and the output of the second multiplexer 250. The terminal is connected to the AD input terminal of the processor 260.

The operation of the signal converter of the current transformer configured as described above is as follows.

First, the current transformer 200 measures and outputs current of each phase (R, S, T, N). Then, the voltage measuring unit 210 adjusts the burden resistance value according to the current I _r measured by the current transformer 200 and outputs an appropriate input voltage.

That is, the voltage measuring unit 210 may adjust the burden resistance value according to the magnitude of the current I _r output from the current transformer 200. As shown in FIG. 3, the current output from the current transformer 200 is I _ra. Since the secondary current is small if the size of the switch is small, switch 1 and the switch 2 are turned off to increase the voltage (V _r ), and if the current output from the current transformer 200 has the size of I _rb, the switch 1 Is ON and switch 2 is turned off, and if the current output from the current transformer 200 has the size of I _rc, the size of the input voltage V _r is adjusted by turning on the switches 1 and 2. . These switches 1 and 2 operate under the control of the processor 260 to set the most appropriate analog input voltage.

As such, the voltage V _r determined by the voltage amplifier 210 is input to the first multiplexer 220, and the first multiplexer 220 selects one voltage V _r under the control of the processor 260. The first amplifier 231 and the second amplifier 232 of the amplifier 230 are output.

Then, the first amplifier 231 and the second amplifier 232 amplify the output voltage of the first multiplexer 220 and output the first amplified voltage and the second amplified voltage to the second multiplexer 250.

Here, the first amplifier 231 has a voltage follow with an amplification gain of 1 times, and the second amplifier 232 has a amplification gain of more than twice. Therefore, the output voltage of the first amplifier 231 takes a gain of 1 times according to the voltage, so that no overflow occurs during the AD conversion in the processor 260, but the second amplifier 232 has an amplification gain of 2 times or more. By having an overflow may occur during the AD conversion in the processor 260.

Accordingly, the comparator 240 receives the second amplified voltage output from the second amplifier 232 and compares it with a preset reference voltage and determines whether the signal is output so that no overflow occurs during AD conversion.

At this time, the comparator 240 generates a high signal to the second multiplexer 250 and the processor 260 when the second amplified voltage output from the second amplifier 232 is greater than the reference voltage. When the second amplified voltage output from the amplifier 232 is less than the reference voltage, a low signal is generated to the second multiplexer 250 and the processor 260. As such, the comparator 240 determines when a voltage out of the AD input range is output from the second amplifier 232 and generates a signal for controlling the operations of the second multiplexer 250 and the processor 260 accordingly. It performs the function.

Then, when a signal is input from the comparator 240, the second multiplexer 250 switches the output voltage of the first amplifier 231 to the processor 260 to output the signal, and the signal is input from the comparator 240. If not, the output voltage of the second amplifier 232 is switched to the processor 260 and output.

Table 1 shows the output of the second multiplexer 250 according to the output signal of the comparator 240.

A terminal B terminal Output of first multiplexer Output signal of the comparator 0 0 1x gain Low One 0 n times gain High

Therefore, the processor 260 receives the signal switched by the second multiplexer 250 according to the output signal of the comparator 240 and performs AD conversion. At this time, the processor 260 should determine whether the voltage input through the second multiplexer 250 is the output voltage of the first amplifier 231 or the output voltage of the second amplifier 232. This is because the calculation of the amplification ratio is required internally. To this end, the output signal of the comparator 240 is input to the amplification ratio determination terminal of the processor 260, and the processor 260 determines the amplification ratio according to the output signal of the comparator 240.

As described above, the signal conversion device of the current transformer according to the present invention determines the voltage input to the processor according to the output voltage of the amplifier, so that the overflow does not occur during the AD conversion of the processor, and the operation time is increased.

In addition, the signal conversion device of the current transformer according to the present invention can measure the exact amount of electricity, it is easy to apply to overcurrent protection products utilizing the current transformer.

In addition, the overcurrent protection product to which the signal converter of the current transformer according to the present invention is applied has an effect of operating stably and increasing reliability.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

Claims (4)

A first multiplexer for multiplexing the voltage of each phase measured through the current transformer, An amplifier which amplifies the voltage output from the first multiplexer and outputs a first amplified voltage and a second amplified voltage; A comparison unit comparing the output second output voltage with a preset reference voltage and determining whether to output a signal according to a comparison result; A second multiplexer for selecting and outputting any one of the outputted first and second amplified voltages according to whether the comparator outputs a signal; And a processor for converting the output voltage of the second multiplexer into a digital value. The method of claim 1, wherein the comparison unit, And outputting a signal when the output second amplification voltage exceeds a predetermined reference voltage and not outputting a signal when the output second amplification voltage is less than or equal to the reference voltage. The method of claim 1, wherein the second multiplexer, And selecting and outputting the first amplified voltage when the signal is output from the comparator, and selecting and outputting the second amplified voltage when the signal is not output from the comparator. The apparatus of claim 1, wherein the processor senses an amplification ratio of an output voltage of the second multiplexer by receiving an output signal of the comparator.