KR20130073659A - Instrument and method to obtain ratio error of current transformer for watt-hour-meter - Google Patents

Abstract

PURPOSE: An apparatus and method for measuring the ratio error of a converter for a watt hour meter are provided to measure the ratio error of the converter in a live wire state in which the watt hour meter is wired with a transformer, raise the measuring response speed of the ratio error, and reduce measuring errors. CONSTITUTION: An apparatus for measuring the ratio error of a converter for a watt hour meter includes a primary current detecting unit, a secondary current detecting unit, a micro controller unit (500), and an indicating part (201). The primary current detecting unit detects the size and phase signal of the primary current of a converter. The secondary current detecting unit detects the size and phase signal of the secondary current of the converter. The micro controller unit calculates a phase difference between the signals detected by the detecting units. According to the phase difference, the micro controller unit calculates a current ratio which is the ratio between the value of the waveform of the secondary current corresponding to the waveform of the primary current and the value of the waveform of the primary current, and then calculates an error between the calculated current ratio and the nominal current ratio of the converter. The indicating part indicates the values of the phase difference and the ratio error. [Reference numerals] (201 (230)) Indicating part; (220) Input part; (310) Input a CT primary signal; (410) Input a CT secondary signal

Description

Non-error measuring device and current measuring method of current transformer for power meter {Instrument and method to obtain ratio error of current transformer for watt-hour-meter}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-error measuring apparatus and a measuring method thereof of a current transformer for an integrated power meter having a phase discrimination function capable of discriminating whether a phase of a voltage line and a current transformer period is normally connected. Non-error measuring device and current measuring device of electric current meter for phase current meter which can measure the error ratio of the current to the secondary and the current between the voltage line and the instrument current transformer. It is about a method.

The amount of power used by consumers using voltages or currents higher than high voltage is measured by the wattmeter based on the voltage and current supplied through the transformer consisting of an instrument transformer and an instrument current transformer. At this time, in order to check the fault of the instrument transformer, the disconnection of wiring from the instrument transformer, and the reverse phase of the voltage and current supplied from the instrument transformer to the electricity meter, the instrument transformer and the electricity meter must be electrically disconnected and checked. Therefore, the check is very difficult.

Hereinafter, the power amount measurement circuit of the three-phase four-wire low voltage consumer will be described.

1 is a power measurement circuit diagram.

In Fig. 1, reference numeral 10 denotes a power supply, 20 indicates a load, and 40 indicates a current transformer CT for converting and outputting a current flowing from the low voltage power supply 10 supplying a large current into a constant current ratio. admit.

In Fig. 1, reference numeral 60 denotes a power meter which includes first to third voltage coils not shown for each phase and first to third current coils not shown.

In FIG. 1, R, S, and T represent each phase of the power supply, and N represents a grounded neutral wire.

1S is a source in which the current flowing in R phase is converted into a constant current ratio by the current transformer 40 CT1 for the instrument and the output current is input to the wattmeter 60, and 1L is a current meter inputted from 1S. The load is fed back to the instrument current transformer 40 CT1 via the first current coil of 60).

P1 is a voltage supplied to the first voltage coil of the wattmeter by receiving the voltage of the R phase with respect to the neutral line N, and may also refer to the R phase.

2S is a source in which the current flowing in the S phase is converted into a constant current ratio by the current transformer 40 CT2 for the instrument and the output current is input to the wattmeter 60, and 2L is a current meter input from 2S. The load is fed back to the instrument current transformer 40 CT2 via the second current coil of 60).

P2 is a voltage supplied to the second voltage coil of the wattmeter by receiving the voltage of the S phase with respect to the neutral line N, and may also refer to the S phase.

3S is a source in which the current flowing in the T phase is converted into a constant current ratio by the CT current transformer 40 CT3 and the output current is input to the wattmeter 60, and 3L is a current meter input from 3S. The load is fed back to the instrument current transformer 40 CT3 via the third current coil of 60).

P3 is a voltage supplied to the third voltage coil of the wattmeter by receiving the voltage of the T phase with respect to the neutral line N, and may also refer to the T phase.

P0 is the neutral (N) grounded.

In the electric power metering system configured as described above, the electric power meter is recalibrated every 7 years since the validity of the test is 7 years according to the provisions of the "Measurement Act on Metering", and the electric power meter 60 or the current transformer 40 is Even if a problem occurs, it is replaced.

However, when the current transformer 40 is out of order and the current error is out of the black error before the validity of the test expires, the measurement of the amount of power is interrupted by cutting off the current supplied to the current transformer. And the error should be measured.

Thus, the technique of measuring a rain error is disclosed by following patent document 1.

That is, Patent Literature 1 independently measures the factors (Gm, Bm, R2, and X2) affecting the error and phase error of the current transformer, so that the error and phase of the current transformer can accurately evaluate the current transformer to be measured. An error evaluation system and a method for evaluating the error, comprising a reference current transformer and a measured current transformer receiving a current equal to the primary applied to the primary side of the reference current transformer and the reference current transformer to the primary side. A current comparator for comparing the secondary current of the transformer and outputting a non-error and a phase error is provided.The secondary side of the reference current transformer is connected in series with the burden for the reference current transformer in series, and the secondary side of the current transformer is measured in series. The load for the current transformer to be measured is connected.

However, in the case of the current error transformer and the phase error evaluation system, during the measurement of the error between the power supply company and the customer, the agreement was concluded based on the maximum amount of power used by the customer. You may be charged for the electricity charges, but in many cases, these regulations are not followed properly. In addition, if the utility company wants to negotiate on the basis of the maximum amount of electricity used, the customer demands to negotiate on the basis of the average amount of power used. In addition, there was a problem such as a dispute between the power supply company and the customer about the replacement time.

In addition, since the wiring of the meter current transformer 40 and the electricity meter 60 is complicated between the power supply 10 and the load 20, the wiring is divided into the wires having a color, but the R, S, and T phases are connected. Due to an error or a misunderstanding of the wiring of the current transformers 40 for the instrument, a problem may occur in which the wiring is reversed.

Korean Unexamined Patent Publication No. 10-2010-0039089 (published Apr. 15, 2010)

Accordingly, an object of the present invention is to provide a current error measuring apparatus and a measuring method of the current transformer in which the transformer measures the error of the current transformer in a live state. .

In addition, another object of the present invention is to provide an apparatus for measuring the error of a current transformer and a measuring method thereof having a very fast response time.

In addition, another object of the present invention is to provide a non-error measuring apparatus and a measuring method of the current transformer that can reduce the measurement error even if the measurement response of the error is very fast.

In addition, another object of the present invention is a non-error measuring apparatus and current measuring method of the current transformer having a phase discrimination function that can determine whether the phase of the voltage line and the phase of the current flow period for the instrument being measured while measuring the error of the current transformer. It is to provide.

The non-error measuring apparatus of the current transformer according to the present invention for achieving the above object is a non-error of the current transformer for measuring the error of the primary current and the secondary current of the current transformer in the live state connected to the electricity meter and the current transformer A measuring apparatus, comprising: primary side current detecting means for detecting a magnitude and phase signal of a primary side current of the current transformer; Secondary current detection means for detecting magnitude and phase signals of the secondary current in the current transformer; The phase difference of the signal detected by the primary side and secondary side current detecting means is calculated, and the value of the waveform of the secondary side current corresponding to the waveform of the primary side current and the value of the waveform detected at the primary side current according to the phase difference. A microcontroller unit for calculating a current ratio, the ratio of the calculated current ratio to the nominal current ratio of the current transformer; And a display unit for displaying the phase difference and the non-error value.

Further, in the non-error measuring apparatus of the current transformer according to the present invention, the primary side and secondary side current detection means is characterized in that it comprises a zero crossing pickup.

In the non-error measuring apparatus of the current transformer according to the present invention, the magnitudes of the waveforms of the primary side and secondary side currents are characterized in that they are RMS values.

In the non-error measuring apparatus of the current transformer according to the present invention, the detection of the primary side current and the secondary side current is characterized by detecting with a clamp type current transformer.

In the non-error measuring apparatus of the current transformer according to the present invention, the signal detected by the clamp-type current transformer is amplified in the amplifier via an input filter, the amplified signal is an output filter for removing noise generated in the circuit It is characterized in that the input to the micro-controller unit.

In addition, the method for measuring the error of the current transformer according to the present invention for achieving the above object is a method of measuring the error of the primary current and the secondary current of the current transformer in the live state, the method of measuring the error of the current transformer, 1 A current phase difference detecting step of detecting a phase difference between the difference side current and the secondary side current in the microcontroller unit; A current ratio calculation step of comparing the value of the primary side current waveform as a reference in the current phase difference detecting step with the secondary side current waveform having the same waveform as the primary side current waveform in the microcontroller unit and calculating the current flow; And a non-error calculation step of calculating, by the microcontroller unit, an error of the current flow ratio calculated in the current flow ratio calculation step with respect to the nominal current flow ratio of the current transformer.

In the non-error measuring method of the current transformer according to the present invention, the phase difference is characterized in that the signal of the primary side current and the secondary side current of the current transformer is calculated from the zero crossing signal at the same time.

In addition, the non-error measurement device of the current transformer having a phase discrimination function capable of determining whether the phase of the voltage line and the instrument current period of the instrument according to the present invention for normal connection is different between the voltage line and the current period of the instrument current period in the live state. In the non-error measuring device of the current transformer for measuring the difference between the primary current and the secondary current of the current transformer having a phase discrimination function that can determine whether the connection is normal, the magnitude and phase signal of the primary current of the current transformer Primary side current detecting means for detecting; Voltage detection means for detecting a voltage phase signal of the voltage line; The phase difference between the signal detected by the primary side current detecting means and the voltage detecting means is calculated, and when the phase difference is in the in-phase range, the display unit displays the value of the phase difference or the "normal" in the in-phase range on the display unit. And a microcontroller unit for instructing the display unit to display the value of the phase difference exceeding the in-phase range or "inverted phase" when the phase difference exceeds the in-phase range.

In addition, the non-error measurement method of the current transformer having a phase discrimination function capable of determining whether the phase of the voltage line and the instrument current period of the instrument according to the present invention for normal connection is different between the voltage line and the instrument current period in the live state. In the non-error measuring method of the current transformer for measuring the error of the primary current and the secondary current of the current transformer having a phase discrimination function that can determine whether the connection is normal, the voltage of the primary current and voltage line of the current transformer A voltage / current phase difference detection step of detecting a phase difference of the microcontroller unit; If the phase difference detected in the voltage / current phase difference detection step is in the in-phase range, the phase difference value or "normal" within the in-phase range is displayed on the display unit, and the detected phase difference indicates the in-phase range. If exceeded, a phase difference display step of instructing the display portion to display the value of the phase difference or " reverse phase ".

As described above, the apparatus for measuring the error of the current transformer according to the present invention and the measuring method thereof have an effect of measuring the error of the current transformer in a live state in which a power meter and a current transformer are connected.

In addition, the non-error measuring apparatus and current measuring method of the current transformer according to the present invention has an effect that the measurement response of the error is very fast.

In addition, the non-error measuring apparatus and the measuring method of the current transformer according to the present invention has the effect of reducing the measurement error even if the measurement response of the error is very fast.

1 is a power measurement circuit diagram
2 is a waveform diagram illustrating a concept of a phase difference applied in the present invention.
3 is a block diagram illustrating the concept of a non-error measuring apparatus of the current transformer according to the present invention.
4 is a block diagram of an apparatus for measuring error of a current transformer according to the present invention;
5 is an operation flowchart of the non-error measuring apparatus of the current transformer according to the present invention.

The concept of the non-error measuring apparatus of the current transformer according to the present invention will be described with reference to the waveform diagram of FIG. 2 and the block diagram of FIG. 3.

2 is a waveform diagram illustrating a concept of a phase difference applied in the present invention, and FIG. 3 is a block diagram illustrating a concept of a non-error measuring apparatus of a current transformer according to the present invention.

In the current transformer 40 for the instrument, the primary side current and the secondary side current have a phase difference θ as shown in FIG. 2 due to the characteristics of the coil and the core.

In order to compare the magnitudes of the primary and secondary currents of the instrument current transformer 40 having a phase difference as described above, the effective value of the primary current and the secondary current are measured for a long time, for example, for 10 seconds. The current ratio can be calculated, but it takes a lot of time to measure the current ratio, and includes an error due to the phase difference between the primary current and the secondary current.

Therefore, in order to remove the error according to the phase difference between the primary side current and the secondary side current, the current flow ratio of the section where the current waveform on the primary side and the secondary current waveform are equal to each other may be measured. That is, the rms value of the value corresponding to the current waveform on the primary side (effective value of S1 in the first cycle) and the current waveform on the secondary side (effective value of S2 in the first cycle) in the current transformer having the waveform as shown in FIG. 2. Comparing with, the error due to the phase difference θ of the primary side current and secondary side current is completely eliminated.

Hereinafter, the concept of the apparatus for measuring the error of the current transformer according to the present invention will be described first.

In Fig. 3, reference numerals 110 and 120 denote primary sides for detecting primary side current signals and secondary side current signals of the instrument current transformers 40 (CT1, CT2, CT3) of the electric power measuring circuit shown in Fig. 1. Clamped current transformers and secondary-side clamped current transformers.

The primary clamp type current transformers 110 and C-CT1 and the secondary clamp type current transformers 120 and C-CT2 are current detectors having a tong shaped core similar to a hook meter for measuring current in live wires. Clamp the cores of the current transformers 40 (CT1, CT2, CT3) to the primary and secondary sides, respectively.

Signals generated from the clamped primary side clamp type current transformers 110 and C-CT1 and the secondary side clamp type current transformers 120 and C-CT2 are wired through shielded cables (not shown) so as to be shielded from external noise. It is input to the primary side phase detector 130 and the secondary side phase detector 140, respectively.

The signals detected by the phase detector 130 on the primary side and the phase detector 140 on the secondary side are synchronized by the synchronizer 135, and the phase difference detector 160 is based on the primary phase of the current transformer 40 for the instrument. The phase difference θ of the primary and secondary signals is detected.

In addition, the signal generated by the primary-side clamp current transformers 110 and C-CT1 obtains a signal (effective value of S1) corresponding to the magnitude of the primary current in the primary current detection unit 150, and the secondary clamp current transformer ( The signal generated at 120 and C-CT1 may obtain a signal (effective value of S2) corresponding to the magnitude of the secondary current from the secondary current detector 170. Here, the signal corresponding to the magnitude of the secondary side current has a phase difference θ between the primary side current signal and the secondary side current signal as described above, that is, the current corresponding to the secondary side current waveform corresponding to the primary side current waveform. Obtain a signal (effective value of S2) corresponding to the magnitude of.

The ratio of the primary side current and the secondary side current is calculated by calculating the effective value of the first cycle corresponding to the magnitude of the primary side current and the effective period of the first cycle corresponding to the magnitude of the secondary side current. The current flow ratio display unit 210 is displayed.

In addition, the error calculation unit 190 is a side of the current transformer 40 for the instrument by the nominal current flow ratio of the current transformer 40 for the instrument inputted through the input unit 220 and the current flow ratio calculated by the current flow ratio calculator 180. The flow rate rain error is calculated, and the calculated value of the current flow ratio rain error is displayed on the rain error display unit 230.

Hereinafter, a non-error measuring apparatus of the current transformer according to the present invention will be described in detail with reference to the block diagram of FIG. 4.

4 is a block diagram of the apparatus for measuring the error of the current transformer according to the present invention.

In Fig. 4, reference numerals 310 and 410 denote primary clamps for detecting the primary side current signal and the secondary side current signal of the instrument current transformer 40 (CT1, CT2, CT3) of the electric power measuring circuit as described above. The primary side signal input unit and the secondary side signal input unit 410 are inputted from the type current transformer and the secondary side clamp type current transformer to the non-error measuring apparatus of the current transformer according to the present invention through a shielded cable or the like.

In addition, reference numerals 320 and 420 are input filter units for removing noise included in the primary side signal and the secondary side signal of the current transformer 40 for the instrument by an external factor of the non-error measuring apparatus of the current transformer according to the present invention. Reference numerals 330 and 430 denote amplification of the signals filtered by the primary input filter unit 320 and the secondary input filter unit 420 to a size of a signal that can be processed by the analog-to-digital converter (ADC) of the microcontroller unit. Reference numerals 340 and 440 denote primary output filters and secondary outputs for removing noise included in signals output from the primary amplifier 330 and the secondary amplifier 430 caused by an internal circuit. 350 and 450, a primary side zero crossing pickup unit and a secondary side zero crossing pickup unit that output a voltage signal (digital signal) when a sinusoidal signal crosses a zero potential. The.

Also, reference numerals 370 and 470 denote analog-to-digital converters for converting analog signals output from the output filter units 340 and 440 into digital signals, and reference numeral 500 denotes zero crossing pickup units 350 and 450. The phase difference θ of the primary and secondary signals is detected (detected delay times of the primary and secondary signals) based on the primary phase from the signals inputted from It is a micro-controller unit that functions as the error calculator 190 and outputs the calculated current ratio and the error to the display unit 210 and 230 and receives information input by the user through the input unit 220. .

Hereinafter, the operation of the apparatus for measuring the error of the current transformer according to the present invention will be described with reference to FIGS. 4 and 5.

5 is an operation flowchart of the rain error measuring apparatus of the current transformer according to the present invention.

The non-error measuring apparatus of the current transformer according to the present invention "ON" by the user (S10), and inputs the nominal current ratio of the current transformer 40 for the instrument to be measured through the input unit 220 (S20).

In addition, the user may clamp the clamps of the primary clamp type current transformers 110 and C-CT1 to the primary side wires of the instrument current transformer 40 and the clamps of the secondary side clamp type current transformers 120 and C-CT1 to the instrument current transformers 40. Fastening to each of the secondary wire of the () (S30).

As described above, the respective signals inputted to the primary side signal input unit 310 and the secondary side signal input unit 410 have noises removed from the primary side input filter unit 320 and the secondary side input filter unit 420, respectively, and thus the primary side amplifiers. 330 and the secondary amplifier 430.

The zero potential is detected from each signal amplified by the primary amplifier 330 and the secondary amplifier 430, and sent to the microcontroller unit 500. In the microcontroller unit 500, the phase difference (θ) of the secondary signal, The delay time is calculated (S50).

The microcontroller unit 500 detects signals corresponding to the first period of the primary side signal and the first period of the secondary side signal having a phase difference of the primary side signal and θ (S60), and changes from each value detected in step S60. The current ratio is calculated (S70) and displayed on the display unit 210, and the error of the current ratio calculated in step S70 is calculated and displayed on the display unit 230 with respect to the nominal current ratio inputted through the input unit 220 in step S20. .

The primary signal and the secondary signal input to the microcontroller unit 500 remove noises contained in the circuit by the output filter parts 340 and 440 amplified by the amplifiers 330 and 430. After the conversion, the signals are converted into digital signals by the analog-digital converters 370 and 470.

Although the period of the waveform has been described as one period in the above embodiment, the present invention is not limited thereto, and the current ratio may be calculated for a plurality of periods (for example, 10 cycles) in order to reduce the error of the current ratio calculation. However, calculating the current ratio over a long period of time (more than 0.5 seconds) is contrary to the object of the present invention to compensate for the phase difference [theta].

Hereinafter, the operation of the non-error measuring apparatus of the current transformer having a phase discrimination function that can determine whether the phase of the voltage line and the instrument current period of the instrument according to the present invention is normally connected will be described with reference to FIGS.

Probe 310 at the metering terminal inlet voltage terminal in synchronization with the time of the output current phase angle of the primary-side clamp type current transformer 110 (CT1) that detects current at an arbitrary voltage line as a reference for non-error measurement of the instrument current transformer 40. ) Is compared with the current phase angles of the primary side clamp type current transformers 110 and CT1 obtained by direct contact or by detecting an electric field or magnetic field with an electric field detector or a magnetic field detector on an insulated wire.

When the phase difference range of the signal between the primary clamp current transformer 110 and the probe 310 is in phase (for example, within ± 1 °), it may be determined whether the primary clamp current transformer 110 is in phase between the phase and the voltage line clamped. Can be.

That is, it is possible to check the presence or absence of incorrect wiring between phases at the same time as measuring the error of the current transformer.

As a method, a case of measuring whether or not incorrect wiring between phases of the instrument current transformers 40 and CT1 attached to the R phase of the low-voltage three-phase four-wire power amount measurement circuit will be described as an example.

1) Primary-side clamp type current transformers 110 and C-CT1 to the K terminal of the R-phase instrument current transformers 40 and CT1 and Secondary-side clamp type current transformers 120 and C to the k terminal of the current transformers 40 and CT1. CT2) is engaged in step S30 to detect the phase of the current (S40).

2) A voltage probe (V. Probe) 310 is contacted to the voltage line connected to the P1 terminal of the electricity meter 60 (S130) to detect a signal from the voltage line (S140).

3) The phase of the voltage signal detected in the step S140 corresponding to the time when the detection signal of the current of the R-phase instrument current transformer 40 (CT1) detected in the step S40 and the phase reference of the signal are synchronized (S150). The phase difference is calculated by the controller unit 500 (S160).

4) If the phase calculated in step S160 is in the in-phase range, the display unit displays the value of the phase difference or "normal" within the in-phase range on the display unit. If the phase difference exceeds the in-phase range, the display unit The value of the phase difference exceeding the range of the in-phase or " reverse phase " is displayed on the display unit (S 170). If the phase difference exceeds the in-phase range, the difference is about + 120 ° or -120 °.

Comparing the voltage signal and the signal of the primary (k-terminal) current of the instrument current transformer 40 in the above embodiment may be defective in the instrument current transformer 40 because the instrument current transformer 40 in use may be defective. The comparison is based on the output secondary current because an error can occur.

The non-error measuring apparatus and current measuring method of the current transformer according to the present invention can be used to measure the error of the current transformer for current meter or other instrument current transformer even in the live state.

10: power 20: load
30 instrument transformer 40 instrument current transformer
50: test terminal block 60: power meter
310: primary signal input part of the current transformer 320, 420: input filter part
330, 430: amplifier 340, 440: output filter
410: secondary signal input of the current transformer 350, 450: zero crossing pickup
500: Micro Controller Unit

Claims (9)

In the non-error measuring device of the current transformer for measuring the error of the primary current and secondary current of the current transformer in the live state in which the wattmeter and the current transformer are connected,
Primary side current detection means for detecting magnitude and phase signals of the primary side current of the current transformer;
Secondary current detection means for detecting magnitude and phase signals of the secondary current in the current transformer;
The phase difference of the signal detected by the primary side and secondary side current detecting means is calculated, and the value of the waveform of the secondary side current corresponding to the waveform of the primary side current and the value of the waveform detected at the primary side current according to the phase difference. A microcontroller unit for calculating a current ratio, the ratio of the calculated current ratio to the nominal current ratio of the current transformer;
And a display unit for displaying the phase difference and the non-error value.
The method of claim 1,
And said primary and secondary current detection means comprises a zero crossing pickup. The method of claim 1,
The magnitude of the waveform of the primary side and secondary side currents are non-error measurement apparatus of the current transformer, characterized in that the RMS value.
4. The method according to claim 2 or 3,
And detecting the primary and secondary currents using a clamp current transformer.
5. The method of claim 4,
The signal detected by the clamp-type current transformer is amplified by the amplifier through an input filter, the amplified signal is input to the microcontroller unit through an output filter for removing noise generated in the circuit. Measuring device.
In the non-error measuring method of the current transformer for measuring the error of the primary current and the secondary current of the current transformer in the live state,
A current phase difference detecting step of detecting a phase difference between a primary side current and a secondary side current of the current transformer in a microcontroller unit;
A current ratio calculation step of comparing the value of the primary side current waveform as a reference in the current phase difference detecting step with the secondary side current waveform having the same waveform as the primary side current waveform in the microcontroller unit and calculating the current flow;
And a non-error calculation step of calculating, by the microcontroller unit, an error of the current ratio calculated in the current flow ratio calculation step with respect to a nominal current flow ratio of the current transformer.
The method according to claim 6,
And the phase difference is calculated from a zero crossing signal at the same time as the signals of the primary side current and the secondary side current of the current transformer.
In the non-error measuring device of the current transformer for measuring the non-error of the primary current and secondary current of the current transformer of the current transformer having a phase discrimination function that can determine whether the phase of the voltage line and the instrument's current flow period in the live state is normally connected,
Primary side current detection means for detecting magnitude and phase signals of the primary side current of the current transformer;
Voltage detection means for detecting a voltage phase signal of the voltage line;
The phase difference between the signal detected by the primary side current detecting means and the voltage detecting means is calculated, and when the phase difference is in the in-phase range, the display unit displays the value of the phase difference or the "normal" in the in-phase range on the display unit. And a microcontroller unit for indicating to the display unit that the phase difference exceeds the range of the in-phase, and to display the value of the phase difference exceeding the in-phase range or "inverted phase" on the display unit. Non-error measuring device of current transformer with discriminating function.
In the non-error measuring method of the current transformer for measuring the non-error of the primary current and secondary current of the current transformer of the current transformer having a phase discrimination function that can determine whether the phase of the voltage line and the instrument's current flow period in the live state is normally connected,
A voltage / current phase difference detection step of detecting, by a microcontroller unit, a phase difference between the primary side current of the current transformer and the voltage phase signal of the voltage line;
If the phase difference detected in the voltage / current phase difference detection step is in the in-phase range, the phase difference value or "normal" within the in-phase range is displayed on the display unit, and the detected phase difference indicates the in-phase range. And a phase difference display step of instructing the display unit to display the value of the phase difference or "reverse phase" when the phase difference is exceeded.

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