KR20140021329A - Electronic watt-hour meter - Google Patents

Abstract

An electronic watt-hour meter is disclosed. The electronic watt-hour meter including a voltage sensor for measuring an inputted voltage, and a current sensor for measuring an inputted current comprises; a measuring unit which calculates and measures a voltage size, a current size, a voltage and current phase difference, active power, reactive power, and a power factor; a storage unit which stores a voltage size factor for compensating the voltage size, a current size factor for compensating the current size, a voltage/current phase difference factor for compensating the phase difference of the voltage and current, and a current direction factor for compensating a current direction; a first compensation unit which compensates the voltage size measured in a voltage sensor using the voltage size factor; a second compensation unit which compensates the current size measured in a current sensor using the current size factor; and a third compensation unit which compensates a phase difference between the voltage and current compensated in the first and second compensation units using the voltage/current phase difference factor. The third compensation unit compensates a direction of the current compensated in the second compensation unit using the current direction factor. [Reference numerals] (11) Voltage sensor; (12) Current sensor; (14) Voltage size factor storage unit; (15) Current size factor storage unit; (18) Voltage/ current phase difference factor storage unit; (19) Current direction factor storage unit; (21) Metering unit; (AA) Voltage input; (BB) Current input; (CC) Voltage; (DD) Current

Description

[0001] ELECTRONIC WATT-HOUR METER [

The present invention relates to an electronic wattmeter, and more particularly to an electronic wattmeter used in a power system.

Electronic meters measure voltage and current, and measure power using the measured voltage and current. In general, an electronic wattmeter uses a voltage sensor and a current sensor to measure the magnitude and sign of voltage and current.

Current sensors include Current Transformet (CT), Rogowski Coil, and Shunt resistors.These current sensors have a positive or negative sign depending on the direction of the current being measured. Measure with negative (-).

Therefore, when the current sensor is not correctly installed in the electronic wattmeter, the current sensor measures the current differently from the direction of the current flowing in the electronic wattmeter, so that the sign of the measured current may be different.

In this case, the electronic wattmeter does not accurately measure the power, etc., and in order for the user to accurately measure the power, the user needs to check the direction of the current flowing through the electronic wattmeter and correct the sign of the current.

The technical problem to be solved by the present invention is to provide an electronic wattmeter that stores the direction of the current in the electronic wattmeter, accurately measures the sign of the current, regardless of the direction of installing the current sensor in the electronic wattmeter, to accurately measure the power, etc. It is.

In order to solve the above technical problem, the electronic wattmeter including a voltage sensor for measuring the input voltage, the current sensor for measuring the input current, voltage magnitude, current magnitude, voltage and current phase difference, active power, reactive power And a metering unit for calculating and measuring a power factor, a voltage magnitude factor compensating for the voltage magnitude measured by the metering factor, a current magnitude factor compensating the current magnitude, and a voltage / current phase difference factor compensating for the phase difference between the voltage and the current. And a storage unit to store a current direction factor for compensating the current direction, a first compensator for compensating the magnitude of the voltage measured by the voltage sensor using the voltage magnitude factor, and the magnitude of the current measured by the current sensor. The difference between the second compensator compensated using the current magnitude factor, the voltage compensated by the first compensator, and the current compensated by the second compensator. And a third compensator for compensating a phase difference using the voltage / current retardation factor and compensating a direction of the current compensated by the second compensator using the current direction factor.

The storage unit of the present invention, the storage unit, characterized in that for setting and storing the current direction factor so that the active power always has a positive sign (+).

The third compensator of the present invention compensates +1 which is a current direction factor stored in the storage unit when the metering unit measures the positive power having a positive sign, or the metering unit has the effective sign having a negative sign. When the power is measured, the current direction factor stored in the storage unit is -1.

The present invention as described above, by blocking the metering error of the electricity meter can be generated by installing the current sensor of the electricity meter different from the set direction, accurate metering is possible.

1 is an example of an electronic wattmeter in accordance with the present invention.
2 is a flow chart for performing calibration in manufacturing an electronic wattmeter according to the present invention.
Figure 3 is an exemplary view showing the procedure of the metering process of the electronic electricity meter according to the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Terms including ordinals such as first, second, etc. may be used to describe various elements, but the elements are not limited by such terms. These terms are used only to distinguish one component from another.

When a component is said to be 'connected' or 'connected' to another component, it may be directly connected to or connected to that other component, but other components may be present in between. It should be understood that. On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a component, or a combination thereof, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Wherein like reference numerals refer to like elements throughout.

1 is an exemplary view of an electronic wattmeter 1 according to the present invention.

Referring to FIG. 1, the electronic power meter 1 according to the present invention includes a voltage sensor 11, a current sensor 12, an analog digital converter (ADC) 13, and a voltage magnitude factor storage unit 14. ), The current magnitude factor storage unit 15, the first compensation unit 16, the second compensation unit 17, the voltage / current phase factor storage unit 18, the current direction factor storage unit 19, the third compensation The part 20 and the metering part 21 are included.

The voltage sensor 11 measures the voltage input to the electronic wattmeter 1, and the current sensor 12 measures the current input to the electronic wattmeter 1.

The current sensor 12 may be, for example, a current transformer (CT), a Rogowski coil, and a shunt resistor, but the present invention is not limited thereto. Current sensors can be used. The current sensor 12 measures the sign of the current as positive (+) or negative (-) according to the direction of the current.

The voltage and current measured by the voltage sensor 11 and the current sensor 12 are analog signals, and the ADC 20 converts them into digital signals.

The voltage magnitude factor storage unit 14 stores the voltage magnitude to be compensated by the first compensation unit 16.

The first compensator 16 compensates the magnitude of the voltage measured by the voltage sensor 11 by using the voltage magnitude factor stored in the voltage magnitude factor storage unit 14.

The current magnitude factor storage unit 15 stores the current magnitude to be compensated for by the second compensation unit 17.

The second compensator 17 compensates for the magnitude of the current measured by the current sensor 12 by using the current magnitude factor stored in the current magnitude factor storage unit 15.

The metering unit 21 calculates and measures the voltage magnitude, the current magnitude, the voltage / current phase difference, the active power, the reactive power, and the power factor.

In an embodiment of the method in which the first compensation unit 16 compensates the magnitude of the voltage, an analog signal having a voltage of 220 V (volt) is output as the digital signal 100 through the ADC 13, and the metering unit 21 is provided. In case of weighing, it is assumed to weigh correctly.

When the analog signal having the voltage of 220V (volt) is output as the digital signal 90, the metering unit 21 cannot measure accurately. Therefore, if the output value is multiplied by the calibration factor 100/90, the metering unit 21 is the digital signal 100. The first compensation unit 16 may compensate for the magnitude of the voltage by using 100/90 as a calibration factor.

Since the method of compensating the magnitude of the current is the same as the method of compensating the magnitude of the voltage, description thereof is omitted.

The current direction factor storage unit 19 stores the current direction to be compensated for by the third compensation unit 20.

The third compensation unit 20 compensates the direction of the current compensated by the second compensation unit 17 by using the current direction factor stored in the current direction factor storage unit 19. Therefore, even when the current sensor 12 is not correctly installed in the electronic wattmeter 1, the sign of the current can be measured accurately.

In one embodiment of the method for compensating the current direction, when the active power metered by the electronic meter 21 when manufacturing the electronic wattmeter 1 has a positive sign, the current sensor 12 is correctly installed. The current direction factor is set to +1.

If the effective power measured by the metering unit 21 has a negative sign, it is determined that the current sensor 12 is not installed correctly, and the current direction factor is set to -1.

Based on the current direction factor set in the current direction factor storage unit 19, if the metering unit 21 measures the active power having a positive sign, the current stored in the current direction factor storage unit 19 The third compensation unit 20 compensates for the direction factor +1. That is, the active power is multiplied by +1 so that the active power has a positive sign.

However, when the metering unit 21 measures the active power having a negative sign, the third compensation unit 20 compensates for the current direction factor -1 stored in the current direction factor storage unit 19. That is, the active power is multiplied by -1 so that the active power has a positive sign.

As a result, it is possible to always measure the effective power with a positive sign, and the electronic wattmeter 1 can accurately output power and the like regardless of the correct installation of the current sensor 12.

If the current can be distinguished by a positive (+) sign or a negative (-) sign, it can be used as a current direction factor, so it is obvious that various methods of current direction factor can be used.

The voltage / current phase factor storage unit 18 stores the voltage / current phase difference factor to be compensated for by the third compensation unit 20.

The third compensator 20 compensates for the phase difference between the voltage and the current by using the voltage and the current compensated by the first compensator 16 and the second compensator 17, respectively.

As an embodiment of the method in which the third compensation unit 20 compensates the phase difference between the voltage and the current, when the electronic wattmeter 1 outputs the phase difference between the voltage and the current at 60 ° (Degree), the metering unit 21 Assume accurate metering. When the electronic wattmeter 1 outputs a phase difference between voltage and current at 58 °, it compensates using a voltage / current phase factor to output a phase difference between voltage and current at 60 °.

Based on the compensated voltage and current, the electronic metering unit 21 can measure the correct voltage size, current size, voltage / current phase difference, power, and the like, and the electronic wattmeter 1 can also output accurate metering values. .

2 is an exemplary view showing a procedure for performing calibration when manufacturing the electronic wattmeter 1 according to the present invention.

Referring to FIG. 2, a voltage and a current of a calibration condition are input to the electronic wattmeter 1 (S11). That is, the electronic wattmeter 1 inputs a voltage and a current to the electronic wattmeter 1 so that the electronic wattmeter 1 can output voltage, current, voltage / current phase difference, power, and the like to a specific value.

The metering unit 21 calculates a voltage magnitude, a current magnitude, a voltage / current phase difference, a current direction, and a power by using each calibration factor, and based on the calculated result, each calibration factor to be stored in the electronic wattmeter 1. Determine and store (S12).

In detail, before performing calibration, the electronic electricity meter 1 has each calibration factor in a default state.

The metering unit 21 measures the voltage, current, phase difference between the voltage and the current, power, and the like using the calibration conditions of the voltage and the current under the calibration conditions.

When the meter 21 accurately measures a specific value such as voltage magnitude, current magnitude, phase difference between the voltage and current, and power, each calibration factor in the default state is stored as a calibration factor of the electronic power meter 1.

However, if the meter cannot be accurately metered, each calibration factor in the default state is modified and stored in the electronic power meter 1 such that the voltage magnitude, the current magnitude, the phase difference between the voltage and the current, the power, and the like become specific values.

In other words, each calibration factor is stored in the electronic wattmeter 1 so that the electronic wattmeter 1 accurately outputs voltage, current, phase difference between the voltage and current, power, and the like.

Calibration is completed when the electronic power meter 1 stores each calibration factor (S13).

As shown in FIG. 1, the calibration factor includes a voltage magnitude factor, a current magnitude factor, a voltage / current phase factor, and a current direction factor.

3 is an exemplary view showing a procedure of the weighing process of the electronic watt hour meter 1 according to the present invention.

Referring to FIG. 3, a voltage and a current are input to the electronic power meter 1 (S21).

The electronic electricity meter 1 loads each calibration factor (S22). The calibration factor is a voltage magnitude factor, a current magnitude factor, a voltage / current phase factor and a current direction factor.

The metering unit 21 calculates and measures the voltage size, the current size, the active power, the reactive power, and the power factor using the loaded calibration factors (S23).

In detail, the voltage size measured by the voltage sensor 11 is compensated by the first compensation unit 16, and the current size measured by the current sensor 12 is compensated by the second compensation unit 17.

The phase difference between the voltage and current compensated by the first compensator 16 and the second compensator 17 is compensated by the third compensator 20, and the direction of the current compensated by the second compensator 17 is 3, the compensation unit 20 compensates.

The metering section 21 includes a first compensation section 16 and a second compensation section 17. The effective power, reactive power, and power factor are measured based on the voltage size, current size, voltage / current phase difference, and current direction compensated by the third compensation unit 20.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined by the following claims.

1: electronic power meter 11: voltage sensor
12 current sensor 13 ADC
14: voltage size factor storage unit 15: current size factor storage unit
16: first compensation unit 17: second compensation unit
18: voltage / current phase factor storage unit 19: current direction factor storage unit
20: third compensation unit 21: metering unit

Claims (3)

In the electronic wattmeter comprising a voltage sensor for measuring the input voltage, a current sensor for measuring the input current,
A metering unit for calculating and measuring voltage magnitude, current magnitude, voltage and current phase difference, active power, reactive power, and power factor;
A voltage magnitude factor that compensates for the voltage magnitude, a current magnitude factor that compensates for the current magnitude, a voltage / current phase difference factor that compensates for the phase difference between the voltage and current, and a current direction factor that compensates for the current direction A storage unit for storing;
A first compensator for compensating the magnitude of the voltage measured by the voltage sensor using the voltage magnitude factor;
A second compensator for compensating the magnitude of the current measured by the current sensor by using the current magnitude factor; And
The phase difference between the voltage compensated by the first compensator and the current compensated by the second compensator is compensated using the voltage / current phase difference factor, and the direction of the current compensated by the second compensator is the current direction factor. Electronic electricity meter including a third compensation to compensate using.
The electronic power meter of claim 1, wherein the storage unit sets and stores the current direction factor such that the active power always has a positive sign.
3. The method of claim 2, wherein the third compensator compensates for +1, which is a current direction factor stored in the storage unit, when the metering unit measures the active power having a positive sign, or the metering unit displays a negative sign. The electronic power meter having a compensation of -1, which is a current direction factor stored in the storage unit, when the effective power is measured.

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