KR200144067Y1 - Current converting circuit for complex apparatus of multi-functional electric power applied - Google Patents

Abstract

The present invention relates to the current conversion circuit of the multi-function power supply-type complex meter, integrating the current signal input from the transformer in the integrator to output a negative voltage proportional to the input current and again in proportional to the input current in the inverting comparator By outputting with a positive voltage, it is possible to read the accurate amount of active power, ground reactive power, and phase reactive power.

Description

Current conversion circuit of multifunction power supply

1 is a block diagram showing the configuration of the power amount detection unit of the power supply-demand complex meter.

2 is a circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

4: current conversion circuit 5, 13, 16: power-to-voltage conversion circuit

OP1 ~ OP6: Comparator C1 ~ C6: Capacitor

R1 ~ R3: Resistance

The present invention relates to a current conversion circuit of a multi-function power supply and demand multi-function device, in particular, by converting the current signal detected through the current transformer in the three-phase wire into a voltage proportional to the input voltage, the accurate reading of the effective power and the jising reactive power The present invention relates to a current conversion circuit of a multifunction power supply multi-function instrument.

In general, it is well known that the integrated power meter is to measure the effective power amount to calculate the charge while accumulating and displaying the sum of the power consumed within a certain time.

In addition, a regular wattmeter is used to measure the effective power amount, and a precision wattmeter is used for precise measurement of the daily power amount and the maximum demand power, and a time switch and a reactive power meter are additionally installed to measure the reactive power amount by power factor measurement. It should be.

Therefore, it is necessary to use a multi-function power supply complex meter that integrates ordinary electricity meter, precision electricity meter, time switch, and reactive electricity meter, and to inform externally of the measurement value and operation process by complicated internal configuration, and the voltage detected by the instrument transformer. Since the effective power, ground reactive power, and phase reactive power are calculated by multiplying the signal and current signal detected by the current transformer, the current signal detected by the current transformer should be converted to the correct voltage proportional to the input current.

Accordingly, an object of the present invention is to provide a current conversion circuit of a multi-function power supply-complex unit which converts a current signal detected by a current transformer into a voltage proportional to an input current.

The present invention for achieving the above object by integrating the current signal input from the transformer in the integrator while outputting a negative voltage proportional to the input current and by outputting a positive voltage proportional to the input current in the inverting comparator It is to make it possible to read the accurate amount of active power, ground reactive power, and reactive reactive power.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a voltage signal proportional to a load voltage flowing through a three-phase line in the first to third transformers and obtaining a current signal proportional to current consumption flowing through the three-phase line in the first to third current transformers. Figure 3 shows the configuration of the power detection unit of the multi-function power supply-complexing instrument which calculates the correct values of the active power, the ground reactive power, and the reactive reactive power, using the three-phase line not shown in the drawing. The power signal detection unit of the multi-function power supply and multi-function multimeter for obtaining the effective power by using the current signal in proportion to the current consumption flowing through the three-phase wire as a current transformer to obtain a proportional voltage signal As shown in the drawing, the voltage signal of the transformer for the first to third instruments is input and the first balance adjusting unit 1 and the first Complementary compensators (2) are provided, respectively, the first voltage conversion circuit (3) for outputting the voltage for the active power, and the current to convert the current value from the first to the third current transformer to a voltage proportional to the input current and output A multiplier multiplies the voltage for the effective power input from the conversion circuit 4 and the first voltage conversion circuit 3 and the current conversion circuit 4 with the voltage, adds and integrates the voltage into a voltage signal proportional to the effective power. A first voltage-frequency conversion circuit 6 for receiving and integrating a voltage signal from the first power-voltage conversion circuit 5 and the first power-voltage conversion circuit 5 and converting a pulse frequency; The phase of the voltage input from the transformer for the first to third instruments by 90 degrees to delay the phase (Phase) is converted to output the abnormal circuit (7) and the input from the abnormal circuit (7) The second equilibrium adjusting unit 8 and the second phase compensating unit 9 correspond to the phase-converted voltage signal. A second voltage conversion circuit 10 provided to each of the phase reactive power voltage and the ground reactive power voltage, and a power frequency that is synchronized with the power frequency by receiving a voltage signal of which phases are converted from the abnormal circuit 7. The frequency detection circuit 11 outputs the synchronization signal and the power supply frequency synchronization signal from the frequency detection circuit 11 as a clock signal, and divides and integrates the oscillation frequency signal from the oscillation circuit 12a to input frequency. Multiplying the frequency fluctuation detecting circuit 12 outputting the voltage signal proportional to the ground reactive power voltage input from the second voltage converting circuit 10 and the voltage from the current converting circuit 4; The second power-voltage conversion circuit 13 which adds, integrates and converts the voltage into proportional to the reactive power, and a voltage signal proportional to the frequency input from the frequency variation detection circuit 12 is received. A first frequency error correction circuit 14 for correcting the voltage from the second power-voltage conversion circuit 13 and outputting a voltage signal proportional to the ground power of the reactive power, and the first frequency error correction circuit 14 A second voltage-frequency conversion circuit 15 for receiving the voltage signal from the second signal, integrating the voltage signal, and converting the pulse frequency into a pulse frequency; A third power-voltage converting circuit 16 for multiplying, adding, and integrating the voltage from the converting circuit 4 into a voltage proportional to the reactive power, and a frequency input from the frequency variation detecting circuit 12; A second frequency error correction circuit 19 for correcting a voltage from the third power-voltage conversion circuit 16 while receiving a voltage signal proportional to and outputting the voltage signal in proportion to the advance power of the reactive power; The second frequency error correction arc (17) A third voltage-frequency conversion circuit 18 for integrating the input voltage signal and converting the signal into a pulse frequency, and pulses from the first to third voltage-frequency conversion circuits 6, 15 and 18 described above. When operating by the system clock while receiving the frequency, it stores the counting and weighing value of the metering pulse signal for the precision meter, the present value of the metering signal for the maximum demand meter, the memory of the cumulative value, the calendar clock function, the load survey Central control unit to perform functions, data communication function, self-test function, maximum demand power recovery function, monthly power factor calculation function, warning function, measurement value, record value, set value send / receive function, and various set value change function by communication It is composed of (19).

2 shows the configuration of the current conversion circuit, in which the current signal supplied from the first current transformer through the capacitor C1 is negatively fed back through the resistor R1 and the capacitor C2 in the comparator OP1, and thus the resistor R1. And a negative voltage which is integrated with the integral value of the capacitor C2, and is inverted by the comparator OP2 to which the ground voltage is applied to the non-inverting input terminal. 1 is input to the power-voltage conversion circuit 5, the current signal supplied from the second current transformer through the capacitor (C3) is negative feedback through the resistor (R2) and the capacitor (C4) in the comparator (OP3) resistance ( R2) is integrated to the integral value by the capacitor (C4) and output as a negative voltage, and is inverted by the comparator (OP4) to which the ground voltage is applied to the non-inverting input terminal, and is output as a positive voltage. Thereby input to the second power-voltage conversion circuit 13, and the third current transformer The current signal supplied through the condenser C5 is negatively fed back through the resistor R3 and the capacitor C6 in the comparator OP5 and integrated into the integral value of the resistor R3 and the capacitor C6 (negative ) Is inverted by the comparator OP6 to which the ground voltage is applied to the non-inverting input terminal, and is outputted to the third power-voltage conversion circuit 16 by outputting a positive voltage.

The current conversion circuit of the power supply / demand system of the present invention configured as described above is provided with the first balance adjusting unit 1 and the first phase compensator 2 when the voltage signals of the transformers of the first to third instruments are input. The first voltage conversion circuit 3 outputs the voltage for the effective power, and the current conversion circuit 4 which receives the current signal from the first to third current transformers converts the voltage into a voltage proportional to the input current. .

That is, the current signals from the first to third current transformers are respectively input to the comparators OP1, OP3, and OP5, respectively, by the resistors R1, R2, R3, and capacitors C2, C4, C6. Integrates to the integral value and is output as a negative voltage proportional to the input current to be input to the first to third power-voltage conversion circuits 5, 13 and 16. The power is again applied to the inverting input terminals of the comparators OP2, OP4, and OP6 to which the ground voltage is applied to the non-inverting input terminal. (5) (13) (16) to be inputted so that the amount of active power, ground reactive power, and reactive reactive power can be read with accurate values.

Therefore, in the first power-voltage conversion circuit 5 which receives the voltage for the effective power and the voltage from the first voltage conversion circuit 3 and the current conversion circuit 4, these voltage values are multiplied, added and integrated to the effective power. Convert to a voltage signal proportional to.

The first voltage-frequency conversion circuit 6, which receives the voltage signal from the first power-voltage conversion circuit 5, integrates it and converts it into a pulse frequency and outputs the converted pulse frequency.

The abnormal circuit 7 receiving the voltage signal from the transformer for the first to third instruments delays the phase by 90 ° so that the phase-converted voltage signal is input to the second voltage conversion circuit 10. Thus, the second balance adjusting unit 8 and the second phase correcting unit 9 are provided to output the reactive reactive power voltage and the ground reactive power voltage, respectively.

The frequency detecting circuit 11, which receives the phase-converted voltage signal from the abnormal circuit 7, outputs a clock signal to the frequency variation detecting circuit 12 as a power frequency synchronization signal synchronized with the power frequency, so that the oscillation circuit 12a Divide and integrate the oscillation frequency signal from) to output as a voltage signal proportional to the input frequency.

That is, the frequency detection circuit 11 receives the voltage signal detected by the instrument transformer in a state in which the phase is delayed by 90 degrees in the abnormal circuit 5, and the two voltage signals are respectively applied to the resistor R1 ( R2) and the capacitors C1 and C2 are input to both ends of the comparator Com so that the output terminal detects a power frequency synchronization signal corresponding to a phase difference of 60 Hz by the phase difference between the two voltage signals.

The second power-voltage changing circuit 13, which receives the ground reactive power voltage from the second voltage converting circuit 10 and the voltage from the current converting circuit 4, respectively, multiplies and adds these voltage values. Integrate the voltage into a voltage proportional to the reactive power.

Therefore, the first frequency error correction circuit 14, which receives a voltage signal proportional to the frequency input from the frequency variation detection circuit 12, corrects the voltage from the second power-voltage conversion circuit 13. A voltage signal proportional to the ground power of the reactive power is output to the second voltage-frequency conversion circuit 15 to be integrated to convert the pulse frequency into a pulse frequency.

In the third power-voltage conversion circuit 16 which receives the advance reactive power voltage from the second voltage conversion circuit 10 and the voltage from the current conversion circuit 4, these voltage values are multiplied and added. And convert the signal into a voltage signal proportional to the reactive power and output it to the second frequency error correction circuit 17 to correct the voltage from the third power-voltage conversion circuit 16 while proportional to the advance power of the reactive power. Output as a voltage signal.

In addition, the third voltage-frequency conversion circuit 18 receiving the voltage signal from the second frequency error correction circuit 17 integrates it and converts it into a pulse frequency to convert the first to second voltage-frequency conversion circuits. (6) It transmits to the central control unit 19 together with the pulse frequency of (15) to store the counting pulse value and the measured value of the metering pulse signal for the precision electricity meter, the present value, the maximum value, the cumulative value of the metering signal for the maximum demand meter, and the last year. Calendar watch function, load survey function, data communication function, self-test function, maximum demand power return function, monthly power factor calculation function, warning function, meter value, record value, set value transmission / reception function, communication Perform various setpoint change functions.

Therefore, according to the current conversion circuit of the multifunctional power supply / complex unit of the present invention, current signals are input from the first to third current transformers to the comparators OP1, OP3, and OP5, respectively, so that the resistors R1, R2, ( The first to third power-voltage conversion circuits 5 and 13 (integrated to the integral value by R3) and capacitors C2, C4 and C6, respectively, with negative voltages proportional to the input current. 16), and the positive voltages inverted by the comparators OP2, OP4, and OP6 to which the ground voltage is applied to the non-inverting input terminal, respectively, are first to third voltage-current conversions. It is input to the circuits 5, 13, and 16 so that the effective amount of power, the amount of ground reactive power, and the amount of reactive reactive power can be read with accurate values.

Claims (1)

The current of the multi-function power supply-complex instrument, which receives the current value of the first to third current transformers and transfers the current value to the first to third power-voltage conversion circuits 5, 13, and 16 in proportion to the input voltage. In the conversion circuit, the current signal supplied from the first current transformer through the capacitor (C1) is negative feedback through the resistor (R1) and the capacitor (C2) in the comparator (OP1) by the resistor (R1) and the capacitor (C2) The first power-voltage conversion circuit 5 is inverted by a comparator OP2 which is integrated with an integral value and outputted as a negative voltage and then again applied with a ground voltage to a non-inverting input terminal. The current signal supplied from the second current transformer through the condenser C3 is negatively fed back through the resistor R2 and the condenser C4 in the comparator OP3 by the resistor R2 and the condenser C4. It is integrated as an integral value and output as a negative voltage, and then ground voltage is returned to the non-inverting input terminal. Inverted by the applied comparator OP4 to be input to the second power-voltage conversion circuit 13 at a positive voltage, and the current signal supplied through the capacitor C5 from the third current transformer is the comparator OP5. ) Is returned through resistor R3 and condenser C6, integrated to the integrated value by resistor R3 and condenser C6, output as negative voltage, and ground voltage is applied to non-inverting input again. Inverted by the comparator (OP6) is a current conversion circuit of the multifunction power supply multi-function multimeter characterized in that configured to be input to the third power-voltage conversion circuit (16) with a positive voltage.