KR19990024440A - Phase voltage error detection device for three-phase AC power - Google Patents

Abstract

The present invention relates to a phase voltage error detection device for a three-phase AC power supply, and a three-phase AC power supply phase voltage error detection device for detecting an error in each phase voltage of the three-phase AC power supply of a, b, and c, An AC / DC converter for converting three-phase AC power into a DC voltage having a predetermined level and supplying the DC voltage; A phase voltage error detection unit connected to each phase of a three-phase AC power source and outputting a value below a predetermined reference voltage when the voltage is lowered in at least one of a, b, and c phases; A power generation unit generating power more than a predetermined level when a value greater than or equal to a predetermined reference voltage is input from the phase voltage error detecting unit and not generating power if less than a predetermined reference voltage; And a display unit which turns on the display when the power generation unit generates a power higher than a predetermined level and turns off the display when the power is not generated.

By using the three-phase AC power phase voltage error monitoring apparatus according to the present invention, the accuracy and efficiency of phase voltage error detection is increased and the cost of construction is reduced.

Description

Phase voltage error detection device for three-phase AC power

The present invention relates to a device for monitoring a power supply abnormality, and more particularly, to a phase voltage error detection device of a three-phase AC power supply for monitoring the disconnection and voltage drop state that may occur when the three-phase AC power supply. will be.

Conventionally, as a phase error monitoring device for monitoring the disconnection and voltage drop state that may occur when supplying a three-phase AC power supply, a device for monitoring the voltage of each phase at a constant cycle using a microcomputer after lowering the voltage of each phase to low pressure Alternatively, an electronic device in which error detection is performed using a voltage difference of three phases is used.

However, a three-phase AC power phase error detection device using a microcomputer has a high manufacturing cost, and has trouble in performing other functions by repeating a predetermined method of detecting polling errors periodically for three phases. Caused. In addition, in detecting a voltage error of a three-phase AC power source using an electronic device, it is difficult to detect a sensitive error and it is not easy to detect an error of one of the three phases.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the conventional three-phase error monitoring apparatus described above, and provides a three-phase AC power phase voltage error detecting apparatus capable of detecting a three-phase AC power error with high accuracy using a cheaper component. The purpose is to provide.

1 is a block diagram of a configuration of a phase voltage error detection device of a three-phase AC power supply according to the present invention.

FIG. 2 shows a detailed configuration diagram of a phase error detection device of the three-phase AC power supply of FIG. 1.

3A is a graph showing the voltage of a three-phase AC power supply against time.

FIG. 3B is a graph showing the collector voltage of TR1 of FIG. 2 according to FIG. 3A.

3C is a graph illustrating the primary voltage of the zener diode of FIG. 2 according to FIG. 3A.

In order to achieve the above object, a three-phase AC power supply phase voltage error detecting device for detecting an error in each phase voltage of the three-phase AC power supply of a, b, and c includes the three-phase AC power supply of a predetermined level. An AC / DC converter for converting the DC voltage to supply the DC voltage; A phase voltage error detection unit connected to each phase of the three-phase AC power source and outputting a value equal to or less than a predetermined reference voltage when the voltage is lowered in at least one of the a, b, and c phases; A power generation unit generating power above a predetermined level when a value above a predetermined reference voltage is input from the phase voltage error detecting unit and not generating power when below a predetermined reference voltage; And a display unit which turns on the display when the power generation unit generates a predetermined level or more, and turns off the display when the power is not generated.

The phase voltage error detection unit may include a resistor for dropping a voltage of each phase voltage of the three-phase AC power supply; Three diodes each having a, b and c phases voltage-dropped through the resistors connected to the anode portion one by one; When the voltage drops a, b and c through the resistor and the collector, the base and the emitter are connected to each other and the voltage of any one of the phases is lowered, the voltage from the three diodes is affected by affecting the diode input portion. A first transistor for causing a sum of not exceeding a predetermined reference voltage; And a zener diode that does not conduct the input voltage when the output of the three diodes falls below the predetermined reference voltage.

The power generation unit may include: a first transistor configured to be switched on when the zener diode is turned on to output a predetermined voltage; A second transistor that is switched off when the first transistor is switched on and outputs the predetermined voltage; A third transistor which is in a switched-on state when the second transistor is switched off; And a fourth transistor configured to be switched on when the third transistor is in a switched-on state so that a predetermined collector current flows.

The display unit may include a light emitting diode connected to the collector of the fourth transistor to emit light when the collector current flows when the fourth transistor is conductive.

The display unit may further include a relay connected to the collector of the fourth transistor in parallel with the light emitting diode to be switched when the collector current flows to be used as an external output.

The frequency of the three-phase AC power source is characterized in that 400Hz.

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

1 is a block diagram of a phase voltage error detection device for a three-phase AC power supply according to the present invention. The phase voltage error detection device for a three-phase AC power supply includes an AC / DC converter 100 and a phase voltage error detection device ( 110, a power generator 120, and a display 130. The AC / DC converter 100 converts the three-phase AC power into a predetermined DC voltage. The phase voltage error detection unit 110 is connected to each phase of the three-phase AC power source of a, b, and c phases, and outputs a value below a predetermined reference voltage when one of the a, b, and c phases becomes low. The power generation unit 120 outputs valid power when a value equal to or greater than a predetermined reference voltage is input from the phase voltage error detecting unit 110 and outputs invalid power when less than the predetermined reference voltage. The power here refers to a source of current / voltage, etc., capable of operating the connected load. The display unit 130 is operated by using the power generated from the power generator 120 as a load connected to the power generator 120 described above.

FIG. 2 is a detailed configuration diagram of the phase error detection device of the three-phase AC power supply of FIG. 1, which includes an AC / DC converter 100, a phase voltage error detector 110, a power generator 120, and a display 130. It is provided.

The AC / DC converter 100 includes capacitors c1, c2, and c3, diodes D1 to D6, resistors R4, zener diodes ZD2, and capacitors c4, which are three-phase alternating currents a and b. And c phase is smoothed, rectified and stabilized to produce a predetermined direct current voltage.

The phase voltage error detector 110 includes voltage drop resistors R1 to R3, R5 to R7, diodes D7 to D9 and D13, a capacitor C5, a transistor TR1, and a zener diode ZD1. The voltages on a, b and c are lowered through the voltage drop resistors R1 to R3 and R5 to R7. The a, b, and c phases are input to the collector, base, and emitter of the transistor TR1 as shown in FIG. 3A, respectively, so that the transistor TR1 conducts in a section where the a phase is larger than the c phase and the b phase is larger than the c phase. Likewise, the collector voltage, that is, the voltage applied to the anode of the diode D7 appears. If the voltage of the a or b phase is lowered, the conduction time of the transistor TR1 becomes long. That is, the '0' voltage section of FIG. 3B becomes long. In addition, when the voltage of the c phase is lowered, the conduction period of the transistor TR1 is shortened, but the zener diode ZD1 is prevented from conducting. Zener diode ZD1 shows a primary voltage as shown in FIG. 3C when the voltages of a, b, and c phases are normal, but when the voltages of a, b, and c phases decrease, Since the voltage is lower than the voltage on the secondary side, it is only conducting for a very short time even if it is not conducting or conducts at all. The frequency of the three-phase AC power supply here is 400 Hz.

The power generator 120 includes transistors TR2 to TR5 and other diodes, resistors, and capacitors for signal stability, voltage dividing, and the like. The transistor TR2 is switched on when the zener diode ZD1 is turned on in the phase voltage error detector 110. The TR3 transistor connected to the TR2 transistor is switched off when TR2 is switched on. The transistor TR3 is switched on when TR2 is switched off to switch TR5 on. When switched on, the TR5 transistor draws collector current, which is the power source for a given load. The display unit 130 includes a light emitting diode LD1 that is turned on when a collector current of the TR5 transistor flows and a relay switch RL1 for driving an external output terminal.

Hereinafter, the operation of the three-phase AC phase voltage error detection device shown in FIGS. 1 and 2 will be described. First, when all of the phase voltages a, b, and c of the figure are normal, the voltage output through the diodes D7 to D9 of the phase voltage sensing unit 110 conducts the zener diode ZD1. When the zener diode ZD1 conducts, TR2 is switched on and TR3 is then switched off. When TR3 is switched off, TR4 is switched on to switch on TR5 connected to the emitter terminal, to turn on the light emitting diode LD5 connected to the collector terminal of TR5, and to turn on the relay switch.

When any one of the phase voltages a, b, and c of the figure is lowered, the voltage output through the diodes D7 to D9 of the phase voltage sensing unit 110 does not conduct the zener diode ZD1. Then, TR2 connected to the zener diode ZD1 is switched off and TR3 is switched on accordingly. When TR3 is switched on, TR4 is also switched off, preventing TR5 from connecting to the emitter terminals. Since the TR5 of the non-driven switch-off state does not flow current, the light emitting diode LD1 is turned off and the relay switch RL1 is also turned off.

By using the three-phase AC power phase voltage error monitoring apparatus according to the present invention, the accuracy and efficiency of phase voltage error detection is increased and the cost of construction is reduced.

Claims (6)

In the three-phase AC power supply phase voltage error detection device for detecting an error of each phase voltage of the three-phase AC power supply of a, b and c, An AC / DC converter for converting the three-phase AC power into a DC voltage having a predetermined level and supplying the DC voltage; A phase voltage error detector connected to each phase of the three-phase AC power supply and outputting a value equal to or less than a predetermined reference voltage when the voltage is lowered in at least one of the a, b, and c phases; A power generation unit generating power above a predetermined level when a value above a predetermined reference voltage is input from the phase voltage error detecting unit and not generating power when below a predetermined reference voltage; And And a display unit to turn on the display when the power generation unit generates a predetermined level or more, and to turn off the display when the power is not generated. The method of claim 1, wherein the phase voltage error detection unit, A resistor for dropping the voltage of each phase voltage of the three-phase AC power source; Three diodes each having a, b and c phases voltage-dropped through the resistors connected to the anode portion one by one; When the voltage drops a, b and c through the resistor and the collector, the base and the emitter are connected to each other and the voltage of any one of the phases is lowered, the voltage from the three diodes is affected by affecting the diode input portion. A first transistor for causing a sum of not exceeding a predetermined reference voltage; And And a zener diode that does not conduct the input voltage when the output of the three diodes falls below the predetermined reference voltage. The method of claim 1, wherein the power generating unit, A first transistor which is switched on when the zener diode is turned on and outputs a predetermined voltage; A second transistor that is switched off when the first transistor is switched on and outputs the predetermined voltage; A third transistor which is in a switched-on state when the second transistor is switched off; And And a fourth transistor configured to be switched on when the third transistor is in a switched-on state so that a predetermined collector current flows. The method of claim 3, wherein the display unit, And a light emitting diode connected to the collector of the fourth transistor so that the fourth transistor is turned on to emit light when a collector current flows. The method of claim 4, wherein the display unit, And a relay connected to the collector of the fourth transistor in parallel with the light emitting diode, the relay being switched when the collector current flows so as to be used as an external output. The three-phase AC power phase voltage error detection device according to claim 1, wherein the frequency of the three-phase AC power source is 400 Hz.