KR100421732B1 - Automatic bypass circuit in series voltage compensator - Google Patents

Abstract

The present invention provides a bypass circuit that allows the supply voltage to be supplied to the load in an unintended manner to prevent the interruption of the power supply by using the principle that the voltage across the transformer rises when the normal bypass operation is impossible due to the failure of the compensator. It is composed of a transformer and a compensation circuit connected thereto. That is, the present invention provides a series voltage compensator 10 including a transformer and an inverter, a rectifier circuit unit 21 connected to rectify an output value of a transformer, a switching circuit unit 22 driven by an output value and an external control signal of the rectifier circuit. This allows the power supply voltage to be supplied to the load by a separate bypass circuit even if the compensator that operates to compensate for the power supply voltage becomes a low voltage through an unexpected failure. It is possible to prevent the load supply interruption of the power supply voltage due to the increase of the voltage, which enables stable system operation.

Description

Series voltage compensator with automatic bypass circuit {AUTOMATIC BYPASS CIRCUIT IN SERIES VOLTAGE COMPENSATOR}

The present invention relates to a series voltage compensator mainly used for compensating for low voltage by monitoring input voltage fluctuations in series. In particular, in order to prevent malfunction of the system according to the failure of compensator, the power voltage is loaded in an uninterrupted manner. To be supplied to the Sudden failure of the compensator will result in a failure to supply normal power to the load. Indeed, as the damage caused by the failure of the compensator used in the industrial site often causes significant damages, it is urgently required to derive a solution to overcome this.

The present invention has been made to solve the problems of the prior art, and when using a compensator system for a very important load to provide a switching circuit that can supply commercial power to the load without any trouble even when the compensator failure. will be. The compensator of the above structure is installed to compensate for the low voltage occurring once or twice a year. Therefore, the compensator requires high reliability and at least the compensator should not cause a load problem. However, no matter how reliable the compensation device is, there may be an unexpected failure of the compensator due to power element deterioration or other reasons. Therefore, even in the event of an unexpected failure of such a compensator, a technique for switching input power directly to a load is urgently needed.

1 is a configuration diagram of a conventional series voltage compensator

2 is a block diagram of an inverter used in the series voltage compensator of FIG.

3 is a view showing an inverter control signal waveform;

4 is a configuration diagram of a voltage compensator according to the present invention;

********** Symbol description of the main parts of the drawing **********

10: transformer 11, 12: snub circuit

20: inverter 30: bypass circuit

31: rectifier circuit 32: switching circuit

33: switching terminal according to the external control signal

L1: Transformer output stage L2: Inverter side transformer

In order to achieve the above object, the present invention provides a bypass function by maintaining a short circuit state of a rectifier circuit and a rectifier for rectifying an output value of an inverter side terminal of the transformer in a series voltage compensation device including a transformer and an inverter. In order to be able to perform it is characterized in that it is composed of a switching circuit driven by an external control signal and the output value of the rectifier circuit generated according to whether the low voltage in the power supplied to the load.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a block diagram of a conventional series voltage compensator. In Fig. 1, the power supplies Va, Vb, and Vc represent voltages applied to the series voltage compensator for each phase when three-phase power is applied. Looking at the structure first, a series input transformer 10 is installed in series with the power supply, and a single phase inverter 20 is used as an input of the transformer. Snubber circuits 11 and 12 in which a resistor and a condenser are connected in series are provided at front and rear ends of the series injection transformer, respectively. Assuming that it is connected to a three-phase power supply, each phase consists of three pairs of inverters and series input transformers. A capacitor bank Vdc is used as an energy storage element, and the capacitor bank Vdc is always charged and is in a standby state. This capacitor bank is used as an input power source of the inverter 20. 2 and 3 are views showing the operation principle of the voltage compensation device of FIG. In normal power supply, if the switches S1 and S3 of the inverter 20 of FIG. 2 are turned OFF and the switches S2 and S4 are always turned on, the inverter-side series input transformer 10 maintains a short-circuit state. (L1) also maintains a short circuit. Therefore, the load current flows directly from the input through the transformer to the load without voltage compensation. 3 is a view illustrating an operating waveform of the voltage compensator of FIGS. 1 and 2. In FIG. 3, when the power supply voltage is a normal voltage, as described above, the switches S2 and S4 maintain the ON state, and the switches S1 and S3 maintain the OFF state, thereby forming a closed circuit, and as a result, the voltage compensator performs the bypass operation. Meanwhile, in order to perform a compensation operation according to the occurrence of the low voltage at the power supply voltage, the switches S1, S2, S3, and S4 in FIG. 2 perform ON and OFF operations according to signals as shown in FIG. AC voltage is generated from the circuit, and the normal voltage can be supplied to the load by supplying the compensation voltage, which is the generated AC voltage, to the load.

In other words, when an abnormal voltage is input to the input, that is, when a low voltage occurs, the controller accurately determines the amount of low voltage, generates a short voltage for each phase, and adds it in series to the input power to supply a normal power supply to the load. Therefore, when the compensator operates normally, a constant voltage can be supplied to the load even when the input voltage is normal as well as a low voltage. In normal power supply, when the switches S1 and S3 of the inverter of FIG. 2 are turned OFF and the switches S2 and S4 are always turned ON, the inverter-side series input transformer maintains a short circuit and eventually the output stage of the transformer maintains a short circuit. Therefore, the load current flows directly from the input through the transformer to the load.

3 illustrates the operation waveform of the compensator. In FIG. 3, it can be seen that the switches S2 and S4 maintain the ON state and the switches S1 and S3 maintain the OFF state in the bypass operation. On the other hand, during the compensation operation, the switches S1, S2, S3, and S4 perform ON and OFF operations according to a given signal to supply a compensation voltage, which is an AC voltage generated from the capacitor bank Vcd. In addition, when an abnormal voltage is input to the input, for example, when a low voltage is generated, the controller accurately determines the amount of low voltage, generates a voltage that is insufficient for each phase, and adds the normal power to the load in series with the input power. Therefore, when the compensator is normal, a constant voltage is supplied to the load not only when the input voltage is normal but also when the compensator is low. If a normal bypass operation is not performed in the compensator system due to the burnout of the switching element, the switches S2 and S4 in FIG. 2 cannot be kept in an ON state, and thus the inverter-side series input transformer L2 is short-circuited. I can't keep it. At this time, the output terminal (L1) of the transformer appears to be divided most of the input power, so that normal power supply to the load is impossible. Therefore, in the present invention, when the compensator suddenly malfunctions, it is advantageous not to use the compensating function of the compensator system, and it is made to operate the load normally by supplying the load to the load without any input commercial power.

4 is a circuit of the present invention made to overcome this problem. As described above, the present invention uses the principle that the voltage across the transformer rises when the normal bypass operation is impossible due to the failure of the compensator, and consists of a transformer and a compensation circuit connected thereto. In other words, in the present invention, the present invention relates to a series voltage compensator 10 including a transformer and an inverter, a rectifier circuit part 31 connected to rectify an output value of a transformer, a switching circuit part driven by an output value and an external control signal of the rectifier circuit. It consists of 32. On the other hand, the switching circuit unit 32 is connected to the transistor T1 driven by the output value of the rectifier, the resistor element R1 for limiting the gate current connected to the base terminal and the collector terminal of the transistor, and the emitter terminal of the transistor T1. And a Zener diode (ZD) connected to the base terminal to maintain a constant gate voltage, connected to an input / output terminal of the Zener diode, and an emitter and a collector of the transistor T1 to perform a switching function by an external control signal. The switching terminal 33 is comprised.

Referring to the operation of the embodiment according to the present invention configured as described above are as follows. First, the operation of the circuit can be divided into two operation modes according to the state of the compensator. That is, when the compensator system is normal and when the compensator system is in a fault state. First, the operation mode when the compensator system is normal may be divided into a case in which the input voltage is in a normal voltage state and a case in which the input voltage is in a low voltage generation state. When the input voltage is normal, the inverter 20 is in bypass (BY-PASS) state and the lower switch of each phase, that is, S2, S4 is in the ON state. Therefore, the series input transformer L2 of the inverter stage is in a short circuit state, and thus the voltage applied to the series input transformer L2 is maintained at zero. At this time, the both ends of ab are kept open by an external control signal, so that the voltage provided to the bypass circuit 30 connected to the series input transformer is also zero, and thus is connected to the emitter and the gate of the transistor T1. By setting the voltage across the zener diode ZD to zero, the circuit is placed in an inoperable state.

On the other hand, when a low voltage occurs in the input voltage, both ends of ab are shorted by an external control signal for controlling the short circuit of the ab terminal 33. The transistor T1 serving as a switch of the invention circuit is short-circuited by the ab terminal and thus becomes a turn-off state as the gate voltage becomes zero. At this time, the circuit of the present invention becomes an open circuit according to the switch OFF to block the compensation current according to the operation of the inverter flows into the bypass circuit 30. This is because the bypass circuit 30 may operate due to the compensation voltage generated when the compensation voltage is generated according to the low voltage, thereby supplying a low voltage power supply voltage to the load. The short circuit between ab ends is judged according to the low voltage of the power supply, and the short ends of ab are short only when the low voltage is generated in the power supply and there is no problem in the compensator.

On the other hand, when the compensator system breaks unexpectedly, the bypass circuit 30 operates substantially, thereby performing the bypass function, which is an original function of the present invention. In other words, when the inverter is placed in an open state due to a failure of the compensator system and the bypass operation, which is a function of the inverter, cannot be performed, the inverter-side series input transformer L2 cannot maintain a short circuit state. At this time, the commercial power is applied to the output terminal L1 of the series input transformer as it is, and the voltage of the inverter side transformer L2 is also increased. The elevated voltage is rectified through the diode rectifier and the rectified voltage is supplied across ab by limiting the current through the resistor R1. At this time, the ab terminal maintains an open state by an external control signal so that the current and voltage passing through the resistor R1 are supplied to the transistor T1 and the zener diode ZD. The supplied voltage adjusts the voltage at the zener diode (ZD) connected to the ab terminal to make and supply a gate signal suitable for driving the switch. Therefore, the voltage supplied between ab turns the transistor T1, which is a switching element, TURN ON, and finally shorts the inverter-side series input transformer L2 to provide a path through which a short circuit current can flow. Therefore, even when the compensator system is broken, the input voltage can be supplied to the load almost without any disturbance, thus enabling stable operation of the system.

Although the invention has been particularly shown and described with reference to the preferred embodiments, those skilled in the art will appreciate that various modifications are possible without departing from the spirit and scope of the invention. Accordingly, the invention is limited only by the claims.

As described above, the present invention allows the power supply voltage to be supplied to the load by a separate bypass circuit even if the compensation device for compensating for the power supply voltage becomes a low voltage causes an unexpected failure. It is possible to prevent the interruption of the supply of the power supply voltage due to the voltage increase of the transformer and to continuously supply the power supplied to the important load, thereby enabling the stable system operation.

Claims (2)

In the series voltage compensation device including a transformer and an inverter connected to the transformer to supply a compensation voltage for compensating for the low voltage when the power supply voltage supplied to the load, A rectifier circuit connected to an inverter side terminal of the transformer to rectify an output value of the transformer; A switching circuit which is driven by an external control signal applied according to whether or not a low voltage is generated in a power supply supplied to a load and an output value of the rectifier circuit to bypass the power supply voltage to the load by maintaining a short circuit state of the transformer; Series voltage compensation device comprising an automatic bypass circuit consisting of. The switching circuit of claim 1, wherein the switching circuit comprises: a transistor driven by an output value of a rectifier; A resistance element connected to the base terminal and the collector terminal of the transistor to limit a gate current; A zener diode connected to the emitter terminal and the base terminal of the transistor to maintain a constant gate voltage; And a switching terminal connected to an input / output terminal of the zener diode and an emitter and a collector of the transistor to perform a switching function by an external control signal.