KR101009483B1 - Sag protector - Google Patents

Abstract

PURPOSE: A sag protector is provided to supply normal external power to a load by operating a pulse circuit when a controller malfunctions. CONSTITUTION: A pulse circuit(600) comprises a constant voltage circuit and a pulse generating circuit. A constant voltage circuit supplies constant voltage power to a primary coil of a choke transformer of the pulse generating circuit and an FET(Field Effect Transistor) switch. The pulse generating circuit is comprised of the pulse generating circuit and the pulse outputting circuit. The pulse generating circuit outputs a pulse signal to the gate of the FET switch. The pulse output circuit outputs a pulse signal to the gate of an SCR(Silicon Controller Rectifier) switch(200).

Description

Power failure compensation device {SAG PROTECTOR}

The present invention relates to a technique for compensating instantaneous power failure, and in particular, to configure a control circuit so that normal external power is supplied to a load in case of malfunction of the power failure compensator so as to prevent damage to an industrial electric device due to an internal failure of the power failure compensating device. It is about a momentary power compensation technology.

In general, the reliability of power in the industrial field is high, but the fact is that the instantaneous voltage drop and instantaneous power failure often occur. This momentary instability is caused by short circuits in the power system, lightning and switching of large loads.

Most industrial devices can withstand these momentary interruptions due to their mechanical properties and electrical inertia, but they include programmable logic controllers (PLCs), electronic switchgears, relays, starters, and microcontrollers that make up the plant's automatic production facilities. Etc. can be lost by voltage sags (Voltage SAG / Dip) of the control power supply which occur at very short moments of several cycles.

The sag (sag, instantaneous low voltage) refers to the phenomenon or rate of decrease of the pulse instantaneously monotonically with time, usually expressed as the ratio of the decrease to the maximum pulse amplitude. Therefore, voltage sag refers to a phenomenon in which an input voltage falls momentarily.

This drop in voltage can cause significant economic damage by shutting down production facilities. In addition, SAG Protector has been proposed to solve the damages caused by the temporary stop of numerous facilities in various fields operating in the industry.

A device for compensating for an instantaneous power failure is a conventional UPS (Uninterruptible Power Supply), but the UPS is frequently stopped because it is not effective against inrush current generated from peripheral devices. In addition, the UPS has a problem of supplying control power to the load for an excessive amount of time without distinguishing between a power outage and a permanent power outage, and it is economically inefficient because it requires a considerable maintenance cost to periodically check the battery used in the UPS.

Another device that compensates for momentary power failure is the conventional VSP (Voltage SAG Protector). These voltage sag protection devices have the advantage of compensating for the shortcomings of the UPS, but sometimes there is a secondary risk that the output voltage drops due to malfunction of the voltage sag protection device even though the external power supply is normal.

Therefore, due to the above problems, the conventional instantaneous power outage compensator has a limitation in system efficiency and does not guarantee 100% stability as a whole.

An object of the present invention is to prevent the external power is not supplied to the load due to the internal failure of the instantaneous power failure compensation device to prevent damage to the industrial electrical equipment instantaneous power failure to control the normal external power is supplied to the load during the malfunction of the power failure compensation device To provide compensation technology.

In the instantaneous power failure compensation device according to the present invention, when the external power supply is abnormal, the controller turns off the bidirectional switch and controls the inverter to convert the charge stored in the capacitor into AC power, and then boosts the AC power by boosting the voltage to the load. A momentary power compensator for supplying a pulse circuit that outputs a pulse signal to the gate of a bidirectional switch when the external power is in a normal state and the controller malfunctions and the inverter control signal is abnormal. It is configured to include.

Bidirectional switch according to the present invention is characterized in that it comprises a; SCR (Silicon Controlled Rectifier) switch connected in parallel in the opposite direction.

The pulse circuit according to the present invention comprises a constant voltage circuit for making a constant voltage power supply to the pulse generating circuit; And a pulse generator circuit for switching the constant voltage power supply to generate a pulse signal when the inverter control signal of the controller is abnormal and outputting the generated pulse signal to the gate of the SCR switch.

The constant voltage circuit according to the present invention is configured to supply a FET (Field Effect Transistor) switch connected in series with the primary coil of the choke transformer and the primary coil of the choke transformer constituting the pulse generating circuit by reducing the external power to form a constant voltage power supply. The pulse generating circuit may include: a pulse generating circuit configured to generate a pulse signal by switching and controlling a constant voltage power supply when the inverter control signal of the controller is detected abnormally and output the generated pulse signal to a gate of the FET switch; And a pulse output circuit for inducing a pulse signal to the secondary coil of the choke transformer by on / off of the FET switch and outputting the induced pulse signal to the gate of the SCR switch.

According to the present invention, the control circuit is configured such that normal external power is supplied to the load in the event of a malfunction due to an internal failure of the instantaneous power failure compensator so that external power is supplied to the load in the event of a malfunction of the instantaneous power compensation compensator to prevent damage to industrial electrical equipment. It is effective to prevent.

1 is a block diagram showing the configuration of a momentary power compensation device according to an embodiment of the present invention;
2 is a block diagram showing the configuration of the SCR switch shown in FIG.
3 is a block diagram showing the configuration of the pulse circuit shown in FIG.

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

1 is a block diagram showing the configuration of a momentary power compensation device according to an embodiment of the present invention.

The momentary power compensation device detects that the external power is abnormal or normal, and turns off or turns on the Silicon Controlled Rectifier (SCR) switch 200 according to the detection result to cut off the external power in abnormal state, and the external power in normal state is It operates to be supplied to the load. This operation is described below.

The controller 100 of the momentary power compensation device turns off the SCR switch 200 connected in parallel in opposite directions when the external power is abnormal and controls the inverter 400 to convert the charge stored in the capacitor 300 into an AC power source. After the conversion, the control unit is boosted through the transformer 500 so that the boosted AC power is supplied to the load.

The controller 100 of the momentary power compensation device controls the external power to be supplied to the load by turning on the SCR switch 200 when the external power is in a normal state.

As described above, the controller 100 controls the SCR switch 200 according to the state of the external power in a normal operation state so that the power is stably supplied to the load, but the controller 100 causes the SCR switch 200 due to an internal failure. There may be a situation that can not control.

In the present invention, when the controller 100 malfunctions due to an internal failure, the pulse circuit 600 operates so that external power is supplied to the load.

The pulse circuit 600 outputs a pulse signal to the gate of the SCR switch 200 when the external power is in a normal state and the controller 100 malfunctions and the inverter control signal of the controller 100 is in an abnormal state. Control to be supplied.

A detailed configuration of the pulse circuit 600 will be described below with reference to FIG. 3.

FIG. 2 is a block diagram showing the configuration of the SCR switch shown in FIG. 1, and FIG. 3 is a block diagram showing the configuration of the pulse circuit shown in FIG.

The pulse circuit 600 includes a constant voltage circuit 610 and a pulse generator circuit 620, the components of which will be described.

The constant voltage circuit 610 of the pulse circuit 600 generates a constant voltage power and supplies it to the pulse generator circuit 620, and the pulse generator circuit 620 switches and controls the constant voltage power when the inverter control signal of the controller 100 is abnormal. The pulse signal is generated and output to the gate of the SCR switch 200. The SCR switch 200 is operative to operate so that external power is supplied to the load.

The constant voltage circuit 610 decompresses the external power through the transformer T1 and converts the decompressed power into DC power through the rectifier BD1 composed of a bridge diode to make a constant voltage power. The constant voltage circuit 610 supplies DC power to the smoothing capacitor EC1 and the constant voltage IC U1 to make a 12-volt constant voltage power supply to the pulse generating circuit 620.

The constant voltage circuit 610 supplies constant voltage power to the pulse generation circuit 620 including the pulse generation circuit 621 and the pulse output circuit 622. The constant voltage circuit 610 depressurizes an external power source to generate a constant voltage power source, and constitutes a pulse generating circuit 621 and a pulse output circuit 622, and a primary coil of the choke transformer T2 and a primary coil of the choke transformer T2. It is supplied to a field effect transistor (FET) switch (Q2) connected in series.

The pulse generator circuit 620 includes a pulse generator circuit 621 and a pulse output circuit 622, the configuration and operation of these circuits will be described.

The pulse generation circuit 621 generates pulse signals by the transistor Q1 receiving the inverter control signal of the controller 100 and the on / off control of the transistor Q1 (U2-B, C, D). It is composed of The operation of the pulse generation circuit 621 is as follows.

The pulse generation circuit 621 receives the inverter control signal of the controller 100 and inputs it to the gate of the transistor Q1 to generate a high signal or a low signal. If the inverter control signal is a normal high signal, the pulse generation circuit 621 generates a low signal and inputs the generated low signal to the pulse generation logics U2-B, C, and D formed by the NAND gate to turn off the pulse generation. On the contrary, if the inverter control signal is an abnormal low signal, the pulse generation circuit 621 generates a high signal and inputs the generated high signal to the pulse generation logics U2-B, C, and D to turn on pulse generation.

The pulse generation circuit 621 transmits the pulse signal generated by the pulse generation logics U2-B, C, and D to the gate of the FET switch Q2 constituting the pulse output circuit 622 when the inverter control signal is abnormal. Output

The pulse output circuit 622 may include a Zener diode ZD1 receiving a constant voltage power and a FET switch Q2 connected to a diode D2 connected in reverse series to the Zener diode ZD1 and an anode of the diode D2; A choke transformer T2 connected in parallel to the zener diode ZD1 and the diode D2; It includes two filter circuits connected to the secondary coil of the choke transformer (T2).

The pulse output circuit 622 receives the pulse signal of the pulse generating circuit 621 to turn on / off the FET switch Q2 to supply or cut off a constant voltage power supply to the primary coil of the choke transformer T2. As the constant voltage is supplied on / off to the primary coil of the choke transformer T2, a periodic on / off signal is transmitted to the secondary coil of the choke transformer T2 by magnetic induction.

The pulse output circuit 622 passes the pulse signal induced in the secondary coil of the choke transformer T2 by the periodic on / off to the filter circuit and transmits the pulse signal passed through the filter circuit to the gate of the SCR switch 200. Output

The SCR switch 200 connected in parallel conducts by the pulse signal of the pulse output circuit 622 so that external power is supplied to the load.

Although the present invention has been described in more detail with reference to the examples, the present invention is not necessarily limited to these embodiments, and various modifications can be made without departing from the spirit of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

100: controller 200: SCR switch
300: capacitor 400: inverter
500: transformer 600: pulse circuit

Claims (4)

When the external power supply is abnormal, the controller turns off the bidirectional switch, a SCR (Silicon Controlled Rectifier) switch connected in parallel in opposite directions, and controls the inverter to convert the charge stored in the capacitor into AC power and then boost the voltage by using a transformer. As an instantaneous power failure compensation device that supplies the supplied AC power to the load,
A constant voltage circuit for supplying a primary coil of a choke transformer and a field effect transistor (FET) switch connected in series with the primary coil of the choke transformer to form a constant voltage power by reducing the external power; And
When the inverter control signal of the controller is abnormally detected, a pulse generation circuit for switching the constant voltage power supply to generate a pulse signal and outputting the generated pulse signal to the gate of the FET switch and on / off of the FET switch A pulse generation circuit including a pulse output circuit for inducing a pulse signal to a secondary coil of the choke transformer and outputting the induced pulse signal to a gate of the SCR switch;
Consists of a pulse circuit comprising a,
The pulse circuit outputs a pulse signal to the gate of the bidirectional switch when the external power is in a normal state and the controller malfunctions and the inverter control signal of the controller is abnormal to control the external power to be supplied to the load. Power failure compensation device.
delete delete delete

Images