SU1249640A1 - Device for controlling three-phase triac switching device with protection - Google Patents

Abstract

The invention relates to electrical engineering and can be used to protect three-phase active and inductive loads, in particular electric motors; from a deep decrease in the supply voltage. The purpose of the imaging retention is to increase reliability. When one of the phases is cut off, the three-phase rectifying bridge (L

Description

(TBM) 2 goes into two-phase rectifying mode with the rectified current decay to zero, which leads to locking of the thyristor 5, extinguishing the LEDs of the phase optocouplers 7 and locking the triacs 1 at the moment of current transition in the phases through zero. When the supply voltage is deeply reduced, the current through the LED of the optocoupler 19 decreases. It goes out, which causes the thyristor 3 to lock. The TVM 2 goes into two-phase rectifier mode and the switch also turns off. When a short circuit in the load circuit signal

The invention is electrical engineering and can be used to protect three-phase active and inductive loads, in particular electric motors, from a deep reduction in the supply voltage.

The purpose of the invention is to increase reliability.

The drawing shows a schematic diagram of the device.

A device for controlling a three-phase switch on triacs 1 with protection contains a three-phase in-ground bridge 2 on thyristor 3 and five diodes 4, the input of which is connected to the phases of the network, and the output is loaded on a circuit of series-connected starting thyristor 5, load resistor 6 and light-emitting diodes of three-phase optocouplers 7, the photothyristor of each of which is connected via a limiting resistor 8 to the output of a bridge rectifier 9, the input of which is connected to the control junction of the corresponding triac 1.

Two phase sensors of current Yu are made on each of the shunt 11 connected to the input of the bridge rectifier 12, the output of which is loaded on the series-connected adjustable resistor 13 and the zener diode 14, by the shunt LED. protective optocoupler 15. The photo thyristors of both protective optocouplers 15 are connected in parallel and through a resistor 16 and the stop button Stop 17 are connected to the output of the rectifying bridge 2.

17-

From one of the shunts 11, a rectifying bridge 12 is applied to the LED of the optocoupler 15, the photothyristor of which turns on and shunts the LED of the optocoupler 19. The LED of the optocoupler 19 goes out, which causes the thyristor 3 to be locked and the switch off. Thus, due to the execution of the thyristor control unit 20 TBM 2 on the optocoupler 19, the operation of the phase optocouples 7 is unstable with incomplete recovery of the supply voltage after its fit. I zp f-ly, 1 ill.

Parallel to the photo thyristors of the optocouplers 15, through the variable resistor 18, the LED of the optocoupler 19 of the thyristor control unit 3 of the bridge 2 is turned on. The photo thyristor of the optocoupler 19 of the control unit 20 through the limiting resistor 21 is connected between the control electrode and the anode of the thyristor 3. The starting unit 22 is made on the closing contact of the Start button 23, connected through the limiting resistor 24 between the control electrode and the anode of the starting thyristor 5.

The device works as follows.

In the initial state, the three-phase rectifying bridge 2 operates on a circuit of series-connected resistors 16 and 18 and an LED of the optocoupler 19, which controls the voltage level in the supply network. Under normal voltage, the light-emitting diode of the optocoupler 19 illuminates, its photo-thyristor turns on, which leads to the turning on of the thyristor 3. The circuit is ready to start.

When a short press is applied, Start 23 on the thyristor control unit 5 appears a triggering pulse, and the thyristor 5 turns on. A current begins to flow through the phase optocouplers 7 LEDs and their photothyristors turn on, which connects the load to the AC network .

When one of the phases of the mains supply, the three-phase rectifying bridge 2 goes into a two-phase rectifier mode with the rectified current zero to zero, which causes the thyristor 5 to be locked, the LED of the phase optocouplers 7 to go out and the triacters I to be locked at the moment of current transition in the phases through zero.

When the mains voltage is deeply reduced, the current through the LED of the optocoupler 19 decreases, it goes out, which causes the thyristor 3 to lock, the Three-phase tempering bridge 2 goes into two-phase high mode and the switch turns off as i and in the case of one of the supply phases network. The magnitude of the shutdown setting of the optocoupler 19 is adjusted by varying the resistance of the resistor 18.

During a short circuit in the load circuit, the signal from one of the bypasses 11 through the rectifying bridge 12 is applied to the LED of the optocoupler 15, the photoristor of which turns on and shunts the LED of the optocoupler 19. The LED of the optocoupler 19 goes off, which causes the switch to turn off the thyristor 3 and turn off the switch like and in the event of a decrease in the supply voltage. The magnitude of the set point for the operation of the optocouplers 15 is controlled by changing the resistance of the resistors 13.

If the switch is turned off, the Stop button 17 is pressed, which causes the current in the LED circuit of the optocoupler 19 to stop current, and the switch is turned off as described.

In all cases, the switch can be re-enabled only after a corresponding press of the Start 23 button.

Thus, due to the execution of the thyristor control unit of three

the phase rectifying bridge on the optocoupler eliminates the unstable operation of the phase optocouplers with an incomplete restoration of the supply voltage after its fit, which increases the reliability of the switch.

Formula

4 3 o

bratis

0

0

five

five

0

five

0

five

0

Claims (2)

1. A device for controlling a three-phase switch on protected triacs containing a three-phase rectifying bridge on five diodes c. thyristor, the control electrode of which is connected to the control unit, the input of the specified bridge is connected to the terminals for connecting the mains phases, and the output is connected to a circuit of serially connected starting thyristor, the control electrode of which is connected to the starting block, load resistor and LEDs three phase optocouplers, the photothyristor of each of which is connected through a limiting resistor to the output of the bridge. rectifier, the input of which is intended to be connected to the control junction second triac. two phase current sensors, each of which is connected to a shunt connected to the input of a bridge rectifier, the output of which is connected to a series-connected adjustable resistor and a zener diode, which is bridged by a protective optocoupler LED, and the photo thyristors of both protective optocouplers are connected in parallel and connected to One of the terminals of the resistor, characterized in that, in order to increase reliability, the control unit is complete on the optocoupler, whose photo thyristor is connected to the thyristor anode through a limiting resistor, and the LED through a variable resistor is connected in parallel to the photothyristors of optocouplers, the cathodes of which are connected to the negative, and the other output of the resistor to the positive pole of the three-phase rectifying (bridge. g 2. The device according to claim 1, about tl 1 - that the starting block is made on the closing contact of the button. The start connected through the limiting resistor to the anode of the starting thyristor.