SU741341A1 - Output device for quick-action relay protection - Google Patents

Description

The charging circuit is parallel and counter-connected with a charging diode and an auxiliary control key, the control circuit of which is connected in turn with the diode. connected | 51M-parallel switch-off solenoid,

The drawing shows a circuit diagram of the device.

The device consists of a main 1 and auxiliary 2 controlled switches (for example, thyristors), a switching capacitor 3, a diode 4 charging, and resistors 5-8, a starting capacitor 9, a coupling diode 10, a resistor 11, a diode 12, a resistor 13, a starting diode 14 , control contact 15 (e.g., electronic protection output contact), switch-off solenoid 16.

In the static position (the protection did not operate, the control contact 15 is open) the pulsating supply voltage (not shown) is applied to the device terminals, the thyristors 1 and 2 are locked, the switching capacitor through the resistors 5 and b is charged to the maximum value, and the capacitor 9 charged to the midpoint potential of the divider on resistors 7 and 8.

When the main thyristor 1 is opened, under the influence of a short-term interference, the switching-off solenoid 16 is energized and a current flows through it. Since the nature of the load is inductive, the current in the solenoid lags behind the voltage and reaches its maximum value (many times greater than the value of the thyristor holding current) as the potential approaches zero. In this case, the thyristor 1 is not closed, and on the solenoid 16, an emf of caMoiJduction is induced, equal to the voltage drop on the primary thyristor 1 and resistor 6. The magnitude and polarity of the induced emf are such that through the trigger diode 14 the auxiliary thyristor 2 opens 3 through open auxiliary thyristor 2 is applied to Katony of main thyristor 1, which is locked, capacitor 3 begins to discharge through solenoid 16, however, its energy is not enough to trigger the solenoid 16 solenoid 16 switch. The auxiliary thyristor 2 is locked after the current from the capacitor 3 through it becomes less than its current (the current through the resistors 5 and b can be neglected due to the large resistance of the resistor 5) and the capacitor 3 is recharged to the maximum potential.

Thus, the main thyristor 1, opened under the influence of Kpa

at the end of the first half period of the supply voltage is forcibly closed. With a brief opening of the main thyristor 1, the electromagnet of the solenoid 16 of the shutdown will not have time to work, i.e. excluded .o false shutdown switch.

When the protection is triggered, contact 15 closes, the main thyristor 1 is unlocked, and the end of the first half period of the supply voltage is closed.

During the next half-period of the supply voltage, the main thyristor 1 opens (contact 15 is closed), the auxiliary thyristor 2 is locked by the supply voltage and the switching capacitor 3 in the direction of: resistor b, thyristor 1, diode 4 is recharged and recharged to the maximum value . It is again possible to lock the main thyristor 1 at the end of the half-period of the supply voltage.

Thus, for the duration of the closed position of the control contact 15, the main thyristor 1 is unlocked at the control electrode at the beginning of each half-period of the supply voltage, and at the end of each half-period it is forcibly locked.

After several half-periods, the electromagnet of the shut-off solenoid operates and turns off the oil switch, after which the control contact 15 is opened. The main thyristor 1 is locked and the device switches to the static position. The duration of the current pulse in the load depends on the time of the closed state of contact 15, i.e. At the end of each half-period of the supply voltage, the main thyristor is forcibly locked.

Claims (2)

1. Vasilievsky N.N. et al. Anna is a school of automation and telemechanics of power supply devices. N., i ed. Transport, 1971, pp. 119-121. 2. Author's certificate SSSS 473234, cl. I 01 N 83/20, 1972 (prototype).