SU744772A1 - Device for output cascade of pulsed quick-action protection system - Google Patents

Description

The invention relates to electrical engineering and can be used for interfacing the semiconductor protection portion running from the auxiliary power source to the output ₅ le PE electromechanical running from the central battery.

A device is known for an output protection stage, comprising an output electromechanical relay connected to the power supply buses via a thyristor, which is switched on by control signals supplied from the protection and switched off by another additional thyristor using a pre-charged capacitor (1J. 15

The disadvantage of this device is the insufficiently fast return and readiness for repeated operation, determined by the time the capacitor is recharged, as well as the possibility of a complete loss of the return ability when the additional thyristor is opened simultaneously with the main thyristor, and both thyristors remain open, and output stage does not return. '

Closest to the proposed one is a device for the output stage, in which the additional normally closed indoor is replaced by a normally open dinistor and the processes of overcharging the switching capacitor are accelerated [21.

However, in known devices, the possibility of a cascade triggering from a single pulse is not fundamentally possible. As a rule, a regular sequence of pulses, determined by a period or half-period of industrial frequency, comes from the protection to the output stage. A single impulse is a hindrance and operation from it should be excluded.

The purpose of the invention is to increase the speed and noise immunity of the device.

This goal is achieved by the fact that in the device for the output stage of the pulse high-speed protection, containing a relay, a thyristor connected. an anode to the plus of the power supply, integrating an RC circuit, a dynistor ', a co-encoder and two resistors, one of which is connected to the minus of the power supply, an additional limiting and switching dinistors, a resistor and a capacitor are introduced, moreover, one relay coil output, one of said capacitor terminals of the integrating RC-circuit, the output of the other of the aforementioned resistors ¹⁰ and one of the terminals of the resistor is connected again inputted to a minus power supply, the other terminal of the relay coil connected to the cathode bounding dynistor to anode where I ⁵ is connected the other terminal of the capacitor integrating PC-circuit, the other terminal of one of the aforementioned registorov and one of the terminals of the resistor of the integrating PC tsepy 'to others in gom at the conclusion of which are connected / ²⁰ cathode of the thyristor and one of the terminals of the aforementioned condenser to another another end connected vyv'od 'one of the aforementioned resistors, one of the terminals of the newly introduced valuable con ²⁵ Satoru dynistor and the cathode, the anode of which is connected to the positive power source and the anode of the switching dynistor, a cathode which under for prison staff to the other terminal of the newly introduced capacitors and resistors.

The dash is a schematic diagram of the device.

The device contains an output relay 1, thyristor 2, a switching source of ³⁵ pulses for closing the thyristor, assembled on a dinistor 3, capacitor 6 and resistor 11, another same source of switching pulses on dinistor 4, capacitor 7 and resistor 9, an integrating element, containing a resistor 10 And a capacitor 8, a discharge resistor 12 and a limiting dynistor 5.

The device operates as follows. ⁴⁵

In the absence of control pulses on the control electrodes of thyristor 2, the latter is closed, the output relay 1 is de-energized. In this mode dynistors 3, 4, resistors 9, 11 and capacitor ⁵⁰ 7 obrazu- dissolved sultivibrator located in the oscillatory mode. The voltage on the left side of the capacitor 6 is ύ _π , on the right is approximately +0.5 Un · When a single control pulse ⁵⁵ (i.e., noise) arrives at thyristor 2, it opens, the integrating capacitor 8 starts charging. The voltage on the capacitor 6 through the thyristor is applied to the Shockley diode 2 at 3 _h in the closing direction, closing it. The oscillatory process of the multivibrator breaks down. Capacitor 6. through the resistor 11 begins to be charged to the breakdown voltage of the dinistor 3, the breakdown of which occurs at a given point in time. At this moment, the voltage of the capacitor 6 is applied to the thyristor 2 in the closing direction, and it closes. At the same time, the vibrations of the multivibrator are renewed, which generates additional switching pulses coming through the capacitor 6 to the thyristor 2. This ensures reliable closing of the thyristor regardless of the previous state of the circuit and prevents sticking of the thyristor. In this mode, i.e. when the thyristor 2 is opened once, the voltage across the capacitor 8 does not reach the breakdown voltage of the limiting dynistor 5, and the output relay 1 remains de-energized. The capacitor 8 is discharged through the resistor 12.

When the control pulses to the thyristor 2 arrive at a specific and predetermined frequency, the capacitor 7 does not have time to completely discharge. After the second or third pulse, the voltage across the capacitor 7 reaches the breakdown voltage of the dynistor 5, accompanied by the operation of the output relay 1,

In addition to eliminating the drawbacks indicated above, this device consumes less power than the known one in idle mode, since due to an increase in the efficiency of switching pulses, it is possible to significantly increase the resistances of resistors 9 and 11.

The technical and economic effect of the use of this device is to increase the reliability of the power system by reducing the time for eliminating accidents and eliminating false protection trips under the influence of interference.

Claims (2)

1. USSR author's certificate No. 462227, cl. H O1 H 83/20, 1973. 2. USSR author's certificate No. 426257, cl. H 01 H 83 / 2O, 1972. P