SU838856A1 - Device for disconnection of automatic switch - Google Patents

Description

(54) DEVICE FOR DISABLING AUTOMATIC

Claims (2)

SWITCH pa the reliability of this device is also due to the burning of mechanical contacts connected between the discharge capacitor and the tripping coil and the lack of performance checks in normal mode. The fuse integrity control unit is connected in parallel with the discharge capacitor and resistor. Therefore, it is 1m. It acquires a zero protection property, the use of which under certain conditions (according to the Rules for the production of explosion-proof and mine electrical equipment - PEVRE) is not allowed. The reliability of operation in this case (with the zero protection derived, and therefore the absence of the integrity control unit of the fuse) also turns out to be low, because when the fuse blows, the executive body is rendered inoperative. The purpose of the invention is to increase the reliability of the device for switching off the automatic switch. The goal is achieved by the fact that a voltage transformer connected to the zinc network of my network, the secondary winding of which through a series-connected fuse, rectifier and resistor connected to the discharge capacitor, is connected to a device containing a transformer connected to a transformer. and a key element connected to the disconnecting switch TyiiiKe switch, additionally introduced block leakage monitoring capacitor, made on two transistors of different conductivity, bases the first transistor of which is connected to the connection point of the positive output of the discharge capacitor, the diode anode and the disconnecting switch coil, and the base of the second transistor is connected via a resistor to the connection point of the positive output of the newly introduced improved reliability capacitor and the anode of the second diode, the cathodes of the diodes through the closing the switch contact is connected to the negative output of the rectifier (the combined negative leads of the discharge capacitor and the capacitor of the increased reliability, the emitters of the transistors The main conductor is connected, the collector of the nerve transistor is connected to the negative terminal of the second rectifier, and the collector of the second transistor through the winding. The relay to the positive terminal of this switch, whose input is connected to a bone voltage divider connected to the secondary winding of the transformer tension The key element is designed as a thyristor; between the anode and the control electrode of which the parallel-connected, overcurrent contacts of the overcurrent protection and the leakage capacitor leakage control relay are connected, a positive terminal is connected to the control electrode, and a minus terminal of the fuse integrity control unit is connected to the control electrode . The fuse integrity control unit is designed as a transformer, the primary winding of which is connected in parallel to the fuse, and the secondary winding is connected to the rectifier. The drawing shows a diagram of the device. The device contains a voltage transformer 1 connected to the protected network, the secondary winding of which is connected through a series-connected fuse 2, a rectifier 3 and a resistor 4 connected to the discharge capacitor 5; fuse integrity control unit 6, disconnecting coil 7. oil switch 8, its closing block-contact 9, shunt and discharge capacitor 5, thyristor 10 connected between the disconnecting coil 7 and discharge capacitor 5. To the control electrode of the thyristor 10 pin 11 of the maximum current protection is connected and the output of the integrity control unit of the fuse 6. The device also contains a leakage capacitor leakage control unit consisting of transistors 12 and 13 of different conductivity, whose inputs are connected to different be zheni.y voltage applied to a discharge capacitor 5, and capacitor 14 of high reliability. The latter is connected via resistor 15 to an uplink 3, and the outputs of transistors 12 and 13 are through relay 16, pin 17 of which is connected to the control electrode of thyristor 10, and rectifier 18 is powered by a voltage divider on capacitors 19 connected to the secondary vol. the coil of the voltage transformer 1 after the fuse 2. A diode 20 is connected in the conductive direction between the connection point of the discharge capacitor 5 with the resistor 4 and the disconnecting unit contact 9 of the automatic switch 8, and the diode 21 is connected between the connection point of the diode 20 and block 9-contact and the point interconnecting the additional capacitor 14 and resistor 15 and an additional oppositely directed diode 20. Entrance block integrity monitoring fuse 6 galvanically separated from the outputs and. connected in parallel to fuse 2, and the discharge capacitor leakage control unit introduced additionally with its output (pin 17 of output relay 16) acts on the control electrode of the thyristor 10 and at the same time on the automatic switch blocking device against repeated switching on for a short circuit. The device works as follows. In the absence of damages in the protected network and in the device itself, when the automatic switch is turned off, and the input voltage is applied, the thyristor 10 is locked and no current flows in the tripping electromagnet 7. In this case, both capacitors 5 and 14 are shunted by a block-pin 9 of a switch 8 by means of two diodes 20 and 21, and the input of the integrity control device of the fuse is bounded by a working fuse, as a result of which there is no signal at its output. Contact 11 overcurrent protection and contact 17 of the relay 16 of the discharge capacitor leakage control device are open, since switch 8 is off, and transistors 12 and 13 are locked due to the absence of potential difference on the capacitors 5 and 14. When the automatic switch 8 is turned on, its unit The contact 9 is disconnected, and the discharge capacitor 5 through the resistor 4 and the additional capacitor 14 of increased reliability is charged through the resistor 15. The transistors 12 and 13 remain locked, since the potential difference at their input is zero due to the fact that the constant charging times of the capacitors 5 and 14 are chosen to be equal. Relay 16 is therefore de-energized, and its contact 17 is open. If a short circuit occurs in the network, the overcurrent protection operates. And its contact 11 closes the control electrode circuit of the thyristor 10. The latter opens and the shut-off electromagnet turns off the circuit breaker 8. After the short-circuit current is disconnected, contact 11 of the overcurrent protection opens and block contact 9 the circuit breaker is closed and the thyristor 10 is shunted through diode 2, which is then locked, and the coil 7 is de-energized, due to which the circuit returns to its original state It is also prepared for further work. In the event of a fuse, a fuse 2 is connected to the output of the integrity monitoring device of fuse 6, a signal is applied to the control electrode of the thyristor 10, and the shut-off electromagnet turns off the circuit breaker 8. In the event of a leakage, B is discharged by a capacitor 5, which basically electrolytic capacitors, characterized by a large capacity, but low reliability, are reduced, the voltage on it decreases, and on capacitors 14, increased reliability, which is why metal remains constant, whereby a potential difference is applied to transistors 12 and 13. The transistors 12 and 13 open, the relay 16 is activated and its contact 17 closes the control electrode circuit of the thyristor 10. The latter is unlocked and the shut-off electromagnet 7 turns off the switch 8. The other contact of the relay 16 blocks the ON switch from short-circuit to short-circuit, which indicates a malfunction. the executive body and the inadmissibility of the operation of such switchgear before elimination, an accident. The proposed device increases the reliability of switching off the circuit breaker. 1. The device for switching off the circuit breaker, which contains a voltage transformer connected to the protected network, the secondary winding of which through a series-connected fuse, rectifier and resistor, is connected to the discharge capacitor, the fuse integrity monitoring unit, connected to a voltage transformer, and a key element connected to the switch disconnecting switch, characterized by By the fact that, in order to improve reliability, a leakage capacitor leakage control unit was added to it, made on two transistors of different conductivity, the base of the first transistor of which is connected to the connection point of the positive terminal of the discharge capacitor, the diode of the diode and the disconnecting switch coil, and the base The second transistor is connected through a resistor to the connection point of the positive terminal of the newly introduced capacitor of increased reliability and the anode of the second diode, the cathodes of the diodes through the closing contact off It is connected to the minus output of the rectifier and the combined negative leads, the discharge capacitor and the capacitor of increased reliability, the emitters of transistors of different conductivity are combined, the collector of the first transistor is connected to the negative terminal of the second rectifier, and the collector of the second transistor is connected to the positive output of this rectifier A mittel whose input is connected to a capacitive voltage divider connected via a fuse to the secondary winding of a voltage transformer. 2. The device according to claim 1, characterized in that the key element is made in the form of a thyristor, between the anode and the control electrode of which are connected in parallel connected closing contacts of overcurrent protection and a leakage leakage control relay, a positive terminal is connected to the control electrode and to the cathode - minus output of the fuse integrity control unit. H. The device according to claim 1, characterized in that the fuse integrity control unit is in the form of a transformer.