SU137570A1 - Three-phase automatic reclosing (AR) device of double action - Google Patents

Description

Three-phase automatic reclosing (AR) devices of double action are known, having a trigger element, a time delay element of the first and second AR cycle, and a performer circuit with an output relay.

The disadvantage of such devices is that the presence of contacts in the device complicates its design and reduces the reliability of operation.

In the described device, this disadvantage is eliminated by the fact that two independent RC circuits are used as the time delay elements of the first and second AR cycles, and two separate switches made on cold cathode tiratrons are used as the executive body.

The drawing shows a schematic diagram of the device.

The device consists of two circuits identical in structure, corresponding to the first and second AR cycles, and circuits common to both cycles. The first and second circuits are formed by working capacitances C, and C, respectively, with charging resistances d.1 and ensuring the operation of the output relay device, measuring capacitances C „„ resistance 7i and 711 of the relaxation generator, indicating relays Ry and Split tiratrons T, and, with a cold cathode, decoupling diodes D and D ;, as well as auxiliary resistors / ,; and R ,, The common elements for both cycles of the device are: stabilovolt St, the output intermediate relay relay and the voltage divider on the resistances R, R-2, R vi R. The values of the latter are selected so that before the start of the circuit (contact closure / 7) the voltage on the resistance Rz is small, and on the resistance R 4 is sufficient to charge the working capacitors C and C ,, of the device.

AO 137570-2 Under these conditions, when the operating current is connected to the AR device, its working capacitances begin to charge, while a negligible charge of measuring capacitances can be almost neglected. A charge sufficient to operate the output relay accumulates on the working capacitances over time, depending on the constants. time contours Q, and determined by the requirements of the readiness of the device to action.

The device is started up for the object being switched on by closing the contact P, which leads to the shorting of the resistances RZ and the voltage divider, as a result of which the voltage across the resistance R increases to a value which, being stabilized, is sufficient for reliable control of the tira- trons. Measuring capacitances begin to charge through resistances RJ. By varying the magnitude of these resistances, the time delays of the first and second cycles vary. The steps of the variable resistances RJ are chosen so that the shutter speed range of both cycles varies within the desired limits. The required accuracy of time exposures is provided by the stabilization of the voltage of the chains of relaxation generators by the stability of Art.

With increasing voltage on the measuring capacitance C ,, of the first cycle to a value sufficient to unlock the thyratron Gl, the latter is ignited and the capacitance C is discharged through it and the indicating relay RU1 to the working winding of the output relay. Unlike contact switching, the capacitance is not fully discharged, and the voltage drops to a level determined by the voltage drop on the open (high) thyratron.

As a result of the discharge of the capacitance, the output relay is briefly triggered and, closing its contacts in the circuit of the on / off switch, self-holds in this position with its successive holding winding. The action of the AR device in the first cycle is signaled by the alarm relay RU. At the end of the activation process, the output relay returns to its original position.

If the action of the automatic reclosing operation was unresolved and the switch remained in the on position, then after opening of the start-up I contact, the device returns to its original position. In this case, the working capacitance of the first cycle is recharged to a voltage sufficient for the output relay to work, and the measuring capacitances of both cycles are discharged through resistance R to their initial (very small) values.

If the automatic reclosure was unsuccessful in the first cycle, then a new switch tripping will cause the automatic reclosure to restart. The latter may work on the chains of the second cycle, which did not have time to act on the relay when the switch was first disconnected. Indeed, an unlocking with an appropriate time delay tiratron G. sp. the relaxation generator of the second cycle provides the possibility of low-frequency discharge of the parallel winding of the output relay (via the signal relay RUC) of a capacitor, 7, whose energy is completely conserved due to the presence of a diode D in its charging circuit. The output relay triggers briefly and just as first cycle, turns on the switch. If it turned out to be successful, then after opening the start-up contact / 7, the device circuit returns to its original position and through the ready time during which the working tanks C, of both cycles accumulate sufficient energy, the device is ready for action again.

If the automatic reclosure is unsuccessful in the second cycle, then a new (third) switch-off opens the contact I, which, as discussed above, eliminates the possibility of charging working capacitors. Since now both capacitors Cp and CpU are discharged, the automatic reclosing device will not be able to produce a new reclosing. This position is maintained until the automatic reclosing device is again prepared for the action, which will happen in the usual way, disassembled above, by switching the circuit breaker postoperatively.

Subject invention

A two-phase, three-phase automatic reclosing (AR) operation device comprising a trigger element, time delay elements of the first and second AR cycle, and an actuating circuit with an output relay characterized by. that, in order to simplify the device and increase its reliability, as elements of the time delay of the first and second AR cycles, two independent RC circuits were used, and two separate switches made on cold cathode thyratrons were used as the executive body.