SU104074A1 - Remote trigger device - Google Patents

Description

The present invention relates to a type of remote signaling starting devices having pulse transformers, the secondary windings of which are separated by means of semiconductor gates, and a starting relay in the actuating circuit.

The invention aims to improve the clarity and reliability of the start-up by attenuating interference from voltage fluctuations feeding the device.

The task is solved with the help of a filter connected between the pulse transformers and the actuator circuit, consisting of the secondary winding of the matching transformer and the connected capacitor in series with it and tuned to the frequency corresponding to the steepness of the current signal.

The drawing shows a schematic diagram of the proposed device, on which is indicated: L - amplifying lamp, H - beginning relay, included in its anode circuit, 1 IT. .. 4IT - pulse transformers.

In the state of readiness of the lamp / 7 circuit is open and the beginning relay P and the repeater PN are excited. When the object is disconnected, its contact n (In ... 24n) closes. The disconnected position of the object corresponds to the closed state of the contact of the RK coding relay circuit, prepared at the corresponding contact of the UIPi finder of the remote signaling installation. In series with the contacts p and the primary windings Wi of the pulse transformers (the circuit provides for six objects for each pulse transformer) load (object) resistors IR are included. .. 24 /, the connection and disconnection of which causes the same current changes in the windings of the pulse transformers.

Theoretically, with simultaneous winding of the on / one and disconnection of another object, the magnetic state of the pulse transformer does not change and therefore the pulse in the secondary winding does not occur.

But if we take into account that the time from the moment of switching the contact in the coding circuit to the moment of breaking the contact is calculated (2 4), then the probability of coincidence of the moment of switching on and off

objects with a similar degree of accuracy caused by different, independent reasons are excluded. Practically, only one case is of interest when one action causes another.

Thus, when any object is disconnected, accompanied by the closure of the corresponding contact n (In ... 24p), the primary impedance of the corresponding impulse transformer IT flows through the primary winding Wi and the magnetic state of its core is induced, and in its secondary winding Wz is induced There is a negative impulse on the lamp grid L. The lamp current decreases dramatically. The starting relay I releases the measles and breaks at its HI contact the anode circuit of the lamp, rigidly fixing thereby the change in the state of the object.

At the same time, the PD relay, which is a follower of the start-up relay I and is required for the multiplication of contacts, drops off the bark.

With its contacts, the ND influences the transfer relays and other nodes of the remote signaling installation (not shown in the drawing) and starts it.

When the unit is bypassed at the first contact of the ShRts finder, the HI contact in the anode circuit of the lamp is shunted through the resistance Ri and the relay I and LI are again excited. At the contact of the seeker, corresponding to the given object, the RK trigger is triggered, fixing the disabled position of the object.

When the object is turned on, the scheme works in the same way.

The letters Wi and Wz denote the windings of the matching transformer Tp, which must be turned on with respect to their polarity, shown in the diagram, and providing, together with the rectifier} B, connected in parallel with the secondary winding W, obtaining the most acceptable pulse shape.

When laid, the flaw half-wave resistance and the RZ leakage and the lamp L are bypassed with a 1V rectifier, and the voltage of the positive half-wave decreases. At the same time, the capacitor C charges. At a negative half-wave, the rectifier 1B does not shunt the resistances R and Rs and, moreover, the voltage on the capacitor Ci turns on according to the voltage on the winding 2 of the matching transformer Tr, which entails an increase in the amplitude of the negative transformer. momentum. Variable resistance Rs allows the sensitivity of the circuit to be regulated.

The circuits of the secondary windings of pulse transformers IT include semiconductor BI - jBs valves, which serve to eliminate the mutual influence of these transformers.

The use of impulse transformers with a large number of input circuits in the described starting arrangement makes it highly sensitive to supply voltage jolts. It is easy to show that even with five impedance transformers connected to a pulse transformer, the impulse amplitude at a jerk voltage is equal to the amplitude of the working impulse, i.e., special measures are required to eliminate the effect of voltage jolts.

It should be noted that shocks (or sharp fluctuations) of the supply voltage can occur not only due to their occurrence in the AC mains supplying the rectifier, but also during the operation of the remote alarm system itself, due to the operation of the relay and the searcher. These voltage fluctuations can reach in some cases large values of ± 7 - {+ 10%.

Thus, it is necessary to reliably build up from voltage jolts, because otherwise during the operation of the installation, the starting relay will spontaneously release, which will make the installation of the remote signaling system impossible.

To eliminate the effects of supply voltage jolts, which

: the reliability of the proposed starting device may be impaired, the difference in the rise rates of the front and the decay of the pulses at the output of the impulse transformers during voltage shocks is used.

The working impulse has a very steep front, limited only by the presence of interturn capacitances and the capacity of semiconductor rectifiers in the secondary winding.

The impulse during a voltage push has a much lower rate of rise of the front, as well as its fall, due to an increase in the time constant of the circuit due to the filter Dp, ICF.

The problem of reducing the amplitude of the pulse when the supply voltage is jolted is solved by introducing into the circuit between the pulse transformers IT and the actuator circuit of the filter formed by capacitor Cc connected in series with the secondary winding of the matching transformer Tr and the dissipation inductance of the latter and tuned to the frequency corresponding to the slope of the rising edge of the signal.

The device carries out continuous monitoring of the operability of the electron — emission, heat, and penetration of the filament to the cathode.

When a lamp burns out or a loss of emission below the permissible value of the relay H is released and is no longer restored. This causes a “crash” signal.

During the breakdown of the heating circuit at the cathode, the latter receives a more positive potential with respect to the grid — the relay I disappears and is no longer restored.

The device has a deeply hard negative feedback, which is obtained due to the large value of resistance R and which significantly stabilizes the operation of the circuit during power supply fluctuations and loss of lamp emission.

Subject invention

A triggering device for remote signaling containing pulse transformers, the secondary windings of which are separated by semiconductor gates, and a starting relay in the actuating circuit, characterized in that, in order to increase the clarity and reliability of the start-up by attenuating the interference caused by the power supply voltage fluctuations, between the pulses a filter consisting of the secondary winding of a matching transformer and a series-connected capacitor connected in series with it and tuned th at a frequency corresponding to the signal current steepness.