SU750607A1 - Timer - Google Patents

Description

(54) TIME RELAY

one

The invention relates to a semiconductor time relay and can be used in devices for automation, telemechanics, communications, etc.

Time relays are known that contain an RC driver circuit, a zero-organ, thyristors with loads in the anode circuits, and a switching capacitor 1.

However, the known time relays do not provide sufficient time lag stability with a change in the voltage of the power source and the ambient temperature.

Also known are time relays that are free from this drawback, in which a single junction transistor 2 is used as a zero-body.

However, the known time relays cannot be used in cases where contactless control of external devices or loads that do not have a galvanic connection to the load controlled by this time relay is required.

A time relay 2 is taken as a prototype, providing periodic

operation of two galvanically coupled loads.

However, this time relay cannot be used in cases when it is necessary to switch on the load only for a certain time, as well as to carry out the series connection or the periodic operation of several galvanically uncoupled loads.

The purpose of the present invention is to create a time relay capable of performing the above operations, i.e., to extend the functionality of the time relay.

Claims (2)

To achieve this goal, a time relay containing a cascade consisting of main and auxiliary thyristors with loads in anode circuits connected by cathodes to the negative pole of the power supply is an intermodal switching capacitor connected to an RC circuit connected in parallel with the main thyristor and a single junction transistor whose emitter is connected between the capacitor and the resistor of the RC circuit, and one base is connected via a resistor to the positive pole of the source, additionally equipped with cascades p on the number of time exposure ranges and a pulse transformer in each stage, the primary winding of which is connected between the first base of the single junction transistor and the anode of the main thyristor, one of its secondary windings is connected between the control electrode and the cathode of the auxiliary thyristor of its cascade, and the other secondary winding is connected between the control the main thyristor of the subsequent cascade, and one of the secondary windings of the pulse transformer of the last stage is switched on through a diode between at the control electrode and the cathode of the main thyristor of the first stage. The drawing shows a circuit diagram of the described time relay. The relay contains primary 1 and auxiliary 2 thyristors with resistors 3 and 4 in the anode circuits, switching capacitor 5 connected between the thyristor anodes, time defining an RC circuit consisting of resistor 6 and capacitor 7 connected in parallel to load 3 of the main thyristor and single junction a transistor 8 used as a null organ, the emitter of which is connected to the output of an RC master circuit (the connection point of a resistor 6 and a capacitor 7), the second base is connected via a resistor 9 to the positive pole of the power source, and first cutting the primary winding of the pulse transformer 10 - with the anode of the main thyristor. One of the secondary windings of the pulse transformer 10 is connected between the control electrode and the cathode of the auxiliary thyristor 2, and the other secondary windings are used for contactless control of external circuits. The described time relay works as follows. In the initial state, when the supply voltage is applied, the thyristors 1 and 2 of the time relay are closed. The time relay is triggered by applying a positive pulse from an external triggering circuit between the control electrode and the cathode of the main thyristor 1. In this case, the thyristor 1 opens and connects the resistor 2, the time of the driving RC circuit (resistor 6 and capacitor 7) and the single junction transistor 8 to the source nutrition The capacitor 7 begins charging the RC circuit through resistors 6 and open thyristor 1. When the voltage on capacitor 7 reaches the response threshold of the single junction thyristor 8, the latter opens and the capacitor 7 discharges through the emitter-first base of the single junction transistor and the primary pulse winding transformer 10. The voltage pulse generated in the secondary windings of the transformer opens an additional thyristor 2, as a result of which the switching capacitor 5 charged through the load 4 additional thyristor 2 and open main thyristor 1 to the voltage of the power source, begins to discharge through the thyristor 2 and the transition of the cathode-anode of the main thyristor 1. As a result, the current through the main thyristor 1 decreases to a value less than the holding current, and the thyristor 1 is closed . The resistor 4 of the auxiliary thyristor 2 is selected such that the open thyristor current is less than the holding current, i.e., after closing the main thyristor 1, the additional thyristor 2 also closes and the circuit returns to its original state. For the series connection of several galvanically unrelated loads, similar time relay cascades are interconnected so that the additional secondary winding of the pulse transformer of the previous cascade is connected between the control electrode and the cathode of the main thyristor of the subsequent cascade. The drawing shows the inclusion of two cascades of time relay. At the same time, at the moment of switching off the main thyristor 1 of the first stage, the main thyristor 1 of the second stage turns on. If it is necessary to perform periodic work of the loads, the additional secondary winding of the pulse transformer of the last stage is connected through diode 11 between the control electrode and the cathode of the main thyristor of the first stage (shown in dotted lines). At the same time, when the main thyristor of the last stage is turned off, the main thyristor of the first stage turns on and the cycle repeats. This time relay will allow you to control the operation of several loads according to a predetermined program. Claim 1. A time relay comprising a cascade consisting of main and auxiliary thyristors with loads connected by cathodes to the negative pole of the power source with resistors in the anode circuits, an intermodal switching capacitor, an RC driving time connected in parallel with the main thyristor resistor and a single junction transistor, the emitter of which is connected between the capacitor and the resistor of the RC circuit, and one base is connected via a resistor to the positive pole of the power source, characterized by that. that, in order to extend the functionality by specifying the time exposure ranges, it is equipped with additional stages by the number of time exposure ranges and a pulse transformer in each stage, the primary winding of which is connected between the other base of the single junction transistor and the anode of the main thyristor, and one of its secondary windings is connected between the control electrode and the cathode of the auxiliary thyristor of its cascade, and the other secondary winding is connected between the control electrode and the cathode ohm main thyristor subsequent cascade. 2. A device according to claim 1, characterized in that, in order to provide a relaxation mode, one of the secondary windings of the pulse transformer of the last stage is connected via a diode between the control electrode and the cathode of the main thyristor of the first stage. Sources of information taken into account in the examination 1. USSR author's certificate number 444328, cl. H 01 H 47/18, 1972. 2. USSR author's certificate number 530455, cl. H 01 H 47/18, 1975.