SU999122A1 - Timer - Google Patents

Description

(54) TIME RELAY

This invention relates to capacitor transistor time relays that are widely used in automatic control devices, communications, telemechanics, and other fields of technology.

The proposed solution is referred to as a small-sized thermostable relay and is used in automatic control devices, communications and telemechanics of moving objects and objects with autonomous power sources.

Known capacitor time relays containing a zero-body, time specifying the KS circuit, the first and second thyristors fl.

Due to the inclusion of the first and then the second thyristor, the accumulation of time intervals occurs, which allows a long time delay to be formed. At the same time, with the inclusion of each thyristor, the power consumption of the time relay increases, which causes its overheating and a decrease in the accuracy of the time delay.

To increase the dwell time, the number of thyristors is increased, which leads to further

increasing energy intensity, overheating and reduced accuracy. Increasing energy intensity not only leads to overheating and reduced accuracy, but also makes it difficult to use it further, for example, when designing a time relay on an NMKPO assembly.

A capacitor transistor time relay is known, which contains a null organ with an input driving RC circuit and an output transistor control unit, first and second thyristors, RC thyristor control circuits, the first of which is inserted parallel to the anode load of the first thyristor, and the second is connected to the plus bus and the cathode of the second thyristor, and transistors connected by collectors and emitters

20 to the midpoints of these RC circuits and C2 thyristor cathodes.

Claims (2)

Introduction of additional elements to the time relay, such as thyristors, transistors, RC circuits, and connection, in a certain way allows one to ensure the sequential disconnection of the first and second thyristors. However, this does not reduce the energy consumption in the process of forming the time, since the main drawback of the circuit, the increase in energy intensity with the inclusion of each subsequent thyristor, is preserved. The disconnection of the thyristors only begins here only after the inclusion of all the thyristors (first and second) will fully complete the time delay. Thus, the second known time relay retains an increased power consumption, the result of which is overheating and a decrease in the accuracy of the time delay. The purpose of the invention is to simplify the circuit, reduce energy consumption and improve accuracy. To achieve this goal, a time relay containing an RC circuit connected through a diode between the power supply buses, a null organ whose input is connected to the output of an RC circuit, the first and second thyristors, RC thyristor control circuits , the first of which is connected in parallel to the anode load of the first thyristor, and the second is connected to the positive power supply bus and the cathode of the second thyristor, two transistors connected by emitters to the middle points of the thyristor control RC circuits, and collectors to cathodes t The base of the transistor connected to the second RC control circuit is connected to the anode of the first thyristor, the control transistor connected to the base emitter junction parallel to the diode, and the collector to the midpoint of the RC control circuit, the second thyristor, the main RC circuit, the transistors connected to the RC control circuits are made with pnp conductivity, the base of the transistor connected to the first RC control circuit is connected to the collector of the control transistor, the control electrode of the first thyristor ra is connected to the output have more, RC-circuit connected between the power supply rails. Due to the use of transistors of the pp conductivity and the connection of the base of one of them and the control electrode of the first thyristor in the proposed way, the first thyristor is disconnected simultaneously with the inclusion of the second thyristor, which reduces power consumption and overheating of the time relay. This improves accuracy by reducing the superheat temperature and simplifies the time relay circuit, since there is no need for additional thyristors, RC circuits for their control, additional transistors and a pulse generator. The drawing is a circuit diagram of a time relay. The time relay contains an RC driver circuit on resistor 1 and capacitor 2, the common connection point of which is connected to the emitter of the single junction transistor .3, which is a null organ, the first thyristor 4 and the second thyristor 5, RC control circuits of the first and second thyristors, consisting of a resistor b and a capacitor 7 and a resistor 8 and a capacitor 9, respectively, a transistor 10 pnpp of conductivity for controlling the thyristor 4 and a transistor 1-1 of the same type of conductivity for control thyristor 5. The time setting of the RC circuit on resistor 1 and capacitor 2 is connected by a resistor to the positive bus 12, and a capacitor through the diode 13 to the negative bus 14. A resistor 15, which is the anode load of the thyristor 4, is also connected to the positive bus, and the output winding an electromagnetic relay 16 which serves as a load for the thyristor 5. The cathode of the thyristor 4 is connected to the 1 inyc bus 14 directly, and the cathode of the thyristor 5 through a diode 17, the control electrode of the thyristor 5 is also connected to the negative bus 14. The control electrode of the thyristor 4 connects It is not connected to the positive bus 12 via a capacitor 18. The RC control circuit (resistor 6, capacitor 7) is connected to thyristor 4 by parallel to resistor 15. Another circuit is similar to RC circuit (resistor 8, capacitor 9) is connected to the positive bus and to the thyristor cathode 5 The emitters of transistors 10 and 11 are connected to the middle point of RC circuits (resistor 6, capacitor 7 and resistor 8, capacitor 9), and the collectors are connected to the cathodes of thyristors 4 and 5. At the same time, the base of transistor 11 is connected to the thyristor anode 4, and the base of the transistor 10 is connected to the transistor 19 of the control unit associated with the output of a single transistor 3. The relay-stand transistor comprises a control transistor 19, the control node contacts 20. The relay operates in the following manner. When the power supply is connected to the servers 12 and 14, the charge through the resistor starts to charge the capacitor 2. Simultaneously the capacitors 18 and 7 are charged. At the same time, the thyristor 4 is turned on by the charge of the capacitor 18, the capacitor 9 remains uncharged because its plates are bypassed collector -emitter junction of an open transistor 11. As soon as the voltage on the capacitor 2 reaches the value of the switching voltage of the single junction transistor 3, the resistance of its emitter-second junction is avalanched and the cond Sensor 2. is discharged through the control junction of the transistor 19. As a result of this bit, the transistor 19 opens and forms a circuit for the base current of the transistor 10, which also goes to the open state and provides the conditions for the discharge of the capacitor 7 through the cathode-anode thyristor junction 4 and its shutdown. Simultaneously with the disconnection of the thyristor -4, the transistor 11 is closed, the base of which is now connected to the positive bus via a resistor 15. With the end of the discharge of the capacitor 2 and the turning off of the thyristor 4, the formation of the first time interval begins and the charge of the capacitor re-starts 2. At the same time, the capacitor 9 is charged. With an increase in the voltage on the capacitor 2 to the turn-on voltage of the single junction transistor 3, the process of discharge of the capacitor repeats in the same sequence as during the formation of the first time interval. In this case, the capacitor 9 is discharged through the transistor 19, the diode 1 and the thyristor control transition 5, which becomes conductive, the coil of the electromagnetic relay 16 is connected to the negative bus 14. As a result, the relay is activated and its contacts 20 fix the end of time delay . Thus, in the proposed time relay, an increase in power intensity with the inclusion of the first and then the second thyristor is really excluded. At the same time, the reduction of energy consumption is achieved while simplifying the scheme. Obviously, a decrease in energy intensity reduces the overheating in the relay, and, consequently, it allows to obtain greater accuracy without the use of any special technical means. The invention of the time relay containing the time of the giving RC circuit connected through a diode between the power supply buses, a null organ whose input is connected to the output time of the master RC circuit, the first and second thyristors, the RC thyristor control circuit, the first of which are connected in parallel to the anode load of the first thyristor, and the second is connected to the positive power supply bus and the cathode of the second thyristor, two transistors connected by emitters to the middle points of the thyristor control RC circuits, and to collectors - to the thyristor cathodes for the transistor connected to the second RC control circuit is connected to the anode of the first thyristor, the control transistor connected to the base-emitter junction parallel to the diode, and the collector to the midpoint of the RC control circuit, the second thyristor, an additional RC- A circuit characterized in that, in order to simplify, reduce power consumption and increase accuracy, transistors connected to the RC control circuit are made with pnp-conductivity, the base of the transistor connected to the first RC control circuit is connected with collector control The control transistor of the first thyristor is connected to the output of an additional RC circuit connected between the buses of the power source. Sources of information taken into account in the examination 1. USSR author's certificate number 493826, cl. H 01 H 47/18, 25.12.73.2. Author's certificate of the USSR 554568, cl. H 01 H 47/18, 29. 09.75 (prototype). R itff J