SU873298A1 - Time relay - Google Patents

Description

The invention relates to automation, in particular to devices for creating a time delay.

A thyristor time relay is known, which allows you to disconnect a load with a time delay of SH. directly from the network.

However, this device even with small time delays requires the use of electrolytic capacitors, which reduces their reliability. ¹

A time relay is also known, which contains a timing ZS-circuit, two thyristors, a switching capacitor, resistors, a diode, zener diodes, and the load in the anode circuit of one of the thyristor ¹ Moat [2].

However, in this device, to obtain long time delays, it is necessary to use a time-setting capacitor of large capacity.

The aim of the invention is to increase the utilization rate of the capacitance of the timing capacitor.

This goal is achieved in that in a time relay containing a timing circuit made in the form of two resistors and a capacitor connected in series, an isolation diode connected between a common connection point of the second terminal of the first resistor and the first terminal of the second resistor and a common connection point of the second terminal of the second resistor ' and one of the plates of the time of the back of the capacitor, the other plate of which is connected to the cathode of the thyristor, the load is included in the anode circuit of the latter, and the control electrode is included start key, transition control electrode - thyristor cathode is shunted by a resistor ^ thyristor is connected to the output of the rectifier bridge, a capacitor, an additional diode is introduced, the anode of which is connected to the thyristor cathode, the cathode is connected to the connection point of the thyristor control electrode and one of the capacitor plates, the second lining of which is connected to the common point of connection of the first clamp of the second resistor, the anode of the diode diode, included in the forward direction for the charge current time ·; the master capacitor, and the second terminal of the first resistor, the first terminal of which is connected to the anode of the thyristor.

The drawing shows a circuit diagram of a time relay.

The time relay contains a timing circuit made in the form of resistor ¹ ditch I and 2 and a capacitor 3, an isolation diode 4, a thyristor 5, a load 6, a start key 7, and a current limit. a resistor 8, a resistor 9, a capacitor 10, a diode 11. The device is powered through a rectifier bridge 12..

The time relay works as follows: When the device is connected to the network through the load resistance 6, resistor 1 and diode 4, the resistor 5 starts to charge the time-setting capacitor 3, also through the load resistance 2, the resistor 8, and the control transition of the thyristor 5 charges the capacitor 10. The capacity of the time-setting of the capacitor 3 is selected 7-10 times larger than the capacitance of the capacitor 7, the resistance of the resistor 1 is also significantly greater than the resistance of the load 6. Therefore, the charge current of the capacitors 3 and 10 is determined by the resistor 1. So ak capacitor 3 is considerably larger capacitance capacitor 10, the charge of ^ 5 ^ Res total resistance of the charging current of the capacitor 10 is much smaller than the charging current of the capacitor 3, this current is insufficient to turn on the thyristor 5, so the capacitors 3 and 10 charges to a voltage. The device is turned on by a start key 7, when it is closed, voltage is applied to the control electrode of the thyristor 5 through a resistor 8, When the thyristor 5 is turned on, the capacitor 10 through, resistor 1, thyristor 5 and diode 11 are discharged. The capacitance of the capacitor 10 and resistor 1 is selected so that the capacitor 10 has time to discharge in a time shorter than the duration of one half-period of the supply voltage. Therefore, by the end of the half-cycle, the thyristor 5 is turned off, and at the beginning of the next half-cycle, the capacitor 10 starts

873298 ⁴ charging, turns on the thyristor 5, This process is repeated in each subsequent half-cycle, that is, the load 6 is connected to the network "When the thyristor is turned on, part of each half-cycle is cut off and short pulses of voltage appear at the anode of the thyristor, 5-10% of the voltage nutrition. Capacitor 3 is discharged through resistors 1 and 2 and the thyristor

5. The discharge time constant of the capacitor 3 determines the time delay of the relay. As soon as the capacitor 3 is discharged to a voltage lower than the voltage of the pulses at the anode of the thyristor 5 when it is turned on, then at the next half-cycle it starts to be charged together with the capacitor J0, while the charge currents are redistributed between them and the current of the capacitor 10 becomes insufficient to turn on the thyristor 5. Load 6 is disconnected from the network, and capacitors 3 and 10 are charged to the full voltage of the network, t * e. the device returns to its original state and is ready for barely turning on.

Due to the fact that in the proposed time relay, the thyristor turning on process does not depend on the discharge current, the time of the master capacitor, the discharge current can be chosen arbitrarily small, which allows one to obtain large time delays with a relatively short time. capacities of the timing capacitor.

Claims (1)

(54) TIME RELAYS The invention relates to automation, in particular, devices for creating time delays. A thyristor time relay is known, which allows disconnecting a load with a time delay fll directly from the network. However, this device, even at short time intervals, requires the use of electrolytic capacitors, which reduces their reliability. It is also known that the time relay, which contains the time setting the NS circuit, the thyristor, the switching capacitor, the resistors, the diode, the zener diodes, the load on the anode circuit of one of the thyristors G2. However, in this device, it is necessary to use a time-setting capacitor of a large capacity to obtain long time exposures. The aim of the invention is to increase the capacity utilization time of the driving capacitor. The goal is achieved by the fact that in a time relay containing a master circuit, made in the form of two resistors connected in series and a capacitor, a dividing diode connected between the common connection point of the second terminal of the first resistor and the first terminal of the second resistor and the common connection point of the second clamping the second resistor and one of the plates, the time of the driving capacitor, the other facing of which is connected to the thyristor cathode, is loaded into the anode circuit of the latter, the electrode is turned on in the control unit The start key, the control electrode - thyristor cathode transition is bounded by a resistor | 1 the thyristor is connected at the output of the rectifying bridge, a capacitor, a diode is additionally inserted, the anode of which is connected to the thyristor cathode, the cathode to the connection point of the thyristor control electrode and one of the capacitor plates . the second plate of which is connected to the point of connection of the first scoop of the second resistor, the anode of the separation diode, connected in the forward direction for the charging time of the driving capacitor, and the second terminal of the first resistor, the first clip of which is connected to the thyristor anode. The drawing shows a circuit diagram of a time relay. The time relay contains the time I set. a common circuit made in the form of resistors I and 2 and capacitor 3, separation diode 4, thyristor 5, load 6, start switch 7 and current limiting resistor 8, resistor 9, condensate $ p 10, diode P. Power is supplied to the device through a rectifying bridge 12.-. The time relay works as follows. When the device is connected to the network through the load resistance 6, the resistor 1 and the diode 4, the resistor 5 starts charging time, the master capacitor 3, also through the load resistance 2, resistor 8, and the thyristor 5 controlling the transition, the capacitor 10 is charged. the drive capacitor 3 is chosen 7-10 times greater than the capacitance of the capacitor 7, the resistance of the resistor 1 is also significantly greater than the resistance of the load 6. Therefore, the charging current of the capacitors 3 and 10 is determined with the resistor 1. Since the capacitance of the capacitor 3 is significantly b If the capacitor 10 capacitance is 10, then when charging them, the total resistance is the capacitor 10's charging current is much lower than the capacitor 3's charging current, this current is not enough to turn on the thyristor 5, so the capacitors 3 and 10 charge up to the mains voltage. The device is turned on by the start key 7, when it is closed, a voltage is supplied through the resistor 8 and the control electrode of the thyristor 5. When the thyristor 5 is turned on, the capacitor 10 goes through the resistor 1, thyristor p 5 and the diode 11 times. The capacitance of the capacitor 10 and resistor 1 is selected so that the capacitor 10 has time to discharge in less than one half-period of the supply voltage. By the end of the half-period, the thyristor 5 is turned off, and at the beginning of the next half-period, condensation generator 10 begins to appear, turns on the thyristor 5, This process is repeated in each subsequent half period, i.e. The load 6 turns out to be connected to the network. When the thyristor is switched on, part of each half-period is cut off and short impulses are generated at the thyristor anode, with a voltage of 5-10% of the supply voltage. Capacitor 3 is discharged through resistors 1 and 2 and thyristor 5. The constant discharge time of capacitor 3 determines the time delay of the relay. As soon as the capacitor 3 is discharged to a voltage lower than the voltage of the pulses on the anode of the thyristor 5 when it is turned on, during the next half-period it begins to charge together with the capacitor JO, the charge currents are redistributed between them and the current of the capacitor 10 becomes insufficient to turn on the thyristor 5. The load 6 is disconnected from the network, and the capacitors 3 and 10 are charged until the network is fully energized. Tie. the device returns to its original state and is ready for barely; next inclusion. Due to the fact that, in the proposed time relay, the thyristor turn-on process does not depend on the discharge current time of the driving capacitor, the discharge current can be chosen arbitrarily small, which makes it possible to obtain long delays for a relatively small capacitance time of the driving capacitor. The invention of the time relay containing the time of the master circuit, made in the form of serially connected two resistors and a capacitor, a separation diode connected between the common connection point of the second terminal of the first resistor and the first terminal of the second resistor and the common connection point of the second terminal of the second resistor and one of the plates of the master capacitor, the other lining of which is connected to the thyristor cathode, a load is included in the anode circuit of the latter, a switch key is included in the control electrode, The thyristor control elec- tro-cathode is shunted with a resistor, the thyristor is connected at the output of the rectifying bridge, a capacitor, characterized in that, in order to increase the capacity utilization rate, the control electrode of the thyristor and one of the capacitor plates, vtdra the facing of which is connected to the common connection point of the first terminal of the second resistor, the anode of the separation diode, turned on forward na8 board for current charge time zadamschego kovdensatora, and a second terminal of the first resistor, a first clamping member which is connected to an6du thyristor. Sources of information taken into account in the examination 1. Radio, 1977, W 5, s, 54. 2 -.- Kublanovsky Ya. S. THpHCtopHbie devices. M., Energie, p. 42-43,