SU1647797A1 - Device for controlling triac - Google Patents

Abstract

The invention relates to electrical engineering and can be used in power switching links of single or periodic operation. The purpose of the invention is to expand the functionality of the device. For this purpose, to form single pulses, the switch is set to position a, and for periodic generation of pulses - to position b. During the periodic formation of pulses, unlocking the thyristor by the control current of the triac causes the relay to operate. As a result, the capacitor is disconnected from the network and discharged to the relay coil. After the capacitor is discharged, the relay returns to its initial state, and its contact connects the capacitor to the network. When forming a single pulse, the operation of the relay does not lead to the disconnection of the network axis capacitor. 1 il.

Description

The invention relates to electrical engineering and can be used in power switching links of single or periodic operation.

The aim of the invention is to expand the functionality of the device.

The drawing shows an electrical diagram of a device for controlling a simulator.

A device for controlling a triac 1. connected through the load resistor 2 to the poles of the network, contains a transformer 3. The primary winding 4 of the transformer 3 is connected to the poles of the network. The secondary winding 5 of the transformer 3 extreme terminals connected to the inputs 6i and 62 of the switch 6 polarity. The middle point of the secondary winding 5 is connected to one output of the capacitor 7, to the cathode

the first thyristor 8 and one output of the first resistor 9. The other output of the first resistor 9 is connected to the cathode of the second thyristor 10 and one output of the second resistor 11. The other output of resistor 11 is connected to the control electrode of the first thyristor 8, the anode of which through the third resistor 12 connected to the control electrode of the second thyristor 10. The anode of the latter is connected to the power output of the triac 1 and the anode of the first zener diode 13. The cathode of the latter is connected to the connection point of the anode of the third thyristor 14 by the output 6 of the polarity switch 6.

The cathode of the thyristor 14 is connected to the control electrode of the triac 1. To the anode and cathode of the thyristor 14 is connected the input of the phase-mounted unit 15, the output of which is connected to the control electrode of the thyristor 14. To the output 64 of the switch 6

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polarity, the anode of the starting diode 16 is connected. The cathode of the latter is connected through the ballast resistor 17 to the input of the two-pole control switch 18. The first output of the latter is connected to another output of the capacitor 7, in parallel with which a second Zener diode 19 is connected. The connection point of the cathode of the Zener diode 19 to another output of the capacitor 7 is connected via a current relay coil 20 to the anode of the first thyristor 8. The coil of the relay 20 is bounced by a buffer diode 21 connected the cathode with the cathode of the Zener diode 19. The second output of the control switch 18 through the disconnecting contact 22 of the current relay 20 is connected to the connection point of the cathodes stz5litron 19 and the buffer diode 21 and the other output of the capacitor 7 with cat shkoy relay 20 current. Parallel to the first thyristor 8, the closing contact 23 of the current relay 20 is connected.

The device for controlling the triac operates as follows.

When forming single pulses, control switch 18 is set to position a, and for periodic single pulse generation control switch 18 is set to position b. The polarity of the generated pulses is determined by the position of the switch 6 of the polarity. Consider an example of the periodic formation of control pulses for multiple triac unlocking 1. For this purpose, the switch 18 is connected to pole b. The polarity switch 5 is set to the position at which poles 6i and 6z, 6z and 64 are connected. In this case, with half-waves of positive polarity on pole 64 of switch 6, through diode 16, resistor 17, switch 18, pole b, through disconnecting contact 22 of relay 20 to the capacitor 7 receives a charge current.

Then, the voltage removed from the Zener diode 19, through a chain of the coil of the relay 20 and the resistor 12, is applied to the control electrode of the thyristor 10.

When the control current of the thyristor 10 is flowing through the coil of the relay 20, this relay cannot operate because the device has selected a relay with a response current greater than the control current of the thyristor 10. Unlocking the latter in the positive half-period of the voltage (relative to the anode of the diode 16) prepares the control circuit of the triac 1. When changing the polarity of the mains voltage, the positive half-wave voltage is removed from the pole 6 of the switch 6 and through the thyristor 14 is fed to the control electrode of the triac

1. The amplitude of this half-wave is limited by the Zener diode 13. At the same time, the control current passing through the ballast resistor 17 and the thyristor previously opened

10 also affects the thyristor control transition 18. The latter is unlocked and shunts the thyristor control transition 10, the unlocking of the thyristor 8 causes an increase in the current in the coil circuit of the relay 20,

0 which reaches the relay trigger value.

When the relay 20 trips, contact 22 opens, disconnecting the storage capacitor 7 from the pole 64 of switch 6,

5 i.e. from the power source. Contact 23 closes, shunt thyristor 8. Thus, thyristor 10 turns out to be locked and cannot miss the positive half-waves of triac driving in the following

0 half a half, and the contact 22 remains open for the time of the discharge of the capacitor 7 to the coil of the relay 20. Depending on the capacitance of the capacitor 7 it can be from fractions of a second to units or tens of seconds.

5 After the discharge of the capacitor 7 to the value at which the discharge current is less than the holding current of the relay 20, this relay returns to its initial position, i.e. Contact 23 opens, deactivates the thyristor 8, and closes0 the contact 22, connecting the positive capacitor 7 to the pole b. In this process, the formation of a single pulse control triac 1 is repeated,

5 The device is disconnected by setting switch 18 to the neutral position. To form a single pulse, switch 18 is connected to pole a. 8 this case after unlocking

0 of the thyristor 10 and the supply of control current to CHNtwcTOp 1 according to the described technology, the thyristor 8 is unlocked. The latter shunts the control transition of the thyristor 10 and simultaneously controls the control transition of the thyristor 10 and simultaneously causes an increase in the current of the coil of the relay 20 to the value of the operation current. However, the operation of the relay 20 does not lead to the disconnection of the capacitor 7 from the pole a. eight

As a result, only one one-period pulse is generated. The pulse polarity is determined by the position of the polarity switch 6.

Claims (1)

Invention Formula 5 A device for controlling a simstrom containing a transformer, the primary winding of which is intended to be connected to an AC network, the outermost terminals of the secondary winding are connected to the inputs of a polarity switch, The middle point of the secondary winding is connected to one capacitor lead, the cathode of the first thyristor and one lead of the first resistor, the other lead of which is connected to the cathode of the second thyristor and one lead of the second resistor, the other lead of which is connected to the control electrode of the first thyristor, the anode of which is connected through the third resistor with the control electrode of the second thyristor, the anode of which is designed to "connect to one power terminal of the triac and is connected to the anode of the first zener diode, the cathode of which is connected with the anode of the third thyristor and the first output of the polarity switch, the cathode of the third thyristor is designed to be connected to the control electrode of the triac, the phase-shifting unit, the output of which is connected to the control electrode of the third thyristor, the starting diode, the anode of which is connected to the second output of the polarity switch A control switch, characterized in that, in order to extend the functionality, current relays are introduced with one open and one normally open contact, a buffer diode, a second zener diode and a ballast resistor, and the control switch is designed as a bipolar switch with a neutral position, with the cathode of the starting diode connected to one output of the ballast resistor, the other output of which is connected to the input of the control switch, one output output of which is connected through the disconnecting contact of the current to the cathode of the second a zener diode, another capacitor lead, a buffer diode cathode, one coil lead of the current relay, and a single output pin of the control switch; another coil lead of the current relay is connected to the anode of the buffer diode, the anode of the first thyristor and through the closing contact with one output of the capacitor and the anode of the second zener diode.