CS225930B1 - Circuitry for controlling thyristors with galvanic separation - Google Patents

Description

The invention relates to a circuit for controlling thyristors with galvanic separation of ignition pulse generators from thyristor circuits.

In the phase control of thyristors, which are connected as power actuators of thyristor converters, it is necessary to galvanically isolate the output of the ignition pulse generator from the thyristor circuits. Galvanic isolation of the ignition pulse generator is necessary because the thyristor is in

It is most often connected to the mains voltage and for safety reasons it must not be applied to the ignition impulse generator or to the regulator that controls the generator and is galvanically connected to it.

So far, transformers have been used for galvanic isolation of generator output pulses. The disadvantage of this solution is that a normal transformer does not transmit the unusual edge of the pulses with sufficient steepness, and thus the switching conditions of the thyristors are worsened. Special transformers that carry a leading edge with sufficient slope are complex to manufacture and require high ignition pulse power.

These drawbacks are eliminated by a circuit for controlling thyristors with galvanic isolation according to the invention, which is characterized in that the anode of the thyristor is connected to the cathode of the charging diode, whose anode is connected via a charging resistor to one terminal of the limiting resistor diodes and one capacitor field. The other half of the capacitor is connected to the cathode of the limiting diode and to one control resistor terminal, the other terminal of which is connected to the thyristor control electrode and one damping resistor terminal.

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A second damping resistor terminal is coupled to a thyristor cathode, a limiting anode anode, a Zener diode cathode, a switching transistor collector, and a second optoelectronic coupler input, the first output of which is coupled to the switching transistor base, a second limiting resistor terminal. input resistance. The other input of the input resistor is connected to the input terminal of the wiring. The first wiring control coupling is coupled to the first input of the optoelectronic member, the second input of which is connected to the second wiring control terminal.

The advantage of this circuit is that it is simple, easy to manufacture from available domestic components and galvanically separates the generator circuit from the circuit of transistors with additional electrical strength. Another advantage is that the above mentioned connection can be used for all kinds of ignition pulse generators used so far and various connections of controlled thyristor converters »

An example of a circuit for controlling thyristors with galvanic isolation according to the invention is shown in the block diagram in the attached drawing.

The anode of the thyristor 11 is connected to the cathode of the charging diode 6. The anode of the charging diode 6 is connected via a charging resistor with one terminal of the limiting resistor 2 ^{to the} emitter of the switching transistor 2, cathode of the Zener diode 4 and one pole of capacitor 8. the cathode of the diode limiters 7 and one terminal of resistor 9. the other control terminal of the control resistor 9 is connected to the control electrode of the thyristor 11, and one outlet of the damping resistor 10. the second terminal of the damping circuit 10 is connected to the cathode of the thyristor 11 ^»8 anode of diode limiter 7, with the cathode of the Zener diode 4, with the collector of the switching transistor 2 and with the second input 04 of the optoelectronic switching member 7.

The optoelectronic coupler 1 is a semiconductor element formed by sealing the GaAs diode in the infrared region of the spectrum with a silicon NPN transistor. After pushing enough current through the GaAs, the diode starts to glow and the radiation is sensed by a phototransistor which opens. The first output 03 of the optoelectric coupler 1 is connected to the base of the transistor 2, the second terminal of the limiting resistor 3 and one terminal of the input resistor 12. The second terminal of the input resistor 12 is connected to the input terminal 13 of the wiring. The first wiring control signal 14 is connected to the first input 01 of the optoelectric element 1. The second input 02 of the opteelectric element 1 is connected to the second wiring control terminal 15.

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A damping capacitor 20 may be connected in parallel to the damping resistor 10.

The wiring works as follows:

The controlled converter is connected from thyristors which are controlled by eptoelectric couplers. The ignition of the thyristor is described for one inverter thyristor, the ignition of the other thyristors is the same except that it is only phase shifted.

If there is a negative voltage at the anode of the thyristor 11 - when the thyristor is not conducting current - this voltage charges the capacitor 6 through the charging diode 6, the charging resistor 2 and through the diode limiting 7 by the voltage of the cathode thyristor 11. a diode 4 which is connected via a limiting diode 2 parallel to the capacitor 8. The polarity of the voltage on the capacitor 8 is indicated in the drawing.

If there is then a positive voltage at the anode of the thyristor 11, then the thyristor can conduct current, the capacitor 8 is no longer charging or discharging because the switching transistor 2 is non-conductive.

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If the output pulse from the ignition pulse generator is applied to the control terminals 14, 15 by energizing the pulse through the GaAs of the optoelectric element 1, with the positive pulse polarity on the first control terminal 14, the diode illuminates the phototransistor which opens. . Since the collector and the phototransistor emitter are connected between the collector and the base of the switching transistor 2, the transistor 2 jumps open and is open for the duration of the control pulse on both wiring control terminals 14, 15. Capacitor 8 starts to discharge via the open switching transistor 2. The discharge current of the capacitors 8 flows through the control resistor 9, through a parallel combination of the damping resistor 10 and the control electrode-cathode transition, thyristors 11 and through the switching transistor 2 with limiters connected between base and emitter. a resistor 3 which, when the transistor 2 is closed, maintains the base potential at the emitter potential of the transistor 2. The base of the transistor 2 is provided with an input resistor 12 which allows the switching transistor 2 to be controlled independently of the optoelectric element 1.

Upon application of the ignition pulse, the current flowing through the control electrode opens the thyristor 11 which conducts the current. If the polarity of the voltage changes to a negative value at the anode of the thyristors 11, the thyristor 11 stops conducting current, the capacitor 8 starts charging and the whole process is repeated.

The invention is used to control thyristor transducers and is particularly suitable for controlling single-phase thyristor transducers that drive the drive windings of motors and electromagnetic clutches.

Claims (2)

SUBJECT OF THE INVENTION 1. A thyristor control apparatus with galvanic separation, characterized in that the anode of the thyristor (11) is connected to the cathode of the charging diode (b), the anode of which is connected via a charging resistor (5) to one terminal of the limiting resistor (3). a switching transistor emitter (2), a cathode diode of the kener diode (4) and one pole of capacitors (8), the other pole of which is connected to the cathode of the diode limiter (7) and one terminal of the control resistor (9) a thyristor electrode (11) and one damping resistor terminal (10), the other terminal of which is connected to the thyristor cathode (11), the anode diode limiter (7), the kener diode (4), the transistor collector (2), and with a second input (04) of the optoelectric coupler (1), the first output (03) of which is connected to the base of the switching transistor (2), the second terminal of the limiting resistor (3) and one terminal of the input resistor (12) connected to the input input terminal (13), the first control terminal (14) of which is connected to the first input (01) of the optoelectric element (1), the second input (02) of which is connected to the second connection control terminal (15). The coupling according to claim 1, characterized in that a damping capacitor (20) is connected in parallel to the damping resistor (10).