SU957371A1 - Thyristor control device - Google Patents

Description

one

The invention relates to prestage equipment and can be used in the construction of controlled semiconductor voltage and current converters.

Known devices for controlling thyristors include a transistor, a resistor, a phase-shifting capacitor, and terminals for connecting a current source and a thyristor SP. Q

A disadvantage of the known devices is the limited operational capabilities due to the fact that the control is carried out by changing the resistance value.

Closest to the present invention is a thyristor control device comprising a series-connected transistor control element, a diode bridge, a control unit, and terminals for connecting the anode, cathode, and control electrode of the thyristor 2.

A disadvantage of the known device is a limited phase shift, due to the need for significant control voltage.

The purpose of the invention is to create a maximum phase shift during amplitude-phase control of the thyristor.

Claims (2)

The goal is achieved by the fact that in the device for controlling the thyristor the control unit is made on the basis of two diodes and a transformer, the input winding of which is connected; not the first lead to the first output terminal of the diode bridge and the second lead through the serially connected first diode and resistor to the base of the transistor of the regulating element and simultaneously to the first lead opposite the switched output winding of the transformer, the lead of which is connected via a second diode to the terminal for connecting the control electrode of the thyristor The terminals for connecting the anode and cathode of which are connected respectively to the anode of the first diode and the second output post of the diode bridge. The schematic diagram of the device for controlling the thyristor is shown in Fig. The device contains a regulating element on a transistor 1 with the first 2 and second 3 resistors, a diode bridge 4, a transformer 5 with a successor JHO-oppositely turned on input i (per-switch) 6 and output (secondary) 7 windings, the first 8 and second 9 diodes. The cathode of the second diode 9 is connected to the terminal for connecting the control electrode of the thyristor 10, in series with which the load 11 is connected. The control device of the thyristor operates as follows. In the absence of a control signal at the base of transistor 1, the current in the primary winding 6 of transformer 5 is absent, however, the thyristor 10 is open, as the current in the control electrode circuit flows through the secondary winding 7 of transformer 5 and through diode 9 playing the role of a full-wave rectifier. current is thus set to the initial minimum opening angle of the thyristor 10 in the range of 10–12 el. depending on the active (ohmic) resistance of the secondary winding 7 of the transformer 5. When the control signal Uynp is applied through the Emitter-collector transition of the transistor 1, a current flows which causes the transformation of the voltage of the primary winding 6 to the secondary 7 in antiphase with voltage the anode of the thyristor 10. At the same time, the toK of the control electrode reaches the value required to open the thyristor 10 after some time. If the voltage of the secondary winding 7 of the transformer 5 is greater than or equal to the supply voltage, then the thyristor 10 does not open at all and there is no current to the load resistance 11. In this case, the opening angle of the thyristor is 180 eel. When the voltage of the secondary winding 7 of the transformer 5 is less than the mains voltage, the opening angle of the thyristor is less than 180 degrees. Such a wide range of variation in the opening time of the thyristor 10 is explained not only by the ratio of the amplitudes of the voltages of the secondary winding 7 of the transformer 5 and the network, but also by changing the phase of the current in the control electrode of the thyristor 10. The current phase of the control electrode depends on the total inductance of the secondary winding 7 transformer 5, which in turn depends on the primary winding 6, i.e. from the magnitude of the control voltage U, p, p Thus, the change in voltage and total inductance of the secondary winding 7 of the transformer 5 allows you to adjust the opening time of the thyristor 1P within 10-180 el. hail to completely lock the thyristor 10, when the input signal O is maximized. Using the proposed device for controlling the thyristor provides cost effectiveness of control due to the possibility of controlling the thyristor using small control signals, obtaining a wide control range of the control signal phase without using the phases of a rotary capacitor or other type of phase shifter. A device for controlling a thyristor, containing a series-connected transistor regulating element, a diode bridge, a control unit and terminals for connecting the anode, cathode and control of a thyristor electrode, characterized by the fact that in order to create a maximum phase shift during amplitude-phase control of the thyristor, the control unit is made on the basis of two diodes and a transformer, the input winding of which is connected by the first terminal to the first output terminal of the diode bridge and the second terminal through a serially connected first diode and resistor to the base of the transistor of the regulating element and simultaneously to the first output opposite the switched output winding of the transformer, the second output of which is connected via a second diode to the terminal for connecting the control electrode of the thyristor, the terminals for connecting the anode and cathode of which are connected with anode the first diode and the second output terminal of the diode bridge. Sources of information taken into account in the examination 9573716 1, USSR Authorship Certificate If 729769, cl. Н02 М 1/08, 1978. 2.Avtsch) testimony of the USSR tr, cl. H02 M 1/08, 1977.