SU871287A1 - Device for rendering conducting two anti-parallel thyristors - Google Patents

Description

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The invention relates to electrical engineering and can be used in installations for testing semiconductor devices, as well as in control circuits of various technological equipment.

A device is known for one-time unlocking, a thyristor containing a thyristor, the anode of which is connected via a diode and load to one terminal of the network, and its cathode through another diode to another terminal of the network. The thyristor control junction is connected to one of the network terminals via a series of switches, a capacitor, a resistor and a diode connected in series, and the other network terminal via a resistor. The device provides the thyristor conductivity during the supply of the AC network for only one half period.

The disadvantages of the known device is that it does not ensure the stability of the half-wing when changing the nature and magnitude of the load, as a result of which, when used in test benches, it gives greater error in measurements; It does not allow one to obtain several half-periods per load; it does not ensure obtaining a normalized number of half-periods per load.

A device for one-time unlocking of two anti-parallel-connected thyristors is known, which contains a starting circuit formed by a diode, a resistor and a capacitor connected in series, a null organ consisting of a series-connected limiting resistor and a transformer and connected to the input terminals G2.

Claims (2)

A disadvantage of the known device is that it does not allow to achieve several half-periods of sinusoidal yielding on a common load. In addition, the device does not provide a normalized number of half-periods of sinusoidal voltage on the total load. The aim of the invention is to expand the functionality of the device. The goal is achieved by the fact that the device for unlocking two anti-parallel-connected emitters is equipped with a software unit, two OR circuits and a register, the first input of which is connected to the starting circuit, the second to the output of the zero-organ, the third to the software unit, and the common point it is connected to the input terminal, while the odd register outputs through the first OR circuit are intended to be connected to the control electrode of one of the thyristors, and even outputs through the second OR circuit to the control electrode of the other thyristor a. The drawing shows a functional diagram of the device. The device contains thyristors 1 and 2, connected anti-parallel to each other relative to the other, so that the anode of the first and the cathode of the second thyristors are connected to one of the network terminals, and the cathode of the first and the anode of the second thyristors is connected to the load 3. The second output terminal is connected to the second network terminal. Parallel to the input terminals is connected a null organ 4, which includes, for example, series-connected resistor 5 and transformer 6. A starting circuit 7, consisting of a series-connected switch 8, a capacitor 9, a resistor Yu, and a diode 11, is connected via switch 8 to the first input of the register 12; and through the diode 11 with the input terminal. The second input of the register 12 is connected to the output of the nullorgan 4 (one of the outputs of the secondary winding of the transformer), the third input of the register with the program block 13, and the common register point is connected to the zero phase of the input terminal. The odd outputs of register 12 are connected via the OR 14 circuit to the control electrode of the thyristor 1, and the even outputs through the OR 15 circuit to the control electrode of the thyristor 2. The device operates as follows. When switching the key 8 of the circuit 7 from position to to position a, a signal is received at the input of register 12. which sets register 12 to the initial (operational) state. Register 12 uses as many steps as necessary to obtain the largest required number of half-periods on the load. The outputs of the odd steps are connected to the inputs of the OR circuit 14, and the outputs of the even steps are connected to the inputs of the circuit OR 15. The signal from block 13, which sets the required number of working half-periods of sinusoidal voltage to start the thyristors 1 and 2, is fed to input III of the register 12. Periodic the signals generated from the network by the transformer 6, continuously start the register 12 through its input II as many times as the half-periods were set by block 13. From the even and odd outputs (,) of the register 2 through the IDN circuits 14, 13 the specified number is received control pulses, respectively, on thyristors 1 and 2, control pulses are generated at the beginning of the half-periods of the sinusoidal voltage of the network. Thyristors 1 and 2 are opened alternately, the wire has a specified number of half-periods of sinusoidal voltage, as a result of which a specified number of half-periods of sinusoidal voltage will be obtained on load 3. After the register 12 issues a predetermined number of triggering pulses, register 12 is turned off. In order to obtain new half-periods of sinusoidal voltage (new cycle of operation), it is necessary to input a new, restoring pulse to the initial (operating) state from the trigger circuit to the input of register 12. . As a register 12, for example, a ring counter with an open positive feedback can be used, and as a program block, for example, binary elements (toggle switches) are used. The proposed device allows to obtain the required number of half-periods of sinusoidal voltage on the load and thereby expand its functionality and area of application. The invention of the device for unlocking two anti-parallely included