SU455456A1 - Multiphase multivibrator - Google Patents

Description

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This invention relates to radio engineering and can be used in automation and computer devices.

A multiphase multivibrator is known, containing the first source of constant voltage, p stages on thyristors, p capacitors connected in an annular circuit between the anodes of the thyristors of adjacent cascades, n time specifying elements made on saturation drossels x, the demagnetization windings of which are connected in a series chain connected to the output of the control signal source.

This multivibrator consumes more power when operating on a low-impedance load.

The purpose of the invention is to reduce the power consumed by the multivibrator when operating at a low impedance load.

To do this, it introduced the second source of constant voltage, n double-winding pulse transformers, n first diodes connected by anodes to the positive pole of the first constant voltage source, and n second diodes connected by anodes to the positive pole of the second source of constant voltage, the thyristor of each cascade is connected by a cathode to a bus connecting the negative poles of the first and second sources of constant voltage, and the anode is connected to the positive pole of the first source by a constant DC voltage through a load connected in series with the first diode and the positive pole of the second source of constant voltage via the series-connected second diode, a main winding of the choke saturation and the primary winding of the pulse tranformatora, the secondary winding of which is connected in parallel with a control transfer thyristor succeeding stage.

The drawing shows a circuit diagram of the proposed multi-phase multivibrator.

The multivibrator contains thyristors 1–4, the cathodes of which are connected to a common bus connecting the negative poles of sources 5 and 6 of a constant wavelength. Anodes

thyristors 1–4 through serially connected diodes 7–10 and loads 11-14 are connected respectively to the positive pole of the constant voltage source 5. Anodes of adjacent thyristors are connected through

capacitors 15-18, forming a ring. To the anodes of thyristors 1-4, there are also connected series circuits consisting of diodes 19-22, primary windings 23-26 pmmpulse transformers 27-30 n of the main windings 31-34 of saturation inductors 35-38.

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The second terminals of these circuits (the ends of the windings 31-34) are combined and connected to the positive pole of the source 6 and the voltage condition. The secondary windings 39-42 of the pulse transformers 27-30 are connected to the control junctions of the thyristors -4, and the secondary windings are connected to the junctions of the thyristors of the subsequent stages. The demagnetizing windings 43-46 of chokes 35-38 are connected in series and connected to the source 47 of the control signal.

Multivibrator works as follows.

If thyristor 1 is open, and all other thyristors are closed, current 11, which is determined by its parameters and source voltage 5, begins to flow through load 11. The core of throttles 35 begins to oscillate. As long as the core of the throttle 35 is in a state of high magnetic permeability, corresponding to the steep portion of the hysteresis loop, and the inductive resistance of the transformer 27 is less than the inductive resistance of the throttle 35, almost all the voltage drop of the source 6 is applied to the main winding 31 of the throttle 35. Therefore the voltage on the secondary winding 39 of the transformer 27 is absent or the magnitude 1 is so small that it is not enough to turn on the next thyristor.

At the moment when the core of the throttles 35 goes into the nascene state, its resistance abruptly changes and becomes equal to the active resistance of the winding 31. From this moment, the voltage is redistributed between the choke 35 and the transformer 27. Because the transformer core 27 is not in the nascent state then the greater part of the voltage of the source 6 is applied to the nervous winding 23 of the transformer 27. As a result, an impulse occurs on its secondary winding 39, which turns on the thyristor 2. When Thyristor 2 is switched on

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thyristor 1 by capacitor 15, which irikladyvaet negative and potential to its anode. Drossel core 35 begins to non-magnetize. The return of the core of the throttle 5 35 from the saturation state to the steep section and the hysteresis pattern is depleted due to the demagnetizing effect of the winding 43. Then all the processes are repeated.

jgPre dm et and 3 on the line n and

Multiphase multivibrator containing the first source of constant voltage, n stages on thyristors, n capacitors connected in a ring circuit between the anodes of the thyristors of adjacent stages, n time of setting elements made on saturation drossels x, the demagnetization windings of which are connected to the sequential the chain connected to the output of the source of the equal signal, characterized in that, in order to reduce the power consumed when working on a low-impedance load, a second source and a voltage supply are introduced into it and n two-winding pulse

5 transformers, n first diodes connected by anodes to the positive pole of the first source and a steady state, and second diodes connected by anodes to the positive pole of the second source

0 and a constant voltage, with the thyristor of each cascade cathode m connected to the power connecting the negative poles of the first and second sources of constant voltage, and the anode connected to a positive

5 to the pole of the first source of direct voltage through a load connected in series with the first diode, and to the positive pole of the second source of constant voltage through connected in series the second diode, the main winding of the nasseli and the primary winding of the imulse transformer, the secondary winding of which is connected in parallel to the control transition thyristor subsequent cascade.

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