SU119219A1 - Static phase-shifting device for control voltage pulses of ion converters - Google Patents

Description

Static phase shifters are currently used to bias the control pulses of a pair of signals supplied to ionic converters containing a pulse generator and a delayed multivibrator.

The proposed device differs from the known ones in that the multivibrator is assembled on cold cathode tubes and equipped with a transformer, the primary winding of which is connected through a capacitor between the cathodes of the multivibrator tubes. Such an embodiment of the device makes it possible to extend the range of control of the phase of the control pulses, ensures its speedlessness and increases the service life.

The drawing shows a schematic diagram of the proposed device.

The device contains a starting pulse generator and a delayed multivibrator assembled on cold cathode tubes.

A start pulse generator serves to obtain narrow pulses that trigger a delayed multivibrator, the lamps of which serve several channels.

It consists of three PT peak-transformers, the primary windings of which, together with throttles D, are assembled into a three-phase star. Each peak transformer has two secondary windings, working respectively on two channels; The secondary windings of all peak transformers are connected to a shielded phase star, after which the required shift of 60 ° between the channels is achieved.

The pulses produced on each secondary winding of a peak-transformer PT, through the limiting resistance are applied to the lamp

No. 119219-2 -

“/, Which, on a positive pulse, forms a voltage jump with a steep front, equal to the difference between the ignition voltages and the burning of the lamp L}.

The voltage produced at the terminals of the lamp L is differentiated by the Ci-Ri-Rz chain, the negative pulses are cut off by the semiconductor diode D, and the positive starting pulses following a period are fed to the input of the delayed multivibrator.

The delayed multivibrator is assembled on La and L cold cathode tubes according to a circuit with a total quenching capacitance C3. The magnitudes of the resistances and 5 in the starting electrode circuit are selected so that the lamp L does not light up, but in the gap the starting electrode-cathode of this lamp maintains a self-contained quiet discharge with a low current (of the order of), which provides initial ionization. The discharge current between the starting electrode and the cathode of the second lamp L is of such a magnitude that a discharge is created between the main electrodes of this lamp.

When the starting pulse arrives at the input of the delayed multivibrator, the JIz lamp is triggered and a positive pulse arises on the resistance. This pulse is transmitted through the quenching capacitance C3 and the primary winding of the transformer T to the cathode of the lamp L and quenches it. After recharging capacitor C3, the lamp Lz is activated, extinguishes the lamp Lh, and the circuit returns to the initial state.

The residence time of the circuit in the second state depends on the magnitude of the quenching capacitance and resistance in its recharge circuit, as well as on the voltage supplying the starting electrode circuit of the lamp L. As this voltage changes, the voltage level on the cathode of the lamp required for its triggering. Consequently, for each given level there is a quite definite time after which the capacitor Cz recharges to the voltage that provides the potential of the cathode of the lamp Ls, necessary for its operation.

The potential of the starting electrode can vary manually (using resistance R) and from control devices. Switching the type of work is performed by the VC toggle switch.

During operation, the circuits on the secondary winding of the transformer T appear positive pulses, in time corresponding to the time of the lamp L trip.

When the voltage on the starting electrode of the lamp L is changed, these pulses are shifted in phase with respect to the initial voltage within 0 ° -270 °, which is twice as large as the range of phase variation in other known circuits. These are then used to control various converter installations.

Subject invention

A static phase-shifting device for controlling voltage pulses of ionic converters, comprising a pulse generator and a delayed multivibrator, characterized in that, in order to extend the range of adjusting the phase of pulses, ensure inertia-free and increase service life, the multivibrator is assembled on cold cathode lamps and equipped with a transformer the primary winding of which is connected through a capacitor between the cathodes of the multivibrator lamps, and control pulses are removed from the secondary winding Wives