SU48757A1 - Device for controlling ionic rectifiers with grids - Google Patents

Description

In devices using ionic rectifiers, in order to switch the current, the control of the rectifiers is achieved by the corresponding switching of grid circuits, which can be powered by both alternating current and direct current. When powering the grids with direct current, considerable difficulties arise when the system has several groups of rectifiers that cannot have a common power source of the grids (for example, a valve motor and other circuits).

In these cases, it is necessary to have as many power sources of the grid circuits and switches that switch them as there are rectifier groups in the system that cannot have connections of the grid circuits.

The number of groups comes to shchishche and higher, which requires a very cumbersome device for supplying the grid circuits with direct current.

When powering the control grids of the rectifier grids with alternating current, these difficulties disappear because it is possible to supply several isolated grid circuits with one source by using intermediate transformers, but difficulties arise in another order.

In those cxejwaxs where the switching of the grid circuits occurs asynchronously with the network supplying the anode circuits of the rectifiers, it may happen that at the very moment the grid circuit is switched on by the switch, the emf. the grid transformer will be zero or even a negative value that cannot unlock the rectifier. Consequently, it will not be unlocked immediately when the grid circuit is turned on, but when the bp the grid transformer will reach the value needed to unlock the rectifier.

When the grid is opened, the emf the transformer does not disappear immediately, but decays with a constant {rot, determined by the corresponding parameters. Therefore, it is possible that the burning period of the rectifier is delayed, which causes unpleasant consequences and often leads to short circuits. In the present invention, it is intended to give a device free from the indicated disadvantages.

Since most devices always contain a certain number of ion pairs, rectifiers, in which each rectifier serves to rectify one half-wave of the operating voltage, the description is given with reference to

to one pair of ion devices with control grids.

The drawing shows the switching circuit, 8 of which is 1 n 2-ion rectifiers, 3-resistances in the grid circuits, limiting the current strength in them, 4-source of direct current, giving a negative (locking) potential on the rectifier grids, 5- resistances used to damp the grid transformers and connected in parallel with the secondary windings 6.

The primary windings 7 of grid transformers are shorted to a circuit consisting of a DC source 9, a resistance 8, a secondary winding of a transformer 10, and a switch 16,17.

The primary winding of the transformer I is connected through a resistance 12 to a rectifier consisting of two detectors of any type and a transformer 14 fed from a phase regulator 5, adventitious to the same network that feeds the anodes of rectifiers 1, 2.

In the primary winding of the transformer 11, a pulsating current will flow, the change curve of which is a commuted sine wave, and in (the winding 10 will be induced by an emf with a double network frequency.

At the time the brush of the switch 16, 17 is connected to the plate, a constant current from the source 9 will flow along the windings 7, which will cause a rapid change in the magnetic flux in the grid transformers, inducing 6 emf in the windings.

The direction of the direct current in the windings 7 must be such that the E.D.S., which is induced at the time of its inclusion in the windings 6, has a direction corresponding to unlocking of the rectifiers 1, 2.

When the switch opens 16,17 DC in the windings of the grid transformers in their secondary windings 6, the emf peaks will be induced. reverse direction corresponding to the locking of rectifiers.

When the brush 17 moves along the plate 16, the DC value in the windings 7 does not change, the voltage of the emf associated with the DC current is not induced, and the unlocking of the rectifiers 1, 2 at this time occurs due to induction in the windings of 6 emf double frequency. The need to power the neviVic windings 7 with a double-frequency current is caused by the following: since each rectifier 1.2 serves to rectify one half-wave of the operating voltage, the anode voltages of these two rectifiers are 180 ° apart.

If the grid transformers were powered by the operating frequency current (the same as the anodes), then to displace the grid voltages also by 180. you would have to turn out one of the secondary windings 6, which would lead to an unacceptable difference of the emf peaks, supplied to the grids of each of the rectifiers 1.2, with the closure and opening of the switch 16, 17 (i.e., the unlocking peak for one straightening, the bodies would turn out to be the locking dd of the other).

When feeding grids with a double frequency, the need to shift by 180 grid voltages does not occur. From what has been said, it is clear that the introduction of unlocking and locking peaks limits and rigidly fixes the period of unlocking the rectifiers.

The subject matter of the invention.

A device for controlling ionic rectifiers with / grids to which alternating current of double frequency is supplied as compared to the frequency in the main circuit, characterized in that, in order to clearly fix the on and off of the ionic rectifier, in series with the primary winding of the grid transformer connected to the source of double frequency, switching on the battery and the rotating switch-switch 16, 17, designed with their closures of x-switches to create the unlocking and locking impu sy.