DE558727C - Circuit for converting direct current into alternating current by means of grid-controlled discharge vessels - Google Patents

Description

When converting direct current into alternating current, discharge vessels are often used used with control electrodes that are coupled with via a transformer or other type of coupling are connected to the AC circuit or network to be fed. In the event that the AC circuit has no pronounced natural frequency, it is necessary to determine the frequency of the generated Alternating current, for which purpose on

ίο The most common capacities are used for the primary winding of a transformer are connected in parallel, through which the discharge vessels with are coupled to the AC circuit.

According to the invention, the frequency is determined by an alternating voltage generated with the fed reactance is determined by high iron saturation. In order to change the The frequency of the alternating current to be generated is expediently variable in series with the reactance Resistance may be provided.

The drawing shows an embodiment. The direct current is generated from lines 1 and 2 Via the anode circuits of two electron tubes 3 and 4 after the primary winding 5 one Transformer supplied, the secondary winding 6 of which is connected to the load circuit is. The direct current conductor 1 is here at the center point of the primary winding 5 of the main transformer and the direct current conductor 2 connected to the cathodes of the tubes; the current pulses supplied to the winding 5 flow through it alternate the two halves of the winding in opposite directions.

The tubes 3 and 4 are controlled by grids attached to one of the secondary windings 6 taken voltage are, with the interposition of the grid transformer 7,8, its primary winding 7 is connected to the secondary winding 6 of the main transformer is. The outer terminals of the secondary winding 8 of the grid transformer are over Resistors 9 connected to the grids of the tubes 3 and 4, the middle tap across a reactance 10 and a resistor 11 to the cathodes of the tubes 3 and 4.

So that one tube before the current flow is interrupted in the other tube becomes conductive, it is necessary that the positive grid voltages match those in the secondary winding 6 occurring alternating current voltages lead. This desired lead is in Embodiment achieved in a known manner by a capacitor 14, which has a Transformer 15 is switched on in the primary circuit of the grid transformer.

The desired frequency of the occurring in the primary winding 5 of the main transformer AC oscillations can now

be determined by means of an impedance, which consists of a saturated reactance 12 and a controllable Resistance 13 exists. By changing the resistor 13, the frequency of the generated AC current set as follows.

The operation of the arrangement during a period of the alternating current is essential the following:

If the grid of the tube 3 is positive, then the current flowing in the primary winding 5 is in the secondary winding 6 induce an EMF, which is also the primary winding 7 of the grid transformer notifies, in the secondary winding 8 an EMF is now induced, which the grid of the tube 3 with positive and the of the tube 4 "charges with negative potential. As soon as the reactance 12 is saturated, becomes the voltage drop across it is rapidly reduced, which means that the winding 7 is practically short-circuited and the voltage on windings 7 and 8 drops to zero. The reactance ao now causes in a known manner that the positive potential of the grid of the tube 3 is still maintained is, while the grid of the tube 4 also receives a positive potential. Both tubes are this way has become conductive, the terminal voltage on windings 5 and 6 becoming zero. Of the Magnetic flux in the reactance 12 is now weaker; this causes a reversal of the current in the winding 7, and consequently in the secondary winding 8 of the grid transformer induces an emf in the reverse direction. The grid of tube 3 now becomes negative and that of tube 4 remains positive. The tube 4 now conducts for half a period the stream. By increasing or decreasing the resistor 13, the period of time the Coil 12 needs to be saturated, enlarged or reduced, thereby increasing the frequency of the alternating current in the output circuit is determined.

In the arrangement shown, the ♦ 5 reactance 12 is shunted to the primary winding 7 of the grid transformer. It will be readily apparent that the coil 12 will do just as well can also be in the shunt to the secondary winding 8 of the grid transformer. If desired, the frequency can also be controlled by saturating the grid transformer take place yourself. In any case, the time until the saturation point of the control transformer is reached Frequency of the alternating current determined. The mode of operation is essentially the same here as in the case described.

When the frequency is determined by the primary winding of the grid transformer, at Flux increase in the secondary winding 8 induces an EMF of such a direction that the grid of the tube 3 becomes positive and that of the tube 4 becomes negative. As a result of saturation of the iron core of the grid transformer is then the voltage induced in the winding 8 very small or zero, as a result of which both grids become positive in the manner described above. As a result of the reduction in the flow of forces, tensions are now in opposite directions Direction induced in the winding 8, the grid of the tube 3 negative and the grid give the tube 4 positive potential.

In the device described occurs between the terminals of the grid transformer a very high voltage. This voltage can be switched on in a known manner a capacitor 16, 17 between the grid and cathode of each tube can be greatly reduced.

Claims (4)

Patent claims: 1. Circuit for converting direct current into alternating current by means of grid-controlled Discharge vessels whose lattice circles are coupled to the alternating current circuit, the latter not being an explicit one Has natural frequency, characterized in that the frequency by one in one of the coupled circles lying reactance with high iron saturation is determined. 2. Circuit according to claim 1, characterized in that for the purpose of change the frequency of the generated alternating current with the reactance a variable resistance is in series. 3. Circuit according to claim 1 or 2, characterized in that the reactance preferably in series with the variable resistor in parallel with one of the windings a transformer is connected via which the control electrodes are connected to the AC network. 4. Circuit according to claim 1 and 2, characterized in that the reactance one of the windings of a transformer is used, over which the grid of the discharge vessels obtained voltage from the generated alternating voltage. 1 sheet of drawings