DE976788C - Connection of two alternately working transmitter tubes whose anodes are fed from the same AC voltage source - Google Patents

Description

Connection of two alternately working transmission tubes, their anodes be fed from the same AC voltage source The invention relates to to a circuit of two transmitter tubes, their anodes from the same AC voltage source are fed, work alternately and share their high-frequency energy with one another Submit decoupling circuit. Such circuits are particularly suitable for VHF diathermy devices, Ultrasonic generation and the like. In this circuit, the cathode of one and the anode of the other transmitter tube galvanically with one pole of the alternating supply voltage tied together. One tube vibrates in one half-wave and the other Half-wave the other tube using the full transformer secondary voltage. The transformer is therefore evenly loaded. Because the two tubes take turns vibrate, there is the possibility that the tube that is not vibrating is the other withdraws vibrating energy and therefore has a dampening effect on the circles. To this one To avoid the disadvantage, it is advisable to use the grid of the currently non-oscillating Tube a negative reverse voltage for the respective period of non-oscillation admit. According to the invention are therefore for the purpose of a known per se, by a grid bias caused blocking of the non-vibrating tube in the grid circle Each tube is provided with circuit elements from the anode circuit of the respectively oscillating Tube are affected. It is also possible to achieve the intended locking effect to achieve that the anode current is used to control a relay, which in turn a negative reverse voltage to the grid of the non-vibrating tube sets so that the anode current is not directly, but indirectly to the generation the grid voltage on the grid of the non-vibrating tube is used.

Which is the case with the use of a resistor to generate grid voltage The resulting mode of action is as follows: The one in the vibrating tube through this flowing anode direct current flows through the in the cathode grid connection of the non-vibrating tube lying resistance in such a direction that in it a negative voltage arises in relation to the grid of the non-vibrating tube.

If this tube oscillates itself in the next half-wave, it disappears the negative grid voltage, since no anode current flows through the other tube.

In the drawing I and 2 mean the two transmitter tubes, 3 the mains transformer, 4 the decoupling circuit, 5 and 6 the two self-inductions of the tube resonant circuit, 7 and 8 the anode grid capacitors, g a blocking capacitor, io and ii parallel capacitors to the resonant circuit, 12 one or two grounded blocking capacitors, I3 and 14 grid leakage resistors, 15 to I8, 28 and 29 high-frequency chokes, 19 and 20 disconnectors for the heating coil of the transmitter tubes, 21 the tuning capacitor for the decoupling circuit, 22 and 23 the receptacles for the energy consumption circuit, 24 the high voltage winding, 25 the low voltage winding, 26 and 27 the heating windings of the mains transformer 3.

The mode of operation of the circuit is that the resonant circuit 5, 6, 7, 8, 9, Io, II is triggered alternately via the throttles 28 and 29. It Only the transmitter tube works, the anode of which is in the half-wave under consideration applied AC voltage is positive compared to the cathode.

During the same half-wave, the anode of the second transmitter tube becomes negative to the cathode. The capacitors 10 and II are used to increase the Tube capacitance and are parallel to the self-induction via the capacitor or capacitors I2 5 and 6. The capacitor I2, which also consist of two separate capacitors can, serves with its grounding electrode or its grounding line for balancing of the oscillating circuit and for capacitive grounding of the entire tube transmitter.

The resistors 30, 3I are used to automatically generate the negative Grid prestress. The resistor 30 is from the anode current of the tube 2 when This positive anode voltage receives, i.e. oscillates, flows through the resistor 3I of the flow of the tube I. In the embodiment under consideration, is for both Tubes a common resonant circuit provided. But it is also possible for everyone Tube to use separate resonant circuits with the common consumer circuit 4 are coupled. In such a case, there is a risk of energy deprivation the non-vibrating tube is even larger than in the example under consideration with a common resonant circuit, since now, while the one tube circuit to the consumer Energy is supplied by the second circle of the tube, which is not vibrating, as a damping circle can work.

Claims (3)

PATENT CLAIMS: I. Switching of two alternately working transmitter tubes, whose anodes are fed from the same AC voltage source and both of them give their energy to a common decoupling circuit, each of which is the cathode one and the anode of the other transmitter tube with one pole of the alternating supply voltage are galvanically connected, characterized in that for the purpose of a known per se, Locking of the non-vibrating tube in the grid circle caused by a grid bias Each tube is provided with circuit elements that are dependent on the anode current of the respective one vibrating tube can be influenced. 2. Circuit according to claim I, characterized in that the reverse voltage is generated by the anode current itself. 3. Circuit of two alternately working transmission tubes according to claim 2, characterized by resistors (30 or 3I) in the connecting line between Grid and cathode of the tubes (I and 2 respectively). Publications considered: magazine »Philips Technische Rundschau ”, May 1942, pp. 147 to 155; Essay Fransen und Ledeboer: »Generators for shortwave therapy «.