SU36955A1 - Cathode amplifier - Google Patents

Description

The present invention relates to amplifiers, and in particular, amplifiers used at very high frequencies.

Typically, lamp amplifiers are connected in such a way that a high constant voltage is applied to the anode. In the case of powerful amplifiers requiring water cooling, it is necessary to supply water through a tube of rubber or other insulating material so that the resistance of a long column of water prevents leakage of constant and alternating currents to the ground.

Partly to prevent the passage of high-frequency current, partly to save space, the rubber tube is coiled into a coil. At high frequencies, the distributed capacitance of a coiled tube filled with water is sufficient to prevent the high frequency potential from being isolated from the ground.

(621)

Devices are known that bypass this difficulty by modifying the amplification circuits so that the anodes are at a high frequency ratio at approximately ground potential. It follows that in such a case, the cathodes should be at a high potential with respect to earth. This condition requires that the cathodes be separated from the source of the current by means of reactive coils.

The present invention relates to such cathode generators and consists in the fact that the amplified current circuit is connected to one of the above-mentioned coils.

In the cathode generator circuit shown in the drawing, a reactive coil 1 and a variable capacitor consisting of two mechanically coupled capacitors adapted for simultaneous tuning are included in the grid circuit. The point between these two capacitors can be connected to the ground, or, if desired, also to the source; ICOM current, serving to supply the L-signal signalg-i

The middle point of the coil 1 is connected via a resistor 3 to a grounded wire 4. The battery is connected in parallel with the battery 5 and the capacitor 6. The capacitor has a sufficiently large capacity to provide a co4 at the frequency to which the circuit is tuned 1-2, o4eHs small apparent resistance From the two terminals, wires 7 and 8 lead to grids 9 and 10 of the amplifying lamps I and 12. The anodes 13 and 14 of these lamps are interconnected by wire 15, from which the connection is connected through a blocking capacitor 16 and resistance 17 to ground 4 and to the negative pole anode battery 18. Positive terminal anode battery: without self-induction 19 with wire 15. Condenser 16 protects battery 18 from short circuit 5g, but is large enough not to represent significant resistance for high frequency currents. The resistance 17 is large enough to prevent the passage of significant currents of parasitic frequencies. The cathode itself must be connected

with a midpoint of 22 for ampa and with a point of 23 for a lamp 12. These midpoints are obtained by turning on j two capacitors in parallel

heat chains, i.e. to the ends of the cathode.

A variable capacitor 24 is connected between the midpoint 22 and the anode 13; similar variable capacitor 25

included between midpoint 23 and

the anode 14. The capacitors 24 and 25 are connected in parallel to the electrode capacitance, the first lamp II, the second lamp 12.

The filament can be powered by low-frequency direct or alternating current. The case is given as an example.

alternating, the power being supplied through transformer 29. The middle point 31 of the secondary circuit 30 of this transformer is grounded, and the middle points of the coils 32 and 33 are connected to the terminals of its secondary winding. Self-induction I 32 is included in the wire,

connecting one cong thread of the channel 20

with the end of the thread on: Chala 2i, and self-induction 33 is similarly connected between the other ends of those. same-n-ity nalala. Coils 32 and 33, connected in parallel, are self-induction settings, as will be explained below.

The average currents of the coils 32 and 33 are also connected to a pair of capacitors, which form a middle point 34 connected to a grounded clamp of the rheostat 17.

Lead wires 36 lead from two different points of one of the coils 32

and for.

The neutralizing capacitor 37 is connected between the midpoint 23, which lies in the filament circuit of the lamp 12, and the grid 9 of the other lamp 11. The latter is also connected to the wire 7 and thus to the end of the coil G, opposite to the connection with the grid 10. Similarly the neutralizing capacitor 38 is connected between the midpoint 22 and the grid 10 and is thereby connected via wire 8 with the end of coil 1 opposite to the connection with grid 9.

The inductive resistance of the coils 32 and 33 should be greater, but the sensors are necessary for the purpose of tuning, precisely in order to put between the transformer 29 and the cathodes an obstacle to the passage of high frequency currents. If such an increase in coil sizes is undesirable, coils can be taken smaller than what follows from this requirement and supplemented with reactive coils 40 and 41 that can be switched between the middle points of coils 32 and 33 and the secondary circuit terminals 30. If this proves desirable, additional self-induction coils can be saved, even if the coil settings are large enough.

When the circuit is operated, the anodes -13 and 14 are supplied to the battery; 18 constant potential. The value of the other goes from the cathodes 20 and 21 to the middle points of self-induction 32 and 33, and then through 31 to the earth returning to the battery 18 through grounding 4.

The current from the transformer 29 passes through the coil 41 and the two halves of the coil 32 in parallel connections, then through the filaments of both I lamps, from here through both the half of the reactive coil 33i to the middle otsko. no (., and from here through the Katushka —F. 1 to another terminal of the secondary end of the valve)

The potentials of the grids 9 and 10 are applied by jr-j with simultaneously and in reverse phase with | current in the tuned circuit 1 -2.... I another potential is supplied by a battery 5 of the grid. A high-capacity capacitor 6 ensures the constancy of the potential of the high frequency of the midpoint of self-induction 1, and the resistance 3 prevents the occurrence of parasitic oscillations.

The anodes 13 and 14, being maintained at a certain potential by the connection that goes through the wire 15, the capacitor 16 and the resistance 17 to ground 4, are in relation to the high frequency at ground potential. Consequently, any device for cooling the anodes should only be provided against direct current leakage.

Rheostat 17 aims to prevent the occurrence of parasitic oscillations: 1N, and also serves as a leakage for high frequency currents that occur in the case of incomplete condensation of the internal capacitances of the two lamps.

Since the anodes are at a constant potential, the variable potential difference between the anodes and the cathodes, created by the alternating voltages applied to the grid, will manifest itself in the high frequency oscillations of the potential of the cathode. These fluctuations in cathode potential will be greater than changes in grid potential, due to the usual amplifying effect of lamps. In this way, the amplified high current is transmitted to the external circuit.

Regarding the lamp 11, the anodic circuit consists of between the Electr of the same lamp capacitance, the cathode 20, and leaves through the upper halves of the coils 32 and 33 connected in parallel and through the capacitors forming the neutral point 34 to the neutral point, hence through the resistance 17 and through the capacitor, large capacity 16 to the anode 13. A similar circuit can be traced from the electrode capacitance of the lamp 12 through the lower connected parallel

half of the coils 32 and 33, to point 34 and from here to the anode 14.

Independently, if we consider the external circuit as two tuned circuits, one circuit, this circuit gives a case of resonance to the current and, therefore, tends to prevent T, from reaching the transformer by itself, therefore, self-induction 32 and 33 do not need to count on .. throttle action.

To prevent the occurrence of spurious oscillations, resistors 17 and neutralizing capacitors 37 and 38 serve.

Self-induction 1, acting as an automatizer with the transformer, supplies the same potential, but of opposite sign, to wire 8. Thus, the potential supplied through the capacitor 37 and the wire 8 to the grid 10 is phase inverse relative to the potential supplied to the grid 10 through the cathode 21-grid 10 between the electrode capacitance 10. Therefore, the capacitor 37 , neutralize generation; Workers 12. In the same manner, the 1-capacitor prevents the lamp 11 from generating.

In conventional amplifying circuits, em. The bone to be neutralized to prevent generation is grid-anode capacitance. In the described scheme, the capacity to be neutralized to avoid generation is the cathode grid. The latter is significantly less than the capacitance between the grid and the anode. Difficulties in the use of intracranial capacitance with the capacity of the line to generate in the described case, therefore, less than in the usual case.

The subject of the patent. A cathode amplifier, in which the anode is maintained at almost constant potential, and the potential of the cathode changes under the influence of potential fluctuations on the grid, the energy of the heating circuit is supplied from the battery through self-induction coils, and the entire self-induction of the anode circuit is concentrated in the wires of the heating circuit, differing in that the amplified current circuit is connected to one of the above-mentioned self-induction coils 32, 33. to the patent of the company Westinghouse Electric Products Lz 8-10955