SU45550A1 - Tube generator - Google Patents

Description

It is known that in the feedback-tube oscillator circuits, the frequency of the oscillations generated is largely determined by the natural frequency of the grid oscillating circuit. To a small extent, however, it also depends on the magnitude of the load resistance, especially when the lamp should be used according to its power and when the load resistance in the anode circuit corresponds to the lamp; The excited frequency depends to a considerable extent on apparent load resistance, for example, on tuning and coupling to the antenna. To reduce this undesirable dependence, the load to be loaded is not included directly in the self-excited cascade, but through amplifying cascades. The invention makes it possible to obtain high-power generators without a noticeable dependence of the generated frequency on the apparent load resistance.

The generator is proposed to arrange so that the phase transmitted through the reverse

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The connection to the control voltage loop is mainly determined by the phase of the electron current through the lamp. From this point of view, screened lamps are particularly suitable; However, it is also possible to use conventional tri-electrode lamps, which, when using neutralizing agents, in particular neutralizing tanks (neutrodynamic), destroy the capacitive coupling of the anode to the control grid through the electrode capacitance.

In FIG. 1 shows a self-excited oscillator circuit; FIG. 2, 3, 4, 5, б, 7 represent variants of the generator circuit.

If the tuned grid circuit 7 of lamp 2 (Fig. 1) is feedback-coupled to the anode circuit, oscillations are generated, the frequency of which is determined by the condition that the phase of the alternating voltage induced in grid 2 must correspond to the phase required to maintain the available anode current. If, however, some apparent resistivity 3 is included in the anode circuit of the lamp, then this changes the phase shift between the grid voltage and the anode current and the frequency of the generated oscillations gets a different value for which the above condition of the phase state is satisfied again. In order to make independent the impact of the useful resistance, which is in the anode circuit, on the phase of the current passing in the anode circuit, and thereby also make the frequency of the generated oscillations independent of the change in the resistance of the load circuit, in series with the latter resistance to it. This is done by using lamps, the internal resistance of which is large compared to the external apparent resistance, when the total apparent resistance of the anode circuit is mainly determined by the internal resistance of the lamp and the change in apparent resistance of the useful circuit little reflects on the phase variations of the anode current and the generated frequency. The use of such circuits, i.e. circuits for which to generate oscillations, is used, for example, a shielded lamp, the high internal resistance of which meets the requirements described above, however, still does not lead to the desired goal.

The reason why, even in such schemes, the excited frequency strongly depends on changes in the apparent resistance of the useful circuit, is seen in that, especially at short waves, the capacitance between the anode and cathode forms a significant capacitive shunt connected in parallel with the internal resistance of the lamp so that the apparent resistance of the useful the loop in relation to the circuit containing the feedback element can no longer be considered as being connected in series with high resistance. The shunt capacitance is the capacitance between the anode and the screen grid, which in most cases has the potential of the cathode as well as the capacitance directly between the anode and the supply wires, and such as the cathode and supply wires.

Which of these containers prevails with respect to the harmful effect will each time depend on the design of the transmitter. In order to eliminate this drawback, the generator has such a device that the currents passing through the capacitors 4 and 5 do not form an immediate shunt parallel to the internal resistance of the gap anode-cathode, but are used for feedback (Fig. 2). Then, to the anode current circuit, which is formed by the internal resistance, the feedback element and the load resistance, the currents passing through the capacitances do not form a shunt to the internal resistance of the grid, but form a shunt to the load resistance. The phase of the current passing through the feedback elements (as noted) is determined by the large internal resistance of the lamp and, thus, the generated oscillation frequency does not depend on changes in the load resistance.

The described scheme in which the detrimental effect of the capacitance of the screen grid-anode is eliminated is shown in FIG. 3. A load loop in the form of a tuned loop 5, connected to antenna 6, is connected between the anode and the grid, and a feedback coil 7, connected in series with the load loop, connects the cathode to the screen grid. Thus, the currents passing through the capacitance of the anode screen grid will pass through the feedback coil 7. In this case, it is necessary that for the currents passing through the capacitance of the screen anode, and the currents passing through the useful circuit, the same feedback element.

One could also, as depicted in FIG. 4, for capacitive currents passing through the lamp capacitance, have a special feedback coil 7.

FIG. Figure 5 shows a circuit in which capacitance formed between the supply wires to the anode and cathode is neutralized. For this, a screen is arranged around the anode wires, which is connected to one of the points of the feedback rolls 7. In this case, instead of using the currents passing through the capacitor-feedback loop, current-free currents passing through the capacitance of the electrode wires are used. Also, in this case, it would be possible to have a separate feedback element for the parallel current circuit.

It is especially advisable to connect both circuits, as shown in FIG. b, where the external screen is connected to the screen grid and the current free currents passing in both circuits are connected to the feedback coil 7.

In the examples given, the external screen and the screen grid were connected to the cathode directly through a feedback element. Only the high-frequency connection made in this way is important. Instead of connecting the screen grid to the cathode through a feedback element and in this current circuit, provide a source of grid direct voltage connected to the shunt capacitor, as shown in the previous figures, it would also be possible through the choke between the cathode and a screen grid to bring the voltage to them and to bring a high frequency from the screen grid to the feedback element through a blocking capacitor. A similar diagram is shown in FIG. 7

Significant in the described schemes is that the phase of the currents in the feedback circuit is largely determined by the high resistance of the lamps. Therefore, it is recommended to neglect the maximum use of lamp power in the interests of greater frequency constancy and not to match the load with the lamp.

It is also essential that the inductive coil 9, when it is turned on

between the anode and the cathode is an inductive bridge to the gap. The anode-cathode would be chosen so large that this shunting would not matter, or that the current passing through it would also be used for feedback.

The subject of the patent.

A tube generator with a feedback element connected in series with the output circuit, using an amplifying lamp with high internal resistance and means for eliminating capacitive coupling between the anode and the control grid, in particular with shielded lamps, characterized by such a phase that the voltage phase transmitted via feedback to the contour of the control grid is determined only by the phase of the current between the cathode and the anode, for which high-frequency currents passing from the anode through the capacitance are supplied to the element feedback loops located in the external circuit of the lamp, and the screen grid is connected to the cathode via a feedback element, the load being connected between the anode and the screen grid, and the feedback element, in common to both of them the cathode, the capacitance is connected between the supply wires leading to the anode and the cathode, or is connected to an external screen, eliminating their influence, and this external screen is connected to the cathode via a feedback element by a high-frequency link.