DE624390C - Circuit arrangement for amplifier tubes heated with pulsating current - Google Patents

Description

GERMAN EMPIRE

ISSUED ON JANUARY 22, 1936

REICH PATENT OFFICE

PATENT LETTERING

M 624390 CLASS 21 a ⁴ GROUP 35 is

Siemens & Halske Akt.-Ges. in Berlin-Siemensstadt *)

Patented in the German Empire on February 9, 1933

To eliminate the effects of heating amplifier tubes with pulsating current The most varied means are used for the disturbances caused. Most frequently the mid-point circuit is used, where the grid and anode circuit are connected to a common or connected to separate resistors connected in parallel to the filament ends are. While these midpoint circuits are suitable for single-tube amplifiers To bring about a completely sufficient calming occur with cascade connections in spite of the

ig performed balancing errors on the are due to the fact that the points of symmetry of the individual tubes are different Have interference potential. 'Such potential differences between the points of symmetry

ao arise when several tubes are heated in series from the same power source or Tubes of different heating voltages are connected in parallel. But also with tubes With the same heating, this phenomenon shows up if as a result of deviations in the system structure the symmetry potentials are different to the potentials of the heating cables. Ultimately, such differences in the symmetry potentials can also occur with completely tubes of the same type with parallel-connected filaments of the same voltage arise when a shift in the course of the operation of the tubes as a result of uneven thread wear of the symmetry points takes place. Then the center taps will be on the correct one If the value is readjusted, they arise from the potential difference between the symmetry points related disorders.

The effect of the disturbances brought about by the difference in the symmetry potentials is to be examined in more detail below with reference to FIGS. 1 and 2. Yig. 1 shows a normal amplifier circuit in which two amplifier tubes V ₁ and F ₂ are coupled to one another in a known manner via resistors and capacitors. The tubes are heated in parallel from a common power source W, which supplies pulsating power. The symmetry resistors R ₁ and R ₂ simulate the filament centers M ₁ and M ₂ to which the grid and anode circuits of the tubes are connected in terms of alternating current. To calm the heating current, choke coils D ₁ and D _{2 are switched} into the heating current feeds.

If, for whatever reason, there is a potential difference between the symmetry points M ₁ and M ₂ , the current flows from the interference frequency via the coupling resistors. The circuit extends over the following circuit elements: Sym-

*) The patent seeker stated as the inventor:

Hermann Bendel in Berlin-Charlottenburg.

point M ₁ , capacitor C _a , anode resistance iRaj coupling resistance C _k , grid resistance R _g , capacitor C _s , symmetry point MacSy'nimetrievidistors R ₂ , heating current feeds, symmetry resistors _{JS 1 , symmetry point JIi 1} . It should also be mentioned that the internal resistance R ₁ is parallel to the anode resistance R _a in this circuit. Since the grid resistance R _g is generally much greater than the parallel connection of R _a and R ₁ , the interference voltage is practically the full size at the input circuit of the tube V ₂ -

The equivalent circuit diagram of the amplifier circuit is shown in FIG. It shows a bridge circuit which is in equilibrium with respect to the heating interference voltage when the filament centers JJi ₁ and Ji _{2 of} the tubes have the same interference potential. If this is not the case, the interference voltage is applied to the resistor R _s , as already mentioned.

It has already been proposed to eliminate the interference by switching on Resistances in the heating circuit or by suitable dimensioning of the heating choke to give the symmetry points the same potential. One such solution is, for example Cannot be used for row heating, since in this case the filament centers are not can be brought to the same potential. ". In addition, this proposal is disadvantageous in that than a relatively large voltage loss is brought about by the additional resistances in the heating circuit, since the Heating current of a tube must flow through the additional resistor. ,

According to the invention, to avoid these disadvantages, it is proposed to delay the production of equal symmetry potentials and to make the circuit so that the anodes are given an alternating current potential that is equal to or at least approximately equal to the potential of the symmetry point of the next tube. This would mean that the point A in FIG. 2 receives the same potential as the symmetry point M ₂ , so that an interference current cannot flow through the coupling resistor R _g. In terms of circuitry, there are various options for giving the anode the desired potential in terms of alternating current. So z. B. the anode of a tube can be connected via an additional resistor or a coupling resistor already in the anode circuit to a suitable potential of a voltage divider in the heating circuit.

It is known in amplifier cascades, the symmetry potentials, the direct current are different, to be made equal in terms of alternating current in that they are sufficiently through large capacitors are connected together. In this way you can admittedly also the disturbances caused by the difference in the symmetry potentials remove. However, the circuit has the disadvantage that it is now not possible at all tubes to adjust the symmetry potentials as differently as it is with consideration to the greatest possible degree of interference elimination on each individual tube is desirable were. In the circuit according to the invention, the symmetry potentials as such are not changed, only theirs harmful effect is eliminated by preventing interference currents through the coupling means can flow.

When establishing the connection potential for the anode in the heating circuit, it must be taken into account that points A and JJi ₂ in FIG. 2 also coincide with regard to the phase position. It may therefore be necessary to connect the anode to the heating circuit using apparent resistors. When using apparent resistances, suitable dimensioning can also be used to ensure that there is equipotentiality for different interference frequencies (harmonics).

If the gain is regulated between two tubes, so care must be taken with the circuit according to the invention that by the adjustment of the control element, the potential relationships established are not changed. SS

In FIGS. 3 and 6, two exemplary embodiments of the concept of the invention are shown. FIGS. 4 and 7 show the associated equivalent circuit diagrams and FIG. 5 shows a corresponding one Equivalent circuit diagram for series heating of the amplifier tubes.

The amplifier circuit shown in FIG. 3 shows the same coupling means as the circuit according to FIG. According to the invention, however, the anode coupling resistor R _{a is not} connected via the capacitor C _a to the symmetry point M _{1 of} the amplifier tube V ₁ , but to a tap point of the choke D ₁ located in the heating circuit of this tube. With a suitable choice of this tapping point, it is possible, by dividing the voltage across the external resistance R ₀ and the internal resistance E ₁ . of the tube to establish a potential at the point which is equal to the potential of the point of symmetry of the tube V ».

The potential relationships can be seen from the equivalent circuit diagram in FIG. The symmetry resistors R ₁ and R ₂ connected in series with the heating chokes are connected in parallel to the heating voltage source'PF. The series connection of the external resistance ^ and the

internal resistance R _it lies between the tapping point of the throttle D ₁ and the points of symmetry M ₁ -. At the grid resistor R _s of the tube ₂ V do not occur interference voltage, by suitable choice of the tap on the inductor D ₁ to the point A gave the same levels of interference is "as the point of symmetry Ai ₂ of the intensifier tube _V2.

In Fig. 5 an equivalent circuit diagram for ίο series heating of the amplifier tubes is shown. Otherwise, the same circuit is assumed as in Fig. 3. The anode. Resistance R ₀ is led here to the tap point of the throttle D ₂ . The ends of the series circuit consisting of the internal resistance R _t and the external resistance R ₀ are at two potentials which include the potential of the symmetry point M ₂ . It must therefore be possible, through a suitable choice of the tapping point at D ₂ , that the point receives the same potential as the point M ₂ , so that interference voltages cannot occur at the grid resistor R _g.

In the circuits described so far, the anode resistor was connected to a resistor in the heating circuit. If such resistors in the form of heating chokes are not present and the voltage drop caused by switching on a special resistor is to be avoided, then it is advisable to implement the circuit according to FIG. In this case, the anode of the amplifier tube V _{1 is} connected to a potentiometer connected in parallel to the heating current source PF via a high-resistance resistor R. W ₁ , W ₂ connected. In this way it is possible to give point A the desired potential. In this circuit, the connection of the anode of the amplifier tube V ₁ to a suitable potential in the heating circuit does not take place via the normal coupling resistor R ₀ , as in the previous one, but via a special resistor. This was done with a view to regulating the degree of gain. This is done with the help of a variable tap on the normal anode coupling resistor R _a . The DC voltage is also fed to the anode via this resistor. The grid and anode circuit are connected to the tube V ₂ via two separate symmetry resistors in order to avoid coupling between the grid and anode circuit in the symmetry resistors. With regard to the implementation of the inventive concept, the connection could also be made to a common symmetry resistor. 7 shows the associated equivalent circuit diagram. The symmetry resistors R ₁ and R ₂ are parallel to the heating current source, as are the potentiometers W ₁ , W ₂ . The series circuit of the internal resistance R ₁ and the additional resistance R is between ₁ M and the tapping point of the potentiometer W _1, W. ₂ By suitably setting this point, the anodet can be given the potential of point M _{2 in} terms of alternating current, so that the coupling resistance R _g is kept free of interference current.

According to a further concept of the invention, the interference effect of unequal symmetry potentials can be reduced without additional expenditure on switching means by placing the anode resistance R _a (for example in FIG. 1), not as shown, at the point of symmetry of the tube V ₁ , but at the point of symmetry M _{2 of} the tube V _{2 is} connected. As a result, the interference voltage between M ₁ and M ₂ is no longer divided between the resistors R _s and the parallel connection of R ₁ and R _a , but between Ri and R ₀ . With the normal dimensioning of R ₁ equal to R _{0, there} would be an improvement of around 0.7 Neper •. In the equivalent circuit diagram according to FIG. 2, the anode resistor R ₀ would have to be connected between points A and M _{2 for this type of circuit.} Since R _g is generally large compared to R _a , the interference voltage is divided between the resistors Ri and R _n , as already mentioned.

The idea of the invention was explained using amplifier circuits in which the Tubes are coupled via ohmic resistances and capacitances. The idea of the invention is of course also suitable for amplifier circuits with other coupling means applicable. There are only minor differences in the for such circuits Dimensioning of the individual switching elements. Of course, the concept of the invention can also be used for amplifier tubes with indirect Heating of the cathode can be used, as these tubes produce the same interfering effects can.

Claims (5)

Patent claims: 1. Amplifier cascade circuit whose no Tubes are heated with pulsating current and have different symmetry potentials of the heating circuits, characterized in that the circuit is made such that the anodes have alternating current a potential is given which is equal to (or approximately equal to) the potential of the symmetry point of the next Tube is. 2. amplifier cascade circuit according to claim 1, characterized in that the anode of a tube via an additional union resistance or a coupling resistance already in the anode circuit connected to a suitable potential of a voltage divider in the heating circuit is. 3. amplifier cascade circuit according to claim i, characterized in that the switching means required to regulate the gain are switched into the grid circuit. 4. amplifier cascade circuit according to claim 2, characterized in that the additional resistance (or an additional resistance combination) taking into account the other resistances is designed to be frequency-dependent such that the anode is independent of the frequency of the interference potential the same potential as the point of symmetry of the following Tube has. 5. Amplifier cascade circuit, the tubes of which are heated with a pulsating current and have different S3 ^r mmetriepotentiale, characterized in that the end of the anode resistor of a tube facing away from the anode is connected in alternating current to the symmetry point of the next tube in such a way that a substantial interference voltage drop between this end the anode resistance and the point of symmetry is not present. 1 sheet of drawings