DE500725C - Vibration generator, receiver or amplifier circuit using discharge vessels working with secondary electrons - Google Patents

Description

The present invention relates to vibrator, receiver or amplifier circuits with discharge vessels that work with secondary electrons. Among the discharge vessels used here should to be understood as those in which secondary electrons are generated on a metal surface, which then in a new secondary electron flow for all purposes of reinforcement electrical currents and voltages to generate undamped vibrations of any frequency, to receive electrical vibrations, etc.

It is already known in discharge tubes with secondary electron current through Change in the primary electron flow to influence the secondary electron flow. Circuits are known in which the electrodes, through which the primary electrons the required speed is given (hereinafter referred to as the grid anode for short) and where the secondary electrons are generated (hereinafter referred to as the counter electrode designated), are influenced by currents and voltages to be amplified, so that one obtains increased currents and voltages in the secondary electron current path.

Vibration generator circuits are also known which operate on the same principle the voltage influencing the voltages of the grid anode and the counter electrode are based.

In the present invention, for the purpose of amplification, vibration is generated of any frequency, wireless reception, etc., the voltage at the counter electrodes not influenced; on the contrary, they are set to the value that is most favorable in each case for the purpose at hand.

As a vibration generator circuit for undamped vibrations of any frequency and with absolute constancy, the tube can be used in the most varied of circuits will.

First of all, in the case of three-electrode tubes, you can choose between the cathode, the grid anode and the grid known vibration generator circuit with and without external circuitry Influencing the oscillation circuits connected to the electrodes can be used. It will be ensured that that the phase difference of the voltage between the grid and the grid anode is as much as i8o ° amounts to.

In the secondary electron current path, the vibrations of the occur through the to the Primary electrodes connected to oscillation circuits at a certain frequency. From them they can be aperiodic or by means of tuned oscillation circuits to other oscillation circuits, antennas, cables etc. are taken over.

Fig. Ι shows a circuit without external influence on the electrodes K, Ga

and G connected oscillation circuits. The circuits CL and C ₁ L ₁ are not connected to one another. Vibrations occur when both circles are coordinated with one another. The amplified vibrations are transmitted on the secondary electron current path through the coils L _s to the coils L _e in the long-distance line for the purpose of high-frequency telephony along lines.

Ό The circle CL sent between grid G and cathode A "He can be calibrated as a wave meter so that it is adjusted to the desired transmission wave and then the oscillation circuit C ₁ L _{1 is} adjusted to it while simultaneously setting the most favorable coupling to the coil L ₁ or to the maximum deflection of a switched into it the measuring instrument is adjusted. the tuning accuracy of the shaft coupling when properly be less than ¹ J ₂ ° / _0th

Of course, all of the tube's vibration generator circuits are also three-electrode tubes customary and known measures both with regard to the tubular construction penetration, Electrode spacings, internal capacitances, etc. as well as with regard to external circuit measures to increase the efficiency or the harmonic purity, among other things, bias on the grid via resistors, chokes, capacitors etc. to apply.

Another example of a circuit diagram for generating vibrations is shown in Fig. 2. Here, in the secondary electron current path L ₁ .35, the oscillation circuit L ₁ C ₁ , in which the vibrations are generated, and whose self-induction L ₁ and capacitance C _{1 determines} the frequency. The self-induction L lying in the connection line between grid G and cathode K is coupled to that of the oscillation link L _1. The degree of coupling is adjustable and can be set to the most favorable value. A capacitor can be connected in parallel with the self-induction L and the resulting oscillating circuit can be precisely or approximately matched to the frequency of the circuit / -1C _1.

Grid anode G _a and counter-electrode and anti-anode ^ ₀ can be connected to self-induction L via a suitably dimensioned capacitor C ₂ to facilitate the generation of vibrations. Even if the circuits always oscillate when there is feedback, this circuit can be used to suppress the harmonics in a particularly expedient manner. Fig. 3 shows an example of the connection. This circuit can also be made in the circuit according to FIG. 1 as in the following oscillation generator circuits.

The external circuitry can of course also be influenced here by inductive and capacitive coupling between the oscillation circuit in the secondary electron current path and the grid.

Fig. 4 shows an example of a circuit for generating oscillations without external circuitry influencing the oscillating circuits, Fig. 5 shows a circuit where there is an external circuitry influencing between a self-induction in the grid anode lead and the oscillating circuit in the secondary electron current path, while between the grid C and cathode K in exactly or approximately at the frequency of the latter tunable oscillation system.

The oscillations come about in this circuit exactly as before in the one shown in Fig. 3, only that the coil L ₁ favors the onset of the oscillations.

In all cases described so far and also in the following cases, instead of Oscillating circles, wholly or partially coordinated coils or chokes occur.

It is important for all circuits that between grid and anti-anode voltage If possible, there is a phase difference of 180 °.

As a receiving tube for electrical alternating currents of any frequency to receive them Lines, antennas, etc. - Telephonic un-: l Telegraphy - show it the following circuits.

In Fig. 6, which is shown as a receiving and amplifier circuit in contrast to Figs. 4 and 5, z. B. the electrical oscillations - audible and high frequency, telegraphy and telephony, damped and undamped - on the lines α- and b , in which the coils L and the capacitor C, which are symmetrically connected here, are arranged. Through this they are transferred to the grid circle C ₁ L ₁ , log whose coupling with the coils L of the line can be regulated as required. A suitable capacitance C ₂ with and without an ohmic resistance (or chokes) connected in parallel can be switched on between the resonant circuit and the cathode. Any other circuit known in receiving circuits to improve the efficiency or possibly setting a specific receiving tone in and on the grid circle can be carried out (see the examples in the following circuits). This comes into question for any receiving circuit that works close to the limit where the oscillations begin. The connection to the grid anode G ₁₁ and the counter electrode is the usual one. This lies in the secondary electron circuit

Display or recording instrument T via a capacitor K or transformer Tr. All known: telephones, loudspeaker telephones, recorders of all kinds, electrostatic instruments, relays, microphones, etc. come into consideration as such. Of course, other discharge tubes of the same type or three- and four-electrode tubes or amplifiers can also be connected here, these using the same batteries as voltage and current sources if necessary. Interconnection of chokes, resistors, etc. can be used here in order to be able to set the coupling between the first pipe and the subsequent pipes or amplifiers as desired. The tube works here as a pure audio receiving tube, but against this with a much stronger effect.

Fig. 7 shows the tube as a receiving tube in a circuit that is easy to understand. The secondary electron current path, in which the display instrument of any kind is located, or the grid anode line is once again fed back to the antenna - or the line, etc. - or the grid circle, possibly with approximate or different coordination (coil L., capacitor C ₁ ) : either to Increasing the sensitivity without the tube generating vibrations, or with a tighter coupling so that the tube generates vibrations so as to achieve beat reception. Of course, all other Schwinggenererschal-SS lines can be used here, z. B. the earlier described, with and without external circuitry influencing the oscillating circuits connected to the pipe. This circuit does not oscillate by itself because the circuits coupled to the antenna are not switched on in the line to the electrode in which the _{% of} the current shows a negative characteristic. The circles CL ₁ and C ₂ and / "" are rather on the electrodes G and G ₀ ,

+5 which together with the cathode K represent a completely normal three-electrode tube.

When used for beat reception, it can be used in the secondary electron current path or the grid anode lead switched on an oscillating circuit of audible frequency to give preference to very specific reception tones or to filter out air disturbances. With this one, which of course can be equipped with variable capacities and self-inductions, that becomes Indicator or additional amplifier coupled.

Of course, external overlay can also be used to receive beats.

The frequency to be superimposed is then either the antenna or the grid circles or the grid anode circuit or the oscillation circuit or coils in the secondary electron current path (Fig. 8). The foreign overlay is then borrowed as required Vibration energy still adapted to its amplitude.

With all of these receiving circuits, suitable T " resistors, chokes with and without tuning, etc., with and without capacitors connected in parallel, can be switched on both in the grid anode line and in the secondary electron current path.

If the tube is used in high-frequency amplifier or multi-tube audio circuits and beat reception, you can of course also use the second, third or last tube through the appropriate Means - oscillation circles etc. - bring or also to generate oscillation supply the extraneous beat frequency to a current path of any one of the tubes.

With such amplifier circuits - the same applies to the preceding transmitter circuits like the following telephone circuits ■ - ■ can tubes one after the other different primary and secondary electron saturation currents are used, see above z. B. that the secondary electron saturation current of each subsequent tube is greater than that of the previous one, so as to achieve greater reinforcing effects. Naturally Combinations of three-, four-, and five-electrode tubes with and without can also be used here Secondary electron radiation can be used.

For the purposes of telephony with electric waves lengthways, with and without wire and any other purpose where the amplitude of the undamped generated by the pipe Waves to be influenced, sound transmission, image transmission, etc., can be a big one Number of circuits can be applied.

Any type of lattice circle influencing in every oscillation generator circuit via switched-on capacitors, coils, parts of the self-induction of the lattice coils, also capacitors and coils or chokes between the lattice circle and cathode or grid is possible. Then the grid anode current, the grid anode voltage, the voltage and the current to the counter electrode or to it and finally the voltage of the anti anode or the anti anode current can be influenced. An example is shown in Fig. 9, in which K capacitors are switched on, M is the microphone and e is the microphone battery. Of course, pre-influence tubes of any known type can be used.

Also the influencing method by connecting a variable resistor in parallel to primary electron current path-grid anode-cathode- and secondary electron-

Stromweg (Fig. ίο) e.g. in the form of a tripod Four or five electrodes raw with and without secondary electron radiation with all known circuits then z. B. the grid is discussed, applies.

Another grid can be switched on between the grid and the grid anode serves to remove the space charge in the primary electron current path. All for this Double grid tube known circuits as well as all the above circuits analogously are usable.

Claims (4)

Patent claims: i. Vibration generator, receiving or amplifier circuit using working with secondary electrons So discharge vessels, characterized in that a coordinated working circuit with the help of a grid (G _a ) in the secondary electron current path and an oscillating circuit tuned to approximately the same frequency between a grid controlling the primary electron current and the cathode are switched on, both of which are connected in terms of circuitry or through internal tubular capacitors Feedback · are coupled to one another. 2. Circuits according to claim r with tube capacitive feedback, thereby characterized in that a point on the primary electron current path is used for convenience the generation of vibrations by a capacitor or a resistor or a combination of such with is connected to the oscillating circuit lying in the secondary electron flow path. 3. Receiving circuit according to claim 1, characterized in that the input circuit directly or via transformers, oscillating circuits, resistors or the like is connected to the grid which influences the primary electron current, while the receiving instrument or the amplifier or the trunk line preferably via a capacitor in the secondary electron current path is switched on. 4. receiving circuit according to claim. 3, characterized in that for the purpose of switching off of disturbances in the secondary electron current path or the line leading to the electrode through which the Prianary cartridges have the required speed is issued, an oscillation circuit tuned to audible frequencies is switched on. 1 sheet of drawings