DE595408C - Tube transmitter in which the anode power is reduced through the use of almost rectangular AC voltage and current curves - Google Patents

Description

The present invention relates to

- Circuits for generating high frequency electrical vibrations with the help of electron tubes (tube transmitters) and aims to the power loss converted into heat on the anodes of these tubes in the

■ to keep the ratio to the overall performance implemented as small as possible.

It is already known to reduce the size to achieve the anode power loss by taking the anode alternating voltage and the anode alternating current, gives a rectangular course as precisely as possible, so that either the anode current is always large and the anode voltage small or the anode. - the electrode voltage becomes large and the anode current becomes small (see yearbook of wireless telegraphy and Telephonie, Vol. 14, p. 126, 1919). It has also already been suggested that the rectangular shape of the anode current through to achieve a rectangular alternating grid voltage.

In order to achieve a rectangular course of the anode current in addition to a rectangular course of the anode voltage, it has already been proposed to connect a system of circles to the tube, which at the frequencies of n, 2 n, 3 ti, 4 / ζ, ζ η etc. Has resonance points. This creates complicated circuits that require a large amount of switching means.

According to the invention it is therefore proposed to divide the anode circle into two parallel circles to divide, of which one for the fundamental wave, the other for the harmonics one Resistance approximately equal to the limit resistance, while the former for the harmonics, the latter represents a very high resistance for the fundamental wave.

An embodiment of the invention is shown in the figure.

Here 1 means the transmitter tube with the cathode 2, the grid 3 and the anode 4. * The grid alternating voltage is taken from an alternating current source 5, the voltage of which can be sinusoidal and is fed to the grid via a resistor 6. Between Grid and cathode is an auxiliary rectifier 7, z. B. a gas rectifier, connected in series with a DC voltage 8. In series with the alternating voltage 5 is also a DC voltage 9. As soon as the sum of the AC voltage 5 and the DC voltage 9 is greater than the sum of the DC voltage 8 and the ignition voltage of the rectifier 7, this rectifier is permeable and practically represents a short circuit

so that the voltage on the grid 3 cannot increase any further. That way will a nearly rectangular shape of the alternating grid voltage is achieved.

The anode DC voltage is supplied in a known manner via a choke 20 and kept away from the oscillating circuits by a block capacitor 10. The system The oscillation circuit contains two branches that are connected in parallel to each other. Of the The first branch consists of a capacitor 11 and one connected in parallel to it Self induction 12; to both in series there is an ohmic resistor 13, its value is equal to the limit resistance, which is caused by the anode voltage and the emission of the ' Tube is determined. The second branch consists of a capacitor 14 and one Self-induction 15 connected in parallel to each other are, and a further self-induction 16, which is in series with both. The value of self-induction 15 is the same as that of self-induction 16. On coil 15 is in In a known manner, a coil 17 is coupled, which feeds the vibration energy to the antenna; the antenna is represented by the capacitor 18 and the resistor 19.

The circles 11, 12 and 14, 15 are both on matched the operating wave of the transmitter.

If one denotes the alternating current resistance of the capacitor 11 or the coil 12 for the operating frequency with X ₁ and its damping with d _lt, then the resistance of this circuit for the fundamental wave is _{XJd 1} . Since (I _{1 is} a very small number and ti is at least 3 due to the symmetry of the current curve, it can always be achieved that X ₁ Jd _{1 is} large, XJn small compared to the limit resistance. The whole of the elements 11, 12, thus 13 ordered branch has a resistor, for all candidate harmonics is virtually infinite for the fundamental wave equal to the critical resistance. the oscillation circuit 14, 15 may be obtained by appropriate coupling of the coil 17 in a known manner such damping d ₂ give that its resistance for the fundamental wave X ₂ Jd ₂ equals the limit resistance.As one can easily recalculate, this condition can also be fulfilled for the whole branch consisting of the elements 14, 15, 16. The resistance of this branch is, however, for high frequencies essentially equal to the resistance of the coil 16 alone, i.e. for the / z-th harmonic equal to X ₂ -n. If X _{2 is} chosen to be sufficiently large, the resistance of the branch 14, 15, 16 for the harmonic waves make any size against the limit resistance.

By connecting branches 11 in parallel, 12, 13 and 14, 15, 16 will now indeed be one Created resistance, both for the fundamental wave and for all harmonics the Has the value of the limit resistance and therefore has a supplies square anode alternating voltage of the correct magnitude.

Claims (5)

Patent claims: 1. Tube transmitter, in which, through the use of approximately rectangular alternating voltage and current curves the anode power loss is reduced, characterized in that the anode circuit in is divided into two parallel branches, one of which is for the fundamental wave, the others have a resistance approximately equal to the limit resistance for the harmonics has, while the former for the harmonics, the latter for the fundamental represents a very high resistance. 2. Tube transmitter according to claim i, characterized in that the one parallel branch of the anode circuit, a closed circuit (11, 12) in series with an ohmic one, matched to the operating shaft Resistance (13), the other branch is also matched to the operating shaft closed circuit (14, 15) to which the consumer is coupled can, in series with a self-induction (16). 3. Tube transmitter according to claim ι or 2, S5, characterized in that the generation an approximately rectangular grid alternating voltage parallel to the grid alternating current source an auxiliary rectifier in series with a DC voltage source is connected. 4. modulation circuit for tube transmitter according to claim 1 to 3, characterized characterized in that for the purpose of modulating the transmitter, the interval width of the square waves is changed. 5. modulation circuit for tube transmitter according to claim 4, characterized in that that the interval width of the supplied rectangular grid alternating span 11a influence by influencing the grid alternating current source or the auxiliary rectifier upstream DC voltages is changed. 1 sheet of drawings