DE974255C - Traveling field amplifier tube with at least two helices lying one behind the other in the electron beam direction - Google Patents

Description

The amplifications of traveling wave tubes are usually around 20 ... 30 dB. The one for a relay station Required gain is about 90 dB, so that this is only possible when equipping a point with traveling wave tubes three to four tubes are required. Succeeds in reinforcement one tube to around 45 ... 50 dB, you could use two tubes per relay point get along. It also saves coupling and decoupling for one or two tubes, so that due to the lower number of couplings in and out, smaller delay time distortions are achieved can be. Likewise, the space required for two tubes is less than for three or four tubes, even if the two tubes of high gain have to be designed according to singer. You also save on power supplies.

The high gain of around 45 dB can only be achieved with today's tubes with the help of a corresponding long active line piece (helix) can be realized. In power amplifiers, however, are long Tubes "undesirable because of the poor utilization of the spiral path with high modulation. As a result, the linear modulation range of the tube cannot be approached close to the saturation level take advantage of it. In order to remedy this disadvantage, proposals have been made known that the helix in 'several in the direction of the electron beam

009 634/3

Subdivide consecutive (galvanically separated) sections in order to accelerate of the electron beam over as large a part of the delay line as possible the optimal condition between the electron velocity and the phase velocity of the delayed wave maintain.

The operating voltage supply is in technically implemented tubes difficult for these galvanically separated coil sections. With two coils In a tube, the helix on the collector side can be connected to an, for example, ring-shaped metal bushing, which is passed through the vacuum vessel. With several spiral sections however, this is no longer possible without further ado. A metal bushing through the The vacuum vessel is also technologically complex. For the operation of the tube it is best to if the operating voltage can be supplied on one side, e.g. on the tube base. In the case of tubes with several helical sections, however, this is for reasons of high frequency technology difficult, since lead wires guided along the helical sections lead to undesirable feedback being able to lead.

It is also known per se to provide traveling-field helical tubes with an additional damping layer provided to avoid undesired waveforms, for example coaxial or waveguide modes, in addition effectively suppress, so that the tube becomes more stable in operation. The additional cushioning layer is arranged at such a distance from the helix that no essential Additional damping of the basic spiral oscillation form occurs, so the gain is not significantly affected.

In the case of a traveling field amplifier tube with at least two in the direction of the electron beam one behind the other, galvanically separated, damped coils and one parallel to the Coils extending coil holder, which at least in the area of one of the coils with a additional damping layer, which does not significantly affect the reinforcement, is provided now proposed according to the invention that the additional damping layer 16 and 21 at the same time serves as a DC voltage supply for at least one of the coils. If there are several in a row Coils, the DC voltage supply can be produced in that the additional Damping layer in several axially or • helically arranged one from the other isolated attenuation strip is divided. Attenuating strips arranged in this way are in themselves already 'known or proposed.

The invention will be explained in more detail using two exemplary embodiments.

Fig. Ι shows the spiral zone of a traveling field amplifier tube with, for example, two galvanically separated coils lying one behind the other. The two coils 1 and 2 are through the profiled dielectric tube 3 made of glass or ceramic, which is shown in section in FIG is. Instead of the profiled dielectric tube, one with a circular cross-section can also be used cut can be used.

The helix 1 is in electrical connection with the coupling cylinder 7, the helix 2 with the coupling cylinder 8 through the antennas 10 and 11, respectively. The coupling cylinders 6, 7 and 8, 9 represent the continuation of the coupling and decoupling waveguides 4 and 5 within the vacuum vessel 12. As a result of the larger vacuum vessel, the waveguide boundary must be continued within the vacuum vessel both on the side facing the coils and on the side facing away from the coils. This is done through the end walls of the coupling cylinders 6, 7 and 8, 9. On the sides of the waveguides facing away from the helical antennas 10 and 11, the coupling cylinders are each connected by one or more short-circuit bolts or molded parts 13 and 14, respectively. The DC voltage supply wire 19 for the coil section 2 on the collector side, which is galvanically separated from the coil 1, is passed through the hollow part 13. The coils are completed at the mutually adjacent ends of the two filament sections free of reflection by damping coverings 15 and _a I5, so that input and output of the traveling-wave tube are high-frequency-separated. The direct voltage supply of the helical section 2 takes place via a damping lining 16 attached to the outer wall of the dielectric tube. The helix 2 is thus through the antenna 11, the coupling cylinder 8, the connecting wire 19a, the clamp 17, the damping lining 16, the clamp 18 and the the hollow fitting 13 carried out connection wire 19 connected to the operating voltage source, not shown in Fig. 1.

3 shows a section through the tube in the zone of the short-circuit bolt 13.

Another example of the invention is shown schematically in FIG. The helix 19 is mounted between three dielectric holding rods 2o _a , 2O ₆ and 20 _c : On the side of the rods facing away from the helix, a damping layer 21 is attached, which can be used to supply further helix sections with direct voltage. The diameter of the rods in relation to the coil diameter is such that the damping layer 21 no longer significantly influences the reinforcement of the tube.

Of course, the use of the damping lining as a supply line is not limited to one Tube with two coils lying one behind the other limited, but can be used when executing the Use strip-shaped coverings even for tubes with any number of coils one behind the other.

Claims (5)

Patent claims: i. Traveling field amplifier tube with at least two galvanically separated, one behind the other in the direction of the electron beam, damped coils and a coil holder running parallel to the coils, which at least in the area of one of the coils with an additional, the reinforcement is not essential influencing damping layer is provided, characterized in that the additional Damping layer (i6 or 21) at the same time as a DC voltage supply for at least one serves the coils. 2 .. traveling field amplifier tube according to claim i, characterized in that the DC voltage supply for the coils takes place from the side of the beam generation system. 3. Traveling field amplifier tube according to claim i, characterized in that when using η coils, the additional damping layer is divided into (wi) strips isolated from one another. 4. traveling field amplifier tube according to claim 3, characterized in that the additional Damping layer in several axially or helically arranged damping strips is divided. 5. traveling field amplifier tube according to claim 3, characterized in that the DC voltage supplies through the interior of the hollow connecting pieces (13 and 14, respectively) of Coupling cylinder pairs (6, 7 and 8, 9) arranged on the input and output sides are passed through are. Considered publications:
German patents No. 854 811, 873 567, 89369s; French patent specification No. 934 220, 564; British Patent Nos. 660793, 669475. Legacy Patents Considered:
German Patent No. 932731. 1 sheet of drawings