DE723676C - Getter arrangement for multi-system tubes - Google Patents

Description

The present invention relates to a getter arrangement for multi-system tubes, which are used as power amplifiers or high-performance tubes. The tubes can. 5 are now also used for rectification. The intended use is therefore immaterial.

Devices in discharge vessels have become known in which the getter material is not evaporated at the time

ίο which the system parts during degassing have the highest temperature. Furthermore, arrangements are known which cooling surfaces to be provided on the anode. The present one differs from these arrangements Arrangement in that it uses the cooling surfaces not only to cool the heated system parts, but at the same time as a support body for an evaporated getter material, which after the tube has melted still causes permanent gettering. The means of permanent maintenance of the high vacuum are preferably continuously atomizing under the influence of the operating heat Getter substances, the gases released by the operating heat immediately tie.

The easiest way to achieve this goal is to make a thin covering Magnesium or another gas-absorbing substance on the previously degassed anodes.

In order to combine the cooling surfaces with the gas absorbents described, special considerations must now be taken into account in the manufacture of power amplifier tubes. In particular, care must be taken that during the production of the coating acting as a getter opposite the anodes or the surfaces attached to the anodes, the glass bulb is not mirrored or not largely mirrored. Is the largest part of the glass bulb mirror, the cooling surfaces are more or less ineffective, because the radiated heat from them is reflected on the metallized mirror wall ⁴ ^ and fed radiates the anodes again. In this way, the operating temperature of the tube becomes higher and higher until the emissive layer on the cathode is sputtered or the effectiveness of the tube, in particular the cathode, suffers in some other way.

In particular, it is important that those parts of the glass wall that the anode systems are most adjacent, remain fog-free.

A getter arrangement for a multi-system tube with optionally provided with cooling surfaces Systems (anodes) is now designed according to the invention so that the systems expediently concentrically so around the getter substance are arranged around and designed so that they are opposite to the getter as

Shielding agents act, which in the evaporation of the getter most of the glass wall of the tube and that the getter and the systems are independent of each other are heatable.

The getter is atomized and the electrode systems are degassed preferably with an eddy current device. The one to be atomized and the one on the ίο Getter substance to be precipitated is included, facing the anode surface facing the interior to be arranged in such a way that they are heated independently of the electrode systems. It is of crucial importance that when degassing the electrode systems the substance has not yet atomized. A deposit on the anode can only form when the anodes are cold. the end For this reason, both the electrode systems and the substance to be atomized must to be warmed up.

A getter arrangement according to the invention is shown schematically in Fig. 1, which shows a horizontal section through such a tube. In detail, 1 is the discharge vessel, 2 and 3 are the anode systems, which are provided with cooling surfaces 4 and 5. On the cooling surface 4, a bracket 8 is provided by means of an arm 7, which carries the getter substance at 9. In this way it is achieved that the systems 2 and 3 with the eddy current device (coil) in position I are heated or degassed in the same operation. Further, it is achieved that the strap S is heated after rotation of the spool 90 to ⁰ in the position II and the intended substance thereon 9 atomized into the interior space. In position I, the getter substance is practically not heated; neither are the electrode systems in position II of the eddy current device.

Another embodiment is shown in Figs. Here are again the corresponding parts are designated as in Fig. 1. The substance to be atomized is shaped as a sheet metal strip arranged in the axis of the vessel and forms the Part of a circuit in which eddy currents are induced with coil position II, which heat the metal strip 10 up to the evaporation temperature of the getter and this evaporate. For this purpose, a bracket 11 is arranged, the surface of which with the Coil position II is parallel. The shape of this bracket 11 is shown in the side view of FIG. 3 clearly visible. The central arrangement of the magnesium strip 10 has above all the Advantage that the interior facing surfaces of the anode 2 and 3 and the Cooling surfaces 4 and 5 are dusted approximately evenly. This advantage as well as a strong interlinking of the bracket with the inducing magnetic field is achieved by the angular bend of the bracket, as can be seen from Figs. 2 and 3! But nothing stands in the way of giving the bracket another suitable shape. Another embodiment is shown in FIG. Here are anodes 2 and 3 connected by wires 12 and 13 together. In this way a circuit is created which is perpendicular to the cross-sectional area of the anode systems. The at 14 arranged getter substance is thus also with a suitable position of the eddy current arrangement to be atomized without the anode systems 2 and 3 being significantly heated. The wire 13 can of course be the same Give shape like the wire 12 and provided with getter material. That way, a second getter substance are more or less atomized.

The getter arrangement according to the invention is by no means based on power tubes with two Electrode systems limited. So is z. B. in the schematic arrangement of Fig. 5 shown how the getter substance in the interior of a tube with five electrode systems is arranged for atomization. The special thing about this is that instead of one Another electrode system a sheet metal disk 22 is arranged. On the inside of the same is the getter substance on a stem 15 16 attached. In position II, one through which high-frequency currents flow is capable Coil to heat the disc 22 so that the substance 16 evaporates and the dem Internally facing parts of the anode systems 17, 18, 19, 20 and 21 are dusted.

Also on ring-shaped electrode arrangements The invention is in no way limited. So there is z. B. the possibility of two electrode systems to be provided with flat cooling surfaces and to be arranged parallel to one another at a certain distance. »05

Nothing stands in the way of arranging another getter substance inside the tube, which primarily has the task of accelerating the degassing during the manufacture of the tubes. Such a get- »> o Substance is preferably arranged in a chamber separated by a screen. Whichever embodiment the idea of the invention may assume, such an arrangement of getter substance is always essential and electrode systems that, on the one hand, the getter and the systems independently of one another can be heated and that, on the other hand, the system parts to be fogged by the atomizing substance Protect the main part of the glass wall from precipitation. For this purpose, the

substance to be atomized in the interior of the anode systems forming a ring, which with Cooling surfaces are provided, arranged.

Since the heating of getter substance and electrode systems preferably with a Eddy current device takes place, then the further point of view is decisive for the structural design of the high-performance tube, that the getter substance arranged in the interior is brought into such a current loop becomes sufficiently strong despite the shielding effect of the ring formed by the anodes with the generating coil foot is chained.

This task is followed by another Subject of the invention thereby. ' solved that the getter substance is part of a die Electrode systems comprehensive current loop forms. It is generally not so done, the ends of a magnesium strip across the end faces of the anodes or To lead away cooling surfaces to the outside and to connect there with each other. It is coming rather, on arranging the current loop so that it is maximally enforcing At the same time, the flow does not induce any appreciable eddy currents in the system parts.

This purpose is achieved to a great extent by the special one additionally shown in Fig. 2 Loop shape.

In the position of the loops shown there in dashed lines, the one to be achieved is independent heating of getter substance and electrode system also achieved.

Claims (6)

Patent claims: ι. Getfceranordnung for multi-system tube with optionally provided with cooling surfaces systems (anodes), characterized in that the systems are conveniently arranged concentrically to the getter material around and formed so that they act with respect to the ¹ getter as a shielding means that provide the greatest during the evaporation of the getter Keep part of the glass wall of the tube fog-free, and that the getter and the systems can be heated independently of one another. 2. Getter arrangement according to claim 1, characterized in that the systems (2, 3) arranged parallel to one another and the anodes of the systems in pairs with one another are connected by conductors (12, 13) to which the getter material (14) is attached is (Fig. 4). 3. Getter arrangement according to claim 2, characterized in that the anodes of the systems connecting conductors, one perpendicular to the cross-sectional areas Form a closed current loop lying on the anode. 4. Getter arrangement according to claim 1, characterized in that the systems are arranged on a circle concentric to the tube axis and that on a metal plate also lying on this circle (22) the getter material is attached, for example, to an inwardly protruding stem (15) (Fig. 5). 5. Getter arrangement according to one or more of the preceding claims, characterized in that the getter material on one in the axis of the overall system lying conductor (10) is attached, to which preferably perpendicular _ bent extensions are located by an outside of the systems Brackets (11) are closed to form a circuit (Fig. 2 and 3). 6. Process for degassing by means of eddy currents from multi-system tubes with a getter arrangement according to one of the preceding claims, characterized in that that first the degassing of the systems takes place through a coil which has the same axis direction as the Systems, and that then the evaporation of the getter takes place in such a way that the coil in a perpendicular to the first Position arranged position is, go 1 sheet of drawings