DE843122C - Electric discharge tubes, especially for very high frequencies - Google Patents

Description

Electric discharge tube, especially for very high frequencies The present invention relates to electric discharge tubes having a or several built-in capacitors.

It is generally known to use capacitors and others for switching associated elements, usually located outside the tube, in the tube to accommodate, which is particularly advantageous in the case of tubes for short and very short waves offers by making the connections between electrodes and switching elements shorter will. However, built-in capacitors make it difficult to build them Tubes and also bring the for use for short and very short waves Disadvantage with it that the connections between electrodes and capacitors despite their shortness often still show an inadmissibly high self-induction.

The disadvantages outlined above can be avoided by using a discharge tube according to the present invention oppose the one or more inside contains housed capacitors and in which these capacitors at the same time components of the electrode system. In the present case, components are bodies to understand that are directly or indirectly connected to the electrodes and on any Act as a support element, shielding element and the like. So 'plate-shaped capacitors can be used, which are made of an insulating material, z. B. mica, made plate, the .both sides with a silver layer is covered. Such a plate can then be at the lower or upper end of the electrode system be arranged and at the same time as a shielding part, as a capacitor and as a support to serve.

Another possible embodiment of in a erfindungsgernälßen Discharge tube built-in capacitors consists in the fact that one or more support rods of electrodes are made up of two or more equiaxed conductors, which are separated by insulating material. The conductive layers form in this case the different capacitor layers, the insulating material acting as a dielectric are separated. The rod-shaped capacitors described here can, for. B. as Drawn capacitors can be designed with two or more conductors underneath Interposition of insulating material arranged around each other and by hammering and Pulling until they have been pulled out to a small diameter. Because the mutual The distance between these conductors can be very small, such a capacitor can have a high Have capacity per unit of length. B. io to ioo pF per centimeter depending on the dielectric and the spacing of the conductors. With these drawn capacitors the conductors can be made of copper, nickel or such material and through an intermediate layer of magnesium oxide, titanium oxide or similar insulating material from one another be separated.

Although it already offers advantages for structural considerations, discharge tubes according to the present invention for both long wave and short wave purposes to use, the invention is of particular importance for on short and very tubes working with short shafts, since in these applications the advantage of being eliminated special connections between capacitors and electrodes not only in structural, but is also of great importance from an electrical point of view. That's how it is Invention advantageously applicable to tubes for dm and cm waves, z. B. to the mutual Increase the capacity of certain electrodes and thereby reduce the output attenuation to achieve. Which is the purpose for which the discharge tube according to the invention is applied will, may it be, one always has a design with electrodes and switching elements by the shortest possible route, d. H. in many cases immediately, without separate Wires, connected together.

The invention will now be explained in more detail with reference to a drawing, in Fig. i shows schematically a circuit of a tube according to the invention and Figures 2 and 3 show different embodiments of a tube according to the invention.

In the figures, i denotes the cathode, 2 the input control electrode, 3 the anode, which in such tubes generally consists of two plates connected to one another by a bracket, 4 is a screen grid and 5 is a catching grid. The screen grid 4 is capacitively coupled to the electrode 5.

To get a symmetrical arrangement and the input and output circuits To keep them as completely separated from each other as possible, the cathode i has two supply conductors and the electrodes 4 and 5 are connected or coupled to the cathode on two sides. This arrangement is of great advantage with dm and cm waves, as each feed wire acts as a self-induction. In the arrangement according to FIG. 1, input and output are completely separated from each other. It is essential that the capacitors b directly connected to the electrodes and 5 .sind are connected using connecting wires the shortest possible length.

In the embodiment of FIG. 2, drawn capacitors are used applied, .which also serve as support rods of the grid 5. The wires of this Grids can be wound directly onto the outer conductor 7 of the drawn capacitors be. The inner conductors 8 are connected to the screen grid by means of very short brackets 9 4 connected. The grids 2 and 4 can be wound onto support rods 14 in the usual manner be. In Fig. 2 the whole system is still one connected to the cathode Surrounding shield electrode io.

In the embodiment of FIG. 3, disk-shaped capacitors are used applied. They consist of a z. B. made of mica or ceramic material existing plate on which a silver layer is sprayed on both sides. the Electrodes 4 and 5 are fastened in the insulating plate by means of folded sockets. the Silver layers are now provided in such a way that the one plate with the rabbet sockets of the 'grid 4 makes contact and around that of the grid 5 leaves a space free while the other silver layer is connected to the rabbet sockets of the grid 5, from those of the grid 4, however, is isolated. The, rabbet bushes can be used to manufacture provided with tongues for better contact with the silver layer concerned be. In Fig. 3 the upper silver layer i i is with the tongues 13 of the electrode 4 in connection. Too much heating due to eddy currents during degassing or to avoid during operation, the silver layers with a gap 12 are provided. The silver layer connected to the grid 5 is used at the same time as an umbrella. Such disk-shaped capacitors are preferred arranged at both ends of the electrode system, where they are usually there replace the screens provided. ' The invention makes it possible to achieve the desired effect without making the structure of the electrode system significantly more complicated will. It is evident that the invention also applies to the installation of capacitors in tubes for other purposes, e.g. B. for the usual wavelengths, is applicable. The two described can also be used Combined embodiments occur, and other forms of capacitors may be possible.

Claims (6)

PATENT CLAIMS: t. Electric discharge tubes, in particular for very high frequencies, with an electrode system and one or more inside the condensers housed in the tube, characterized in that these capacitors at the same time form components of the electrode system. 2. Electric discharge tube according to claim i, characterized in that cylindrical capacitors are used will; which at the same time serve as support rods for an electrode. 3. Electric Discharge tube according to Claim 2, characterized in that the wires are of a lattice shape Electrode are wound on the outer conductor, while the inner conductor with connected to another electrode. 4. Electric discharge tube according to claim 2 or 3, characterized in that the cylindrical capacitors are drawn from coaxial conductors with insulating material attached between them. 5. Electric discharge tube according to Claim 1 or 2, characterized in that disk-shaped capacitors are arranged at the ends of the electrode system and at the same time serve as umbrellas. 6. Electric discharge tube according to claim 5, characterized in that the disk-shaped capacitors are made from a mica or similar material existing plate are built on both sides with a Silver layer is coated, the silver layers with the relevant electrodes stay in contact.