DE3913538C2 - Electron collector for an electron beam tube - Google Patents

Description

The invention is based on an electron collector according to the Oberbe handle of claim 1, as be from EP 0 259 606 A1 is known.

Electron collector for traveling wave tubes with a tubular Vacuum envelope part made of metal, inside which several catchers electrodes are insulated, z. B. from DE-PS 25 26th 681 known. From DE-OS 34 38 520 is an electron collector known for traveling wave tubes made of ceramic material. There are this so-called multi-stage electron collector, d. H. they point several interceptors on different potential tread on. Single-stage electron collectors are also known.

EP 0 259 606 A1, mentioned at the beginning, describes an electron beam receiver for Runtime tubes known, in which an essentially tubular Interceptor electrode with the interposition of semi-tubular Insulating shells clamping in an outer or vacuum envelope ning metal tube is clamped.

In one of the US 3,172,004 removable electron beam tube the collector electrode by means of ceramic tube sections against existing beamform shutters and the delay line iso liert. Vacuum tightness in the area of the electron collector can can be achieved by vacuum-tight design of the connection surface Chen of collector electrode and ceramic tube section or through an additional outer vacuum envelope.  

The Ge exists in particular for tubes with higher performance Drive local overheating in the area of the electron catch gers.

The invention is based on the object one simple in terms of construction and manufacture Specify electron collectors for high power tubes which is also a green in single-stage design or operating mode Steady heat distribution allowed to achieve.

This task is carried out with the subject of Pa claim 1 solved.

The electron trap described enables at robu stem structure and simple manufacture a desired heat distribution. The soldering may be in one Work process feasible.

Based on the embodiment shown in the figure the invention is explained in more detail below.

The electron collector shown is not part of one traveling wave tube, especially for the Use in missiles.

Parts of the vacuum envelope are the outer metal tube 1 , part of the ceramic tube 2 and the cap-shaped electrical part 5 . The metal tube 1 and the electrodes 3 , 4 and 5 are made, for. B. made of copper. The insulating tube is preferably made of a good heat-conducting ceramic, for. B. from a BeO ceramic. The essentially cylindrical Iso lierrohr 2 is vacuum-tight soldered to the metal tube 1 .

The inner wall of the insulating tube 2 is provided with a metal coating 6 to which the tubular electrode 3 with the perforated panel 4 and the cap-shaped electrode 5 are soldered. The ring-shaped solder joint on the circumference of the cap-shaped electrode 5 is carried out in a vacuum-tight manner. About the metallization 6 on the Innenwan extension of the insulating tube 2 is applied to all electrodes 3 , 4 , 5, the same potential. So it is a so-called single-stage electron collector.

The local temperature load can be influenced in the desired manner by the choice of the shape and the position of the pinhole 4 . If necessary, it may be advisable to provide further pinholes. The insulating tube 2 is a bit longer beyond the cap-shaped electrode 5 to increase the dielectric strength, since between the metal tube 1 and the collecting electrode 3 , 4 , 5 there is a larger operating voltage difference.

Claims (5)

1. electron collector for an electron beam tube, in particular traveling wave tube, with a part of the vacuum envelope bil denden metal tube ( 1 ) and a substantially tubular on collecting electrode, which is fastened within the metal tube ( 1 ) with intervening insulators, characterized net, that the insulating means are designed as an insulating tube, that the tubular collecting electrode at its end facing away from the incoming electron beam ( 7 ) has a pinhole ( 4 ), and that a cap-shaped electrode ( 5 ) is subsequently provided in the electron beam direction ( 7 ) the inner wall of the insulating tube ( 2 ) is attached in a vacuum-tight manner. 2. Electron collector according to claim 1, characterized in that the tubular electrode ( 3 ) with the hole diaphragm ( 4 ) and the cap-shaped electrode ( 5 ) are at the same operating potential chem. 3. Electron collector according to claim 1 or claim 2, characterized in that the inner wall of the insulating tube ( 2 ) has a continuous metallization ( 6 ) to which the cap-shaped electrode ( 5 ) and the tubular electrode ( 3 ) are soldered. 4. Electron interceptor according to claim 3, characterized in that between the tubular electrode ( 3 ) and the cap-shaped electrode ( 5 ) further perforated plate-shaped electrodes are provided, which are also soldered on their circumference to the metallization ( 6 ). 5. electron collector according to one of claims 1 to 4, characterized by an essentially rotational symmetry training.