FR2775117A1 - Electron gun grid construction for axial beam production - Google Patents

Abstract

The electron beam (50) traverses an opening (23) at the top of a bell-shaped grid (22) but is placed at the base of the hollow.The result is that electrons passing through the grid at the periphery are focussed on the axis.- DETAILED DESCRIPTION - An INDEPENDENT CLAIM is also included for an electron beam tube

Description

GRID FOR ELECTRONIC TUBE WITH AXIAL BEAM
IMPROVED PERFORMANCE
The present invention relates to the field of electron tubes with axial beam with grid and in particular those with inductive output known under the abbreviation IOT (for the English name Inductive
Output Tube). It relates more particularly to the grid of these tubes.

 An IOT comprises an electron gun which emits an electron beam directed along a longitudinal axis, this beam passing through a resonant cavity with which it interacts, before being collected in a collector which adjoins the resonant cavity.

 In these tubes the barrel comprises a cathode generally with a concave emissive part, a heating device, a control grid and an anode, the grid being located between the cathode and the anode.

 The grid is used to modulate the emission of electrons so as to group them into packets as soon as they are emitted by the cathode. The beam thus modulated crosses the single cavity in which electromagnetic energy is extracted. These tubes have a high yield and gain.

 Figure i very schematically illustrates a known electron gun for IOT type tube. The thermoemissive cathode bears the reference 1. It is solid with an emissive face 2 concave. A heating device 3 by conduction or radiation is located opposite the emissive face of the cathode 1. The control grid bears the reference 4. It is placed opposite the emissive face 2 of the cathode 1. It is very close to it, the interval which separates them can be of the order of a few tenths of a millimeter.

 Then there is an anode 5 provided with a central opening 6.

 The electrons form a beam (not shown) directed along the axis XX '. In this beam, the electrons are grouped in bundles as soon as they pass through the central opening 6. Beyond the central opening 6, they enter the body of the tube (shown in dotted lines) from the resonant cavity to the collector.

 The grid 4 comprises an openwork part 7 with bars in a central zone and a solid peripheral part 8, the assembly being in the form of a substantially flat or slightly concave disc to follow the emissive face 2 of the cathode 1. The grid 4 is fragile and its bars are thin. The grid 4 is intended to be connected to a grid connection part 10 situated at the base of the barrel, opposite the grid 4 relative to the heating device 3. It receives by this part 10 an electrical modulation signal . This connection is made by means of a support 9 electrically integral conductor on one side of the solid part 8 of the grid 4 and on the other of the grid connection part 10. This support 9 is formed by the assembly of several substantially cylindrical parts, one of which 91 surrounds the grid 4.

 At the base of the barrel there is also, in addition to the grid connection part 10, a cathode connection part, a heating device connection part and an anode connection part.

These connection parts are not shown. They are isolated from each other by dielectric spacers. These connection pieces 10 are distant from the cathode 1 and the heating device 3 and are therefore not exposed to high temperatures.

 The support 9 of the grid 4 is located near the cathode and surrounds it. It is generally made of metal because of its electrical properties because it contributes to transmitting the modulation signal to the gate 4.

 Grid 4, in the state of the art, and for reasons of thermoelectric properties, is made of pyrolytic graphite, a material known for its very low coefficient of expansion in the deposition plane.

 The grid 4 is subjected to significant thermal and electrical stresses but to play its role and modulate the beam effectively it must be able to accept them without deforming.

 The grid-cathode interval must remain substantially constant during the operation of the tube, this is an important parameter in the efficiency of the modulation and the stability of the signal.

 The grid 4 heats on the one hand because of its proximity to the thermoemissive cathode 1 and on the other hand because of the emitted electrons which inevitably strike it.

 When the tube is started, there is a differential expansion between the grid 4 and its support 9 because they do not have the same coefficient of expansion. The grid is generally made of pyrolitic graphite and the support 9 of metal.

 This differential expansion causes stresses on the grid 4 which can deform the perforated area 7, if the grid is fixed tightly to the support 9 and cause contact between the grid 4 and the cathode 1 or, at a minimum, a modification of modulation of the electron beam.

 It has been proposed, as in FIG. 1, to resiliently mount the grid 4 on its support 9 using an elastic and electrically conductive seal 11. This joint absorbs the differences in expansion. A relative sliding movement between the grid 4 and the support 9 is possible during expansion, which avoids the appearance of too great mechanical stresses in the grid 4. However, the coaxiality of the cathode and the grid is difficult to ensure. The interval between the grid and the cathode may vary. Another drawback of this structure is that it is expensive to produce. The elastic seal 11 must leave a mechanical clearance between the grid 4 and the support 9 without interrupting the electrical continuity between the two. The establishment of the seal is delicate and requires a complicated support 9 with several parts assembled together.

 The present invention seeks to overcome these drawbacks and for this purpose proposes a grid for an electron beam tube with an axial beam with improved performance which is particularly simple to produce. It leads to an inexpensive cannon which allows, in operation, to maintain a precisely defined cathodegrid distance, independent of the temperature stabilization time of the different electrodes. It allows the removal of the metal grid support.

 More particularly, to achieve this, the grid according to the invention has the shape of a bell and is mono-material, this bell having an openwork part at its top, this part being substantially transverse to the axis of the beam.

 The grid will preferably be made of pyrolitic graphite because of its thermal, electrical and mechanical properties suitable for this type of application. Preferably the grid is in one piece.

 The grid is intended to be fixed at the base of the bell to a grid connection piece.

 This grid connection piece may include a sleeve around which the grid is fitted.

 The fixing between the grid and the grid connection part can be carried out for example by soldering, screwing. To further improve the performance of the grid, it is advantageous to provide a series of slots directed substantially along the axis of the electron beam at the base of the grid. This series of slots allowing elastic compensation of the differences in expansion which may occur between the grid and the grid connection part.

 The present invention also relates to an electronic tube with an axial beam equipped with such a grid.

Other characteristics and advantages of the invention will appear on reading the following description of examples of illustrated grid, by the figures which schematically represent:
- Figure 1 (already described) an electronic tube with axial beam whose barrel has a known grid;
- Figure 2 an axial beam electron tube according to the invention whose barrel comprises a grid according to the invention;
- Figure 3a a perspective view of a grid according to the invention with a series of slots and Figures 3b, 3c different variants for the slots.

 In these figures the scales are not respected for the sake of clarity.

 FIG. 2 schematically shows a grid 20 according to the invention mounted in an electronic tube with an axial beam 50 directed along the axis XX '. It is assumed that the tube has an inductive output (IOT). Only a part of the barrel of the tube is shown, the rest is shown diagrammatically by dotted lines. The grid 20 has the shape of a bell 22 and is mono-material.

 This bell 22 has a top 21 and is extended by a substantially cylindrical skirt to a base 27.

 The perforated part 23 of the grid 20, substantially transverse to the axis XX 'of the beam is located at the top 21 of the bell. This perforated part 23 is intended to be placed opposite the active face 41 of the cathode 40 when it is mounted in the barrel of the electronic tube. The perforated part 23 follows the surface of the active part 41 of the cathode 40 and for this purpose it can be concave, in a bowl, for example substantially spherical.

 Other configurations are possible such as a flat perforated part 23 as shown in FIG. 3a.

 The grid 20 is mono-material from the top 21 of the bell to its base 27. This characteristic contributes to solving the problem of deformation generated by the differential expansions encountered in the prior art. With such a mono-material bell structure, it is no longer necessary to provide a metal support near the cathode 40 between the perforated part 23 and the connecting part of the grid 24.

 The base 27 of the bell 22 is fixed to the grid connection part 24, this part 24 serving to supply the electrical modulation signal applied to the grid 20.

 The grid connection piece 24 is remote from the cathode 40 and is located near the cathode connection piece 42. In the region of the connection pieces, the temperature never becomes as intense as at the level of the perforated part. 23 facing the active face 41 of the cathode. The harmful effects of the differential expansion between the grid 20 and the connecting piece of the grid 24 are not significant on the perforated part 23.

 The grid connection piece 24, electrically conductive, may include a sleeve 25 around which the base 27 of the bell 22 fits. The grid 20 and the sleeve 25 can be joined together using screws 26 which pass through the sleeve 25 and the skirt of the bell 22. For this purpose holes 28 in the skirt of the bell 22 and threads in the sleeve 25 are provided to accommodate the screws 26.

 FIG. 3a shows a perspective view of a grid 20 according to the invention with holes 28 in the skirt of the bell 22. The perforated part 23 is drawn hatched for the sake of clarity. This structure is not limiting.

 Another type of attachment may consist of a brazing of the base 27 of the bell 22 on the grid connection piece 24.

 To further reduce the harms of differential expansion between the grid 20 and the grid connection piece 24, it is possible to provide around the periphery of the base 27 of the bell a series of longitudinal slots 30, these slots 30 bringing a certain flexibility in the inevitable deformations which occur during heating. These slots 30 provide elastic compensation for differential expansion and remove the mechanical stresses in the grid.

 These slots 30 may not open onto the lower edge of the skirt of the bell 22 but stop before so as to delimit a wedge 31 between the base of the bell 22 and the end of the slots 30.

 After assembly, the base of the bell is divided into a number of blades spaced the width of the slots. These slots 30 do not deteriorate the electrical contact with the grid connection part 24. The wedge 31 ensures rigidity of the base 27 of the bell before mounting on the sleeve 25 but after tightening it can break. The holes 28 are located between the slots 30 in the example shown.

 The slots 30 may be of constant width, but it can be envisaged that they have an upper part 30.1 and a lower part 30.2 of different widths, these two parts being connected to one another.

 Figures 3a, 3b, 3c show several configurations of slots 30. In Figure 3a, the slots 30 have a constant width. In FIG. 3b, the upper part 30.1 is wider than the lower part 30.2 and in FIG. 3c, it is the reverse.

 These slots 30 and these holes 28 can be produced by any known means such as sawing or sandblasting machining for example.

 The grid 20 is advantageously made of pyrolitic graphite which has thermal, mechanical, electrical properties which are particularly well suited to this application. The techniques for making one-piece pyrolitic graphite grids are well mastered.

Other materials can however be used.

 The grid connection piece 24 can be made of an electrically and thermally conductive material, typically copper, molybdenum, an iron-nickel-cobalt alloy or the like.

 The sleeve 25 can also be made of the same materials if it is not in one piece with the rest of the anode connection part 24 which is in the form of a collar.

 On either side of the grid connection piece 24 and the cathode connection piece 42 are shown dielectric spacers 43 which serve for electrical insulation and mechanical maintenance between the connection pieces and therefore the different electrodes concerned.

Claims (13)

 1. Grid for electron tube with axial beam (50) comprising an openwork part (23) intended to be traversed by the electrons of the beam (50), characterized in that it is in the form of a bell (22) and is mono-material, the perforated part (23) being located at the top (21) of the bell, substantially transverse to the axis (ex ') of the electron beam (50).  2. Grid according to claim 1, characterized in that it is made of pyrolitic graphite.  3. Grid according to one of claims 1 or 2, characterized in that it is in one piece.  4. Grid according to one of claims 1 to 3, characterized in that the perforated part (23) is concave.  5. Grid according to one of claims 1 to 4, characterized in that the bell (22) is intended to be fixed at its base (27) to a grid connection part (24) electrically conductive.  6. Grid according to claim 5, characterized in that its base (27) can be fitted around a sleeve (25) of the grid connection part (24).  7. Grid according to one of claims 5 or 6, characterized in that it is intended to be screwed to the grid connection part (24).  8. Grid according to one of claims 5 or 6, characterized in that it is intended to be brazed to the grid connection part (24).  9. Grid according to one of claims 5 to 8, characterized in that the bell (22) carries at its base (27) a series of slots (30) directed substantially along the axis of the beam to allow elastic compensation of differences in expansion likely to occur between the grid and the grid connection piece (24).  10. Grid according to claim 9, characterized in that the lower end of the slots (30) stops before the edge of the base (27) so as to delimit a shim (31) between the end of the slots (30 ) and the edge of the base (27).  11. Grid according to one of claims 9 or 10, characterized in that the slots comprise an upper part (30.1) and a lower part (30.2), these two parts (30.1, 30.2) connected to one another being of different widths.  12. Grid according to one of claims 9 or 10, characterized in that the slots (30) are of constant width.  13. Axial beam electron tube (50), characterized in that it comprises a grid (20) according to one of the preceding claims.