DE1441243A1 - - Google Patents

Description

The invention relates to a circular cylindrical elec- tronic edge-shaped projection peripherally with a multi-barrel tube of the magnetron type with one of the number of anode assemblies extending to the anode assembly surrounding cold cathode, the extremely thin wires of which are provided. These electron-emitting, the anode assembly pull-wires can be made of tungsten, returned side shows a sharp-edged profile. 5 Finally, in an inventive

In known electron tubes the magnetron electron tube on both sides of the cold cathode design, a deflection electrode will be arranged on the cold cathode, which is sufficient in this way Electron emission achieved that a sharp forms and applied with such DC potentials angular profile between two are the cold cathode that the transverse electric field in the forming electrode parts is provided so that ίο area of the blade-shaped projection still is further condensed when an auxiliary potential is applied to it.

two electrode parts in the area of sharp details of the invention emerge from the

angular profile a field of high concentration from the following, exemplary description of some illustrated, which leads to the formation of gas ions, the preferred embodiments on the basis of the drawing when hitting the cold cathode a 15 voltages. It shows

Generate secondary electron emission (cf. for the case of Fig. 1 a section through an electron tube

game British patent specification 627,343). according to the invention,

In other known electron tubes of the size F i g. 2 is a cross section of the electron tube

The cold cathode is gnetron design with one according to FIG. 1, sharp-edged profile provided that the emitting 20 Fig. 3 is an overall view of the electron tube Cathode areas in front of re-incident electrodes according to FIGS. 1 and 2,

trons of high energy are protected and at the same time F i g. 4 and 5 details of a cold cathode

in the shadow of the protruding profile edges are arrangement and

(See, for example, U.S. Patent 2,449,113). FIGS. 6 to 8 show further embodiments of

An improvement in the secondary electron emission electron tubes of the present invention having cold properties by shaping the cathode accordingly.

A cold cathode is known for these electrons. An electron tube according to the invention can be tube not provided. for example as an amplifier magnetron or as an oscilloscope; '

The invention aims to solve the problem of lator magnetron. The electrons will in the case of circular cylindrical electron tubes of the tube according to FIG. 1, an oscillator magnetron contains Magnetron design at the cold cathode is an extensive one that essentially supports a circular disk To achieve secondary electron emission, mige cold cathode (20), which from an anode assembly without that for this purpose a special auxiliary potential or voltage 9 is surrounded. The anode assembly will a failed cathode design required by a self-contained delay line is borrowed. 35 formed. The cold cathode is limited with the

In the case of a circular cylindrical delay line, this task is an interaction path 10, Electron tube of the type specified at the outset within which electrons with the delay through solved that the sharp-edged profile by guide line guided high-frequency waves in Wech at least a blade-shaped projection interact. The tube case has two is formed, which is at least along the largest 40 end plates 2 and 3, the circular central Part of the anode assembly extends. Openings 5 and 6 concentric to the tube axis 4

It is particularly advantageous when they are arranged according to the invention. The end plates 2 and 3 are vacuum ■ measure the electron tube that the formation of the umdicht connected to a housing cylinder 8, Cold cathode hardly affects the frequency behavior of the tube which at the same time influences part of the delay area and that secondary electrons form 9 in a device for 45. The delay line 9 carries the the continuous operation of sufficient levels of high-frequency waves, their electrical and magnetic-emitted can be. table fields meet the interaction path 10.

The cutting edge-shaped wave energy generated is expediently the electron tube Projection along the entire anode assembly over an output line, for example one and at a constant distance from the 50 waveguide 11, which is attached to a Reso anode arrangement. Nanzkreis 12 of the delay line 9 coupled

The electron tube of the present invention can be. For this purpose, there is an opening in the housing cylinder 8 also be designed so that the cold cathode of 13 is provided, which by a for high frequency one Disk of high thermal conductivity exists, wave-permeable window 14 softens in a vacuum-tight manner is closed at least in the area of the cutting edge.

shaped projection with an electron-emitting- The delay line 9 has a plurality of

the layer is provided. In this case, the cold cathode can have anode sheets 15 and 16 which are uniform concentrically within a self-contained one distributed in radial planes (with respect to the tube-anode arrangement be arranged. axis 4) and on the inside of the

According to another embodiment of the invention 60 housing cylinder 8 are attached. The anode sheets The cold cathode can consist of several laterally dividing numerous resonance cavities, which conan one another layered disks of different arranged centrally around the tube axis 4 Thermal conductivity exist, the ones of which are outside. In addition, there are two pairs in a known manner lying disks a much smaller heat-conducting rings 17 and 18 are provided, each with have conductivity than the inner disc 65 of a group of anode sheets galvanically or the inner panes. is bound, which belong to a pair

Furthermore, electron anode sheets according to the invention can each tube in alternating sequence be advantageously designed so that the are arranged. Of course, the invention is also

3 4

in connection with other anode constructions, the cathode is warmed up, which can be applied back to it, falling electrons, which of the longitudinal

The cold cathode 20 consists of a high frequency extending concentrically with the delay line 9 Conductive frequency waves arranged in the electron tube have absorbed sufficient energy, the circular disk, which is held by a rod 21 in order to be able to get back to the cathode (Rückist. The outer edge of the circular disc runs into a heating effect). However, only then can electrons blade-shaped projection 23, which fall back on the cathode when Hochfreeiner exhibiting good electron emission properties on frequency waves along the delay line Layer 24 is coated. The cutting widths. The ones generated by the arc discharges The shaped projection 23 lies in a position perpendicular to the positive gas ions loosen on the cold cathode 20 Tube axis 4 arranged plane, which the first so many electrons that the elec-anode arrangement divides in half. The rod 21 tron concentration in the area of the crossed is mounted in sockets at both ends, which each generate electric and magnetic fields (alternately attached to the associated end plate 2 or 3 areas of action) for excitation of high frequency are. However, the rod 21 can also only be used in a 15-wave form. Once such waves of the end plates. The upper end of the rod is excited, electrons are also on the KaItmit a connection terminal 25 is provided, which cathode is deflected back. The energy exchange in is led out isolated from the upper end plate 2. Electron tubes of the magnetron type and the The associated base consists of a conductive reheating effect, hollow cylinders are well known to those skilled in the art 26, which can be inserted into the opening in a vacuum-tight manner.

tion 5 of the end plate 2 used and with a Die F i g. 4 and 5 show a further, embodiment

Insulator 27 is connected, which in turn forms the form of the invention. The cold cathode 42 is made Terminal 25 receives. The other end of this is made up of three discs, the middle one of which is a large one Rod 21 can be moved in the axial direction. stored within an insulation sleeve 28, which 25 so that in the middle layer a considerable amount of heat on its part in one in the opening 6 of the vacuum-tight amount can be stored, which uniform inserted hollow cylinder 29 is attached. An end to the emission layers 41 is given so that cap 30 encloses this base to the outside during operation of the electron tube vacuum-tight. The rod 21 is thus assured of its uniform electron flow. the supported at both ends; its fixedly mounted upper cold cathode 42 is also terminated on a rod 43 is held galvanically with terminal 25. Furthermore, in the area of the cutting edge, while its lower end slidably shaped cathode projection 45 numerous thin is mounted so that thermal stresses from wires 44 are arranged. The electric field lines can be the same. With 31 and 32 are permanent crowding together in the area of these wires, see above called magnets. The essentially U-shaped 35 that in particular at the wire tips the electrical Magnets are more clearly shown in FIG. 3 to recognize. Field strength reaches high values and as a result

During operation of the electron tube described, an intensive ionization of the gas molecules is achieved by the magnets 31 and 32 in the alternating mode. The wires 44 measure only a few thousandths of an effective distance 10 an essentially axially parallel millimeter in diameter and are generated preferential magnetic field. The anode arrangement is made of tungsten or another metal, preferably at ground potential, so that after application a high melting point. Such metals each capture a negative constant potential at the cold cathode but very easily gas molecules, which are then absorbed by 20 in the interaction path 10 in a trans. In order to prevent this, a universal electric constant field is established. The electron tube on the tungsten wires 44 discussed begins to work immediately after the coating is made of a material with an equally high application of the constant electric field, because of the melting point, but less good conductivity in the area of the blade-shaped cathode. The tungsten wires are coated, for example, jump 23 in the manner described above, one with rhenium, iridium or platinum, or with a high electric field strength, which is another suitable heat-resistant material.
Ionization of gas molecules is sufficient. The electric field line 9 that occurs between the delay cutting edge area and the cold cathode 42 during operation is large enough to be generated in a field (46 in FIG. 5) whose intensity already has a residual gas pressure of 10 ~ ⁸ mm Hg electrical arc at a short distance from the wires 44 comparative discharges for ionizing the gas molecules is too small. Ignite by the shape of this electric. The positively charged gas ions are only accelerated in the immediate vicinity by the aforementioned electrical and magnetic blade-shaped projection 45 a noticeable field on the cold cathode 20. steered, while on the Deckflächeri 47 hit only a few, so that in particular in the immediate electrons impinge. The cold cathode is made, such as cutting area mentioned an intense ion bombardment of Bo, preferably carried out several layers of cold cathode. This triggers secondary different heat capacities and thermally conductive electrons, which together with the ability to achieve as uniform a temperature as possible through the ionization of electrons released by the ionization and a temperature distribution within the cathode body of the electron flow in the interaction path 10. According to FIG. 5, one uses, for example, to generate which three disks 48, 49 and 51 are used to excite the electron tube 65, the middle one being sufficient. As a result of the continued ionization of the disk 48, preferably a much higher one, the cathode 20 is continuously heated and the electrical thermal conductivity as the two outer disks is maintained electron emission. To further er- 49 and 51 owns, which in turn are made of one material

with higher density and / or higher specific heat exist. As a result, the in in the immediate vicinity of the blade-shaped projection 45, the amount of heat generated, based on the middle disk 48, into the outer disks 49 and 51, in which they are stored for the most part will. The disks 49 and 51 acting as heat accumulators thus on the one hand prevent excessive heating of the middle disk 48 with a high electron return current and, on the other hand, an excessively strong one Cooling of the middle disk if the electron return flow is too low.

The F i g. 6 to 8 show different developments of the invention with on both sides of the Deflection electrodes 62, 63 and 64, 65 and 66, 67, respectively, arranged at cold cathodes. Each of the cold cathodes is again held on a rod 61 and, together with a delay line 9, delimits an interaction path. The deflection electrodes can according to FIGS. 6 and 7 on the same equal potential ao tial like the cold cathode or according to FIG. 8 at a DC potential different from the cathode potential lie. The deflection electrodes are preferably designed as circular disks. Through the deflection electrodes such a disturbance of the electric field course is generated in the area of the interaction paths that the field strength in the cutting edge areas the cold cathode increases. The deflection electrodes according to FIGS. 6 and 7 are in theirs Edge areas still distinctly curved. For example, the deflection electrodes 62 and 63 of FIG F i g. 6 each have a bead-shaped edge. A similar field distortion can be seen from FIG. 7th achieve by means of deflection electrodes 64 and 65, the edge areas of which are curved away from the interaction path are, so that in the edge areas of the deflection electrodes their surface against the Delay line 9 is convex towards. In addition, the deflection electrodes according to FIGS. 6 and 7 operate such a shielding of the emission layers from the end plates 2 and 3 of the tube housing, that no additional interference fields build up between the emission layers and the housing can.

In the embodiment according to FIG. 8, in which the deflection electrodes 66 and 67 through the end plates 2.3 are connected through to external voltage sources, have the deflection electrodes preferably a positive DC potential compared to the cold cathode. As the electron tube with respect to the plane (cutting plane) containing the horizontal center plane of the cold cathode is constructed symmetrically is, the deflection electrodes 66 and 67 are preferably at the same DC potential.

The deflection electrodes according to FIGS. 6 to 8 are used in particular to focus the electrical Field within the interaction paths, so that the field lines on the cold cathode only end in their cutting areas if possible. The geometric shape of the deflection electrodes can of the in the F i g. 6 to 8 shown embodiments also differ.

Claims (11)

Patent claims: 1. Circular cylindrical magnetron type electron tube with one of the anode assembly surrounding cold cathode, its electron-emitting, facing the anode arrangement Side shows a sharp-edged profile, characterized in that the sharp-edged profile by at least one blade-shaped projection is formed, which extends at least along the largest part of the Anode assembly extends. 2. Electron tube according to claim 1, characterized in that the blade-shaped projection along the entire anode arrangement and at a constant distance of the anode assembly extends. 3. Electron tube according to claim 1 or 2, characterized in that the cold cathode from a disk of high thermal conductivity, which is at least in the area of the blade-shaped Projection is provided with an electron-emitting layer. 4. Electron tube according to claim 3, characterized in that the cold cathode is concentric is arranged within a self-contained anode assembly. 5. Electron tube according to claim 1 or 2, characterized in that the cold cathode from consists of several laterally stacked panes of different thermal conductivity, of which the outer panes have a much lower thermal conductivity than the inner disc (s). 6. Electron tube according to one of claims 1 to 5, characterized in that the blade-shaped Peripheral projection with a plurality of extending towards the anode arrangement, extremely thin wires. 7. Electron tube according to claim 6, characterized in that the wires are made of tungsten are made. 8. Electron tube according to one of claims 1 to 7, characterized in that to both Sides of the cold cathode deflection electrodes are arranged, which are designed in such a way and with such DC potentials are applied that the transverse electrical DC field in the area of the blade-shaped projection is compressed even further. 9. Electron tube according to one of claims 1 to 8, characterized in that the Cold cathode is designed symmetrically to a plane running perpendicular to its axis. 10. Electron tube according to claim 9, characterized in that the tube is designed is that the transverse constant electric field is symmetrical to the plane of symmetry of the cold cathode is. 11. Electron tube according to claims, characterized characterized in that the deflection electrodes have a different from the cathode potential Have equal potential. 1 sheet of drawings