DE2337344C3 - Emission electrode consisting of a carrier body that carries a mass that promotes electron emission - Google Patents

Description

The invention relates to an emission electrode, consisting of a carrier body which has a Favoring electron emission, made from a mixture of thorium dioxide and another metal oxide existing melt-sintered mass carries.

Emission electrodes, such as those in emission tubes, Electron beam cathodes, or e.g. B. can also be used for non-consumable welding electrodes come, are varied in terms of their shape and the material used Executions known. So is z. B. in CH-PS 22 466 a cathode body for an electrical Discharge tube described; it has an electrode body consisting of a powder mixture of a high fusible metal, e.g. B. tungsten, and a compound of at least one alkaline earth oxide and at least one other oxide, e.g. B. thorium oxide or aluminum oxide. After the pressing process, the will be off Cathode bodies formed by these materials until the alkaline earth oxides and the others melt S MetaJloxyde heated, whereupon the mass is then allowed to solidify by cooling Alkaline earth oxide and a metal oxide is preferred here because they are under certain molecular ratios react with each other and so in the sintered composite

ίο a mechanically resistant one with the heavy metal powder and form a loadable mass up to a temperature of 1000 ° C. One at higher operating temperature too operating emission electrode, e.g. B. for gas discharge lamps is known from DT-PS 8 13 573 you consists of a sintered, almost black cathode body made from a mixture of tungsten powder and thorium oxide is formed To avoid increased thermal radiation and to improve the specific electron emissivity is also an electron emission on the cathode body favoring thorium oxide layer sintered on; such a layer is white in color, see above that the thermal radiation of the cathode is comparatively low, however, it is disadvantageous that the approximately 50 μπι thick thorium oxide layer evaporates quickly under high temperature stress, which then results in the described Disadvantages again appear.

In the case of an emission electrode for tubes according to DT-OS 15 89 111, a thoriated tungsten rod carries a heating coil, which is also made of tungsten, to heat it. The tip of the tungsten rod and the filament are coated with a mixture consisting of thorium dioxide powder and thorium powder. A binding agent is added to ensure that this powder mixture adheres to the focal point of the electrode. The powder application is umgefornn at about 2000 ⁰ C to a ceramic material by arc discharge; the mass now adheres firmly to the tungsten wire and electrode pin. The binder evaporates when the

Coating compound. The coating compound created in this way has a relatively good electron emissivity, however - in comparison with other previously known electrodes for tubes - a relatively small one Mechanic solidity. Tungsten mixed with thorium dioxide and thorium is extremely brittle, the brittleness increasing with the amount of thorium added to the tungsten. The ability to bind or the stability of a mixture consisting of thorium and thorium oxide is only thermally limited durable. If the temperature rises above the melting point of thorium (1845 ° C), the Mass slightly molten; the electrode then begins to drip. In the solidified state, the Mass a very smooth or even surface structure.

Furthermore, from DT-PS 18 06 856 a non-melting point formed from tungsten with additions of thorium Electrode for so-called tungsten inert gas welding (TIG) known. To increase the electron emissivity this electrode carries one out

Coating layer consisting of thorium dioxide. This coating layer is through on the electrode tip Applied by fusion sintering. Although such electrodes have worked well in practice, they are but against mechanical stress, such as those during welding work when the workpiece is in contact occur easily, quite sensitive; the mass breaks out, making the electrode unusable will. In this patent mentioned was also

already proposed, the upper traction mass, in the present In the case of thorium dioxide, other metal oxides should be added in order to facilitate the sintering process. For this purpose, an S that melts at a significantly lower temperature than thorium dioxide is used Metal oxide. It was found, however, that when using such metal oxides either the mechanical and / or thermal load capacity and to some extent also the electron emissivity decreases. the both metal oxides form a eutectic, so that already if the electrode is slightly superimposed - as already prescribed - the mass becomes molten will; the electrode then fails almost suddenly.

Starting from the emission electrode mentioned at the beginning, which is to be operated at high temperature, the object underlying the invention is to improve this emission electrode in such a way that the melt, which becomes liquid or doughy at high operating temperature, does not drip off the carrier body The object is achieved according to the invention in that the mass promoting electron emission is a mixture consisting of 33 to 50% by weight thorium dioxide, 4 to 15% by weight aluminum oxide and containing 35 to 63% by weight tungsten powder .

The aforementioned composition is together with its highly heat resistant carrier body at least up to the eutectic temperature of the thorium-aluminum oxide mixture (1900 ⁰ C), but preferably to heated than 2100 ⁰ C, whereupon then the forming, tungsten powder-containing melt to solidify can Time Until the melt has solidified, it is left the same or shorter than it corresponds to the later operating condition of the emission electrode.

An electrode made from this mass has a high electron emissivity as well good thermal and mechanical resilience. The addition of the tungsten powder to the mass gives this Relatively good stability at high temperature The mass consisting of the metal oxides mentioned goes into its melting phase when the comparatively high eutectic temperature is reached; However, the tungsten contained in the melt prevents the mass from dripping; it is in one tough, doughy state, which hardly changes even with a high thermal overload of the electrode Even with normal vibrations, the mass sticks to its carrier. It is surprising that through the The high proportion of tungsten powder in the total mass is essentially made up of the two metal oxides certain electron emissivity hardly changes, and is even improved. This is due to, that on the one hand parts of the melt precipitate as crystals when it cools and on the other hand due to the high Proportion of the tungsten powder, the surface of the melt assumes a particularly rough shape. Through this, namely, by peak discharge and enlargement of the surface area, the electron emissivity becomes in particular when igniting the electrode - also from the cold state - significantly improved.

The compound is suitable both for the production of electrode bodies and as an embedding compound, z. B. in an electrode made of tungsten, such as those used in WlG and plasma welding come. Furthermore, it can also be used as an embedding compound in grooves or cavities ceramic material produced electrode body well suited. Such emission electrodes can in Electron beam guns but also for X-ray tubes

u. dgL apply.

In the following, various emission electrodes formed according to the invention are described with reference to the drawing.

F i g. 1 shows in the form of a diagram the quantitative composition of the mixture depending on the expected operating temperature of a specific emission electrode Carrier body at the expected specific operating temperature of the electrode in addition to an optimal electron emissivity also has a corresponding thermal and mechanical stability or operational reliability. As the emission electrode working at an operating temperature of 2,000 ⁰ C, one chooses - to a drop of the mass to avoid - the proportion of the tungsten as high as possible, in the present example, with 53 wt .-%, of the Thoriumdioxides with 40Gew.- ° / o and the proportion of aluminum oxide at 7% by weight; however, if the emission electrode is only to work at 1000 ^° C., the proportions of the mixture components in the total mass are preferably 44%, 45% and 11% in the same sequence as mentioned above.

This mass created in this way is after mixing in a known manner, for. B. provisionally connected to their carrier body by pressing, gluing, sintering or plugging. Depending on the intended use of the electrode, the mass together with the support body is at least up to the eutectic temperature of the thorium dioxide-aluminum oxide (1950 ⁰ C), but preferably up to above the melting temperature of the highest-melting metal oxide, here the aluminum oxide (2050 ⁰ C) up to 2100 ⁰ C to 22O0 ° C heats the eutectic as well as possibly also the excess portion of the aluminum oxide becomes molten. The carrier body with the compound is heated either by means of an electric arc or by igniting an electric arc or by means of resistance heating, occasionally also in a high-temperature furnace lined with magnesium oxide muffles. As stated above, it is important that the cooling of the carrier body with the melt takes place in accordance with the subsequent operating conditions

F i g. 2 shows in a graphic representation and in a greatly enlarged view a micrograph of a in the area of the surface 4 melt-sintered mass 7. The light areas here appear in the micrograph dark. The surface of the mass is rough and shows due to the tungsten 8 contained in the mass clear elevations 5 and depressions 5 '. Crystals 6 are visible in the mass, depending on the Cooling rate of the melt have a different size. The one for electron emissivity the material roughness of the surface is at least 100 μm.

The F i g. 3 and 4 show a ceramic body 9 in which a helical groove 10 is made. This groove is coated with an adhesive, whereupon the powdery mass, e.g. B. is introduced by rolling the body in the mass. ^{The body 9 is then heated to about 2000 °} C. in a furnace lined with magnesium oxide muffles, whereupon the melt-sintering process of the mass begins. The adhesive evaporates; the mass also sinters on the ceramic

see material of the carrier body. The electrode is contacted at 11 and 11 '. Such Electrodes can be used instead of tungsten filament electrodes as electron emission electrodes in electron beam guns can be used.

F i g. Fig. 5 shows in an enlarged view the tip of a welding electrode 12 made of tungsten; it can be used in a torch of a welding torch suitable for TIG or plasma welding. These electrodes have a cavity 13 in which the mass 7 is embedded. The melt sintering of the mass takes place here by igniting an arc, whereby the electrode tip is far above the temperature range heated to their working temperature. Will be the in bulk during operation of the welding electrode The eutectic contained in it is in turn molten, a fact that occurs when the electrode is exposed to high currents occurs, the mass remains due to the high

Proportion of tungsten in a tough state, se that the mass is safe in the cavity of the carrier body! or the welding electrode is held.

In the F i g. 6 and 7 an electrode body consisting of the mass Ί is shown. On a z. B. in the form of a spiral 15 made of tungsten wire or wire helix, a pill consisting of dei mass 7 is pressed. The PiIU can be pressed together with an adhesive. E: however, it is also possible to preheat the carrier body, in the present case the wire 14, with the pill and then melt-sinter it. The electrode is melt-sintered in a furnace with magnesium oxide muffles. Such - shown here on an enlarged scale - Emissionselek electrodes can mainly be used in Elektronstrahlerzeu like picture tubes, X-ray tubes, electron beam cannons.

1 sheet of drawings

Claims (6)

Patent claims: 1. Emission electrode, consisting of a carrier body, which emits electrons favoring, consisting of a mixture of thorium dioxide and another metal oxide Fused-sintered mass, characterized in that the electron emission favoring mass a mixture consisting of 33 to 50 wt .-% thorium dioxide, 4 to 15 wt .-% Aluminum oxide, which contains 35 to G3% by weight of tungsten powder. 2. Emission electrode according to claim 1, characterized in that the carrier body consists of one Thoriated tungsten is an existing welding electrode in which the tungsten powder-containing mass is embedded 3. Emission electrode according to claims 1 and 2, characterized in that the carrier body is a is made of tungsten heating coil, on which the tungsten powder-containing mass is sintered is 4. Emission electrode according to Claims I and 2, characterized in that the carrier body consists of consists of ceramic material and has a groove in which the tungsten powder containing Mass is sintered. 5. Emission electrode according to claims 1 and 3 or 4, characterized in that it has a Electron emission electrode of an electron beam gun or an X-ray tube is 6. A method for producing an emission electrode, consisting of a carrier body which carries a mass containing thorium dioxide and another metal oxide which is connected to the carrier body by sintering at high temperature, characterized in that aluminum oxide is admixed with the thorium dioxide and tungsten powder is added to this mixture "Derar" that the mass consists of 33 to 50 wt .-% thorium dioxide and 4 to 15 wt .-% aluminum oxide and 35 to 63 wt .-% tungsten, whereupon this mass is at least above the melting point of the thorium dioxide-aluminum oxide eutectic (1950 ⁰ C), but preferably heated to 2100 ° C and this forming melt containing tungsten powder is then allowed to solidify to form a melt-sintered mass.