DE2332588C3 - Method for producing a cold electrode for use in a gas discharge lamp - Google Patents

Description

at least one electrical impulse is activated, characterized in that an alkaline metal is used as the activating substance which

from group IA and UA is heated by degradation at a 20 evacuated one at a time

Temperature below the activation temperature is formed, and that the degraded alkaline metal is dissolved in a volatile solvent, allowing an alkaline metal solution to mix with the powdered, high-purity metal from group IVA and VA is formed.

and is filled with a gaseous filler and wherein then the constituents which are added to the powdered nickel are activated by at least one electrical pulse.

After this procedure it is possible to have a To create gas discharge lamp in which the emitted gases in the discharge lamp with the help of the activated Components added to the powdered nickel are removed. In this procedure, however the powdered nickel used to do that

The invention relates to a method for producing cold electrode to form, with impurities that remain a cold electrode for use in a gas discharge only between the nickel powder, the interior manure lamp, in which a powdered metal from the electrode can so contaminate that this group IVA and VA of the periodic table with electrode is no longer mixed for the absorption of an activating substance emitted, in which the 35 gases are suitable. To prevent this, it is necessary to form an electrode from this mixture, sinter it and to provide an additional process step, which is finally activated, in which the electrode is further intimately connected _{to the powdered nickel with a reduction on a rod used as an electrode lead, material such as BaAl 4} is mixed so that its melting point is relatively high, unavoidable impurities, which are trapped in the powder and in a gas discharge vessel, the remaining nickel is attached to the getter powder,

iinnn in iiKlirdiAt · U / αΪγλ Kf «l _nA _ t_» 1 .. ι_Ί · · _ κ ·: _i: η. α ι u: _ _-i J _ η

then evacuated in the usual way and then filled with filler, and in which the Electrode is then activated by at least one electrical pulse.

Various attempts have already been made to determine the electron emissivity of a cold electrode, the is used in a gas discharge lamp to improve the operation of the lamp to favorable influence. The electron emission efficiency of such a cold electrode is determined by, for example Impurities in the electrode material itself, due to the emission of emission gases from the electrode and reduced by gaseous residues which remain in the vessel of the discharge lamp. Around such as connecting BaAU so that they become ineffective.

One has already tried a new and improved one To create a process in which it is no longer necessary to use reduction material to eliminate the unavoidable impurities that are in the material for the electrode remain to be provided, as this results in the manufacturing process of a gas discharge lamp can be simplified, and it has been found that instead of nickel, the metals such as zirconium and Tantalum, which belong to group IVA and VA of the periodic table, are exactly those substances that are called Base material can be used for such an electrode without it being necessary that

to reduce adverse effects and to use any reducing material during manufacture

To increase the degree of electron emission of such a cold electrode, you already have a getter in the Vessel, inserted separately from the cold electrode, so that the emitted gases or similar impurities are absorbed by this getter. When However, if such a getter is also used, the gas discharge lamps can only be operated with difficulty produce and there are particular difficulties if you want to make these lamps smaller.

In order to avoid these disadvantages, which result from the separately used getter, one has created a cold electrode that takes over the operation of such a getter. Such a cold electro treatment process is added, and that also the Electrode made in this way does not have the troubles associated with contamination inside.

On the other hand, a method of the type described above is known (DT-AS 12 25 757) in which also used as a metal from group IVA and VA of the periodic table zirconium and tantalum which is mixed with an alkaline earth metal oxide as an activating agent. The electrode is made from the mixed particles, then sintered and finally activated. The mixture is used for activation of powdered metal and alkaline earth metal oxide like that

far heated that an explosion of the activation mass escapes, the explosion pressure is directed so that kana spray only a negligible part of the activation compound from the electrode

On the other hand, there are various So-.terelectrodes known (DT-AS 15 89 227 and DT-AS11 96 796), which as a sintered component a metal such as zirconium, hafnium, niobium, tantalum, molybdenum, tungsten, iron or nickel have, and as the other component in simple metal oxide such as barium oxide, or strontium oxide a mixed oxide such as barium strontium titanate or barium magnesium aluminate. However, it is It is not known how with such electrodes it can be avoided that impurities get into the Inside the electrode. ,

On the other hand, it is known (DT-PS 9 66 92?) That Manufacture sintered electrode for an electric high pressure discharge lamp that dL · individual Components of the sintered electrode, such as metal powder and metal oxides of the type specified, with one another are mixed and then moistened to a paste before the pressing process, from which then in a Press the desired body is shaped. After pressing, the moisturizing agent evaporates Solvent. Only then does heating take place. This process increases the strength of the Sintered body greatly increased.

The object of the invention is to provide a method of the type mentioned at the outset for production indicate a high-strength cold electrode with the disruptive impurities in the material for the Electrode must be switched off.

This object is achieved in that an alkaline metal is used as the activating substance, that formed from Group IA and 11A by degradation at a temperature below the activation temperature is, and that the degraded alkaline metal is dissolved in a volatile solvent, so that a alkaline metal solution for mixing with the powdered, high-purity metal is formed from group IVA and VA.

If a cold electrode for a gas discharge lamp is manufactured using this method, then it will both improve the performance of the lamp considerably and considerably improve its life raise.

The one produced by the process according to the invention The cold electrode is reactivated in its actual electrode part every time the Gas discharge lamp is discharged, with gaseous impurities in the vessel of the gas discharge lamp arise, for example, be removed as undesirable residues of a discharge, so that the gaseous filler that is filled into the vessel is cleaned, which in turn increases the efficiency increased in electron emission.

An embodiment of the method according to the invention and that according to the invention Process produced cold electrode are described below with reference to the drawings by way of example. It shows

F i g. 1 shows a longitudinal section through a gas discharge lamp with a cold electrode,

2 shows an enlarged side view of the cold electrode according to Fig. 1, partly in section, and

3 shows an enlarged section of a particle, from which the cold electrode according to FIG. 1 and 2 According to FIG. 1 contains a gas discharge lamp with a cold electrode, a vessel 1 made of glass. The in Fig. 1 shown vessel 1 is rectilinear in shape, but can it can generally also be U-shaped. Electrode rods 2 are located at the two ends of the vessel 1 or 4 are provided, one end of which protrudes outward from the vessel and the other end of which is in the Inside the vessel 1 is located at the end of the electrode rod 2 protruding into the vessel t Electrode 3 attached. Consequently, no special getter inserted into the vessel is provided, as its Function is taken over by the cold electrode 3 designed in a special way.

This electrode 3 is manufactured in the following manner by way of example. Powdered zircon that belongs to group IVA of the periodic table can be obtained in a highly pure state by the fact that a compound containing this metal element is degraded at a temperature below that Activation temperature. On the other hand, cesium carbonate is degraded at a temperature below its activation temperature is so that one cesium, an alkali metal belonging to group IA des belongs to the periodic table and is kept in a highly pure state after the carbonate composition tongue has been removed. The powdered cesium obtained in this way is dissolved in a volatile solvent, for example alcohol, dissolved so that a cesium solution is obtained. The purified zircon powder will then mixed with this cesium solution, so that zirconium particles 5 arise, each of which on its entire surface with a cesium layer 6, as shown in Figure 3. is coated and there will be then the coated zirconia particles are arranged in a corresponding shape that corresponds to the electrode. The electrode, which is made up of coated zirconia particles, is then sintered and activated so that a plate that forms the electrode 3 is formed. This electrode plate is mechanical in a known manner attached to the electrode rod 2, which is made of a metal whose melting point is relatively is high, as can best be seen from FIG. 2 reveals. The educated in this way and treated electrode 3 is then closed in the vessel 1, which is then evacuated, is heated and filled with the required gaseous filler, and it becomes the electrode 3 then activated by at least one electrical impulse.

The pollutant gases that are still in the gaseous filler or the fill gas in the vessel 1 remain, or which are generated by the electrode rod 2 when it is heated during the discharge process, are reduced by the electrode 3, as this consists partly of getter material and always then when the electrode is affected by the electrical impulses that are supplied during the discharge process, is activated again, and it w ill be that way induced pollutant gases on a cold part held in the discharge lamp, so that the interior of the vessel 1 only with the gaseous Filler of a high degree of purity is filled. It is therefore not necessary to use a special getter material to be provided in the gas discharge lamp for the absorption of contaminant gases, and since the Electrode that takes on this function through the electrical impulses that are fed to the discharge lamp during the discharge process.

is activated again each time, the function of this electrode remains as a getter for a long time receive.

On the other hand, since the powdered zircon is converted into cesium-coated zircon particles, that is Ratio of the mixture of cesium to zirconium much larger than if one simply mixed cesium with zircon, and through this relatively large proportion of cesium compared to the proportion of zirconium, the Decrease the work to be done by the electrode 3.

It has already been mentioned above that the contaminant gases in the discharge lamp every time then eliminated when electrical impulses of the

Discharge lamp, which further reduces the work done by the electrode, so that the electron emission efficiency of the cold electrode can be effectively increased.

Instead of zircon, other metals belonging to group IVA or VA of the periodic table can be used include, such as tantalum, can be used as the base material for the electrode. And next to cesium other alkali metals of group IA or HA as well as alloys formed from them can be used as filler metals can be used for this base material.

1 sheet of drawings

Claims (1)

Claim: de is described, for example, in Japanese laid-open specification 47 11 510. Aas this laid-open specification shows that in the method for Production of a cold electrode for use in a gas discharge lamp, powdered nickel is provided, which is initially mixed with an alloy which contains at least one alkaline metal or an alkaline earth metal, or that it is with a Mixture of one of the metals and a reducing agent bi di f di Process for the production of a cold electrode for use in a gas discharge lamp which is a powdered metal from Group IVA and VA of the periodic table with a Activating substance is mixed, in which the Electrode formed from this mixture, sintered and finally activated, in which the electrode io material is mixed, the in this way also formed on a nickel mixture serving as an electrode lead into a desired shape, the a cold electrode to be used, is brought, then the molded part at a Temperature below the activation temperature of the to and then filled with filler, 15 ingredients added to the powdered nickel and in which the electrode is then sintered through and then the molded part mechanically on a metal lab for use as Electrode is attached, wherein the electrode is further enclosed in a vessel of a gas discharge lamp The rod used for the electrode supply line, the melting point of which is relatively high, attached and enclosed in a gas discharge vessel, which is then evacuated in the usual way