DE701614C - Indirectly heated cathode with a heating element and surface inside an insulating tube - Google Patents

Description

Indirectly heated cathode with one inside an insulating tube running radiator and an equipotential surface surrounding the insulating tube The well-known indirectly heated cathodes consist of an insulating tube, the equipotential layer and the high-emission layer are arranged on the outside thereof is and that in its interior a heating coil in the form of a heating coil or the like. contains.

Are such indirectly heated cathodes with higher voltages (e.g. more than 30 volts) operated, so occur at the high operating temperatures Conductivity phenomena of the insulation material, which have a slow electrolytic Decomposition of the same and of disturbing electrical phenomena, such as B. Shift in grid bias, noise and, if necessary, breakdown the isolation.

The invention relates to indirectly heated cathodes that the do not have the errors mentioned.

According to the invention, an indirectly heated cathode with an inside an insulating tube extending heating element and a surrounding the insulating tube Equipotential area; in which the geometric shape of the three running into each other Components, radiators, insulating tubes and equipotential surface are selected in such a way that that the mutual contact between the heating element, the insulating element and the equipotential surface in the operating state a movement in one another does not allow the contact of the in one another running parts of the individual bodies, however, only on an extremely small part the total surface is made so that the special shape of the three Cathode parts only exist in one shape of their cross-sections, the cross-sectional shape of the three parts, however, remains the same over the entire length of the parts. This particular one Training has compared to the known indirectly heated cathodes which also have the geometric shape of the three components running into each other, Radiator, insulating tube and equipotential surface is chosen so that the mutual Contact between the heating element, the insulating element and the equipotential surface in the operating state a movement into one another does not allow and the contact of the one running into one another Parts of the individual bodies only cover a small part of the total surface. he follows, in which this effect is due to changes in the cross section along the longitudinal axis the body scores is, the advantage that the insulating body can be easily produced and that a uniform holder and thus a uniform Operating temperature of the radiator reached over its entire length in the insulating body is.

Some particularly useful embodiments of the individual elements are shown in the figures for example.

According to Fig. I, the radiator as a heating coil is not circular, For example, formed with an oval cross-section and in an insulator with a circular Bore stored.

It is essential that the shape of the heating coil depends on the shape of the Insulator bore deviates so far that there is contact between the heating coil and the insulator only takes place at a few points, but in no way over the entire surface of the insulator.

In Figs. A and 3 embodiments of isolators are shown, which are used in combination with equipotential tubes of round cross-section can. In this case it is advisable to give the insulators an angular cross-section admit.

Further embodiments of the isolator for the use of helical Radiators of circular cross-section are shown in Fig. Q. and 5 shown. Here- the holes provided for the radiator have a square, for example triangular Cross-section.

As can be seen from Figures 6 and 7, it is also possible to use isolators with a circular cross-section and the equipotential body a different one To give design.

The invention is based on the embodiments given by way of example not restricted. It is possible to use the individual elements of the, for example specified deviating cross-sectional shapes, as well as the specified elements can be combined with each other as required. It is only essential that the three elements: Heating element, insulator and equipotential element are designed and arranged in such a way that that a completely rigid structure, a minimum of electrical and a maximum thermal conductivity is achieved.

The emission layer located on the equipotential surface can in a manner known per se, both from alkaline earth metal oxides with or without a metal emission layer as well as barium or the like.

Claims (1)

l'A'fI: NTANSL'RÜCHr: i. Indirectly heated cathode with an inside an insulating tube extending heating element and a surrounding the insulating tube Equipo-ential surface, in which the geometrical shape of the three running into each other Components, radiators, insulating tubes and equipotential surface are selected in such a way that that the mutual contact between heating element, insulating element and equipotential surface in the operating state a movement in one another does not allow the contact of the in one another running parts of the individual bodies, however, only on an extremely small part the total surface, characterized in that the special shape of the three cathode parts consists only in one shape of their cross-sections, the cross-sectional shape of the three parts, however, remains the same over the entire length of the parts. z. Cathode after Claim i, characterized in that the bores are circular, oval or angular cross-section and the radiator angular or circular or oval cross-section have (Fig. i to 3. Cathode according to claim i or a, characterized in that that the outer jacket of the insulator has a circular, oval or angular cross-section has and the inner jacket of the equipotential body angular or circular or has an oval cross-section or bulges (Fig. 6 and 7).