CS224267B1 - Power tube grid - Google Patents

Abstract

The novel grid is used to produce those power electronic tubes in which grid emission is undesirable. The novel grid is designed in such a way that its internal surface facing the cathode is coated with a metal having anti-emission properties or with a combination of these metals, and its external surface facing the anode is coated with pyrolytic carbon.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power tube grating which solves the suppression of its unwanted emission.

Suppression of the emission of the grid is particularly important for oxide cathode tubes, in which a large number of emission particles from the cathode to the grid are often already transferred during the processing of the cathode in the tube during production, the emission being activated by a sufficiently high operating temperature of the grid.

Until now, in order to suppress the undesirable emission of power tube grids usually made of high melting point materials such as molybdenum, tungsten or tantalum,. used different types of anti-emission coatings, such as titanium, zirconium, hafnium, tantalum, gold, palladium and pyrolysis carbon based coatings.

Coatings based on titanium and zirconium do not bring. In practice, good results, although reducing the working temperature of the grid due to the dark color of these products, also contribute to suppressing the emission. Their low electrical capacity, their considerable grain size and their lack of cohesion are often a problem.

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Coatings based on gold or palladium or a combination of gold and palladium have in themselves excellent antiemission properties, however, the drawback is the low permissible operating temperature of the grid, which exceeds both the production of the tube and its operation resulting in 224267 decapitation the gold or palladium coating or composition thereof, and thus the loss of the anti-emissive properties of the lattice, and often the retrograde damage to the cathode.

The pyrolytic carbon-based grids are temperature stable even at high temperatures and their dark to black color contributes to lowering the grating working temperature, but they do not sufficiently suppress the emission of the grating.

All of the aforementioned lattice covers are applied to the inner and outer surfaces of the lattices, wherein the inner surface is the cathode-facing surface, the outer surface is the anode-facing surface.

The above drawbacks are overcome by the invention characterized in that the inner surface of the grid is covered with gold, palladium or other metal exhibiting antienis properties or a combination of these metals and the outer surface of the grid is covered with pyrolytic carbon.

Such a grid cover arrangement has the following advantages:

A coating of gold, palladium, or other metals exhibiting good anti-emission properties or combinations of these metals is deposited on the inside of the lattice, i.e. where the emitting cathode particles settle, thereby reducing the emission.

Cover on the inner side of the grid in nature to act as a reflector for _R heat radiation from the cathode, and reduces the operating temperature of the grid.

The pyrolytic carbon coating applied to the outer surface of the grid contributes both to increasing the mechanical strength of the grid at high temperatures and, due to its dark color, to lowering the working temperature of the grid.

The pyrolytic carbon coating applied to the outer surface of the grid further increases, due to its properties, the electrical conductivity of the surface of the grid, important as already mentioned for the operation of high-frequency tetrodes.

Then, both the gold, palladium or a combination thereof on the inner surface of the lattice and the pyrolytic carbon on the outer surface of the lattice do not chemically react together, even at high temperatures.

The combination of these two covers and their suitable arrangement results in such an increase in the permissible specific load of the grid, in which, for a grid covered only with a gold layer, the gold layer evaporates and a grid covered only with a pyrolytic carbon layer. Thus, for example, by using the proposed coating method according to the invention, the achievable output power of the vacuum tube is increased under the same operating conditions compared to the output power of a vacuum tube with only a gold or pyrolytic carbon coated grid about 1.25 times.

Claims (1)

Power tube grating, characterized in that the inner surface of the grating is coated with a metal having antiemission properties or a combination of such metals, for example gold or palladium, and the outer surface of the grating is covered with pyrolytic carbon.