DE1236084B - High voltage rectifier tubes - Google Patents

Description

High voltage rectifier tube The invention relates to a High-voltage rectifier tube, consisting of a glass bulb in which the cathode at one end and the anode at the other end of the tubular envelope and in which the cathode has a smaller diameter than the tubular bulb having pot-shaped anode connected to a glass tube protrudes.

In the known tubes of this type, the cup-shaped anode is through held a metal wire welded to it, the end of which goes into the tip of the tubular piston melted down. A single or two such retaining wires are sufficient with higher demands on the centering of the anode pot compared to that of this Pot partially enclosed cathode did not come out as the tube during transport and can also be exposed to stronger shocks during operation, which are sufficient to to change the position of the anode pot in relation to the cathode. It is therefore in Considered the anode pot by three welded to the anode and to hold wires melted into the top of the bulb. Such a one However, fastening the anode is technologically very difficult.

It is therefore an object of the invention to make the anode rigid fasten it and thus also center it with respect to the cathode.

An arrangement is known which consists of a glass bulb in the cathode at one end and the anode at the other end of the bulb are supported and in which the cathode in a smaller diameter than the A cup-shaped anode connected to a glass tube and having tubular flasks protrudes into it. The pot-shaped anode thus comprises an inwardly drawn-in glass tube or can also be attached to a rod, which in turn on its other end after covered in drawn glass tube. There are also known tubes with cup-shaped anodes, which, however, do not have brackets surrounding the cup-shaped anodes. Farther a cylindrical anode is known that has a cup-shaped holder on one side is covered. With this arrangement there is a space above the anode, but that directly in connection with the anode compartment. As a material for this cover is a metal, for example nickel, called.

Finally, a high-voltage tube with a cup-shaped anode is known, which has such a large wall thickness that the anode itself X-rays prevents it from escaping from the tube. The remaining tubular flask is with a surrounding insulating cylinder, which also prevent the escape of X-rays target. But this tube has the very big disadvantage that the high voltage leading Parts of the socket and the heat sink are formed over a very large area and therefore represent a particular danger.

The invention is based on this known tube in which the rigid Holding an anode in a tubular flask is realized. With this arrangement but there is still the disadvantage that it can easily flash over at the points of the tube take place, on which the getter mirror is reflected. The object of the invention consists in not only rigidly attaching the anode of the tube and thus to center opposite the cathode, but also within the tube To create space that is in communication with the vacuum of the tube itself and in which it is then possible to attach the getter material and knock down the getter mirror allow.

According to the invention, the glass tube surrounds the cup-shaped anode, and the glass tube has one or more openings. Furthermore, the glass tube can be fused to the anode. A clamp connection can exist between the glass tube and the anode. Since it was found that a cover of the cathode-anode space is also necessary for various requirements, the glass tube can also surround the space around the cathode including the mounting plate. In a manner known per se, the glass tube can also consist of glass that is highly absorbent in X-rays. Furthermore, the getter material can be applied within the glass tube or a mirror made of evaporated getter material can be applied to the inner walls of the glass tube. In the following, the tube described is based on the drawing, the F i g. 1 and 2 show two exemplary embodiments of a tube, explained in more detail.

The F i g. 1 shows a longitudinal section through a high-voltage rectifier tube in an all-glass design. The tube consists of a piston 1 with a pressed glass plate 2 in which the base pins 3 are melted. A mounting plate 5 connected to a protective ring 4 is attached to the base pins 3 . A strut 6 is attached to the mounting plate 5 and the cathode 7 of the tube is attached to it. The cathode is almost completely surrounded by a cup-shaped anode 8 which is held by a glass tube 9 . The cup-shaped anode 8 can, for. B. be clamped resiliently in the tube 9 or with its lower edge 10, for example with the help of a ring made of chrome iron, be fused to the lower edge of the glass tube 9. The resilient clamping can be done with the help of a mica strip, a metal spring guided in a groove or by slitting the anode pot. The glass tube 9 is, for. B. as in FIGS. 1 and 2, fused to the upper end of the tubular piston. The central fusing of the glass tube 9 with the piston 1 can be carried out with great accuracy.

Inside the glass tube 9 , a mirror made of a vaporized getter material can be attached in the space between the anode 8 and the connection between the tube and the bulb. The wall of the glass tube is provided with one or more openings 11 which are attached in such a way that during the generation of the getter level inside the glass tube 9, as far as possible, no getter material passes into the remaining interior of the tube bulb. A particular advantage can be seen in the possibility of attaching a mirror made of an evaporating getter material inside the tube, because it was previously not possible to attach such a getter mirror to tubes of the type described here.

In order to shield the X-rays occurring in high-voltage rectifier tubes during the blocking phase, the tube is designed according to F i 2. The F i g. 2 shows a tube according to FIG. 1, in which, however, the protective ring 4 is missing and the glass tube 9 extends beyond the anode pot 8 and with its lower, enlarged part 12 the cathode lead and the mounting plate 5, i. H. surrounds the inner parts of the tube which are at cathode potential. This lower part 12 of the glass tube 9 will so all the X-rays generated taper off to the outside, if for the glass tube 9 a strongly absorbing X-ray glass, z. B. X-ray protective glass is used.

Claims (2)

Claims: 1. High-voltage rectifier tube, consisting of a glass bulb in which the cathode is held at one end and the anode at the other end of the tube bulb and in which the cathode is connected to a glass tube with a smaller diameter than the tube bulb Anode protrudes, characterized in that the glass tube (9) surrounds the cup-shaped anode (8) and that the glass tube (9) has one or more openings (11) . 2. High-voltage rectifier tube according to claim 1, characterized in that the glass tube (9) is fused to the anode (8). 3. High-voltage rectifier tube according to claim 1, characterized in that the anode (8 ) is resiliently clamped in the glass tube (9). 4. High-voltage rectifier tube according to claim 1, 2 or 3, characterized in that the glass tube (9) has an enlarged part (12) which surrounds the space around the cathode (7) and the mounting plate (5) . 5. High-voltage rectifier tube according to one or more of claims 1 to 4, characterized in that the glass tube (9) consists of a glass that strongly absorbs X-rays. 6. High-voltage rectifier tube according to one or more of claims 1 to 5, characterized in that a mirror made of evaporated getter material is arranged on the inner walls of the glass tube (9). Considered publications: German Auslegeschriften No. 1025 076, 1113 037; German patent application L 16087V1I1c / 21g (published June 7, 1956); U.S. Patents Nos. 1917,703, 1967,537.