DE3222434A1 - Cathode ray tube and process for the production of a fluorescent screen for such a cathode ray tube - Google Patents

Abstract

To prevent burning into the glass by the highly accelerated electron beam, it is proposed to apply a layer of quartz between the phosphor layer and the glass window, in cathode ray tubes having a fluorescent screen.

Description

description

Cathode ray tube and method of making a fluorescent screen for such a cathode ray tube The present invention relates to a cathode ray tube with at least one phosphor layer on the inner surface of a glass luminescent screen carrier, that of a point-like focused electron beam accelerated with at least 10 kV is excited to glow.

The invention also relates to a method of production of fluorescent screens for such cathode ray tubes.

There are known cathode ray tubes with very high acceleration and very highly focused electron beams operated to very small ones and to enable very bright luminous points. Such tubes are especially used for Oscillograph tubes and special display tubes are used. The acceleration the electron beams are carried out with operating voltages that are greater than 10 kV, in particular are greater than 14 kV. The energies that hit the screen are very great high, and it has been shown that with prolonged exposure to the fluorescent screen with such high-energy electron beams to glass burn-in of the fluorescent screen carrier can come, which are visible in a disturbing way. Such glass burns are particularly common in such Kai loden ray tubes, the front glass of which is easy to reduce ions, such as lead ions, iron ions, manganese ions or bismuth ions. In particular Such undesirable electron burn-in occurs with glasses containing more lead already after a relatively short loading time.

Glasses with a high content of lead become very high, especially with tubes accelerated electron beams are used as front screen glasses because they have the Reduce the amount of x-rays passing through the front window.

It is an object of the present invention to provide cathode ray tubes indicate in which a disruptive glass burn-in largely on the screen support is prevented.

This object is achieved according to the invention in that between the phosphor layer and the glass surface of the screen support one on the Glass surface firmly adhering quartz layer as a protective layer against glass burn-in is provided by electron impact.

According to a further development of the invention, preferred methods are specified for the production of a fluorescent screen for such cathode ray tubes.

Based on the embodiment shown in the figure, the Invention explained in more detail below.

The figure shows an oscilloscope tube on its glass front window 1 a phosphor layer 3 is applied. This phosphor layer can consist of a consist of a single continuous fluorescent layer. But it can also, as with Color picture tubes common, from a large number of side by side and one above the other There are fluorescent surface parts.

On the inner surface of the phosphor layer facing away from the viewer 3 there is a reflective metal layer, in particular, in a manner known per se a vapor-deposited aluminum layer.

According to the invention is now between the glass screen support 1 and the phosphor layer 3 a quartz layer (SiO2 layer) firmly adhering applied to the glass carrier 1.

The quartz layer is applied before the phosphor layer is applied 3 and any further layers to be applied. According to one embodiment According to the invention, the quartz layer is applied by vapor deposition.

According to a further preferred method for producing a product according to the invention Luminescent screen, the application of the quartz layer takes place in such a way that initially a colloidal silica solution is applied to the glass surface and then this Silica layer by a thermal treatment at about 4000C to a solid adhering quartz layer is converted. The application of the collidal silica solution takes place z. B. by rotation.

Then this thin silica layer is dried, z. B. by blowing air. Then the treatment takes place at increased. Temperature, whereby a very dense quartz layer is obtained. The phosphor layer is then placed on top of this or the individual phosphor layers applied. The application of the phosphors can be done according to a well-known conventional method such as sedimentation, rubbing, etc. take place.

To influence the flow behavior of the silica solution to be applied, can expediently an organic glue, such as. B. polyvinyl alcohol, polyvinyl pyrrolidone, Gelatin or the like can be added.

Claims (7)

Claims 0 cathode ray tube with at least one phosphor layer on the inner surface of a glass screen support, which is formed by a point focused electron beam accelerated with at least 10 kV to illuminate is excited, characterized in that between the phosphor layer (3) and the glass surface of the screen support (1) one firmly on the glass surface adhesive quartz layer (2) as a protective layer against glass burn-in Electron impact is provided. 2. Cathode ray tube according to claim 1, characterized in that the glass of the screen support (1) easily reduced ions, such as those of the Comprises lead, iron, manganese or bismuth. 3. Method of manufacturing a phosphor screen for a cathode ray tube according to claim 1 or claim 2, characterized in that the quartz layer (2) before applying the phosphor layer (3) to the glass surface of the luminescent screen carrier (1) is applied. 4. The method according to claim 3, characterized in that the quartz layer is applied by vapor deposition. 5. The method according to claim 3, characterized in that the quartz layer by applying a colloidal silica solution and subsequent thermal Treatment of this silica solution is applied. 6. The method according to claim 5, characterized in that the flow behavior the colloidal silica solution to be applied by adding an organic Adhesive is set. 7. The method according to claim 5 or claim 6, characterized in, that the thermal treatment of the applied colloidal silica layer Temperatures between 250 "C and 550" C, in particular at about 400 ° C takes place.