SU1070624A1 - Mask picture tube - Google Patents

Abstract

MASK KINESCOP, containing a vacuum cylinder consisting of a bell and a screen glass, and an electron-optical and deflecting system, a rectangular L-shaped cross-section frame with a color-separation mask, and a color cathode luminescence raster applied to the inside of the screen glass, characterized in that, in order to increase the vibration resistance, the socket is made in the form of two cones, each of which has an electron-optical and deflecting system, and the frame is provided with a rigid transverse jumper between the middle By its long sides, it is connected by its flat part with a vacuum balloon, and the outer surface of Pa | Lki is extended outside the limits of a vacuum balloon. y.VX

Description

This invention relates to television electron-beam electron tube color tubes, in particular, small-sized color picture tubes used on mobile objects.

Mask kinescopes are known for receiving color television images in which a spherical mask is fixed inside a vacuum cylinder with special protrusions and seating slots, and the springs ensure that the mask is pressed tightly against the seats c11.

However, the use of masked color kinescopes on moving objects leads to a significant distortion of color rendition due to the mask vibration caused by the vibration of the entire device and to a change in the mask-screen distance. During operation, the mask is heated by the current of three electron beams, which are 70–80% intercepted by the mask. The power supplied to the mask in small-size kinescopes is 5–8 W and significantly heats the mask, creating thermal distortions that weaken the vibration resistance of the kinescope and lead to a further deterioration in color rendition. The introduction of thermal compensation only partially attenuates this effect.

These drawbacks are especially pronounced where the picture tubes are exposed to external influences, i.e. when working on moving objects.

Also known is a mask kinescope containing a vacuum balloon consisting of a socket and a screen glass with an electron-optical and deflecting system, a rectangular L-shaped cross-sectional frame with a color separation mask and a color cathodoluminescent raster deposited on the inner side of the screen glass 12.

The known masked vibration-resistant kinescope has stiffer mounting springs, additional seats for the mask, and an outer layer of cushioning material damping external mechanical vibrations. Vibration resistance is increased by increasing the rigidity of the mount and introducing external damping. In this construction, gaps in the joints are not eliminated in principle, and the introduction of depreciation increases the size and weight of the device as a whole. Therefore, this design only leads to a certain extension of the range of operation of the mask kinescope. In addition, in the known device, the mask is cooled only by radiation, when effective heat removal is possible only with a large temperature difference.

masks and the environment, i.e. with high temperature masks (Stefan-Boltzmann law).

The purpose of the invention is to increase the vibration resistance of a mask kinescope. 5 This goal is achieved by the fact that in a mask kinescope containing a vacuum cylinder consisting of a socket and a screen glass / electro-optical and deflecting system, a rectangular L-shaped cross-sectional frame with a color separation mask, and a color cathodoluminescent raster, deposited on the inner side of the screen glass, the socket is made in the form of two cones, each of which contains an electron-optical and deflecting system, and the frame is equipped with a rigid jumper between the middle

0 long sides and connected by its

the flat part with a vacuum balloon, and the outer surface of the frame is extended beyond the limits of the vacuum balloon. The reduction of the area sharply reduces the amplitude of the mask vibration, and the removal of the frame beyond the limits of the vacuum cylinder practically excludes the heating of the mask due to intensive heat removal through the frame and then through convection to the environment.

0 Figure 1 shows the proposed mask kinescope, a general view in section; figure 2 - frame, top view.

Mask kinescope (kinescope with

5 with two throats and two cones) has a flat mask 1, mechanically or thermally stretched onto frame 2 and secured with glass cement 3 and 4. The frame 5 is glued to the frame with Musca 6 and 7, having separate electro-optical systems and a common deflection systems. The screen glass (screen) 8 has an exact seating surface 9, mated with a similarly shaped frontal inner surface 10 of the frame, which ensures that the screen glass is repeatedly accurate onto the frame during the manufacturing process of a colored screen on the inside surface of the screen glass. . The screen glass in the finished device is glued with a frame on the surfaces 9 and 10.

The introduction of two cones with their spotlights and jumpers 11 provides additional rigidity to the mask, while not interfering with the two electron beams to scan the entire screen, creating a continuous image, joined along line 12. Combining two rasters along line 12

carried out by connecting the diverting systems to one source of personnel and one source of stringal deflection voltages,

which allows both systems to be considered as a single deflection system. The vibration-proof mask kinescope has the following main parameters and dimensions. Screen diagonal 250 mm. It is the small area of the screen that makes it possible to discard spherical screens and use flat screens that provide good color reproduction without adjusting the distance of the mask-screen. Large area screens are spherical to withstand external atmospheric pressure. The dimensions of the windows in the frame are 150-100 mm. You are a honeycomb frame. 2-5 mm. Jumper width 11-4 mm. Lintel thickness 2 mm. The amplitude of vibration of mask 1 is not more than 10–20 µm in the range of 0–2.5 kHz and accelerations of 5–10. Permissible vibrations ensure the correct color retention at a deflection angle of each beam of 45 ° (total deflection of 90) 70 microns. Screen glass thickness 11 mm. The resolution is 625 lines. The contacting of the frame with the external atmosphere due to the intensive heat removal keeps the mask temperature at room temperature, which eliminates the effect of temperature on vibration resistance. Thus, reducing the free area of the mask reduces the angle of beam deflection and increases the allowable oscillation amplitude of the mask, at which there is no color distortion. The withdrawal of the frame to the outer side of the cylinder reduces the temperature of the mask. Eliminating gaps in the mask node The screen glass reduces the amplitude of the mask oscillations due to the mask oscillations in the gaps. All this creates the vibration resistance of a mask kinescope capable of operating under conditions of strong mechanical effects.

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Claims (1)

MASK KINESCOPE, containing a vacuum cylinder, consisting of a bell and screen glass, and an electron-optical and deflecting system,. a rectangular L-shaped frame with a color separation mask, а _; also a color cathodoluminescent raster, applied to the inner side of the screen glass, characterized in that, in order to increase vibration resistance, the bell is made in the form of two cones, each of which is equipped with an electron-optical and deflecting system, and the frame is equipped with a rigid transverse jumper between the middle of long sides and is connected with its flat part to a vacuum cylinder, and the bosom is withdrawn. external surface beyond the ballast