KR840000489B1 - Method of manufacturing a colour television display tube and colour television display tube manufactured according to the method - Google Patents

Abstract

In manufacturing a color television display tube, a reference system is used to adjust the various components of the tube to each other. The system uses the deflection center(and in some cases aloso the electron-optical axis) of a deflection device as a reference point to adjust the tube components. Marks may be provided on the cone of the tube. The assembling of the neck and cone portions, guns, and display windows is also described.

Description

Manufacturing method of color television display tube

1 (a) and 1 (b) is a schematic design and side view of the display screen, the display window by the exposure apparatus, respectively.

2 is a first embodiment of the present invention having a neck portion fixed to a cone portion.

3 is a second embodiment of the present invention having an electron gun assembled to a neck portion.

4 is a third embodiment of the present invention with a display window fixed to the cone.

5 is a fourth embodiment of the present invention with a marking given to the cone for positioning another part of the display tube.

The present invention provides for the production of color television display tubes in which said parts in the display tube, consisting of a neck portion, a cone portion, a display window and three electron beams, are adjusted relative to each other while using the reference setting device. It is about a method.

In the manufacture of color television display tubes, it is customary to eliminate color impurities and focusing errors of the display tubes with various calibration devices. Such color impurities and focusing errors are caused by insufficient precision in assembling various correlated parts such as display windows, funnel parts, electron guns and deflectors in assembling display tubes. Moreover, in the manufacture of these parts, the parts themselves are also limited in precision, as a result of which the same parts are not identical to each other.

Many reference setting devices for adjusting the various parts of the display interface are known. Conventional reference setting devices are disclosed in US Pat. No. 3,971,490. In this patent, the reference surface is ground at the funnel portion of the display tube, and the axis of the neck portion at the funnel portion is regarded as the grinding reference surface. The display window is located in the funnel section and the reference point of the display screen and the reference surface of the funnel section have a common reference point R. In this way, the display screen is mounted on the neck portion of the funnel portion. Thereafter, the effective power source of the electron beam generated by the vaginal electron gun which is installed in the neck portion is installed on the neck axis, and this effective power source is installed with respect to the display screen. However, when such a reference setting device is used, the support surface of the funnel portion whose position has already been determined with respect to the display window needs to be perpendicular to the tech axis. In practice, however, it can be seen that grinding the support surface perpendicular to the axis with a given precision is very difficult or almost impossible. Moreover, when the above reference setting device is used, each position of the deflection device needs to be brought to the deflection center determined on the neck axis of the display tube. Adjustment of the funnel deflector is time consuming and costly in the manufacturing process. Therefore, there is a need for a device that minimizes the number of adjustments and operations for deflection adjustment on the funnel portion of the indicator tube.

It is an object of the present invention to provide a method for producing a color television display tube which allows the deflection device adjustment on the funnel portion of the tube within the tolerance to be supervised with a few simple operations.

Color television display tubes comprising said parts of the display tube made up of the neck portion, the conical portion, the display window, the neck portion and generating three electron beams are made to be adjusted to each other while using the reference setting device. In the method, the reference setting device is fixed to a reference point for adjusting the at least two of the parts so as to adjust the parts to be positioned in place with respect to the calligraphy, wherein the deflection center of the deflection device in which the reference contact is later installed. It is characterized in that it is located within.

The center of deflection is understood to mean the center where the deflection focus of the magnetic field of the deflecting device will be focused on the virtual electron beam whose center line coincides with the longitudinal axis (electro-optical axis) of the deflecting device. The deflection center is the accumulation of points called deflections that observe electrons and emit electrons. Therefore, the deflection center means the same power source as the above-mentioned electron beam is valid.

The manufacture of the deflection device can be carried out with small tolerances. This means that the value of the center of deflection with respect to the point of the given device is fixed accurately. During manufacturing of the display tube, the deflection center is positioned as a reference point and later installed in the display tube by setting marks for adjusting various parts such as display windows, cones, necks and electron guns located at their reference points. It is possible to make the deflection center of the deflection device to be coincident with the reference point determined by the reference setting device. In addition, a reference setting device may be used to fix a reference axis substantially coincident with the electron optical axis of the deflection device installed in the display tube manufactured later. The position of the deflection center can be known early in the manufacturing process of the display tube. According to an embodiment of the method according to the present invention, the reference setting method may be determined by a center setting device which mainly determines the deflection center in the cone by fixing the cone, and fixes the electron optical axis and the deflection center in the cone by fixing the cone. It can also be determined by the determining device. In another embodiment, the reference setting method is fixed with a cone so as to have a direction of deflection center, an electro-optic axis in the cone, and two major axes parallel to the rectangular side of the square end of the cone with reference to the original deflection center. It is determined by the centering device which determines the main axis. The uniformity of the manufacturing process of the display tube is increased in accordance with an embodiment of the present invention which allows at least two or more steps of the manufacturing process of the display tube to allow one part of the display tube to be manipulated with respect to the cone at each of these stages. The centering device here is used to fix the cone in the same manner as above.

In order to adjust these parts, the display section is set in the cone, or if one or more other parts are adjusted by the display section, the display section becomes a reference for the fixed deflection center by the reference setting method.

According to the present invention, the method in which the neck portion is fixed to the conical portion of the display tube is characterized in that the cone portion is fixed by the centering device and the longitudinal axis of the neck portion is in the extension portion of the electron optical axis determined by the centering device.

The method of assembling the electron gun to the neck portion is characterized in that the cone portion is fixed by the centering device and the longitudinal axis of the electron gun is given in a virtual extension of the electron optical axis determined by the centering device. The rotational position of the electron gun about the longitudinal axis can in this case be determined by the centering device.

The display window is fixed to the cone by the centering device so that the conical part is fixed and the display window is fixed to the rectangular end of the cone so that the two main axes of the rectangular display window correspond to the main axis determined by the centering device and the direction of the display window. It is parallel to the line passing through the intersection point of the main axis and passes through the deflection center determined by the centering device perpendicular to the plane fixed by this theory.

Thus, among the basic concepts of the present invention, the deflection and the electro-optic axis of the deflection device, which is later assembled to the tube, is fixed at an early stage of the tube manufacturing process. This makes the positioning of the deflection device in the finished tube fairly simple. When configuring the centering device for holding the cone portion as the dummy deflecting device, the positioning of the deflection device is limited because it simply slides the deflection device on the display tube until the deflection device is supported on the cone portion.

Hereinafter, an embodiment for carrying out the method of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1 (a), the display window has three contact gums 31, 32, and 33 with the vertical axis of the display window for the contact points 31, 32 passing through the exposure point p '. And a line perpendicular to the plane (33 in the figure) passing through (33). Furthermore, the main axis configuration of the display window is fixed in the direction of the axis parallel to the line passing through the starting point on the longitudinal axis of the display window and the contact points 32 and 33. The device having a major axis is installed parallel to the plane of the drawing. The vertical axis of the display window is indicated by P'M 'in FIG. 1 (b). The distance from the short side of the display window 30 at the contact point 31 to the vertical line parallel to the plane of the drawing passing through the exposure point p 'is indicated by one. The distance from the long side of the display window 30 at the contact points 32, 33 to the vertical line parallel to the plane of the drawing passing through the exposure point P 'is indicated by m. Clearly, since the exposure point P 'becomes the exposure point for the blue fluorescent area of the display screen, it becomes the exposure point for the blue fluorescent area of the display screen. In practice there are two more exposure points for the red and blue fluorescence region. These points are located very close to the exposure point P 'and formed at the same time as the exposure center corresponding to the deflection center of the deflection apparatus on the display tube. Moreover, the present invention is described with reference to a display tube having a light beam intended to extend in parallel to a short side portion of the display window. These disclosures for describing the present invention do not have any limitation on the application of the present invention. The invention is used in any pattern of fluorescent regions and the invention is within the scope of the principle although the description is brief. As shown in FIG. 1 (b), the display window having the fluorescent layer is exposed through the shadow mask 34 at the exposure point P 'at a distance r from the support surface 35 of the exposure table. It is sufficient if the point of exposure P 'coincides with any point of the display tube positioned during deflection of the deflector in order to correct the position of the display window in the event of a funnel injury of the display tube.

In FIG. 2, the neck portion 60 is sealed to the cone portion 61. Cone 61 is supported at point 62 and has a stud 63 on the short side of the square end of the cone. The centering device 64 is located on the cone portion which fixes the deflection center D 'in the conical portion and the electro-optical axis 65. In the positioning device, the distance from the deflection center D 'to the plane 66 parallel to the direction of the main axis by the short side portion of the rectangular end of the cone, and perpendicular to the plane of the drawing, is the first (a) degrees and the first. (b) is moved over the conical surface until it is equal to the distance 1 shown in FIG. Once inserted into the positioning device 64, the neck portion 60 is fixed on the outside with respect to three contact points 67 which determine one point of the electro-optic axis 65. By the jig 68 which determines the second point of the electron optical axis, the axis of the neck portion 60 is moved in the extension of the main axis 65. In this position, the neck portion 60 and the cone portion 61 are fixed by a fixing device (not shown). The centering device 64 and the jig 68 are moved and the neck 60 is sealed to the cone 61. It is also possible to fix the neck to the contact point 67 and the axis of the neck will not coincide with the axis 65. However, this coupling coincides with the axis 65 of the electron gun and is thus corrected during assembly of the electron gun in the neck portion. The funnel portion resulting after sealing the neck portion 60 is ground to length and repositioned within the centering device 64. The material of the funnel is ground from the square end of the funnel until the distance from the deflection center point D 'to the grinding cone surface is equal to the distance r shown in FIG.

3 shows the electron gun 70 sealed in the neck portion 71 of the funnel portion 72. As shown in FIG. The centering device 74 is again installed on the funnel component 72 and fixes the electro-optic axis 73 and the deflection center D 'located thereon to the funnel. The electron gun 70 is located on the sealing pin of the stem 76 on the extension line of the electron gun axis. Stem 76 is moved within the extension of shaft 73 after the gun is sealed.

4 shows connecting the display window 80 to the funnel portion 81. The centering device 82 is the main axis substantially parallel to the main axis direction of the rectangular end of the funnel portion 81 with respect to the deflection center (D ') electron optical axis in the conical section 81 and the deflection center (D') as a reference point. Used to determine the principal axis with direction. Centering device 82 is suspended in frame 83 to be rotatable about an axis perpendicular to the plane of the drawing. The funnel portion 81 is fixed by the center setting device 82. As shown in Figs. 1A and 1B, the display window 80 provided with the display screen is fixed in the contact point 84 by the contact points 31, 32, and 33 shown in Fig. 1A. The distance from the deflection center D 'to the plane 85 of the point 84 perpendicular to the plane of the drawing and parallel to the short side of the window coincides with the distance l (Fig. 1a). Since the pressing jig 87 by the guide 86 of the display window 80 is lowered, the pressing jig 87 is pressed against the square end of the funnel portion 81. The vertical axis of the display window passes through the deflection center point D 'and the main axis of the display window 80 is parallel to the main axis determined by the center setting device 82. Since the centering device 82 is adjusted to be rotatable with respect to the deflection center point D ', the rectangular end of the funnel portion 81 is directed toward the rectangular sealed edge of the display window 80. In this position, the display window 80 is fixed to the funnel portion 81.

In order to adjust several parts, it is possible to have a display part in a cone part. This example is shown in FIG. The cone portion 90 has a stud 91 on the short side of the square end of the cone portion. The cone portion 90 is suspended in the frame 93 so as to be fixed by the centering device 92 and to be rotatable about an axis perpendicular to the plane of the drawing. The stud 91 is ground until the distance from the grinding surface to the plane through the deflection center point D 'perpendicular to the plane of the drawing and parallel to the short rectangular end is equal to the distance l (Fig. 1a). The studs on the long rectangular side are likewise ground, so that the distance from the deflection center point D 'to the plane parallel to the plane of the drawing is equal to the distance m (Fig. 1a). When the positioning of the display window is thus connected to the stud grinding, the longitudinal axis of the display window passes through the deflection center point D '.

In the embodiment described with reference to FIGS. 4 and 5, the centering devices 82 and 92 are suspended around the deflection center point D ', respectively, in the case where the fluorescent area of the display screen has a hexagonal structure. need.

Claims (1)

A method of assisting a color television display tube comprising a neck portion, a cone portion, a display window, and an electron gun installed on the neck portion for generating three electron beams, the relative position of at least one of the cone portion and the other components. Positioning the deflecting device on the display tube after installation of all the components so that the deflecting device is coupled to the cone while the centering device is at a reference point corresponding to the deflection center of the deflecting device and for the cone part. A method of manufacturing a color television display tube, comprising the step of causing a center axis thereof to coincide with a reference point set by a centering device so as to position the remaining parts.

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