CS229612B2 - Screening mask for the picture tubes - Google Patents

Description

229 912

BACKGROUND OF THE INVENTION The present invention relates to a screen screen mask with through holes. At the screen with a shielding mask, some of the converging electron beams are projected through a selection screen mask with many open mosaic screens. Generally, a shielding mask is attached to a rigid frame which is again suspended within the screen box.

So far, all commercial color screens have a front or observation screen portion that is either spherical or cylindrical. However, it is desirable to develop a screen with a generally flat screen. However, there are problems that need to be resolved before the flat screen screen is commercially available. The big problem is connected with the shielding mask. According to the screen design concepts of the prior art, the screen mask is similarly curved in screens with curved screen so that it is parallel to the screen contour. But such a mask has insufficient self-supporting strength or stiffness. One way to provide this strength or stiffness would be to subject the strain mask as it is done with some commercially available screens with cylindrical screens. But stress-based methods require unnecessary expensive frame structures. The second way to deliver the mask strength would be to give it a certain degree of shaping. But again, the problem caused a bulge problem during the initial period of screen production caused by heating the shield mask and stretching when the mask is bombarded with electron beams.

The above-mentioned drawbacks are eliminated in the screen mask of the invention in accordance with the invention by being provided with parallel corrugations defined by two undulating sides and two second sides, the distance between adjacent peaks of the undulations being at least twice as large as the distance between adjacent openings.

The screening mask according to the invention is itself very rigid and does not require any additional reinforcing structures. Exemplary embodiments of a screen shield mask according to the invention are shown in the accompanying drawings, in which, in FIG. 1, a screen with a flat screen shield mask is shown in plan view and partly in section, FIG. 2 is a plan view and a partial section of one embodiment of the screen according to the invention; FIG. 3 is a perspective view of a screen mask with the screen mask of FIG. 2; FIG. 4 is a perspective view of a modification of the mask - screen of FIG. 3; FIG. 5 is a plan view of the mask; 6 is an enlarged top view of the mask screen of FIG. 2; FIGS. 7 and 8 show enlarged portions of numbers 7 and 8 in FIGS. 5 and 6; FIGS. a rear view, a plan view of a cylindrical screen assembly with a screen mask, FIG. FIGS. 12, 13 and 14 are a rear view, a plan view and a side view of a screen mask assembly with a screen mask; FIG. 15 is a plan view of a mask-screen screen according to another embodiment of the invention; FIG. 16 is a plan view of a mask-screen shield; FIG. 17 is a cross-sectional view taken along line 18-18 of FIG. 17; FIG. 18 is a cross-sectional view taken along line 18-18 of FIG. 17; FIG. an enlarged partial section along line 19-19 in FIG. 18.

FIG. 1 shows a flat screen screen 16 for a flat screen whose mask 18 has a backward curvature for strengthening it. Fig. 2 shows a mask assembly 18 similar to that shown in Fig. 1. 2 depicts a screen 20 for a color television with an aperture mask according to the invention and comprising a glass container 22 in which there is a vacuum. The box 22 has a rectangular flat screen 24, a funnel portion 26, and a neck 28. On the inside surface 32 of the screen 24 there is a screen 30 of a luminiforene electron gun assembly 34 located at the neck 28 of my three electron nozzles. The rectangular aperture mask 36 is located in the housing 22 adjacent to the screen 22. The electron gun assembly 34 is adapted to project three electron beams through a mask 36 with apertures that impinge on the screen 22. on a screen 30 with a mask 36 serving as a color selection electrode. The magnetic deflection yoke 38 is positioned on the receptacle 22 near the intersection of the funnel-shaped portion 26 and the neck 28 * When the yoke 38 is suitably excited, it causes the electron beams to extend the screen 22 in a rectangular grid.

The aperture mask 36 shown below in Figure 3 is curved or slightly sinusoidal along a horizontal axis 4 in the direction of the longer mask size with the undulating 5 - 229 912 vertical X between the long sides of the mask 18 or the shorter dimension of the mask. it is understood that the term " wavy " is broadly defined herein to encompass shapes including sawtooth and sinusoidal shapes. Although the mask 36 is shown without any curl, it should be understood that the mask 36 with some undulations along the vertical axis is also included within the scope of the present invention, an example of which is described below.

The mask 36 has slotted openings 40 of aligned vertical columns. In order to maintain an acceptable line formation on the screen, i.e. to maintain the same spacing or clustering between the lines of the luminaire, the horizontal spacing between the columns of the apertures varies as a function of the spacing between the mask 36 and the screen 30 of the formula a = 3sq / L, where a is the horizontal spacing between the columns of the holes, q is the difference between the mask and the screen, L is the distance from the screen to the deflection plane of the electron beam, and from the spacers between the center and outer beams of the deflector. Therefore, when the mask outline q is created and the required force and / or stiffness is achieved, the parameter a is allowed to vary horizontally over the mask according to the mask outline. Generally, the dimension of the wave from the peak to the peak of, for example, the point Ak of the wavy or sinusoidal change at the mask should be at least twice as large as the spacing between adjacent holes · 6,229,812

As shown in FIG. 3, the aperture mask 36 is attached to the screen panel 24 by flexible beams 42, ripped along the undulating sides of the mask 36, and by fixed beams 44 disposed at the straight sides of the mask 56.

Each elastic beam 42 is L-shaped, has two limbs 6, 6, and is attached to the screen 24 of the lower arm 46 by suitable means, such as a glazed frit. The screen 36 is attached to the resilient beam 42 of the undulating sides at the points of inflection points where the direction of the undulation of the mask 36 changes. The points are at the midline of the wavy or sinusoidal shape of the mask. 36. The cantilevered structure of the elastic carriers 42 allows springing in the undulation direction, that is to say in the vertical direction (as determined by the screen in its normal operating orientation), thereby allowing thermal expansion of the mask in this direction. But in the perpendicular or horizontal direction, the flexible beams 42 are very rigid. Similarly, the fixed beams 44 on the mask side 36 are rigid in both the horizontal and vertical directions, preventing the center of the movement mask 36.

An alternative version of the mask support arrangement having a similar type of mask enlargement is shown in Fig. 4. In this embodiment, the resilient beams at the top and bottom edges of the mask are replaced by two low-expansion coefficient metal rods 50 compared to the mask material. For example, when the mask material 36 is steel, the rods. 7,229,812 may be invar. The mask 6 is connected to the support rods 50 along the central portion of its corrugated or sinusoidal sides. The rods are attached to the panel 24 by elastic beams 52 which are fastened to both ends of each rod 50 " for the mask 56 are fixed to the short sides of the mask 56 and fully functional, as described with respect to the fixed beams 44 of the previous embodiment, namely the fixation of the mask center 56. The advantage of the mask beam of the present invention can be appreciated by comparing the embodiment of the invention to the prior art. 5 shows a flat screen 56 with a perforated mask 58 of a spherical contour formed by rigid support members 60. FIG. Fig. 6 shows a similar view of the screen assembly and screen masks in Fig. 2 " dashed lines 59 and 57 in Figs. 5 and 6 illustrate the configuration " by which masks are expanded due to bombardment of electron beams. held at its edges by support members 60, it is substantially arched to screen 56. But mask 56 in FIG. 6 is held at different points by resilient beams 42 and is therefore arched only between these undercut points. The effect of this bulge is shown on dbr. 7 and 8, which are enlargements of the designated areas in FIGS. 5 and 6. As shown in FIG. 7, the point of impact of electron beam 66 passing through aperture 64 of the heated domed mask shown by dashed line 39 is shifted by the distance θ from the drop point of the electron beam 62 passing through the opening 68 of the unheated mask. However, in a screen using the present invention, the deflection of the heated mask is much smaller. 8 shows the position of the heated mask, shown by the dashed line 57, only slightly shifted from the non-heated position. The resulting offset of the beam impact location is indicated by the symbol a and in the figure it can be seen that there is considerably less displacement encountered in a known screen to limit mask movement. Although the invention has been described in relation to a flat screen, it should be understood that the invention is also applicable when the screen is curved. Figs. 9, 10 and 11 show a screen panel assembly 70 with a rectangular screen 22 which is cylindrically curved and to which a perforated mask 74 is attached by means of resilient beams 76 and stiffeners 78. The mask 74 is corrugated with corrugated irregular points of curvature or cylindrical The resilient beams 76 engage the screen 72 and are attached to the long sides of the mask 74 at the inflection points. The rigid beams 78 also engage with the screen 72 and attached to the mask 74 in the center of the short sides. In another embodiment shown in Figures 12, 13 and 14, the screen panel assembly 80 is shown with a spherical curvature 9 229 812 in the screen. 82 »Mask 84« is attached to screen 82 by resilient beams 86 and rigid beams 88. Mask 84 is spherically curved, similar to screen 82, and vertically undulating is superimposed thereon. As described above, this also has resilient beams 86 extending from the screen 82 and secured to the inflection points along the long sides of the mask 84, the rigid beams 88 being fixed to the centers, short sides of the mask. Although the foregoing embodiment has been shown by wavy masks attached to the beams at the inflection points on the undulating sides of the mask, the scope of the invention may include other matching points of attachment. For example, the attachment points may be at any other regular locations on the mask that are in the fixed distance from the reference plane, such as the bodechna mask closest to the screen panel »Fig. 15 and 16 show such a mask suspension system. FIG. 15 shows a wavy mask 90 attached to a flat panel 92 by means of flexible beams 94 and rigid beams 96. The flexible beams 94 are attached to panel 92 and attached to the undulating sides of the mask in points on the mask of the closest panel of the screen.

FIG. 16 shows a corrugated mask 98 mounted on its corrugated sides on the screen panel 100 with metal rods 102 attached to the resilient beams 104 and at least partially supported thereon, the resilient beams 104 resembling the beams shown in FIG. It should be understood, however, that the folding effect of the embodiment of FIGS. 15 and 16, although much smaller than that of the single arc embodiment of FIG. 5, will be somewhat greater than that of FIG. while the mask is supported at the inflection points, since the spacing of the braces between the beams is greater. In all of the foregoing embodiments, the mask beams have been shown to begin directly at the edges of the viewing portion. screen shades, as shown in the examples. This includes one possible arrangement of beams within the scope of the present invention. The beams may also protrude from the side walls of the screen-to-screen instead of from the viewing portion. Alternatively, the beams may also protrude between the mask and the frame, which in turn is held within the screen.

FIG. 17, 18 and 19 show another embodiment of the present invention in which a corrugated rectangular perforated mask 110 is attached to a peripheral frame 112 " Frame 112 is suspended within a flat rectangular shade frame 114 by a plurality of spring supports 116 that are releasably attached to the conical pins 118 anchored in the peripheral The fastening of the mask 110 to the frame 112 is accomplished by the tongues 122 ' formed as an integral part of the mask design. The two additional tabs 124 are located at the front of the two opposing vertical mask sides for the vertical mask shift during screen operation.

The tabs 122 and the additional tabs 124 are preferably formed so that their contour is attached to the photo graphical patterns used to expose the apertures during mask manufacturing. The final shape of the mask and tongues is then achieved when the mask is etched.

Claims (6)

Object of the Invention 229 912 A screen mask with a through-hole, characterized in that it has parallel corrugations defined by two undulating sides and two second sides, the distance between adjacent peaks being at least twice as large as the distance between adjacent openings (40). . A shielding mask according to claim 1, characterized in that the undulating sides have inflection points lying in a plane. 3. The shielding mask of claim 1, wherein the undulating faces have inflection points lying on the curved surface. 4. A shielding mask according to claim 3, wherein the curved surface is cylindrical. 5. A shielding mask according to claim 2 or 3, wherein the inflection points are equidistant from the inner surface of the screen. A shielding mask according to any one of claims 1 to 6, characterized in that its other sides are curved. 5.3.1980 Representative: 5 rJtroí ’* 1102