KR200187378Y1 - Mask assembly of cathode ray tube - Google Patents

Abstract

In order to quickly compensate for the shadowing of the shadow mask, a thermal expansion compensation means for supporting a shadow mask, the shadow mask, an opening having a hole through which an electron beam directed toward the shadow mask passes, and an elastic force to expand the frame We propose a mask assembly of a cathode ray tube comprising a.

The thermal expansion correction means is provided with at least two coil springs which are fixed at both ends on both short sides of the circumference of the frame to continuously apply an elastic force to expand the frame toward the long side.

The coil spring further accelerates the expansion of the frame to quickly compensate for the doming phenomenon due to thermal expansion of the shadow mask.

Description

Mask assembly of cathode ray tube

The present invention relates to a mask assembly of a cathode ray tube, and more particularly, to a mask assembly of a cathode ray tube capable of quickly compensating for an initial drift in which a shadow mask expands by receiving thermal energy converted from an electron beam.

In general, the doming phenomenon is that as long as the electron beam emitted from the electron gun collides with the shadow mask and is converted into thermal energy, and the shadow mask absorbing the heat energy causes thermal expansion, it causes a change in the landing of the electron beam, thereby degrading color purity. It is pointed out as a factor.

Therefore, it is recognized that preventing or minimizing the dominant phenomenon is an important technique for achieving good color purity, and it is optimal for minimizing the dominant amount by changing the material and structure from the shadow mask to the frame or the suspension spring. Attempts are being made to find technology.

Among these techniques, there is a technique of making the material of the shadow mask a metal having low thermal expansion rate or applying a tensile force to the shadow mask to minimize thermal expansion itself.In addition to the above technique, the thermal expansion of the shadow mask is compensated by using the correlation between the frame and the spring. There is a technique to try. The technique is widely used to compensate for the shadowing amount of the shadow mask by using a path through which heat is transferred from the shadow mask, that is, a frame and a spring sequentially causing thermal expansion.

However, among the above techniques, a technique in which the material of the shadow mask is made of a metal having low thermal expansion can reduce the amount of domming, whereas the metal has a disadvantage that the metal is more expensive than conventional aluminum-kilted steel. In addition, the technique of applying a tensile force to the shadow mask to minimize thermal expansion requires a high level of skill in the manufacture of the shadow mask, and also has a disadvantage that the application range is limited to a flat panel or a cylindrical panel. On the other hand, a technique for compensating the shadowing amount of the shadow mask by the thermal expansion of the frame and the spring has a disadvantage that the effect can be expected after a predetermined time passes.

Therefore, the present invention is designed to solve the technical problem that the prior art has not solved, the main object of the present invention is to provide a mask assembly that can quickly compensate for the dominant phenomenon of the shadow mask.

The present invention also aims to provide a mask assembly capable of compensating the shadowing amount of a shadow mask with a low cost and relatively easy to apply technology.

1 is a schematic exploded perspective view of a mask assembly according to a first embodiment of the present invention;

2 is a plan view of the frame shown in FIG.

3A-3B are partial cross-sectional views of the mask assembly shown in FIG. 1.

4 is a plan view of a frame according to a second embodiment of the present invention;

5 is a plan view of a frame according to a third embodiment of the present invention;

FIG. 6 is a partial sectional view of the frame shown in FIG. 5; FIG.

The present invention to realize the above object, a shadow mask; A frame supporting the shadow mask, the opening having an opening through which an electron beam directed toward the shadow mask passes; We propose a mask assembly of a cathode ray tube including thermal expansion compensation means for applying an elastic force to expand the frame.

The thermal expansion correction means is provided with at least two coil springs which are fixed at both ends on both short sides of the circumference of the frame to continuously apply an elastic force to expand the frame toward the long side.

Hereinafter, with reference to the accompanying drawings the most preferred embodiment according to the present invention will be described in more detail.

1 and 2 are diagrams of a mask assembly according to a first embodiment of the present invention. FIG. 1 shows a shadow mask and a frame separated to show the inside of the frame, and FIG. 2 shows a plan view of the frame.

The mask assembly of the cathode ray tube includes a shadow mask 11 and an inner shield (not shown) and a frame 17 for supporting the two elements, the frame 17 being a panel (not shown) by an elastic member (not shown). Is suspended on the inner side of the frame. In the mask assembly, the shadow mask 11 performs an action (color screening) of selecting an electron beam emitted from an electron gun (not shown) and landing it on a corresponding phosphor, whereby a plurality of through holes are formed. And a side portion 15 extending from the hole 13 and bent toward the electron gun. In addition, the frame 17 has a circumferential portion 19 fixed to the side portion 15 of the shadow mask 11 and a flange portion 21 that is bent at the circumferential portion 19 and forms an opening through which an electron beam can pass. ).

The mask assembly configured as described above is the same as in the prior art, but the present invention has a difference in that the mask assembly further provides a thermal expansion compensation means.

The thermal expansion compensation means can minimize the dominant amount of the shadow mask 11 and ultimately prevent the dominant phenomenon when the electron beam collided with the shadow mask 11 is converted into thermal energy to thermally expand the shadow mask 11. Will be provided. In this embodiment, the thermal expansion compensation means continuously applies a force to expand the frame 17 to quickly compensate the amount of ming due to thermal expansion of the shadow mask 11 by expansion of the frame. Of course, the conventional frame also receives heat from the shadow mask and expands to compensate for the shadowing amount of the shadow mask, but the frame 17 of the present invention is further provided with a thermal expansion compensation means to significantly shorten the time for which the amount of the domming is compensated.

In the present embodiment, the thermal expansion compensation means having the above-described function includes two coil springs 23. The coil spring 23 is fixed at both ends of the frame 17 perpendicular to both short sides of the circumference 19 of the frame 17, and continuously applies an elastic force to push the frame 17 outward. In other words, it can be said that the frame 17 in the steady state compresses the coil spring 23. Therefore, even if the heat transfer is not performed to the extent that the frame 17 is expanded, the elastic force of the coil spring 23 is rapidly expanded of the frame 17 to compensate for the dominant amount of the shadow mask 11. In particular, the coil spring 23 is pushed by applying an elastic force to both short sides of the peripheral portion 19 of the frame 17, it is possible to quickly compensate the long-axis dominant amount of the shadow mask 11 which has a close influence on the color purity degradation have.

The position of fixing the coil spring 23 to the frame 17 should be limited to the flange portion 21 and the peripheral portion 19 of the frame 17. This is to prevent the electron beam incident on the shadow mask 11 passing through the opening of the frame 17 from being blocked by the coil spring 23. In addition, the two coil springs 23 should be divided and positioned on both long sides of the circumference 19 of the frame 17, respectively.

In the first embodiment, one coil spring 23 is disposed on each of the long sides of the circumferential portion 1 of the frame 17, but the number of the coil springs 23 may be greater than that. In addition, both coil springs 23 should have the same elastic force, and the elastic force should not expand the frame 17 in a steady state, so that the expansion of the heat-transferred frame 17 from the shadow mask 11 can proceed rapidly. Should be optimized

3A and 3B are cross-sectional views of the mask assembly, and show a fixing position of the coil spring when the shadow mask is fixed inside or outside the circumference of the frame.

3A illustrates a case where the shadow mask 11 is fixed to the inner surface of the frame 17, and the coil spring 23 is fixed to the frame 17 through a hole formed in the side surface of the shadow mask 11. do. Alternatively, although not shown in the drawings, it may be directly fixed to the inner side surface of the side surface of the shadow mask.

3b shows that the shadow mask 11a is fixed to the outer side of the frame 17, and the coil spring 23 is fixed to the inner side of the frame 17 and exerts an elastic force to the outside.

The coil spring 23 is fitted to the protrusion formed on the frame 17.

4 is a view showing a plan view of a frame according to a second embodiment of the present invention.

Referring to FIG. 4, it can be seen that the frame 27 includes two coil springs 33 each on both the long side and the short side of the circumference portion 29. This is for quickly compensating not only the long-axis dominant amount but also the short-axis dominant amount of the shadow mask 11. In this case, the coil springs 33 are spaced apart at regular intervals up and down at each corner of the frame 27.

Reference numeral 31 not mentioned denotes the flange portion 31 of the frame 27.

5 to 6 show a third embodiment in which a cylindrical member is provided in the coil spring provided in the second embodiment, in which FIG. 5 is a plan view of the frame and FIG. 6 is a sectional view of FIG.

5 to 6, it can be seen that the coil spring 43 is located in the conduit of the cylindrical member 45. The coil spring 43 is positioned in the conduit of the cylindrical member 45 in order to prevent the coil spring 43 pushing the inner surface of the circumference 39 to the frame 37 from bending. For example, if the coil spring 43 is bent, the coil spring 43 may block the path of the electron beam, and the force for inflating the frame 37 is dispersed, so that it is difficult to quickly compensate for the dominant amount. Therefore, the cylindrical member 45 is to prevent the coil spring 43 from bending. Preferably, the diameter of the cylindrical member 45 does not obstruct the path of the electron beam even when the cylindrical member 45 is thermally expanded. The cylindrical member 45 is also fixed by a clamp 47 welded to the frame 37 to block movement. In the above, the cylindrical member 45 is fixed by using the clamp 47, but the cylindrical member 945 may be fixed by welding the frame 37.

5 and 6 provide cylindrical members 45 in the second embodiment, but may also be provided in the first embodiment.

In the above description of the preferred embodiment of the present invention, the present invention is not limited to this, but can be implemented in various ways within the scope of the utility model registration claims and the detailed description of the invention and the scope of the accompanying drawings. It is also natural to fall within the scope of the present invention.

In the mask assembly as described above, the coil spring further accelerates the expansion of the frame, thereby rapidly compensating the doming phenomenon due to thermal expansion of the shadow mask.

Claims (6)

Shadow masks; A frame supporting the shadow mask, the opening having an opening through which an electron beam directed toward the shadow mask passes; Mask assembly of a cathode ray tube comprising thermal expansion compensation means for applying an elastic force to expand the frame. 2. The cathode ray tube according to claim 1, wherein the thermal expansion correction means includes at least two coil springs fixed at both ends on both short sides of the circumference of the frame to continuously apply elastic force to expand the frame toward the long side. Mask assembly. 3. The mask assembly of claim 2, wherein at least two coil springs are fixed to both long sides of the periphery of the frame to continuously apply elastic force to expand the frame toward the short side. . 4. The mask assembly of claim 3, wherein the coil spring is positioned above the flange portion of the frame and adjacent to the peripheral portion. 4. The mask assembly of claim 3, wherein the coil spring is positioned in a conduit of a cylindrical member fixed to a circumference or a flange of the frame. 5. The mask assembly of claim 4, wherein the cylindrical member is fixed by a plurality of clamps fixed to the frame.