KR200147974Y1 - Mask frame of crt - Google Patents

Abstract

The present invention discloses an improved mask frame support structure of a color cathode ray tube.

Conventionally, the mask frame is rotated by thermal expansion of the mask frame, thereby degrading image quality such as color purity.

In the present invention, at least one holder spring of the plurality of holder springs is configured in a transverse symmetry centering on the coupling hole for coupling with the stud pin, and solved the conventional problem by attaching both ends to the frame through the methyl.

Description

Mask Frame Support Structure

1 is a conceptual view showing a general mask frame support structure,

Figure 2 is an excerpt perspective view showing another conventional support structure,

3 is a conceptual view showing a support structure according to the present invention,

Figure 4 is a perspective view showing a hunder spring structure constituting the support structure of the present invention

* Explanation of symbols for main parts of the drawings

Hl, H2: holder spring

W: (One Hundred Springs) donation

A: head (of one holder spring)

MF: mask frame

S: stud pin

The present invention relates to a color cathode ray tube, and more particularly to a structure for supporting a mask frame in a panel. The color cathode ray tube alternately arranges R, G, and B phosphors to form a fluorescent surface, and an electron beam emitted from the R, G, and B electron guns is applied to the corresponding phosphor of the fluorescent surface through a shadow mask. By selectively landing, a color image is displayed. Since the shadow mask is a metal thin plate formed with numerous electron beam through holes, it is usually attached to a frame and treated as a mask frame assembly. The mask frame is not only used for color screening during cathode ray tube operation, but also for each phosphor in the manufacture of a fluorescent surface. Since it is also used as an exposure mask for forming a pattern, it is necessary to be frequently coupled to and separated from the panel. Accordingly, as shown in FIG. 1, the mask frame MF is formed by a holder spring H. It is elastically coupled to the stud pin 5 of the panel (not shown). The hinder spring H is provided with correction means such as bimetal for compensating for short-termdrift of electron beam landing, such as doming. However, after sufficient time has elapsed since the start of the operation of the cathode ray tube, the mask frame MF heated by the electron beam collision is thermally expanded like a dotted line. Accordingly, displacement (ΔX, ΔY) is generated at each position of the hender springs H as shown by an arrow, thereby causing the mask frame MF to rotate in a predetermined direction. Such rotation of the mask frame MF significantly lowers the image quality such as color purity of the cathode ray tube. This rotation of the mask frame MF occurs because each holder spring (H) is arranged in the same direction as seen in the periphery direction. Accordingly, another conventional support structure is shown in FIG. One Hender spring (H ') is composed of two corresponding partitions (H1, H2) and is arranged symmetrically about the coupling hole (0) engaging the stud pin (5), and then each bimetal ( The rotational component is canceled by adhering to the mask frame MF via BB and B2. However, such a conventional support structure is not only complicated to manufacture but also difficult to attach to the mask frame MF since the spring H 'is composed of a combination of two partitions H1 and H2. In addition, since the holder spring H 'is made of a relatively thin steel plate, it is difficult to maintain the fixed shape of the two partitions H1 and H2, and thus there is a high possibility of misalignment. Accordingly, the fine rotation of the mask frame MF is caused. It is still an object of the present invention to provide a mask frame support structure capable of reliably preventing rotation by the thermal expansion of the mask frame in view of the above-described conventional problems. In order to achieve the above object, the mask frame support structure according to the present invention has a structure in which the mask frame is supported in the panel by a plurality of holder springs respectively provided on the short side and the scene side of the frame, and at least one of the plurality of holder springs. The holder spring is transversely symmetrical with respect to the coupling hole for inserting the stud pins of the panel, and both ends are attached to the frame through bimetal, respectively. According to a preferred feature of the present invention, the mask frame is supported on the panel by a 3-pin support method, and one holder spring is positioned in the middle of the plurality of hender springs. As a result, the image quality and reliability of cathode ray tube can be improved. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the third degree. The mask frame support structure according to the present invention adopts a 3-pin support method, and the holder springs H1 and H2 are provided on two end faces and one scene side of the mask frame MF, respectively, so that the inner surface of the panel (not shown) is provided. Is elastically coupled to the stud pin (5). According to a feature of the present invention, one holder spring (H2) on the long side, which is located in the middle of the three holder springs (H1, H2), is transversely symmetric about a coupling hole (0 in FIG. 4) for inserting the stud pin (5). And both ends thereof are attached to the mask frame MF via bimetals (B1 and B2 in FIG. 4), respectively. This Hender spring H2 of the present invention is particularly well illustrated in FIG. 4, which is the two bases W, to which the mask frame MF is fixed through bimetals B1 and B2 by bending a plurality of steel plates, and these And a head portion (A) having a coupling hole 0 for connecting and protruding outward to insert the stud pin S. On the other hand, the two holder springs H1 attached to the short side of the mask frame MF have the same structure as the usual holder spring, and are preferably attached to the mask frame MF to correspond to each other. That is, they are attached to the outer circumference of the mask frame MF in opposite directions. The operation of the support structure constructed as described above is as follows. When sufficient time elapses after the cathode ray tube starts operation, the heated mask frame MF is thermally expanded as shown by the dotted line in FIG. As a result, displacement occurs as a dashed arrow at each holder spring H1, H2 position, which is offset by the Hender spring H2 of the present invention attached to the scene side to rotate the mask frame MF as in the prior art. This does not occur. That is, the Hender spring H2 of the present invention has two bases W formed at both ends thereof attached to the mask frame MF through the bimetals B1 and B2, respectively, and have a transverse symmetry with respect to the coupling hole O. Therefore, the displacement is not only opposite directions, but also the same size to cancel each other to prevent rotation. In addition, since the two holder springs (H1) attached to the short side is also positioned majestically, the displacement is opposite to each other and effectively canceled, so that the rotation preventing effect is further increased. Thus, according to the present invention, since the rotational components due to thermal expansion of the mask frame cancel each other to achieve an equilibrium, the rotation of the mask frame as in the prior art is essentially prevented. In addition, since the Hender Spring is integrated, it is not only easy to manufacture but also securely prevents rotation. Therefore, the present invention greatly improves image quality and reliability, such as color purity of cathode ray tube.

Claims (4)

In a structure in which a mask frame is supported in a panel by a plurality of holder springs respectively provided on the short side and the long side of the frame, at least one holder spring of the plurality of holder springs is centered on a coupling hole into which the stud pins of the panel are inserted. Mask frame structure, characterized in that both ends are attached to the frame via bimetal, respectively. 2. The mask frame support structure of claim 1, wherein the mask frame is supported by the panel in a 3-pin support manner. The mask frame support structure according to claim 1 or 2, wherein the holder spring is a holder spring positioned in the middle of the plurality of holder springs. 4. The mask frame support structure of claim 3, wherein the remaining header springs are attached to the frame.