KR200171940Y1 - Shadow mask for cathode ray tube - Google Patents

Abstract

A shadow mask for a cathode ray tube that provides heat dissipation means to one surface of a shadow mask, wherein the heat dissipation means comprises a concave groove located in a space between a plurality of beam passing holes for passing an electron beam. Due to the groove, the surface area of the entire shadow mask is increased, thereby facilitating heat dissipation, thereby reducing the amount of doming, and increasing the formability of the shadow mask, thereby providing a shadow mask that can easily perform a molding operation for forming curvature. do.

Description

Shadow Masks for Cathode Ray Tubes

The present invention relates to a shadow mask for a cathode ray tube, and more particularly to a shadow mask for cathode ray tube to reduce the amount of dooming by more smooth heat dissipation.

In general, the shadow mask has a color screening function of passing the electron beam emitted from the electron gun and landing the designated phosphor among the screens formed on the inner surface of the panel, and for this purpose, a plurality of beam passing holes are dot-shaped or slit in accordance with the shape of the phosphor. I'm serving you.

The three R, G, and B electron beams emitted from the electron gun coincide at one point on the shadow mask, i.e., the beam passing holes having a small diameter, and then split into three stems after passing through the beam passing holes. Each R, G, B electron beam is landed on a designated R, G, B phosphor.

As described above, the electron beam that is scanned on the fluorescent surface through the beam through hole formed in the shadow mask is deflected by the deflection yoke, and is moved while moving in a horizontal or vertical direction starting from a point on the shadow mask, so the shadow mask passes through the beam. The electron beam is incident around the dragon hole, which is absorbed by the shadow mask in the form of hot electrons.

The shadow mask that absorbs the electron beam in the form of the hot electrons causes thermal deformation to cause a shape deformation in which the central portion is convex toward the panel surface, which is a doming phenomenon.

When the deformation occurs in the shadow mask shape due to the doming phenomenon, the positions of the beam passing holes provided in the shadow mask are deviated from the initial positions, and thus, the electron beam emitted from the electron gun cannot be accurately landed.

As such, the mis-landed electron beam does not scan the designated phosphor on the screen surface, but scans adjacent phosphors, thereby causing a problem of deterioration of color purity and deterioration of image quality.

Various designs are proposed to prevent the above problems. Looking at the examples, one of them is to manufacture a shadow mask using Invar steel, which is resistant to thermal deformation, and the next one is a conventional material and a small coefficient of thermal deformation. It is used to combine materials in bimetallic form.

However, the shadow mask implemented with conventional designs has its drawbacks, and the Invar steel has a high unit price, which increases the price of the cathode ray tube. The shadow mask made of the bimetal type has a complicated manufacturing process, and thus the entire cathode ray tube There is a problem of increasing the number of processes.

Therefore, the present invention is devised to solve the above problems, and an object of the present invention is to provide a shadow mask that reduces the amount of domming by more smooth heat dissipation.

In order to achieve the above object, the present invention provides a hole for forming a plurality of holes for beam passing through the electron beam, a hole formed around four sides of the hole, and an extension of the hole for the electron gun. In a shadow mask for a cathode ray tube comprising a skirt portion that is bent and formed, heat dissipation means is provided on one surface of the shadow mask.

The heat dissipating means is made up of grooves to smooth the heat dissipation by expanding the surface area of the entire shadow mask.

The groove is also provided between the beam passing holes of the shadow mask, which can be formed by etching.

Accordingly, the heat dissipation is more easily performed, thereby suppressing the domming phenomenon, and the shadow mask having good moldability due to the grooves can be manufactured.

1 is a partial cross-sectional view of a cathode ray tube equipped with a shadow mask according to the present invention.

2 is a perspective view of a shadow mask according to the present invention.

Hereinafter, a preferred embodiment of the present invention with reference to the accompanying drawings in detail as follows.

1 is a partial cross-sectional view of a cathode ray tube equipped with a shadow mask according to the present invention, Figure 2 is a perspective view of a shadow mask according to the present invention, the front body of the cathode ray tube as shown, the user is provided in the direction of the screen portion Forming a panel 2, a shadow mask 4 arranged in parallel with a predetermined interval from the inner surface of the panel 2, a mask frame 6 supporting the shadow mask 4, and a mask frame 6 It comprises a hook spring (8) and stud pins (10) fixedly mounted at both ends of the panel (2).

The panel 2 is made of a glass material and forms a predetermined curvature at its periphery, and forms a protruding jaw 12 at four circumferences toward the rear body of the cathode ray tube to insert and mount an electron gun (not shown). It is combined with a funnel (not shown).

The panel 2 having such a configuration forms a screen 14 composed of phosphors and a black matrix film on the inner surface thereof, wherein the three R, G, and B phosphors form a dot or a slit shape sequentially. It arrange | positioned and the black matrix film | membrane which consists of thin graphite lines is formed in the space except the said fluorescent substance.

The graphite line constituting the black matrix film is a non-luminescent absorbing material, and serves to improve the contrast of the entire screen because the adjacent phosphors are separated to perform color separation.

On the back side of the phosphor and the black matrix film, an aluminum film is deposited to enhance the potential of the phosphor and to improve luminance.

When the screen 14 made as described above emits an electron beam from an electron gun, phosphors that are scanned by the electron beam are excited to emit light and transmit the light to the user. The electron beam is three stems of R, G and B controlled by an image signal. It consists of an electron beam.

The three electron beams emitted from the electron gun are matched at one of the beam passing holes of the plurality of beam passing holes formed in the shadow mask 4, and then split into three stems while passing through the beam passing holes. The specified phosphor is scanned.

Since the shadow mask passes through the electron beam and lands on a designated phosphor, the shadow mask having a color discrimination function includes a hole 18 and a hole 18 forming a plurality of beam passing holes 16 as shown in FIG. 2. It comprises a non-perforated part 20 formed by the four circumferential surface of the) and the skirt portion 22 is formed bent toward the rear body by the extension of the non-perforated part 20.

The perforations 18 form a plurality of beam passing holes 16 that form a slit as an example, as shown in correspondence with the form of the phosphor formed on the surface of the screen 14, and the beam passing holes 16 ) Has a size corresponding to three R, G, and B phosphors constituting one pixel.

The electron beam emitted from the electron gun toward the screen 14 is sequentially deflected by the deflection yoke and sequentially scans the beam passing holes 16 of the shadow mask 4 in a horizontal or vertical direction. 4) receives an electron beam around the beam passing holes 16, which are absorbed by the shadow mask 4 in the form of hot electrons so that the shadow mask 4 is convex toward the panel 2 surface. Doming phenomenon occurs.

When the domming phenomenon occurs as described above, the beam passing holes 16 provided therein are changed from the initial position, so the electron beam emitted from the electron gun passes through the beam passing holes 16 of the shadow mask 4 accurately. Failure to do so may result in mislanding that is scanned into adjacent phosphors instead of the designated phosphors.

As such, when the electron beam does not scan the specified phosphor but scans the adjacent phosphor, color bleeding occurs and color purity is deteriorated. Therefore, the doming phenomenon causing the above problems should be prevented as much as possible.

To this end, the shadow mask newly implemented by the present invention provides a heat dissipation means on one surface thereof, and the heat dissipation means is composed of a groove 24 formed concave on the surface of the shadow mask 4 as shown.

The groove 24 is positioned at a predetermined interval between the plurality of beam passing holes 16 formed in the hole 18, the formation of the groove 24 is formed by etching, the shape of the groove 24 is circular Or oval or any shape is possible.

The surface area of the entire shadow mask 4 is expanded by forming a plurality of grooves 24 between the beam passing holes 16 as described above.

Therefore, the shadow mask 4 is more smooth heat dissipation due to the extended surface area it is possible to suppress the doming phenomenon.

In this way, the shadow mask 4 which provides the heat dissipation means composed of the grooves 24 is manufactured by the beam passing hole 16 through an etching operation or the like, and then presses the shadow mask 4 which forms a flat surface. The shadow mask 4 is supported on the mask frame 6 while forming the same curvature as that of the panel 2 surface.

This is done while fixing the skirt portion 22 of the shadow mask 4 to the mask frame 6, the mask frame 6 being mounted to the inside of the projecting jaw 12 of the panel 2. ) And hook spring 8 are integrated with the panel 2.

The hook spring 8 which integrally couples the mask frame 6 to the panel 2 is a combination of two metals having different thermal expansion coefficients in a bimetal type, and corrects expansion deformation of the mask frame 6 due to heat absorption. It plays a role.

As described above, the shadow mask 4 which is integrally coupled to the panel 2 is formed by forming a beam through hole 16 by etching or the like, and then forming a curvature identical to that of the panel 2 by using a press. As the mask 4 is formed, the shadow mask 4 increases the formability due to the grooves 24 by forming the grooves 24 which are heat dissipating means on the surface of the shadow masks 4. Molding operation for forming the curvature can be more easily performed.

As described above, by forming a groove as a heat dissipation means on one surface of the shadow mask, the heat dissipation of the shadow mask can be more smoothly achieved, and the formability of the shadow mask can be increased to facilitate the curvature forming operation.

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.

As such, the present invention provides a heat dissipation means composed of grooves on one surface of the shadow mask, thereby smoothing heat dissipation of the shadow mask, thereby reducing the amount of doming, and increasing the moldability of the shadow mask due to the grooves, thereby forming a molding operation. There is an effect that can be easily performed.

Claims (4)

Shadow for the cathode ray tube including a hole portion for forming a plurality of holes for passing through the electron beam, a hole portion formed around the four sides of the hole portion, and a skirt portion bent toward the electron gun by the extension of the hole portion A shadow mask for a cathode ray tube, the mask providing heat dissipation means to one surface of the shadow mask. The shadow mask for a cathode ray tube according to claim 1, wherein the heat dissipation means comprises grooves to expand the surface area of the shadow mask. 3. The shadow mask of claim 2, wherein the groove is provided between the beam passing holes. 3. The shadow mask of claim 2, wherein the grooves are formed by etching.