KR200235776Y1 - Panel assembly for cathode ray tube - Google Patents

Abstract

A panel assembly for cathode ray tubes, which facilitates the flow of electrons between the members constituting the panel assembly to quickly remove hot electrons remaining in the shadow mask. Forming a beam passing aperture and connecting a shadow mask disposed at regular intervals from the fluorescent film screen, a mask frame serving as a shadow mask support, and the mask frame and the built-in graphite film to form an electron transfer path. And a contact spring, and a conductive member made of a conductive material and disposed on the joint surface of the shadow mask and the mask frame to increase the moving area of the electrons.

By the conductive member, the shadow mask and the mask frame have a larger contact area, a minimum electrical resistance, and smoother electron movement so that hot electrons remaining in the shadow mask can be removed more quickly.

Description

Panel assembly for cathode ray tube

The present invention relates to a panel assembly for a cathode ray tube, and more particularly, to a panel assembly for a cathode ray tube capable of quickly removing hot electrons remaining in a shadow mask by smoothing electron flow between the members constituting the panel assembly. will be.

In general, a cathode ray tube is a display device that implements a predetermined image by scanning a three-beam electron beam emitted from an electron gun onto a fluorescent film screen composed of a plurality of green, blue, and red phosphors and emitting light.

4 is a cross-sectional view of a cathode ray tube according to the prior art, in which the cathode ray tube is a panel 3 in which a fluorescent film screen 1 is formed on an inner surface thereof and a neck portion 7 for mounting an electron gun 5 on an inner circumferential surface thereof. ) And a funnel 11 connecting the panel 3 and the neck portion 7 and mounting the deflection yoke 9 to the outer circumferential surface thereof are integrally coupled.

When three electron beams 13 are emitted from the electron gun 5, these electron beams 13 are deflected by the magnetic field generated by the deflection yoke 9 to sequentially scan all the pixels of the fluorescent film screen 1. A shadow mask 15 having a plurality of beam passing apertures 15a is mounted inside the fluorescent film screen 1 so that these electron beams 13 can accurately emit corresponding phosphors.

By the shadow mask 15 described above, the electron beams 13 are concentrated in one beam passing aperture 15a corresponding to each pixel, and then separated into the corresponding phosphors in the fluorescent film screen 1 while passing therethrough. The correct color will be achieved.

The shadow mask 15, which is responsible for the color discrimination function, is welded to the mask frame 17 and fixed inside the panel 3, and the mask frame 17 is formed on the inner surface of the funnel 11 by the contact spring 19. A structure is electrically connected to the coated embedded graphite film 21.

At this time, about 80% of the electron beams 13 emitted from the electron gun 5 do not pass through the beam passing aperture 15a and remain in the shadow mask 15 to thermally expand the shadow mask 15. Cause Oming phenomenon. Since the shadowing of the shadow mask 15 reduces the color purity of the screen by shifting the path of the electron beam, hot electrons remaining in the shadow mask 15 are quickly embedded through the mask frame 17 and the contact spring 19. It is important to restrain the shadowing of the shadow mask 15 as much as possible by guiding the graphite film 21 and releasing it through the anode button 23.

However, since the shadow mask 15 and the mask frame 17 are integrated by spot welding, the skirt portion 15b of the shadow mask 15 welded to the mask frame 17 is formed to be bent at a predetermined time during press molding. Excitation is performed at the remaining portions except for the welding point, and a predetermined gap is generated between the skirt portion 15b and the mask frame 17.

Due to this spacing, the electrical resistance increases between the shadow mask 15 and the mask frame 17 to prevent the smooth flow of hot electrons. As a result, the hot electrons continuously accumulate in the shadow mask 15 to cause doming and extend the domming settling time.

In addition, the contact spring 19 which forms the transfer path of the hot electrons by connecting the mask frame 17 and the embedded graphite film 21 is usually provided with a limit to the rapid removal of hot electrons.

Therefore, the present invention is designed to solve the above problems, the object of the present invention is to facilitate the flow of electrons between the members constituting the panel assembly for the cathode ray tube that can quickly remove the hot electrons remaining in the shadow mask To provide a panel assembly.

1 is a cross-sectional view of a panel assembly according to the present invention.

2 is an exploded perspective view of a shadow mask and a mask frame.

3 is an exploded perspective view of a shadow mask and a mask frame according to another embodiment.

4 is a cross-sectional view of a cathode ray tube according to the prior art.

The present invention to achieve the above object,

A panel for forming a fluorescent screen on the inside;

A shadow mask which forms a plurality of beam passing apertures and is arranged at regular intervals from the above-mentioned fluorescent screen;

A mask frame supporting the shadow mask and mounted inside the panel;

A contact spring which connects the mask frame and the embedded graphite film to form an electron transfer path;

Provided is a panel assembly for a cathode ray tube comprising a conductive material and a conductive member disposed on a bonding surface of the shadow mask and the mask frame to increase an area of movement of electrons.

By the conductive member, the shadow mask and the mask frame increase contact area and minimize electrical resistance, thereby making electron movement more smooth. As a result, hot electrons remaining in the shadow mask can be removed quickly, thereby reducing the dormant settling time and preventing excessive doming.

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

1 is a cross-sectional view of a panel assembly according to the present invention. As shown in the drawing, the panel assembly includes a panel 4 having a fluorescent film screen 2 formed therein, a shadow mask 6 disposed inside the fluorescent film screen 2, and the shadow mask 6 described above. It includes a mask frame (8) that is a support, an inner shield (10) for shielding the geomagnetic field, and a contact spring (14) connecting the mask frame (8) and the embedded graphite film (12).

The shadow mask 6 forms a plurality of beam passing apertures 6a for electron beam separation, and the mask frame 8 is formed inside the panel 4 by the stud pins 16 and the spring member 18. It is fixedly mounted.

At this time, when the shadow mask 6 causes thermal expansion, that is, doming, by electron beam collision, the mask frame 8 and the spring member 18 cause thermal expansion by heat transfer to correct the shadowing of the shadow mask 6. In this way, the time taken to correct the shadowing of the shadow mask 6 by thermal expansion of the mask frame 8 and the spring member 18 is referred to as the doming stability time.

The doming settling time is shortened as the hot electrons remaining in the shadow mask 6 are quickly removed, and the initial deterioration of the screen can be minimized as the dormant settling time is shortened. The conductive member 20 is mounted on the joint surface of the shadow mask 6 and the mask frame 8 so that the flow of the water is smoother, and at least two contact springs 14 are provided.

In more detail, FIG. 2 is an exploded perspective view of the shadow mask 6 and the mask frame 8, and the shadow mask 6 includes an effective screen portion 6b in which a plurality of beam passing apertures 6a are formed. ), A skirt portion 6c bent from four edges of the effective screen portion 6b, and the mask frame 8 includes a bottom portion 8b and a bottom portion (8b) in which a beam passage opening portion 8a is formed. A flange portion 8c that is bent from the four edges of 8b) toward the shadow mask 6.

Each of the shadow mask 6 and the mask frame 8 is integrally fixed to each of the skirt portion 6c and the flange portion 8c by welding or the like. As shown, the shadow mask 6 includes a mask frame ( The structure inserted and fixed into the inside of 8) is called a MIFA (Mask Inside Frame Assembly) method, in which the flange portion of the mask frame 8 into which the skirt portion 6c of the shadow mask 6 is inserted ( 8c) The conductive member 20 is disposed inwardly.

The conductive member 20 is a conductive material, for example, made of a metal tape including an aluminum tape, and the conductive member 20 minimizes electrical resistance between the shadow mask 6 and the mask frame 8. At the same time, it serves to increase the moving area of the electrons.

That is, even when the shadow mask 6 and the mask frame 8 are integrated by spot welding, the hot electrons are moved in more areas other than the welding point through the conductive member 20. As a result, hot electrons remaining in the shadow mask 6 may be moved to the mask frame 8 more quickly through the conductive member 20, thereby effectively removing hot electrons remaining in the shadow mask 6.

As shown in FIG. 3, in the case of a MOFA (Mask Outside Frame Assembly) method in which the shadow mask 6 is fixed to the outside of the mask frame 8, the conductive member 20 may include the shadow mask 6. It may be arranged outside the flange portion (8c) of the mask frame (8) facing the skirt portion (6c) of.

Even in this case, the electrical resistance between the shadow mask 6 and the mask frame 8 is minimized by the conductive member 20 and the movement area of the electrons is increased, so that hot electrons remaining in the shadow mask 6 are removed. Can be removed effectively.

In addition, the panel assembly according to the present invention, as shown in Figure 1, the contact frame forming the transfer path of the hot electrons by connecting the internal graphite film 12 coated on the inner surface of the mask frame 8 and the funnel 22 ( It is preferable to have at least two 14), more preferably four contact springs 14 to be mounted on each side of the bottom portion 8b of the mask frame 8.

As a result, the hot electrons remaining in the mask frame 8 may be more smoothly transferred to the embedded graphite film 12 by the contact spring 14 provided with at least two, and thus may be grounded to the outside by an anode button (not shown). .

In the above description of the preferred embodiment of the present invention, the present invention is not limited to this, but can be carried out in various ways within the scope of the utility model registration claim and the detailed description of the invention and the scope of the accompanying drawings. Naturally, it belongs to the scope of the present invention.

As described above, the panel assembly according to the present invention can smoothly move electrons between the members, thereby more effectively removing hot electrons remaining in the shadow mask, thereby preventing excessive shadowing of the shadow mask, and doming stability time. By shortening the screen, the initial deterioration of the screen can be effectively prevented.

Claims (6)

A panel forming an inner surface of the fluorescent film screen; A shadow mask forming a plurality of beam passing apertures and arranged at regular intervals from the fluorescent screen; A mask frame supporting the shadow mask and mounted inside the panel; A contact spring which connects the mask frame and the embedded graphite film to form an electron transfer path; A panel assembly for a cathode ray tube comprising a conductive material and a conductive member disposed on a bonding surface of the shadow mask and the mask frame to increase an area of movement of electrons. The panel assembly for cathode ray tube according to claim 1, wherein the conductive member is made of a metal tape. The panel assembly for a cathode ray tube according to claim 1, wherein the conductive member is attached to the outside of the flange portion of the mask frame. The panel assembly for a cathode ray tube according to claim 1, wherein the conductive member is attached to the inside of the flange portion of the mask frame. The panel assembly of claim 1, wherein at least two contact springs are provided. The panel assembly for a cathode ray tube according to claim 5, wherein four contact springs are provided on four sides of the mask frame bottom.