KR100730107B1 - flat-type cathode ray tube - Google Patents

Abstract

Disclosed is a planar cathode ray tube. The present invention provides a tension mask, a support member for supporting it, and a tension mask assembly having a rigid member; an inner shield having a body portion having an opening through which an electron beam passes, and a flange portion fixed to the tension mask; and tension And shielding means for shielding a space between the mask assembly and the inner shield.

Description

Flat-type cathode ray tube

1 is a perspective view showing a state in which the conventional state of the tension mask assembly and the inner shield coupled to some;

2 is a sectional view of a planar cathode ray tube according to the present invention;

3 is an exploded perspective view illustrating a tension mask assembly and an inner shield according to a first embodiment of the present invention;

Figure 4 is an exploded perspective view showing a partially cut off state of the coupling of the tension mask assembly and the inner shield of Figure 3,

FIG. 5 is an enlarged perspective view partially showing a coupling state of a tension mask assembly and an inner shield according to a second embodiment of the present invention; FIG.

<Brief description of symbols for the main parts of the drawings>

10,30 ... tension mask assembly 11,31 ... tension mask

12,32 ... support member 13,33 ... rigid member

31 a.

41 ... Extension 42,52 ... Bent

51.plate 100,300 ... inner shield

110,310 ... Main body 120,320 ... Flange

The present invention relates to a cathode ray tube, and more particularly, to a planar cathode ray tube having an improved coupling structure between a tension mask assembly and an inner shield.

Typically, a cathode ray tube emits an electron beam emitted from an electron gun through a myriad of electron beam passing holes formed in a shadow mask and lands on a phosphor film formed on an inner surface of the panel to excite each phosphor layer of the phosphor film.

The screen forming the image is designed to have a curvature according to the deflection trajectory of the electron beam deflected by the deflection yoke mounted on the cone portion of the funnel, and the mask provided inside the funnel is also formed to correspond to the curvature of the screen.

However, in the cathode ray tube employing such a mask, a so-called doming phenomenon occurs, in which the mask is heated by the electron beam emitted from the electron gun and swells to the panel side. This doming phenomenon causes the electron beam to fail to land correctly on each phosphor layer of the desired fluorescent film. In addition, as the cathode ray tube is formed to have a predetermined curvature, the viewing angle is narrowed, and a phenomenon in which an image is distorted occurs at the periphery of the screen.

To solve this problem, flat-type cathode ray tubes with flat screens have been developed. In the planar cathode ray tube, a tension mask assembly is fixedly installed in a state in which tension is applied to the inside of the panel.                         

1 is a view illustrating a coupling state of a conventional tension mask assembly 10 and an inner shield 100,

Referring to the drawings, the tension mask assembly 10 is installed in parallel with the tension mask 11 in the direction of both long sides of the mask 11 and the support member 12 for fixing it, and the support member 12 It includes a rigid member 13 is fixed to both ends at each lower end of the). The tension mask 11 is provided with a plurality of strips spaced apart by a predetermined interval, the slot formed therebetween is supported by a tie bar.

The tension mask assembly 10 is coupled to the inner shield 100. In general, the cathode ray tube causes drift of the electron beam scanned from the electron gun under the influence of the geomagnetic field. In order to reduce the influence thereof, the inner shield 100 is attached to the tension mask assembly 10.

The inner shield 100 includes a body portion 110 formed of a thin polyhedron having a portion through which an electron beam passes, and a flange portion 120 formed at a lower end of the body portion 110.

In order to fix the inner shield 100 to the tension mask assembly 10, the flange portion 220 is aligned with the outer sidewall of the rigid member 13, and is then contacted.

However, the combination of the conventional tension mask assembly 10 and the inner shield 100 has the following problems.

A predetermined space portion is generated between the short side portion of the tension mask 11 and the inner shield 100 corresponding thereto. Accordingly, the drift of the electron beam scanned by the electron gun still occurs, and the shielding effect of the geomagnetic field is lowered. In addition, since the support member 12 supports only the long side portion of the tension mask 11, a howling phenomenon may occur on the short side portion by external force. On the other hand, the diffusely reflected electron beam does not pass through the slot formed in the tension mask 11 and penetrates again through this space.

An object of the present invention is to provide a planar cathode ray tube provided with shielding means for shielding the space between the tension mask assembly and the inner shield.

In order to achieve the above object, a planar cathode ray tube according to an aspect of the present invention,

A tension mask assembly having a tension mask, a support member supporting both sides of the tension mask, and a rigid member fixed at both ends to the support member;

An inner shield including a body portion having an opening through which an electron beam passes, and a flange portion formed at a lower end of the body portion and fixed to the tension mask assembly; And

And shielding means for shielding a space between the tension mask assembly and the inner shield.

In addition, the shielding means for shielding the space generated between the short side of the tension mask side and the inner shield,

And an extension part extending from the flange part toward the short side of the tension mask, and a bent part bent from the extension part to support one surface of the tension mask.

In addition, the extension portion is characterized in that the bent portion has a height capable of elastically supporting the tension mask, it is integrally extended from the flange portion.

Further, the shielding means for shielding the space between the inner side of the short side portion of the tension mask,

It characterized in that it comprises a flat plate of the thin plate is fixed to the side wall of the rigid member is installed in the direction of the short side of the tension mask, and bent from the flat plate to support one surface of the tension mask.

Hereinafter, a cathode ray tube according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 shows the cathode ray tube 20 to which the tension mask assembly 30 is applied.

Referring to the drawings, the cathode ray tube 20 includes a panel 21 having a fluorescent film 21a formed on an inner surface thereof, and a funnel 22 sealed to the panel 21 to form a bulb. The tension mask assembly 30 is installed inside the panel 21. An inner shield 300 is fixed to the tension mask assembly 30.

The neck 22a of the funnel 22 is filled with an electron gun 23 for scanning an electron beam toward the fluorescent film 21a. The cone 22b of the funnel 22 has an electron beam of the fluorescent film 21a. The deflection yoke 24 is installed to be deflected according to the dice.

3 is a view illustrating a tension mask assembly 30 and an inner shield 300 according to a first embodiment of the present invention, and FIG. 4 illustrates a combination of the tension mask assembly 30 and the inner shield 300 of FIG. 3. The state is shown.

3 and 4, the tension mask assembly 30 is provided with a tension mask 31, wherein the tension mask 31 is a thin metal material and has a plurality of strips in which a slot 31 a is formed over its entire surface. 31b and tie bars 31c which interconnect the adjacent strips 31b and intersect the slot 31a intermittently.

A plurality of support members 32 are provided in directions parallel to each other so as to support the tension mask 31 in a state in which a predetermined tensile force is applied in both long side portions of the tension mask 31, and the support member 32. At each of the lower ends of the a) both ends are fixed and a plurality of rigid members 33 are provided at positions opposite to each other.

The side wall of the rigid member 33 is coupled to the stud pin (25, see Fig. 2) formed inside the cathode ray tube holder (34) to secure the tension mask assembly 30, and elastic to the holder 34 The leaf spring 35 which is a member is provided.

An inner shield 300 is coupled to the rear side of the tension mask assembly 30.

The inner shield 300 includes a main body 310 through which an electron beam scanned from the electron gun 23 can pass. The main body 310 has an opening 310a formed at the center thereof to allow the electron beam to travel, and is made of at least one thin metal plate. In addition, the main body portion 310 is a trapezoid having a substantially trapezoidal side, and is coupled to each other by a coupling member or the like. A flange portion 320 is formed at the lower end of the main body 310.

Looking at the coupling relationship between the tension mask assembly 30 and the inner shield 300 in detail.

The tension mask 31 is supported by each support member 32 in surface contact along both long side directions, and the rigid member 33 is provided at positions opposite to each other at the lower end of the support member 32. have. The rigid member 33 is positioned in the direction of the short side of the tension mask 31, and both ends thereof are fixed to the lower surface of each rigid member 33.

An inner shield 300 is positioned at the rear of the tension mask 31. The side wall of the rigid member 33 is a flange part formed at a lower end of the main body 310 of the inner shield 300. 320 is contacted. The inner shield 300 is firmly fixed to the tension mask assembly 30 by a separate fixing method such as welding in the state in which the flange portion 320 is in contact with the side wall of the rigid member 33. .

Here, a predetermined space portion is generated between the short side portion of the tension mask 31 and the flange portion 320 of the inner shield 300. Even if the inner shield 300 is installed for shielding the geomagnetic field due to the generation of the space part, drift of the electron beam still occurs, and the resolution of the image is deteriorated. In addition, a means for supporting is not separately provided at the short side of the tension mask 31, and a howling phenomenon occurs. On the other hand, the electron beam that does not pass through the slot (31a) of the tension mask 31 impinges on the tension mask 31, the diffusely reflected beam from it penetrates through the space again.                     

According to a feature of the invention, a shielding means is provided to block the space.

That is, the shielding means is a shielding member 40 extending from the flange portion 320 in the direction of the short side of the tension mask 31, that is, the space portion in the flange portion 320 of the inner shield 300, It includes.

The shielding member 40 extends integrally in a direction from the edge of the flange portion 320 toward the tension mask 31. In addition, at least one is formed to be spaced apart a predetermined interval along the longitudinal direction of the flange portion (320).

The shielding member 40 has an extension portion 41 having a predetermined width extending from the flange portion 320. The length of the extension part 41 corresponds to the height from the edge of the flange part 320 corresponding to the space part to the surface contacting the tension mask 31.

The end portion 41a of the extension portion 41 is formed with a bent portion 42 bent therefrom in the direction in which the tension mask 31 is installed. That is, the shielding member 40 has a substantially "A" shape in cross section. One surface of the bent portion 42 is in surface contact with the non-porous portion 31a along the short side direction of the tension mask 31. The bent portion 42 forms a contact surface at a right angle or an obtuse angle when contacting the non-hole portion 31a.

At this time, the bent portion 42 is in elastic contact with the non-porous portion 31a. This is possible to adjust the length of the extension part 41 extending from the flange part 320. In addition, the bent portion 42 may be supported upward from the bottom surface of the non-perforated portion 31a of the tension mask 31, and on the contrary, the bottom surface thereof is downward from the top surface of the non-hole portion 31a. It may be supported with a tensile force applied.

Accordingly, when the tension mask assembly 30 vibrates or shakes due to an external force, the shielding member 40 supports the airless portion 31a so that the tension mask assembly 30 attenuates the tension mask assembly 30. In addition, as the number of the shielding members 40 is adjusted, increasing the shielding area of the space part may improve the amount of drift of the electron beam due to the geomagnetic field.

5 illustrates a state in which the tension mask assembly 30 and the inner shield 300 are coupled according to the second embodiment of the present invention.

Here, the same reference numerals as in the above-described drawings will refer to the same member having the same function, and only the features according to the present embodiment will be described by explaining.

Referring to the drawings, the support member 32 is supported in the long side direction of the tension mask 31, the rigid member 33 is fixed to the lower surface.

Shielding means for shielding the space portion generated between the tension mask 31 and the rigid member 33 is provided on the side wall of the rigid member 33. In the present embodiment, unlike the case of the first embodiment, the shielding means is provided separately, not directly installed in the inner shield coupled with the tension mask assembly.                     

More detailed description is as follows.

A shielding member 50 is provided to shield the space generated from the sidewall of the rigid member 33 to one surface of the non-perforated portion 31a of the tension mask 31 in the short side direction of the tension mask 31.

The shielding member 50 has a flat plate portion 51 which can be completely shielded from the side wall of the rigid member 33 in the direction of the tension mask 31. The flat plate 51 may be integrally formed along the sidewall of the rigid member 33, or may be formed in at least one divided form. The flat plate portion 51 is a thin metal material, the thickness of which is about 0.3 millimeters, but is not limited thereto.

One end portion of the flat plate 51, that is, the side of the tension mask 31 is formed with a horizontal bending portion 52 in which the tension mask 31 is installed so as to be in surface contact with the non-porous portion 31a. It is. The bent portion 52 has a bottom surface in contact with one surface of the non-porous portion 31a. At this time, it will be said that it is necessary to adjust the length of the flat plate 51 so that the bent portion 52 is in contact with the tension mask 31 elastically. Accordingly, the bent portion 52 may elastically support the upper surface or the lower surface of the non-porous portion 31a.

As a result, the shielding member 50 can shield the space between the short side portion of the tension mask 31 and the rigid member 33. On the other hand, the inner shield is mounted on the side wall of the rigid member 33 to shield the geomagnetic field.

As described above, in the present invention, the planar cathode ray tube may have the following effects by providing shielding means for shielding a space portion generated between the tension mask and the inner shield.

First, since the structure supports the non-perforation in the direction of the short side of the tension mask, it acts in the direction of damping when a howling phenomenon occurs due to external force.

Secondly, since it is possible to shield the space generated between the tension mask and the inner shield, the amount of drift of the electron beam due to the influence of the geomagnetic field can be significantly reduced, thereby preventing deterioration of the resolution.

Third, the electron beam scanned from the residual gun can be prevented from penetrating into the space by being diffusely reflected without passing through the tension mask. It may also be possible to prevent diffuse reflection due to exposure during exposure.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (7)

A tension mask assembly having a tension mask, a support member supporting both sides of the tension mask, and a rigid member fixed at both ends to the support member; An inner shield including a body portion having an opening through which an electron beam passes, and a flange portion formed at a lower end of the body portion and fixed to the tension mask assembly; And And a shielding means for shielding a space portion between the tension mask assembly and the inner shield. The method of claim 1, The shielding means is for shielding a space generated between the short side of the tension mask and the inner shield, And an extended portion extending from the flange portion toward the short side of the tension mask, and a bent portion bent from the extension portion to support one surface of the tension mask. The method of claim 2, And the extension part has a height at which the bent part elastically supports the tension mask and extends integrally from the flange part. The method of claim 3, At least one extension part is formed along the edge of the flange portion at predetermined intervals. The method of claim 1, The shielding means is for shielding the space between the inner side and the short side of the tension mask, And a flat plate portion of a thin plate fixed to the side wall of the rigid member and installed in the direction of the short side of the tension mask, and a bent portion bent from the flat plate portion to support one surface of the tension mask. The method according to claim 2 or 5, The bent portion is a planar cathode ray tube, characterized in that to support the tension mask in a downward direction in surface contact with the upper surface of the non-hole portion in the direction of the short side of the tension mask. The method according to claim 2 or 5, And the bent portion elastically supports the tension mask upwardly in surface contact with the bottom surface of the non-hole portion in the direction of the short side of the tension mask.

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