KR100269921B1 - Cathode ray tube - Google Patents

Abstract

PURPOSE: A cathode ray tube is provided to prevent the mis-landing of electron beam by shielding an earth magnetic field formed around a panel. CONSTITUTION: A cathode ray tube comprises a panel(2), a funnel(4), a shadow mask(14), a mask frame(18), an inner shield(16), and an earth magnetic field shielding portion(20). A screen(8) is formed on an inner face of the panel(2). The funnel(4) is combined with the panel(2). The shadow mask(14) has a multitude of beam pass hole. The mask frame(18) supports the shadow mask(14). The inner shield(16) has a shielding function for earth magnetic field. The earth magnetic field shielding portion(20) is installed at the mask frame(18). The earth magnetic field shielding portion(20) shields the earth magnetic field formed around the panel(2).

Description

Cathode ray tube

The present invention relates to a cathode ray tube, and more particularly, to a cathode ray tube capable of realizing excellent screen characteristics by preventing mis-landing of an electron beam by further shielding a geomagnetic field around a panel.

In general, a cathode ray tube emits an electron beam controlled by a screen signal from an electron gun and sequentially scans the front surface of the screen to transmit the light to the user while emitting the emitted phosphor.

To this end, the cathode ray tube provides a fluorescent screen to the inner surface of the panel constituting the front body, and is coupled to the panel to insert the electron gun into the neck portion of the funnel forming the rear body.

And a shadow mask that is installed in parallel with the panel at a predetermined distance to the back of the screen, the shadow mask having a plurality of beam passing holes formed on the surface thereof to match three electron beams emitted from the electron gun. It is separated again and landed on the designated phosphor.

In addition, the outer peripheral surface of the funnel is provided with a deflection yoke composed of a combination of a vertical coil and a horizontal coil to deflect the electron beam emitted from the electron gun up, down, left and right.

As such, the electron beam deflected by the deflection yoke and scanned onto the screen surface is affected by the geomagnetism until it reaches the screen surface, and the electron beam affected by the geomagnetic field changes its movement path at a predetermined angle so that the specified shadow mask It does not reach the beam-passing hole on the image, which prevents accurate color separation from occurring.

Since the landing characteristics of the electron beam are changed due to the influence of the geomagnetic field, it is difficult to implement a desirable image. As a method for shielding the geomagnetic field, an inner shield is mounted on a mask frame, and the inner shield is a magnetic permeability. It consists of a thin metal plate with high and low coercive properties.

The inner shield is a magnetic field of the inner shield and mutual interference with the geomagnetic field to change the range of the geomagnetic field to a range that does not affect the electron beam travel path, the geomagnetic shielding effect of the inner shield is known to be approximately 50%. .

However, while the conventional cathode ray tube adopts an inner shield to shield the geomagnetic field affecting the electron beam path, the inner shield is mounted close to the inner wall of the funnel so that one end is mounted on the mask frame and faces the electron gun. The shield's magnetic field ranges from the electron gun to the space on the mask frame. The electron beam, which passes through the shadow mask and is scanned onto the screen surface, lands under the influence of the geomagnetic field without any special geomagnetic shielding effect.

As such, the distance of the electron beam scanned through the shadow mask to the screen surface, i.e., the distance between the shadow mask and the panel, is referred to as Q. As the value of Q increases by 1 mm, the movement distance of the electron beam missed by the geomagnetic field is about 4 μm. Known.

Accordingly, there have been a number of devises to improve the shielding range of the inner shield by improving the conventional inner shield, and one of them is to extend and arrange the end of the inner shield to the end of the mask frame and the shadow mask. However, the geomagnetic shielding between the shadow mask and the panel is difficult to expect.

Therefore, the present invention has been made to solve the above problems, an object of the present invention is to provide a cathode ray tube that can implement excellent screen characteristics by preventing the mis-landing of the electron beam by further shielding the geomagnetic field around the panel.

In order to achieve the above object, the present invention, a panel forming a front body and forming a screen on the inner surface, a funnel which forms a rear body and inserts an electron gun into the neck portion and couples the panel to the opening, and the panel on the back of the screen A shadow mask disposed parallel to and providing a plurality of beam-through holes, a mask frame for supporting and mounting the shadow mask, one end mounted to the mask frame and the opposite end disposed close to the funnel toward the electron gun; It provides a cathode ray tube including an inner shield having a system shielding function, and a magnetic field shielding means corresponding to the inner shield and attached to the mask frame to be close to the screen to shield the magnetic field around the panel.

The geomagnetic shielding means serves as a geomagnetic shielding film of magnetic material having a predetermined high permeability and low coercive force, the geomagnetic shielding film being disposed towards the panel with one end mounted on the mask frame and the opposite end approaching the screen. .

Accordingly, the landing characteristics of the electron beam can be improved by effectively shielding the geomagnetic field affecting the electron beam movement path between the shadow mask and the screen.

1 is a schematic cross-sectional view of a cathode ray tube according to the present invention.

2 is a partially enlarged cross-sectional view of FIG. 1.

3 is a perspective view showing some components of a cathode ray tube according to the present invention;

4 is a partially enlarged cross-sectional view of a cathode ray tube according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic cross-sectional view of a cathode ray tube according to the present invention. As shown in the drawing, the cathode ray tube is a panel 2 having a front body, a funnel 4 having a rear body, and a neck 6 like a conventional cathode ray tube. Combine to form a bulb.

A fluorescent screen 8 is formed on the inner surface of the panel 2, and the screen 8 is formed by disposing three colors of green, blue, and red phosphors and graphite lines, which are light absorbing materials, between these phosphors.

The electron gun 10 is inserted into the neck 6, and the electron gun 10 emits three green, blue, and red electron beams controlled by a screen signal, and scans the screen 8 with the shot. The electron beam is deflected by the deflection yoke 12 to scan all the pixels on the screen 8.

The electron beam emitted from the electron gun 10 passes through the shadow mask 14 to reach the phosphor on the screen 8, and the shadow mask 14 has a plurality of beam passing holes corresponding to each pixel on its surface. By forming a coincidence and matching the electron beam emitted from the electron gun 10 in one beam through hole, and separating the electron beam and landing on the specified phosphor, it serves as a color screening function.

As described above, the cathode ray tube implementing the screen by scanning the electron beam from the electron gun 10 to the phosphor, however, the earth magnetic field affects the space on the movement path of the electron beam in the cathode ray tube, so that the electron beam is determined by the geomagnetic field. The bending occurs at an angle of.

Therefore, the inner shield 16 is mounted on the mask frame 18 to shield the geomagnetic field. The inner shield 16 generates a magnetic field by itself as a magnetic material, causing interference with the geomagnetic field, and transmitting the geomagnetic field to the electron beam. Has the ability to switch to a range that does not affect.

However, as the inner shield 16 is shown, one end is mounted to the mask frame 18 and the opposite end is disposed in close proximity to the funnel 4 toward the electron gun 10, so that the magnetic shielding range of the inner shield 16 is limited. Is approximately from the electron gun 10 to the mask frame 18, and has a limit that the magnetic field shielding effect does not reach the space between the shadow mask 14 and the panel 2, that is, the Q value.

In the cathode ray tube having such a conventional structure, the geomagnetic field shielding means according to the present invention is provided. The cathode ray tube newly implemented by the present invention corresponds to the inner shield 16 and is masked to be close to the screen 8. Provided are a magnetic field shielding means mounted to the frame 18.

The geomagnetic shielding means is composed of a geomagnetic shielding film 20, one end of which is mounted to the mask frame 18 and the end-to-end end is disposed toward the panel 2 so as to be close to the screen 8, The geomagnetic shielding film 20 complements the function of the inner shield 16 to exhibit the geomagnetic shielding performance in a space on the Q value.

FIG. 2 is a partially enlarged cross-sectional view of FIG. 1, which includes a shadow mask 14 having a color screening function, a mask frame 18 supporting and mounting the shadow mask 14, and an inner shield coupled to the mask frame 18 (FIG. 16 and the geomagnetic shielding film 20 inserted into the outer circumferential surface of the mask frame 18 are shown.

The shadow mask 14 is molded by the first press operation to form the same curved surface as the curved surface of the panel 2, and then bend-molded the skirt portion 22, which is a welded portion with the mask frame 18, by the second press operation. .

As shown in the drawing, the skirt 22 of the shadow mask 14 is inserted into and combined with the mask frame 18 and referred to as a MIFA (Mask Inside Frame Ass'y) method. It is a method that is applied to large-scale cathode ray tube of high resolution because it prevents deformation more and is excellent in quality.

The shadow mask 14 is usually a thin steel sheet, welded to the mask frame 18 and supported by the panel 2 inner surface. The mask frame 18 is made of a material having high mechanical strength and low thermal deformation. This is preferable.

The mask frame 18 is also equipped with an inner shield 16, the coupling of the mask frame 18 and the inner shield 16 is usually used to clip the inner shield 16 using a clip 24, clamping pins or the like. It is fixed to the mask frame 18.

The geomagnetic shielding film 20 is mounted on the outer circumferential surface of the mask frame 18, and the geomagnetic shielding film 20 is a magnetic material having a predetermined high magnetic permeability and low coercive force. The component of is preferably made of 100% pure iron (Fe) the same as the component of the inner shield (16).

The principle of the geomagnetic shielding film 20 is that, as with the inner shield 16, when a metal material is placed in a magnetic field region in which an external magnetic field exists, a spin moment is formed inside the metal material, and the magnetic conductor is rearranged in a predetermined direction, thereby forming a metal conductor. In this case, a magnetic force is generated in the metal material, and this magnetic force causes a cancellation or reinforcement interference with the external magnetic force. As a result, the external magnetic field uses the principle that the path of the magnetic field is changed by the metal material.

Therefore, the geomagnetic field is shielded by changing the geomagnetic field in a range in which the geomagnetic shielding film 20 is mounted, i.e., in a space adjacent to the mask frame 18 and the screen 2, so as not to affect the electron beam movement path. will be.

As shown in FIG. 3, the geomagnetic shielding film 20 has a rectangular band shape to be mounted on the outer circumferential surface of the mask frame 18, and the width of the band is 10 to 20 mm. In consideration of the Q state and the mounting state of the mask frame 18 mounted on the inner surface of the panel 2, the thickness is approximately 15 mm.

The geomagnetic shielding film 20 is made of a rolled steel sheet having a thickness of approximately 0.1 to 0.18 mm, and the spacing between the surfaces forming the geomagnetic shielding film 20, that is, the size of the square stripe is the outer side of the mask frame 18. Design considering the size of the circumferential surface.

Accordingly, the geomagnetic shielding film 20 is inserted into the outer circumferential surface of the mask frame 18 and then fitted to the mask frame 18.

Coupling of the geomagnetic shielding film 20 and the mask frame 18 can be performed using not only a fitting method but also a welding method, a coupling means such as a clip or a clamping pin, and the like as described above. have.

By providing the geomagnetic shielding film 20 disposed toward the panel 2 in such a way as to be close to the screen 8, the geomagnetic field in the Q, Q, space between the shadow mask 14 and the panel 2 is shielded. The electron beam passing through the shadow mask 14 can be more accurately landed on the screen 8.

4 is a view showing another embodiment of the present invention, in which a shadow mask 14, a mask frame 18 supporting and mounting the shadow mask 14, and an inner shield 16 coupled to the mask frame 18 are shown. And the geomagnetic shielding film 20 attached to the outer circumferential surface of the mask frame 18.

The shadow mask 14 is welded with the skirt 22 positioned on the outer surface of the mask frame 18, and thus the shadow mask 14 is mounted outside the mask frame 18. It is called Mask Outside Frame Ass'y method, which is superior to Mipa method in terms of equipment and workability.

The geomagnetic shielding film 20 is provided as shown by the outer surface of the shadow mask 14 mounted on the mask frame 18 by the MOS method, and the geomagnetic shielding film 20 is formed of the shadow mask 14. The outer peripheral surface of the skirt portion 22 and the outer peripheral surface of the mask frame 18 are mounted.

The combination of the geomagnetic shielding film 20 and the mask frame 18 is a method of fitting the geomagnetic shielding film 20 to the mask frame 18 as described above in the above-described embodiment, a welding method, and a clip. Or by a coupling means such as a clamping pin.

The geomagnetic shielding film 20 is mounted on the mask frame 18 by using the above-described method, and the geomagnetic shielding film 20 wraps around the skirt 22 of the shadow mask 14 with one end and the mask frame 18. And the opposite end is positioned towards the panel 2 so as to be close to the screen 8 so that the space between the shadow mask 14 and the panel 2 can further shield the geomagnetic field affecting the electron beam landing characteristics. It can be.

As described above, the preferred embodiments of the present invention have been described, but the present invention is not limited thereto, and various modifications can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. It goes without saying that it belongs to the scope of the present invention.

As described above, the present invention provides a geomagnetic shielding film in a range where the inner shield does not affect, that is, a space corresponding to the Q value, so that the electron beam passing through the shadow mask is more accurately landed on the phosphor.

Accordingly, the electron beam landing characteristics such as color purity characteristics and white uniformity may be improved, thereby realizing better image quality.

Claims (7)

A panel forming a front body and forming a screen on an inner surface thereof; A funnel forming a rear body and inserting and mounting an electron gun through the neck portion and engaging the panel with an opening; A shadow mask disposed on the rear surface of the screen in parallel with the panel and providing a plurality of beam passing holes; A mask frame for supporting and mounting the shadow mask; An inner shield having one end mounted on the mask frame and an opposite end disposed close to the funnel toward the electron gun, the inner shield having a geomagnetic shielding function; And a magnetic field shielding means corresponding to the inner shield and attached to the mask frame to shield the magnetic field around the panel. The cathode ray tube according to claim 1, wherein said geomagnetic shielding means is made of a geomagnetic shielding film of magnetic material having a predetermined high permeability and low coercive force. The cathode ray tube according to claim 2, wherein the geomagnetic shielding film has a rectangular band shape having a predetermined width. The cathode ray tube of claim 2, wherein the geomagnetic shielding film is disposed toward the panel so that one end is mounted to the mask frame and the opposite end is close to the screen. 7. The cathode ray tube of claim 2, wherein the geomagnetic shielding film is fitted to one circumferential surface of the mask frame and mounted to the mask frame. The cathode ray tube of claim 2, wherein the geomagnetic shielding film is welded to one side surface of the mask frame to be mounted on the mask frame. The cathode ray tube of claim 2, wherein the geomagnetic shielding film is mounted to the mask frame by a clip or a pin on one side of the mask frame.

Images