KR20010001227U - structure inner shield in plat type cathode ray tube - Google Patents

Abstract

The present invention relates to the structure of the inner shield for the planar CRT, and to expand the cross-sectional area of each side of the inner shield to absorb more heat energy from the mask to quickly dissipate it.

The present invention for this purpose is to form a non-linear cross-sectional shape of each side of the inner shield.

Description

Structure inner shield in plat type cathode ray tube

The present invention relates to a flat CRT, and more particularly, to an inner shield structure for a flat CRT serving as a shield for an external geomagnetic field.

In general, the cathode ray tube (or cathode ray tube) is mainly used for a TV or an image display, and particularly, the planar cathode ray tube is a red, green, and blue phosphors 1a coated in a uniform pattern on an inner surface as shown in FIG. A flat panel 1 and a bulbous funnel 2 fused to the inner surface of the panel by frit glass form an outer shape, and the inside thereof maintains a high vacuum.

In addition, a square frame rail (3) is fused and fixed to the inner surface of the panel (1) by frit glass, and a mask (4) for screening the color of the electron beam is fixed to the rail (3) in a tension state. Inner portion (3) of the (3) is fixed to the inner shield (5) shielding the external magnetic field, the bottleneck shaped neck portion (2a) formed in the rear of the funnel (2) electron gun (6) for emitting an electron beam This is enclosed.

When the electron beam is emitted by the image signal applied to the cathode (not shown) of the electron gun 6 from this configuration, the emitted electron beam is accelerated and focused while sequentially passing through a plurality of electrodes constituting the electron gun 6. In addition, it is deflected horizontally or vertically by the magnetic field of the deflection coil 7 provided around the neck portion 2a.

Subsequently, the color is selected while passing through the mask 4 positioned on the path of the electron beam, and the phosphor 1a applied to the inner surface of the final panel 1 emits light, thereby reproducing an image.

At this time, the electron beam emitted from the electron gun 6 causes a miss register as the path is changed by an external geomagnetic field. An inner shield (or magnetic shield) 5 made of magnetic material is used to reduce the miss register. By installing inside the CRT, a closed circuit is formed together with the mask 4 and the rail 3 to shield the inflow of the geomagnetic field.

On the other hand, the transmittance of the mask 4 of the electron beam is only about 20%, and the remaining about 80% is not transmitted and remains in the mask 4 as thermal energy.

As such, if the thermal energy remaining in the mask 4 is not properly released, a domming phenomenon occurs in which the mask is stretched by heat and deforms into a bulging dome type in the direction of travel of the electron beam, which is mislanding of the electron beam. It causes mislanding, which lowers the brightness and color purity.

Factors that can prevent thermal deformation of the mask 4 include a panel 1, a rail 3, and an inner shield 5 installed around the mask 4. It absorbs heat directly or indirectly and plays a role of radiating heat to the outside of CRT.

In particular, the heat dissipation factor among the heat dissipation factors is the panel (1) is the largest, the mask (4), the inner shield (5) in order.

However, since the panel 1 is coated with aluminum (Al) having a very low emissivity on its inner surface, there is a limit to improving the emissivity.

In addition, since the inner shield 5 has a flat shape, each of the inner shields 5 has only a very small emissivity compared to its size.

The present invention has been made to solve the conventional problems as described above, the purpose is to more effectively radiate heat energy of the mask generated by the electron beam through the inner shield.

The present invention for achieving the above object is a flat CRT having a mask that serves as the color selection of the electron beam, and an inner shield to shield the inflow of the external geomagnetic field;

The inner shield structure for a flat CRT tube is provided in which the shape of each surface of the inner shield is nonlinear, so that the heat dissipation efficiency of the thermal energy conducted from the mask is improved by increasing the heat exchange area.

1 is a longitudinal cross-sectional view of a typical flat CRT

2 is a perspective view of a conventional inner shield

3 is a perspective view showing a first embodiment of the inner shield according to the present invention

4 is a perspective view showing a second embodiment of the inner shield according to the present invention

Explanation of symbols for main parts of the drawings

4: mask 50: inner shield

Figure 3 is a perspective view showing a first embodiment of the inner shield according to the present invention, Figure 4 is a perspective view showing a second embodiment of the inner shield according to the present invention, the inner shield structure of the present invention with reference to these accompanying drawings When described in detail as follows.

According to the present invention, the shape of each surface of the inner shield 50 is nonlinear, so that the heat radiation efficiency of the thermal energy conducted from the mask 4 is improved.

Considering that the heat dissipation efficiency or heat exchange efficiency is proportional to the contact area with the atmosphere, increasing the contact area with the atmosphere can improve the heat exchange efficiency per same volume, and the inner shield 50 is based on this fact. It is a form.

On the other hand, the non-linear can be applied in various forms, for example as follows.

As shown in FIG. 3, each surface of the inner shield 50 may be embossed, or each surface of the inner shield 50 may have a concave-convex shape as shown in FIG. 4. In addition, it is a matter of course that a shape such as a sawtooth shape, a waveform, and the like can be applied.

As described above, the cross-sectional shape of each surface of the inner shield 50 was varied into various shapes, which is to expand the surface area of the inner shield 50 to improve heat exchange efficiency.

The inner shield 50 of the present invention having such a configuration can secure an expanded heat exchange area when linear by making the cross-sectional shape of each surface into the non-linear shape of the uneven shape or the embossing shape.

Therefore, when heat energy is generated in the mask 4 by the electron beam, the generated heat energy is radiated to other parts having a lower temperature than the mask.

At this time, when the radiated heat energy is transferred to the inner shield 50, the heat exchange efficiency is improved by the expanded surface area, so that the heat energy of the mask 4 can be quickly released.

As a result, the cooling efficiency of the mask 4 may be improved to prevent the masking of the mask and to prevent mis-landing of the electron beam.

The present invention as described above is able to prevent the doming phenomenon of the mask by more rapidly dissipating the heat energy transferred from the inner shield from the mask more quickly through the surface shape of the inner shield.

In addition, it is possible to suppress the occurrence of mis-landing of the electron beam to prevent the luminance and the color purity from being lowered.

Claims (3)

A flat CRT tube having a mask that serves as a color screening of an electron beam, and an inner shield that shields an inflow of an external geomagnetic field; An inner shield structure for a flat CRT tube having a non-linear cross-sectional shape of each surface of the inner shield so as to increase a heat exchange area so that heat radiation efficiency of thermal energy conducted from a mask is improved. The method of claim 1, Non-linear inner shield structure for flat CRT tubes with embossed shape. The method of claim 1, Non-linear inner shield structure for flat CRT tubes with irregularities.