KR20010095873A - safety glasses of flat cathode ray tube - Google Patents

Abstract

PURPOSE: A safety glass for flat cathode ray tube is provided to obtain optimum luminance and contrast for the flat CRT in an easy manner by easily controlling transmittivity, while maintaining explosion proof properties of the safety glass. CONSTITUTION: A safety glass comprises a glass(3) having a predetermined transmittivity, and a coating layer(30) coated at the front surface of the glass, and which is capable of adjusting transmittivity and has charge and reflecting function. The coating layer includes a titanium nitride layer(31) having light absorbing and conducting properties; and a silicon oxide layer(32) having an external light reflecting function by the index of refraction of the coating layer. The safety glass has a transmittivity of 70 to 90 percent, and is attached to the front of a panel(1) having a transmittivity of 78 percent, by a resin adhesive(10).

Description

Safety glasses of flat cathode ray tube

The present invention relates to a flat cathode ray tube, and more particularly, to a safety glass that is attached to the panel of the flat cathode ray tube to maintain the explosion-proof performance of the cathode ray tube and shield the leakage electromagnetic field.

Generally, a cathode ray tube is a device that substantially realizes an image in an image display device, and is classified into a curved cathode ray tube and a planar cathode ray tube according to the shape of a screen.

The curved cathode ray tube is distorted and the demand for the eye is reduced due to the reflection of light. On the other hand, the planar cathode ray tube is used to eliminate image distortion, minimize reflection by external light, and Maximization can be realized, and the demand is gradually spreading.

Such a flat cathode ray tube is fixed to a flat panel 1 having a phosphor 2 coated on its inner surface as shown in FIG. 1 and a curable adhesive on the entire surface of the panel 1 to maintain the explosion-proof characteristics of the cathode ray tube. The safety glass 3, the metal rail 4 fixed to the inner surface of the panel 1 by frit glass, and the rail 4 are fixed in a state in which tension is applied to the rail 4, and the color of the electron beam is selected. A shadow mask 5 having numerous void-shaped or circular electron beam through holes 5a formed therein, frit glass fixed to the panel 1, and a funnel 6 having a neck portion integrally formed at the rear thereof; The electron gun 7 is enclosed in the neck portion 6a of the funnel 6 and emits an R, G, B three-color electron beam toward the phosphor 2 side, and is installed to surround the outer circumferential surface of the neck portion 6a. With a deflection yoke (DY) (8) or the like that deflects in the horizontal and vertical directions of the screen. It is.

In the planar cathode ray tube configured as described above, power is applied to the heater of the electron gun 7 to generate an R, G, B electron beam from a cathode (not shown), and the R, G, B electron beam is accelerated while passing through a plurality of electrodes in sequence. And focused and then scanned toward the screen in a state deflected in the horizontal and vertical directions by the magnetic field of the deflection yoke 8.

As described above, the scanned electron beam passes through the electron beam through hole 5a of the shadow mask 5, which serves as color screening, to emit the phosphor 2 coated on the inner surface of the panel 1, so that an image is reproduced.

On the other hand, the safety glass 3 constituting the planar cathode ray tube is attached to the front surface of the panel 1 using a curable adhesive for the purpose of improving the explosion-proof performance of the planar cathode ray tube, the safety glass 3 It will be described in detail with reference to Figure 2 as follows.

In general, in order to improve the explosion-proof performance, clear glass having a transmittance of 78% is used as the panel 1, and safety is achieved by using a curable adhesive 10 having a transmittance of 98% or more in front of the panel 1. Glass 3 is attached.

The safety glass 3 is a color glass of 62% transmittance, and is coated with a coating layer 20 composed of six layers for antistatic and antireflection functions, and there is no change in transmittance by the coating layer 20.

When the colored glass having the 62% transmittance configured as described above is used as the safety glass 3, the transmittance of the flat cathode ray tube is about 48%.

That is, only 48% of the light (image) emitted by the electron gun 7 and emitted by the phosphor 1 is transmitted out of the plane cathode ray to realize an image.

On the other hand, as the size of the cathode ray tube increases, the thickness of the panel 1 and the safety glass 3 is increased to prevent explosion, but as the panel 1 and the safety glass 3 become thicker, the planar cathode ray tube is increased. Since the transmittance of is lowered, the appropriate transmittance should be adjusted according to the thickness of the panel 1 and the safety glass 3.

The transmittance of the planar cathode ray tube is one of important factors affecting the brightness and contrast of the planar cathode ray tube.

The higher the transmittance of the planar cathode ray tube, the higher the luminance but the lower the contrast.

In other words, the higher the transmittance, the more light is transmitted through the planar cathode ray tube, and the brighter the image becomes. However, the brighter the image, the less the colors constituting the image become.

Therefore, the transmittance should be adjusted to suit the brightness and contrast of the appropriate required for the planar cathode ray tube.

However, a general cathode ray tube requires a luminance of 31 to 33 Fl and a contrast of 22 or more, whereas when the above-mentioned color glass is used as a safety glass of a flat cathode ray tube, the luminance is increased to 38 F1 and the contrast is also lowered.

Accordingly, in the conventional safety glass, due to the difficulty in adjusting the transmittance, there is a problem in that it does not produce the brightness and contrast required for the flat cathode ray tube.

Accordingly, an object of the present invention is to solve the above problems, while maintaining the explosion-proof performance of the safety glass of the flat cathode ray tube, and more easily controlling the transmittance to obtain luminance and contrast required for the flat cathode ray.

1 is a cross-sectional view showing the configuration of a general flat cathode ray tube

Figure 2 is a cross-sectional view showing the safety glass configuration of a general flat cathode ray tube

Figure 3 is a cross-sectional view showing the safety glass configuration of the flat cathode ray tube according to the present invention

Description of the main parts of the drawing

1 panel 3 safety glass

30 coating layer 31 titanium nitride layer

32: silicon oxide layer

In order to achieve the above object, the present invention, in front of the safety glass, the coating layer made of titanium nitride (TiN) and the coating layer made of silicon oxide (SiO2) is coated to facilitate the control of transmittance and to prevent charging and reflection It provides a safety glass of the flat cathode ray tube constructed.

The safety glass and the coating layer will be described in more detail with reference to FIG. 3 as follows.

The safety glass 3 has a transmittance of 70 to 90% and is adhered by a curable adhesive 10 in front of the panel 1 having a transmittance of 78%, and a coating layer 30 is provided in front of the safety glass 3. Is covered.

The coating layer 30 has a titanium nitride layer 31 having an absorbance of 13-35% and a conductivity of 1000 ohms or less in front of the safety glass 3 in order to facilitate transmittance adjustment and to prevent charging and reflection. A silicon oxide layer 32 having a low refractive index of 1.46 is formed in front of the titanium nitride layer 31 and is coated on the front of the safety glass 3.

Since the titanium nitride forming the titanium nitride layer 31 is a light absorbing and conductive material, the titanium nitride layer 31 has a transmittance adjustment and a conductive function, and the silicon oxide layer 32 has a titanium nitride layer 31 and an oxide. It has a function of preventing reflection of light due to the refractive index of the silicon layer 32.

Hereinafter, preferred embodiments of the present invention will be described.

As shown in Table 1, the safety glass 3 of the planar cathode ray tube according to the first embodiment of the present invention has a coating layer 30 having a thickness of 104-106 nm on the entire transparent glass having a transmittance of 90%. Made of a coated configuration.

The coating layer 30 is composed of a titanium nitride layer 31 having a thickness of 59 nm and a silicon oxide layer 32 having a thickness of 45 nm.

On the other hand, if the thickness of the coating layer 30 to 104 nm or less, the coating properties such as reflectance and resistance is reduced, so that the thickness of the coating layer 30 to 104 ~ 106 nm, while the titanium nitride layer 31 is Enlarged.

The transmittance of the safety glass 3 configured as described above is as follows.

(Transmittance of Transparent Glass (90%)-Light Absorption of Coating Layer (35%)) = 55%

Therefore, when the safety glass 3 coated with the titanium nitride layer 31 and the silicon oxide layer 32 is attached to the panel 1 having a transmittance of 78%, the total transmittance of the planar cathode ray tube becomes 43%.

(Panel transmittance (0.78) × Coated safety glass (0.55)) × 100 = 43%

On the other hand, as shown in Table 1, the safety glass 3 of the planar cathode ray tube according to the second embodiment of the present invention, the coating layer 30 having a thickness of 98-100 nm on the entire color glass having a transmittance of 70% It consists of a coated configuration.

The coating layer 30 is composed of a titanium nitride layer 31 having a thickness of 43 nm and a silicon oxide layer 32 having a thickness of 55 nm.

When the thickness of the coating layer 30 is reduced to 98 nm or less, the reflectance is lowered. Therefore, the thickness of the coating layer 30 is 98-100 nm, while the titanium nitride layer 31 is made smaller.

The transmittance of the safety glass 3 configured as described above is as follows.

(Transmittance of colored glass (70%)-light absorption of coating layer (15%)) = 55%

Therefore, when the safety glass 3 coated with the titanium nitride layer 31 and the silicon oxide layer 32 is attached to the panel 1 having a transmittance of 78%, the total transmittance of the planar cathode ray tube becomes 43%.

(Panel transmittance (0.78) × transmittance of coated safety glass (0.15)) × 100 = 43%

As described in the first and second embodiments, when the safety glass having a different transmittance is coated with a coating layer composed of a titanium nitride layer and a silicon oxide layer with an appropriate thickness, and the safety glass is attached to the panel, the transmittance of the flat cathode ray tube is 43%.

As described above, when the transmittance of the planar cathode ray tube becomes 43%, the planar cathode ray tube can obtain a luminance of about 33-34 F1 and a contrast of about 22 which are required for a general cathode ray tube.

As described above, the present invention was coated on the safety glass of the flat cathode ray tube, the coating layer having a function of adjusting the transmittance, charging, and anti-reflection to adjust the transmittance of the flat cathode ray tube.

Therefore, even if the panel and safety glass which maintain explosion-proof performance become thick, the width | variety of the transmittance | permeability becomes wider, and the brightness and contrast required for a flat cathode ray tube can be acquired more easily.

Claims (5)

Glass having a predetermined transmittance, Safety glass of a flat cathode ray tube, characterized in that the entire surface of the glass is coated with a coating layer having a transmittance adjustment and anti-reflective function. The method of claim 1, The coating layer is a titanium nitride layer having light absorption and conductivity, Safety glass of a flat cathode ray tube, characterized in that consisting of a silicon oxide layer having an antireflection function of the external light by the refractive index of the coating layer. The method of claim 2, The titanium nitride layer is a safety glass of a flat cathode ray tube, characterized in that the absorbance is 15 to 35%. The method of claim 1, The safety glass is colored glass having a transmittance of 70%, In order to set the absorbance of the coating layer on the entire surface of the safety glass to 15%, A safety glass of a flat cathode ray tube, wherein the coating layer has a thickness of 98 to 100 nm. The method of claim 1, The safety glass is a transparent glass having a transmittance of 90%, In order to make the absorbance of the coating layer 35% on the entire surface of the safety glass, A safety glass of a flat cathode ray tube, wherein the coating layer has a thickness of 104-106 nm.