KR100581848B1 - Color picture tube and method for forming blue fluorescent layer thereof - Google Patents

Abstract

According to the present invention, there is provided a panel comprising phosphor patterns of red, blue, and green formed on an inner surface thereof; A funnel sealed to the panel and having a neck portion and a cone portion formed thereon; An electron gun inserted into and inserted into the neck portion of the funnel; And a deflection yoke installed outside the cone of the funnel; wherein the area of the blue phosphor formed on the inner surface of the panel is enlarged from the center of the panel toward the edge of the panel. Provided are a cathode ray tube and a blue fluorescent film forming method of the color cathode ray tube. The color cathode ray tube according to the present invention has an effect of reducing eye fatigue and also improves luminance.

Description

Color picture tube and method for forming blue fluorescent layer according to color cathode ray tube and color cathode ray tube

1 is a schematic configuration diagram of a conventional color cathode ray tube.

2 is an exploded perspective view of a cathode ray tube panel and a funnel;

3A to 3C are explanatory views showing a blue fluorescent film forming method of a color cathode ray tube according to an embodiment of the present invention.

Figure 4 is a flow chart illustrating a blue fluorescent film forming method of a color cathode ray tube according to another embodiment of the present invention.

<Brief Description of Major Codes in Drawings>

13. Panel 14. Funnel

15. Electron gun 16. Deflection yoke

12. Shadow Mask Frame Assembly 31. Panel

32. Shadow Mask 33. Shielding Mask

39. Mercury lamps

The present invention relates to a color cathode ray tube and a method for forming a blue fluorescent film of a color cathode ray tube, and more particularly, a color in which blue light intensity generated differently in a central portion and a peripheral portion of a blue fluorescent film of a color cathode ray tube is formed. A cathode ray tube and a method of forming the same.

In general, a color cathode ray tube is a device in which a red, green, and blue phosphor formed for each pixel is excited to display a predetermined image by scanning an electron beam generated from an electron gun to a fluorescent film formed on the inner surface of the panel.

1 is a schematic configuration diagram of a conventional color cathode ray tube.

Referring to the drawings, the color cathode ray tube assembly includes a panel 13 in which a fluorescent film is formed on an inner surface thereof and a shadow mask frame assembly 12 is mounted therein, and a funnel in which an electron gun 15 is enclosed in the neck portion 14a. (14), a deflection yoke (16) provided on the outer circumferential surface of the neck portion (14a), and a convergence purity magnet assembly (17).

In the conventional color cathode ray tube having the above structure, the fluorescent film formed on the inner surface of the panel 13 is formed by applying red, green, and blue phosphor materials in order to predetermined portions of the panel. When each pixel of the fluorescent films thus formed emits light by the electron beam of the electron gun, cells capable of detecting color in the human eye act to feel color.

Humans can feel color due to the photoreceptor of cone cells in the retina. Abstracts can be divided into three types, each of which can detect red, green, and blue bands. In general, the abstracts are intensively distributed around the so-called fovea in the eyeball, which is the point corresponding to the central part in the human retina. However, according to the human eyes and contrast sensitivity experiments, the human eye can see that the sensitivity to blue light is significantly lower than red or green. This is caused by the relatively small number of abstracts for the blue color, but another reason is that the abstracts for the blue color are less distributed in the center and part. In other words, there is a part in the central fovea, which is the center of the human retina, without an abstraction of blue color.

Often the human eye is comparable to the camera. When considering the chromatic aberration of the lens corresponding to the lens of the camera in the human eye, the blue light incident on the part other than the achromatic axis is affected by the change in the refractive index of the visual medium. The light enters the part away from the fovea, but the light entering the achromatic axis is incident on the fovea without being dispersed. Therefore, even if the light intensity of the incident blue is large in the fove with relatively few abstractions to the blue color, it cannot be detected properly, and this is unnecessary even if the incidence of the blue light into the fovea is strong.

 On the other hand, since blue light has a stronger energy than red or green, blue light excites water molecules contained in retinal cells to generate oxygen harmful to the human body. Therefore, if the user looks at the color cathode ray tube for a long time, it may cause vision deterioration.

The present invention has been made to solve the above problems, it is an object of the present invention to provide a color cathode ray tube is improved the problem of visual acuity by the blue color.

Another object of the present invention is to provide a color cathode ray tube in which the intensity of the blue color is formed differently for each portion of the color cathode ray tube panel.

In order to achieve the above object, according to the present invention, there is provided a panel comprising phosphor patterns of red, blue, and green formed on an inner surface thereof; A funnel sealed to the panel and having a neck portion and a cone portion formed thereon; An electron gun inserted into and inserted into the neck portion of the funnel; And a deflection yoke installed outside the cone of the funnel; wherein the area of the blue phosphor formed on the inner surface of the panel is enlarged from the center of the panel toward the edge of the panel. A cathode ray tube is provided.

According to one feature of the invention, the intensity of light generated from the blue phosphor is such that the light intensity at the center of the panel corresponds to 80% of the maximum light intensity at the panel edge, gradually or stepwise from the center of the panel to the edge of the panel. The area of the blue phosphor is set to increase the light intensity.

In addition, according to the present invention, there is provided a panel in which phosphor patterns of red, blue, and green are formed on an inner surface thereof; A funnel sealed to the panel and having a neck portion and a cone portion formed thereon; An electron gun inserted into and inserted into the neck portion of the funnel; And a deflection yoke installed outside the cone of the funnel, wherein the blue phosphor formed on the inner surface of the panel has different blue phosphor materials having different light intensities depending on the distance from the center of the panel. It is provided with a color cathode ray tube, characterized in that formed.

According to another feature of the invention, the light intensity of the material of the blue phosphor formed at the center of the panel corresponds to 80% of the light intensity of the material of the blue phosphor formed at the edge of the panel, from the center of the panel Different blue phosphor materials are selected such that the light intensity gradually increases or gradually increases toward the edge of the panel.

In addition, according to the present invention, there is provided a panel in which phosphor patterns of red, blue, and green are formed on an inner surface thereof; A funnel sealed to the panel and having a neck portion and a cone portion formed thereon; An electron gun inserted into and inserted into the neck portion of the funnel; And a deflection yoke provided outside the cone of the funnel; wherein the negative voltage applied to the blue electron beam cathode provided in the electron gun is variable, and the negative voltage change is changed. By synchronizing with the scanning signal of the deflection yoke, the intensity of the blue electron beam is incident differently depending on the position of the panel.

Further, according to another feature of the invention, the light intensity of the blue phosphor emitted by the blue electron beam incident on the center of the panel of the light intensity of the blue phosphor emitted by the blue electron beam incident on the edge of the panel Corresponding to 80%, the intensity of the blue electron beam increases gradually or stepwise from the center of the panel to the edge of the panel.

According to the present invention, a method of forming a blue fluorescent film of a color cathode ray tube, the method comprising: providing a shadow mask on an inner surface of a panel to expose a blue phosphor material with an exposure light source, wherein the exposing step comprises: the shadow mask; A plurality of shielding masks having respective exposure sites partitioned in accordance with the distance from the center of the inner surface of the panel are sequentially arranged between the light sources for exposure, and in a section close to the center of the inner surface of the panel, exposure is performed for a relatively short time. The method of forming a blue fluorescent film of a color cathode ray tube is characterized in that the exposure is performed for a relatively long time as the distance from the center of the inner surface of the panel.

In addition, according to the present invention, a method of forming a blue fluorescent film of a color cathode ray tube, the method comprising: providing a shadow mask on an inner surface of a panel to expose a blue phosphor material with an exposure light source, wherein the shadow mask is formed at the center of the panel. Provided is a blue fluorescent film forming method of a color cathode ray tube, characterized in that the size of the light transmitting hole of the corresponding portion is the smallest, and the size of the light transmitting hole is larger toward the edge of the panel.

In addition, according to the present invention, in a gas chamber filled with an inert gas, a mask is disposed on the inner surface of the panel in which the area of the hole formed in the portion corresponding to the center of the panel is minimal and the area of the hole increases toward the edge of the panel. And a sputtering step of attaching the blue phosphor material to the inner surface of the panel in a state where the blue phosphor material is ionized so as to discharge the material by applying a high voltage to the blue phosphor material to form a blue phosphor film. Is provided.

Hereinafter, the present invention will be described in more detail with reference to an embodiment shown in the accompanying drawings.

The color cathode ray tube according to the present invention is characterized in that the light intensity of blue is formed differently depending on the part of the panel. That is, in the entire plane of the panel displaying the image, the light intensity of blue appears relatively weak at the center portion, and the light intensity of blue appears relatively strong at the peripheral portion of the panel. In this way, when the color of the human eye is detected, the phenomenon in which the blue light is unnecessarily strongly incident on the central part of the eye with relatively few blue abstractions can be prevented, thereby preventing damage to the eyesight.

2 is an exploded perspective view showing the bulb of the color cathode ray tube in a separated state.

Referring to the drawings, the bulb of the color cathode ray tube includes a panel 21 and a funnel 22 bonded to the rear of the panel 21. The neck 23 is integrally formed in the funnel 22. The fluorescent film of the color cathode ray tube is formed on the inner surface of the panel 21. The symbol C shown in the figure indicates the center of the cathode ray tube panel, and the symbol P indicates the edge of the cathode ray tube panel.

According to the feature of the present invention, the light intensity of blue light emitted from the center C of the panel 21 is set weaker than the light intensity of blue light emitted from the edge P. For example, the light intensity of the blue color which becomes the minimum at the panel center C is set to correspond to about 80% of the light intensity of the blue color which becomes the maximum at the panel edge P, and the edge from the panel center C is set. Toward (P), the light intensity may be set to increase gradually or stepwise.

As such, setting the light intensity of blue differently for each part of the panel may be implemented in various ways. For example, the coating area is formed differently in applying the blue phosphor material to the inner surface of the panel. In other words, the inner surface center C of the panel 21 forms the smallest coating area of the blue fluorescent film, and increases the coating area of the blue fluorescent film toward the edge P of the panel 21.

It is possible to increase the coating area of the blue phosphor by extending the exposure time at the time of coating the phosphor than that of other red or green phosphors. The phosphor coating process is performed by applying a black matrix to the inner surface of the panel in a predetermined pattern as is known, followed by washing with pure water and applying an undercoating solution to expose the whole surface, and applying, drying, cleaning, Exposure and development operations are repeated for each phosphor. In this case, the exposure of the phosphor is performed by injecting light generated from a mercury lamp through a shadow mask, and the area of the blue phosphor may be enlarged if the time of exposing the blue phosphor is extended compared to the time of exposing the red phosphor or the green phosphor. Can be.

3A to 3C illustrate a process of forming the area of the blue phosphor differently for each part of the panel.

Referring to FIG. 3A, the exposure is performed with the mercury lamp 39 in a state where the shadow mask 32 is disposed on the panel 31. In this case, the exposure time is determined by using the shielding mask 33. Try to be different. For example, in FIG. 3A, the shielding mask 33 is formed so that only the center of the panel 31 is exposed, and the exposure time is set short. In addition, in FIG. 3B, the shielding mask 34 is formed so that exposure is performed only on the portion except for the center portion and the edge portion of the panel 31, and the exposure time is set longer than the exposure to the center portion. In FIG. 3C, the shielding mask 35 is formed so that only the edge part is exposed to light, and the exposure time is longer than that of other parts. As described with reference to FIGS. 3A to 3C, the exposure time may be set differently using a shielding mask capable of shielding a specific portion of the panel.

In another example, the blue phosphor exposure mask may be specially designed to form the size of the blue phosphor differently depending on the panel portion. That is, the size of the light transmitting hole of the mask for blue phosphor exposure is formed differently. For example, in the blue phosphor exposure mask, the size of the light transmitting hole in the center portion is formed relatively small, and the size of the peripheral portion is formed relatively large. Using such an exposure mask, the area of the blue phosphor is formed differently depending on the area even when the exposure operation is performed for the same time.

Another method is to form a fluorescent film using a sputtering method. This is done by placing a mask on the inner surface of the panel in a gas chamber filled with an inert gas and applying a high voltage to the material of the blue phosphor. This attaches the material of the blue phosphor to the inner surface of the panel in an ionized state to form a blue phosphor film. At this time, the hole formed in the sputtering mask disposed on the inner surface of the panel has a small area at the center of the panel, and the area should be formed as it reaches the edge of the panel.

Another method is to use different kinds of blue phosphors. That is, in the center of the panel, a blue phosphor having a relatively low light intensity during light emission is used, and a blue phosphor having a relatively high light intensity during light emission is used as the edge of the panel approaches. In this method, the area of the panel can be partitioned according to the distance from the center C, and different kinds of blue phosphors are respectively applied to the partitioned area. As mentioned above, the process of forming the blue fluorescent film is achieved by applying and drying the blue phosphor material, and exposing and developing the blue phosphor material. At this time, a blue phosphor material having a different light intensity for each part of the panel is selected, and coating, drying, exposure and development are repeatedly performed for each of the blue phosphor materials. Here, during exposure, a shielding mask as shown in FIGS. 3A to 3C is used.

4 is a flowchart showing the process in the case of using different blue phosphor materials.

Referring to the drawing, first, a first blue phosphor having a relatively weak light intensity is applied to the inner surface of the panel and dried (step 41). Next, the first portion is exposed (step 42), and the first portion corresponds to a central portion of the panel, whereby only the first portion may be exposed by using a shielding mask as shown in FIG. 3A. Therefore, only the first blue phosphor applied to the central portion of the panel is cured. Next, development and drying (step 43) are performed to remove the first phosphor material applied to portions other than the central portion. Then, a second blue phosphor having a relatively high light intensity is applied and dried again on the inner surface of the panel (step 44), and between the center portion and the edge using a shielding mask 34 as shown in FIG. 3B. When the second portion corresponding to the middle portion of the exposed (45), developed and dried (46), the second blue phosphor may be coated on the second portion. In the same manner, steps 47 to 49 can be applied to coat the third blue phosphor material having the highest light intensity on the third portion corresponding to the edge of the panel, so that the blue phosphor material of light intensity is applied to the inner surface of the panel. It may be formed for each site.

In another example, a similar effect can be obtained by adjusting the density of the blue electron beam of the electron gun. Among the electron beams generated from the electron gun and incident on each pixel of red, green, and blue, the intensity of the blue electron beam incident on the blue pixel is changed according to the incident position on the panel. For example, there is a method of changing the current of the red, green, and blue electron beams of the electron gun in the circuit section of the electron gun stage. At this time, if the output of the circuit portion is controlled in synchronization with the scan signal, the intensity of the blue electron beam varies depending on the position of the panel. That is, the output of the circuit portion corresponding to the blue electron beam of the edge of the panel, that is, the voltage of the blue cathode, is made into a larger negative voltage, and the output of the circuit portion, that is, the voltage of the blue cathode, is made smaller in the center of the panel. It is to be the voltage of.

In another example, the same effect can be obtained by changing the intensities of the green and red phosphors around the blue phosphor while maintaining the blue phosphor in the conventional method. In other words, green and red phosphors having strong light intensity are used at the center of the panel, and green and red phosphors having strong light intensity are used at the edge of the panel. This results in a weaker blue light intensity at the center of the panel and a stronger blue light intensity at the edge of the panel.

In the color cathode ray tube according to the present invention, since the light intensity of blue is differently emitted for each part of the panel, it is possible not only to reduce eye fatigue but also to prevent eye damage that may occur when viewing the color cathode ray tube for a long time. There is an advantage. In addition, the color's double opponency theory enables relatively improved yellow sensitivity, and yellow is generated by the action of the red and green abstractions, so the improvement of the yellow sensitivity is ultimately the green abstraction. It is possible to improve the relative sensitivity of, which means improving the brightness of the display.

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

Claims (9)

A panel having phosphor patterns of red, blue, and green formed on an inner surface thereof; A funnel sealed to the panel and having a neck portion and a cone portion formed thereon; An electron gun inserted into and installed in the neck portion of the funnel; A color cathode ray tube comprising: a deflection yoke installed outside the cone of the funnel; The area of the blue phosphor formed on the inner surface of the panel is enlarged from the center of the panel toward the edge of the panel formed color cathode ray tube, characterized in that formed. The light intensity of the blue phosphor according to claim 1, wherein the light intensity at the center of the panel corresponds to 80% of the maximum light intensity at the panel edge, and the light intensity is gradually or stepwise from the center of the panel to the edge of the panel. Color cathode ray tube, characterized in that the area of the blue phosphor is set to increase. A panel in which red, blue, and green phosphor patterns are formed on an inner surface thereof; A funnel sealed to the panel and having a neck portion and a cone portion formed thereon; An electron gun inserted into and inserted into the neck portion of the funnel; A color cathode ray tube comprising: a deflection yoke installed outside the cone of the funnel; And a blue phosphor formed on the inner surface of the panel is formed of different blue phosphor materials having different light intensities depending on the distance from the center of the panel. 4. The light intensity of the material of the blue phosphor formed at the center of the panel corresponds to 80% of the light intensity of the material of the blue phosphor formed at the edge of the panel, wherein the panel is from the center of the panel. A color cathode ray tube, characterized in that different blue phosphor materials are selected such that the light intensity gradually increases or gradually increases toward the edge of. A panel in which red, blue, and green phosphor patterns are formed on an inner surface thereof; A funnel sealed to the panel and having a neck portion and a cone portion formed thereon; An electron gun inserted into and inserted into the neck portion of the funnel; A color cathode ray tube comprising: a deflection yoke installed outside the cone of the funnel; The circuit part located in the previous stage of the electron gun is configured to vary the negative voltage applied to the blue electron beam cathode of the electron gun, and the intensity of the blue electron beam is increased by synchronizing the negative voltage change with the scanning signal of the deflection yoke. Color cathode ray tube, characterized in that the incident differently depending on the position of the panel. The light intensity of the blue phosphor emitted by the blue electron beam incident on the center portion of the panel is 80% of the light intensity of the blue phosphor emitted by the blue electron beam incident on the edge of the panel. And the intensity of the blue electron beam is gradually or gradually increased from the center of the panel to the edge of the panel. A method of forming a blue fluorescent film of a color cathode ray tube, comprising the step of providing a shadow mask on an inner surface of a panel to expose a blue phosphor material with an exposure light source. The exposing step sequentially arranges a plurality of shielding masks having respective exposed portions partitioned between the shadow mask and the light source for exposure according to a distance from the center of the inner surface of the panel, and at the center of the inner surface of the panel. The method of forming a blue fluorescent film of a color cathode ray tube, characterized in that the exposure is performed for a relatively short time in the adjacent section, and the exposure is performed for a relatively long time as it is separated from the center of the inner surface of the panel. A method of forming a blue fluorescent film of a color cathode ray tube, the method comprising: providing a shadow mask on an inner surface of a panel to expose a blue phosphor material with an exposure light source; The shadow mask has a small size of the light transmitting hole in the portion corresponding to the center of the panel, and the size of the light transmitting hole toward the edge of the panel increases the blue fluorescent film forming method of the color cathode ray tube. In a gas chamber filled with an inert gas, a mask is placed on the inner surface of the panel in which the area of the hole formed in the portion corresponding to the center of the panel is minimal and the area of the hole increases toward the edge of the panel, and the material of the blue phosphor And a sputtering step of attaching the material of the blue phosphor to an inner surface of the panel in a state of being ionized to form a blue phosphor film by discharging a high voltage at a high voltage to the blue phosphor film.

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