JPS6313299B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to the structure of a phosphor screen of a black matrix color picture tube.

In recent years, a black matrix system has been generally adopted as a useful method for increasing the image contrast of color picture tubes. This black matrix color picture tube has a black light absorber layer in the boundary area of the three primary color phosphor layers, which does not directly contribute to light emission, so that external light incident on the color picture tube is absorbed by the phosphor screen. The objective is to reduce the reflectance of light when it is reflected, to minimize the amount of external light that enters the viewer's eyes, and to increase the contrast of images when the color picture tube is in operation.

The image contrast of a black matrix color picture tube will now be explained with reference to the sectional view of the phosphor screen shown in FIG. In the same figure,
1 is a face plate, and a black light absorbing layer 2 is formed on the inner surface thereof. This black light absorber layer 2 is provided with an aperture 4, and a phosphor layer 3 is aligned and arranged in the aperture 4.
The intensity of external light a that enters the face plate 1 of the color picture tube configured in this way is E 0 , and the intensity of the reflected light b that is emitted to the outside of the face plate 1 again after being reflected by the phosphor screen is E ₀ . is E ₁ , the light transmittance of the face plate 1 is T ₁ , the aperture ratio of the aperture 4 formed in the black light absorber layer 2 is T ₂ , the light reflectance of the phosphor layer 3 is R ₁ , black The light reflectance of the light absorber layer 2 is R ₂ , the intensity of the light emission f of the phosphor layer 3 is F ₀ ,
If the _light emission output from the phosphor screen emitted to the outside of the face plate 1 is _F1 , then _E1 = _E0・_T12・^T2・_R1 + _E0 ^・ _T12 (1− _T2 )・
R ₂ …() F ₁ =F ₀・T ₂・T ₁ …(). Assuming that the light reflectance R ₂ of the black light absorber layer 2 is sufficiently smaller than the light reflectance R ₁ of the phosphor layer 3, from equation (), E ₁ ≒E ₀・T ₁ ²・T ₂・R ₁ …() becomes.

Also, the image contrast c can be defined as C=E ₁ +F ₁ /E ₁ ...(), so by substituting equations () and () into equation (), we get C=1+F ₀ /E ₀・T ₁・R ₁ …() becomes. Strictly speaking, face plate 1
Various factors such as reflection of external light on the surface of the face plate 1, multiple reflections within the face plate 1, and halation caused by scattered electrons must also be introduced.
Here, these effects are ignored as they are sufficiently small. Further, the aperture ratio _T2 of the apertures 4 formed in the black light absorber layer 2 is usually not uniform over the entire surface of the face plate 1, and as shown in FIG. It is large at the center of the plate 1 and becomes smaller toward the periphery. This is indispensable in order to obtain a margin for matching the electron beam to the phosphor layer 3 during operation of this type of color picture tube. Generally, the value of the aperture ratio is often selected to be in the range of 40 to 80% at the center of the face plate 1 and 30 to 70% at the periphery. One of the quality problems of such a black matrix color picture tube is the difference in light output between the center and peripheral parts of the face plate 1. This is formed in the black light absorber layer 2 in order to obtain a degree of alignment between the electron beam and the phosphor layer 3, as described above, and reduces the aperture ratio of the aperture 4 at the periphery of the face plate 1. If the light output in the peripheral area of the face plate 1 is much smaller than that in the center, depending on the type of image, it may give a sense of discomfort to the viewer. . In addition, this problem occurs due to the same cause, but when the color picture tube is not in operation, the appearance of the face plate 1 looks much darker at the periphery than at the center, and in extreme cases In some cases, it may even look like a so-called ring-shaped "unevenness." On the other hand, in order to improve the contrast performance of images in a black matrix color picture tube, it is possible to reduce the light transmittance T ₁ of the face plate 1, as can be seen from the equation () expressing the contrast described above. it is obvious. In a normal black matrix color picture tube, a face plate 1 with a light transmittance of about 85% is normally used, but for the purpose of improving image contrast, a light transmittance of about 60% is used. When a black matrix type color picture tube was evaluated using the face plate 1 having the same ratio, it was possible to achieve a significant improvement in image contrast. However, due to the low light transmittance of the face plate 1, the light output at the periphery of the face plate 1 becomes too small when viewing an image.
Two major quality problems have occurred: it gives a strong sense of discomfort to the viewer, and the appearance of the face plate 1 when the color picture tube is not in operation looks extremely black around the face plate. Ta.

This invention inevitably arises in order to solve the quality problems of conventional black matrix color picture tubes and to improve the image contrast performance of conventional black matrix color picture tubes. To provide a color picture tube which is not only superior in quality to conventional black matrix type color picture tubes but also has sufficiently improved image contrast performance. With the goal.

An embodiment of the present invention will be described below with reference to FIGS. 3 and 4.
This will be explained in detail with reference to the drawings. First, as shown in FIG. 3, a glass panel 5 including a face plate 1 is
After thoroughly cleaning the inner surface, the vacuum evaporator 6
is set to 7 is an evaporation source, which is filled with metals such as chromium (Cr) and nichrome (NiCr). Evaporation source 7 and face plate 1
A vapor deposition pattern 8 that determines the film thickness distribution of the metal vapor-deposited thin film formed on the inner surface of the face plate 1 is provided between the face plate 1 and the surface plate 1 . With this configuration, when vacuum evaporation is performed using metal vapor from the evaporation source 7, the face plate 1 of the glass panel 5 is
A vapor-deposited metal film 9 having a desired thickness distribution, that is, a light transmittance distribution, is formed on the inner surface. Cr and
Vapor-deposited thin films of metals such as NiCr exhibit flat spectral transmittance over a wide wavelength range, so the light transmittance does not depend on light of a specific wavelength or color.
Since it is almost gray, it does not adversely affect the color of the emitted light during operation of the color picture tube. Curve a in FIG. 4 shows the characteristics of the light transmittance distribution from the center to the periphery of the face plate 1 of the glass panel 5 on which the vapor-deposited thin film 9 has been formed on the inner surface in this manner. It is something. The face plate of a conventional black matrix color picture tube had a uniform light transmittance of 85% from the center to the periphery, as shown by straight line b in the figure. On the other hand, the face plate 1 of the black matrix color picture tube according to the present invention has a thickness distribution of the vapor-deposited thin film 9 formed on the inner surface of the face plate 1 as shown by curve a in the figure. The light transmittance is set so that the central part has a light transmittance of 60%, and the light transmittance gradually increases toward the periphery, reaching 85% light transmittance at the periphery. There is.

When a black matrix color picture tube is manufactured using such a face plate 1 with the other configurations being exactly the same as conventional ones, the light transmittance at the center of the face plate 1 becomes much smaller than that of the conventional one. Therefore, the image contrast is greatly improved. In addition, there is a strong sense of discomfort experienced by video viewers due to the difference in light output between the center and peripheral parts of the face plate 1, which has been a quality problem with black matrix color picture tubes, and color picture tubes. The problem of the face plate appearing darker at the periphery than at the center when the face plate is not in operation is also greatly alleviated.

In the above embodiment, the vapor deposited thin film 9 was formed on the inner surface of the face plate 1, but it goes without saying that similar effects can be obtained by forming a similar vapor deposited thin film on the outer surface of the face plate. Moreover, the same effect can be obtained even if the black light absorber layer 2 is formed in advance and then the vapor-deposited thin film is formed.

As described above, according to the present invention, it is possible to improve the contrast of an image in a black matrix color picture tube, to reduce the difference in light output between the central part and the peripheral part of the face plate, and to improve the image contrast when the color picture tube is not in operation. To provide a black matrix type color picture tube which is capable of alleviating the appearance phenomenon in which the peripheral part of the face plate looks darker than the central part, and which is of extremely high quality compared to the conventional one. Can be done.

[Brief explanation of the drawing]

Figure 1 is a cross-sectional view of the phosphor screen in a black matrix color picture tube, and Figure 2 shows the openings formed in the black light absorbing layer provided on the inner surface of the face plate of this picture tube. A characteristic diagram showing the porosity distribution, Figure 3 is a schematic cross-sectional view showing the method of vacuum evaporation to give the face plate the desired light transmittance distribution, and Figure 4 shows the light transmittance distribution of the face plate. It is a characteristic diagram shown by comparison with a conventional example. DESCRIPTION OF SYMBOLS 1... Face plate, 2... Black light absorber layer, 3... Phosphor layer, 4... Opening part, 9... Vapor deposited thin film.

Claims (1)

[Claims] 1. A face plate with a vapor-deposited thin film on its inner or outer surface whose light transmittance gradually increases from the center toward the periphery; and It is characterized by having a black light absorber layer having apertures that gradually become smaller toward the periphery, and a phosphor screen structure provided in the apertures of the black light absorber layer. Black matrix color picture tube.