KR940002756B1 - Beam index type colour cathode-ray tube devices - Google Patents

Abstract

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Description

Beam index type color cathode ray tube device

1 and 2 are a partial cutaway plan view and a side view showing an entire example of a beam index type color cathode ray tube device according to the present invention.

3 is a cross-sectional view showing a part of the fluorescent surface thereof.

4 is a plan view showing the light receiving portion thereof.

5 is a plan view showing a light receiving portion considered in a reflective beam index type color cathode ray tube device.

Fig. 6 is a partially cutaway plan view showing the whole of an example of a beamdess type color cathode ray tube device that has been conventionally proposed.

7 is a plan view showing the light receiving portion thereof.

* Explanation of symbols for main parts of the drawings

10: color cathode ray tube 11: front panel

12 screen panel 14 fluorescent surface

21: light receiving plate 21x, 21y: first and second cross section

22,23: first and second light receiving elements

[Industrial use]

The present invention includes a flat color cathode ray tube having an opposite front panel and a screen panel, and a fluorescent surface having an index phosphor and a plurality of color fluorescent stripes each of a plurality of colors formed on an inner surface facing the front panel of the screen panel, A color image is shown through the front panel, and a light receiving plate that receives light transmitted from the index phosphor and transmitted through the screen panel and generates light having a wavelength is disposed along the fluorescent surface on the outer surface side of the screen panel. A light-receiving part comprising a light-receiving beam and a light-receiving element, in particular, a light-receiving beam index type color-cathode light-emitting device in which a light-receiving element for detecting light generated in the light-receiving plate is attached to the end face and the index light is detected outside the color-cathode line. It is about.

Overview of the Invention

The present invention provides a flat color cathode ray tube having an opposing front panel and a screen panel, and having a phosphor surface having an index phosphor and a plurality of color phosphor stripes each of a plurality of colors formed on an inner surface of the screen panel facing the front panel. A color image is shown through the front panel, and a light receiving plate that emits light of different wavelengths from light emitted from the index phosphor and transmitted through the screen panel is disposed along the fluorescent surface on the outer surface side of the screen panel. In a so-called reflective beam index type color cathode ray tube device in which a light receiving element for detecting light generated by the light receiving plate is provided and index light is detected outside the color cathode ray tube, the light receiving plate is placed on a screen of a fluorescent screen. It is opposite to each other in the left and right directions on the screen on one edge side in the vertical direction The first and second cross-sections toward the center portion of the fluorescent screen, respectively, to be inclined to each other, and the extension lines of one edge in the left-right direction and the other edge of the fluorescent screen of the first and second sections of the light receiving plate. By attaching the first and second light-receiving elements at positions near the phase of the image and synthesizing the outputs of these first and second light-receiving elements as an index signal, a substantially uniform high level in each part including the corner portion of the fluorescent surface The index signal of is obtained, and the switching of the primary color signal of each color which modulates the electron beam according to the position with respect to the color phosphor stripe of each color of the electron beam on the fluorescent surface based on the index signal in each part of the screen is performed. In addition to being accurate and stable, the excitation phosphors are excited to reduce the dark beam current to obtain the required level of index signal. The black level of the image can be lowered and a high quality image with high contrast can be obtained.

[Prior art]

A type of beam index type color cathode ray tube device, in which a front panel and a screen panel facing each other are provided, and a flat color having a fluorescent surface having an index phosphor and a plurality of color phosphor stripes each of a plurality of colors formed on an inner surface of the screen panel facing the front panel. A light receiving plate having a cathode ray tube, which allows a color image to be seen through the front panel, and receives light transmitted through the screen panel from the index phosphor on the outer surface side of the screen panel and generates light having a different wavelength, is a fluorescent surface. It is known to be called a reflection type, which is disposed along the surface of the light receiving plate, and is provided with a light receiving element that detects light emitted from the light receiving plate, and the index light is detected outside the color cathode ray tube.

6 shows a reflection type beam index type color cathode ray tube device that has been proposed in the related art, which is composed of a color cathode ray tube 10 and a light receiving portion which are provided on the outside.

The color cathode ray 10 is a tubular body formed flat with an opposing front panel 11 and a screen panel 12 and a neck portion 13 connected to the front panel 11 and the screen panel 12. A fluorescent surface 14 having a rectangular shape as a whole having a plurality of index phosphor stripes and a plurality of color phosphor stripes of red, green, and blue on the inner surface of the screen panel 12 facing the front panel 11, respectively. Is formed, and the electron gun structure 15 is embedded in the neck portion 13, and the fluorescent surface 14 is scanned by the electron beam emitted from the electron gun structure 15.

However, the front panel 11 transmits color light generated from the color phosphor stripe, and the screen panel 12 transmits index light over the ultraviolet region generated from the index phosphor stripe. Further, no color phosphor stripe is formed in the horizontal scanning initiation portion 14S of the fluorescent surface 14, but only an index phosphor stripe is formed.

The light-receiving portion has a light-receiving plate 41 which forms a quadrangle as a whole disposed along the fluorescent screen 14 on the outer surface side of the screen panel 12, and the upper and lower sides of the fluorescent screen 14 on the screen (in FIG. 6). A light receiving element 42 such as one photodiode is provided in the center of the end face 41Z parallel to the left and right directions on the screen on one side of the edge 14Z on the left side.

The light receiving plate 41 is excited by the index light generated from the index phosphor stripe of the fluorescent surface 14, and the specific fluorescent substance in which the light receiving element 42 generates secondary index light of different wavelengths providing high sensitivity. It is formed of this dispersedly mixed acrylic resin plate, receives index light generated from the index phosphor stripe of the fluorescent surface 14 and transmitted through the screen panel 12, and generates secondary index light according to the received index light. The light receiving element 42 detects secondary index light generated by this light receiving plate 41.

In such a beam index type color cathode ray tube apparatus, when the fluorescent surface 14 is scanned by the electron beam emitted from the electron gun structure 15, index light is generated from the index fluorescent stripe of the fluorescent surface 14, and the index light is Secondary index light is generated at the position where the index light of the light receiving plate 41 is incident to the light receiving plate 41 through the screen panel 12 and enters the light receiving plate 41. Light is detected by the light receiving element 42, so that an index signal is obtained from the light receiving element 42.

The index signal thus obtained detects the positions of the red, green, and blue color phosphor stripes of the electron beam on the fluorescent surface 14, and the electron beams correspond to the red, green, and blue primary color signals corresponding to the positions. Electron beams that are density modulated by the primary, red, green, and blue primary color signals are incident on the red, green, and blue color phosphor stripes, and are densely modulated from the red, green, and blue color phosphor stripes. Color light of red, green, and blue of intensity corresponding to the density of the light is generated, and the color light is transmitted through the front panel 11, and a color image is displayed through the front panel 11.

[Problem to Solve Invention]

By the way, light-receiving elements, such as a photodiode, have the directivity different from detection sensitivity according to the incident angle of incident light, and the detection sensitivity becomes low, so that an incident angle is large.

The light receiving portion of the reflective beam index type color cathode ray tube device proposed in the related art is formed in a rectangle corresponding to the fluorescent surface 14, as shown in FIG. Since the light receiving element 42 is provided at the center of the end surface 41Z parallel to the left and right direction on the screen on the upper edge 14Z side of the upper side of the screen, the secondary index in the light receiving plate 41 is provided. The incident angle of the secondary index light into the light receiving element 42, and thus the detection sensitivity of the light receiving element 42, varies greatly depending on the position where light is generated, and thus the position where the index light is generated on the fluorescent surface 14.

In particular, in the corners of the upper left and right upper portions of the fluorescent screen 14, the incident angle of the secondary index light to the light receiving element 42 is significantly increased, and the detection sensitivity of the light receiving element 42 is significantly lowered. Furthermore, even if the beam currents are the same, the diameter of the beam spot becomes large at the corners of the fluorescent surface 14, so that the amount of beam received by the index phosphor stripe is reduced, and thus the amount of index light generated from the index phosphor stripe, and thus the light receiving plate 41, The amount of secondary index light generated is reduced.

For this reason, in the reflection type beam index type color cathode ray device proposed conventionally, the level of the index signal in each part of the fluorescent screen 14 is largely changed, especially the upper left and right images on the screen of the fluorescent screen 14. In the corners of the index signal, the level of the index signal is relatively low, the dark beam current that excites the index phosphor strip is small, and when the absolute value of the lowest level of the index signal is low, particularly at the top of the screen, a fluorescent surface based on the index signal. The change of the primary color signal of each color which densely modulates the electron beam corresponding to the position with respect to the color phosphor stripe of each color of the electron beam on (14) causes a disadvantage that it is not accurate and stable.

In addition, in order to avoid this disadvantage, increasing the dark beam current that excites the index phosphor strip and increasing the absolute value of the lowest level of the index signal results in a disadvantage that the image level rises and the contrast of the image decreases.

Therefore, in order to avoid the above-mentioned disadvantage in the conventionally proposed beam index type color cathode ray tube apparatus shown in FIG. 6 (FIG. 7), as shown in FIG. 5, the light receiving plate 14 has a fluorescent surface. Although formed in a rectangle corresponding to (14), the positions of two left and right positions of the cross section 41Z parallel to the left and right directions on the screen on the upper edge 14Z side of the fluorescent screen 14 on the screen It is conceivable to provide two receiving elements 43 and 44 in the arrangement, and to combine the outputs of these two photoreceptors 43 and 44 as index signals.

According to such a structure, it is generated from the part corresponding to the upper left corner part in the screen of the light receiving plate 41 by the index light which generate | occur | produced from the upper left corner part in the screen of the fluorescent screen 14, and the light receiving element 43 Corner portion of the upper right image on the screen of the light receiving plate 41 due to the incident angle of the secondary index light incident on the light receiving element 43 and the index light generated from the corner portion of the upper right corner on the screen of the fluorescent screen 14 The incident angle to the light-receiving element 44 of the secondary index light incident on the light-receiving element 44, which is generated from the portion corresponding to, is in the conventionally proposed beam index type color cathode ray tube device shown in FIG. 6 (FIG. 7). Generated from the corners of the upper left and right corners on the screen of the fluorescent screen 14 in the display and generated from the portions corresponding to the corners of the upper left and right corners of the screen of the light receiving plate 41 by the index light. W becomes smaller than the angle of incidence to the second index of light the light-receiving element 42 is incident on the light-receiving element (42).

Also, FIG. 6 differs depending on the generation position of the secondary index light in the light receiving plate 41 of the incident angle of the secondary index light into the light receiving element 43 or 44, and thus the generation position of the index light in the fluorescent surface 14. FIG. The incident angle to the light receiving element 42 of the secondary index light in the conventionally proposed beam index type color cathode ray tube device shown in (7) is smaller than that.

Therefore, the lowest level of the index signal is higher than in the case of the conventionally proposed beam index type color cathode ray tube apparatus shown in FIG. 6 (FIG. 7), and the index signal in each part of the fluorescent surface 14 of the index signal is high. The level difference is smaller than that of the conventionally proposed beam index type color cathode ray tube apparatus shown in FIG. 6 (FIG. 7).

However, even when the light receiving portion is configured as shown in FIG. 5, the diameter of the beam spot becomes large, and the amount of index light generated from the index phosphor stripe, and therefore, the amount of secondary index light generated from the light receiving plate 41 is small. The incident angle of the secondary index light to the light receiving element 43 or 44 becomes larger at the corners of the upper left and right sides on the screen of the fluorescent surface 41, and the light receiving plate to the light receiving element 43 or 44 of the secondary index light ( The difference according to the generation position of the secondary index light in 41) and hence the generation position of the index light in the fluorescent surface 14 is further larger.

Therefore, the lowest level of the index signal is lower, and the difference of the level in each part of the fluorescent surface 14 of the index signal is larger. Therefore, even if the light receiving portion is configured as shown in FIG. 5, the above-described disadvantages in the conventionally proposed beam index type color cathode ray tube apparatus shown in FIG. 6 (FIG. 7) cannot be reliably avoided.

In view of such a point, the present invention obtains an almost uniform high level index signal in each part including the corner portion of the fluorescent screen, and adapts the electron beam on the fluorescent surface based on the index signal in each part of the screen. Switching of the primary color signal of each color which densely modulates the electron beam in correspondence with the position of the color phosphor stripe of is performed accurately and stably, while reducing the dark beam current that excites the index phosphor to obtain the index signal of the required level. It is possible to reduce the lump level of the image and to obtain a high quality image with high contrast.

[Means to solve the problem]

In the present invention, there is provided a flat color cathode ray tube which is provided with an opposing front panel and a screen panel, and has a phosphor surface having an index phosphor and a plurality of color phosphor stripes each of a plurality of colors formed on an inner surface of the screen panel facing the front panel. At the same time as the color image is shown through the front panel, a light receiving plate which receives light transmitted from the index phosphor and passes through the screen panel and generates light of different wavelengths is disposed along the fluorescent surface on the outer surface side of the screen panel. In a so-called reflective beam index type color cathode ray tube device in which a light receiving element for detecting light generated in the light receiving plate is provided on the end face of the light plate, and the index light is detected outside the color cathode ray tube, On one edge side of the up-down direction in the screen, in the left-right direction in the screen The first and second cross sections are inclined in the opposite directions to each other toward the center portion of the fluorescent screen, respectively, and the one end edge and the other end edge in the left and right directions on the screen of the fluorescent screen of the first and second end faces of the light receiving plate, respectively. The first and second light receiving elements are provided at positions near the extension line of the line, and the outputs of the first and second light receiving elements are synthesized as index signals.

[Action]

In the beam index type color cathode ray tube device according to the present invention configured as described above, the diameter of the beam spot is increased, and the amount of index light generated from the index phosphor and incident on the light receiving plate, and thus the amount of secondary index light generated from the light receiving plate, is increased. Also in the corner portion of the screen of the fluorescent surface to be reduced, the incident angle of the secondary index light to the first or second light receiving element is sufficiently small, and to the light receiving plate of the incident angle of the secondary index light to the first or second light receiving element. Since the difference due to the position where the secondary index light is generated, and thus the position where the index light is generated on the fluorescent screen, becomes significantly smaller, the minimum level of the index signal is sufficiently high, and the difference of the level on each part of the fluorescent surface of the index signal is Significantly smaller.

Therefore, in each part of the screen, the switching of the primary color signal of each color which densely modulates the electron beam is made stable and corresponding to the position of the fluorescent stripe of each color of the electron beam on the fluorescent surface based on the index signal. . In addition, since the minimum level of the index signal is sufficiently high, it is possible to reduce the lump level of the image by reducing the dark beam current that excites the index phosphor to obtain the index signal of the required level, thereby obtaining a high quality image with high contrast. have.

EXAMPLE

1 and 2 show the entire example of the beam index type color cathode ray tube apparatus according to the present invention, FIG. 3 shows a fluorescent screen, and FIG. 4 shows a light receiving unit.

The beam index type color cathode ray tube device according to the present invention is also roughly composed of a color cathode ray tube 10 and a light receiving portion provided outside thereof.

The color cathode ray tube 10 has a tubular body formed flat with an opposing front panel 11 and a screen panel 12 and a neck portion 13 connected to the front panel 11 and the screen panel 12. do.

The front panel 11 has a rectangular shape that transmits color light, and the screen panel 12 has a slight curvature while forming a rectangular shape corresponding to the front panel 11 which transmits index light, which will be described later. On the inner surface facing the front panel 11 of the screen panel 12, a fluorescent surface 14 that is curved along the screen panel 12 and forms a quadrangle as a whole is formed.

The neck portion 13 includes an electron gun structure 15, and the fluorescent surface 14 is scanned by an electron beam emitted from the electron gun structure 15. Since the fluorescent screen 14 is curved along the screen panel 12, when the fluorescent screen 14 is scanned by the electron beam, the incident angle of the electron beam does not greatly differ in each part of the fluorescent screen 14. .

The fluorescent surface 14 is provided with an index phosphor and a plurality of color phosphor stripes of red, green, and blue, respectively. However, the index phosphor need not necessarily be formed as a plurality of stripes.

For example, as shown in FIG. 3, on the inner surface of the screen panel 12, a light shielding layer 31 made of carbon or aluminum oxide (A1 ₂ O ₃ ) is formed in a stripe shape at a predetermined interval. The index phosphor layer 32 is formed over the portion between the light shield layer 31 and the light shield layer 31 on the inner surface of the screen panel 12, and deposition of aluminum, for example, on the index phosphor layer 32. Metal reflective film 33 is formed, and a plurality of red, green, and blue color phosphor stripes R, G, and B are formed in a predetermined array pattern on a portion of the metal reflective film 33 on the light shielding layer 31. In this way, the fluorescent surface 14 is formed. However, red, green, and blue color phosphor stripes R, G, and B are not formed in the horizontal scanning start section 14S of the fluorescent surface 14.

The light receiving plate 21 that is curved along the screen panel 12, that is, along the fluorescent screen 14, is disposed on the outer surface side of the screen panel 12 of the color cathode ray tube 10. Although this light receiving plate 21 is a substantially quadrangular shape as a whole, as shown in Fig. 4, one edge in the up-down direction on the screen of the fluorescent screen 14, for example, the upper side of the screen (see Fig. 1). The shape which has the 1st end surface 21x and the 2nd end surface 21y which inclined in the opposite direction with respect to the left-right direction in a screen, respectively, and toward the center part side of the fluorescent screen 14 on one edge 14Z side of the left side in the left side). It is done.

Then, on the screen of the fluorescent screen 14 of the first end surface 21x and the second end surface 21y of the light receiving plate 21, one edge 14x in the left and right direction and the other end edge 14y are in line with each other. The first light receiving element 22 and the second light receiving element 23 such as a photodiode are respectively provided at positions slightly inward from the position near the position, for example, the position on the extension line.

The light receiving plate 21 is excited by the index light over the ultraviolet region generated from the index phosphor layer 32 of the fluorescent surface 14 so that the second index light of different wavelengths at which the light receiving elements 22 and 23 provide high sensitivity. The index light is formed of a transparent polymer, for example, an acrylic resin plate in which a specific fluorescent substance which generates light is dispersed and mixed, and is generated from the index phosphor layer 32 of the fluorescent surface 14 and transmitted through the screen panel 12. In response to the received index light, a secondary index light is generated. The light receiving elements 22 and 23 detect the secondary index light generated by the light receiving plate 21, and the output of the light receiving elements 22 and 23 is synthesized as an index signal.

In addition, a cross section other than the mounting surfaces of the light receiving elements 22 and 23 of the light receiving plate 21 and the surfaces on the side opposite to the side of the index light are covered with, for example, an aluminum deposition film, and the light receiving plate 21 has a peripheral edge thereof. In, for example, it is provided on the outer surface of the screen panel 12 by a double-sided adhesive tape. Moreover, the light receiving elements 22 and 23 are provided in the above-mentioned position of the light receiving plate 21, for example by the adhesive which let light pass.

Hereinafter will be described the operation and effect of the present invention having the configuration as described above.

When scanned with respect to the electron beam emitted from the electron gun structure 15 of the fluorescent surface 14 under the same constitution as described above, the index phosphor layer 32 is excited by the electron beam passing through the metal reflective film 33 and the index phosphor layer Although light is emitted from the light emitting layer 32, light generated from the portion on the light shielding layer 31 of the index phosphor layer 32 is blocked by the light shielding layer 31, and the light shielding layer 31 of the index phosphor layer 32 is blocked. Only the light generated from the portion 32i therebetween passes through the screen panel 12 as index light and enters the light receiving plate 21, and the index light of the light receiving plate 21 enters in response to the incident index light. Secondary index light is generated at the position, and the secondary index light is detected by the light receiving elements 22 and 23, so that an index signal is obtained.

The position of the red, green, and blue color phosphor stripes R, G, and B of the electron beam on the fluorescent surface 14 is detected by the obtained index signal, and the electron beam is red and green corresponding to the position. The electron beams, which are densely modulated by the blue primary color signal and densely modulated by the red, green and blue primary color signals, enter the red, green and blue color phosphor stripes R, G, and B, and the color phosphor stripe R Red, green, and blue color light of intensity corresponding to the density of the electron beams density-modulated from G, B are generated, and the color light is transmitted through the front panel 11 so that a color image can be seen through the front panel 11. do.

In this case, the index light generated from the upper left corner of the fluorescent screen 14 is generated from a portion corresponding to the upper left corner of the screen of the light receiving plate 21 to the light receiving element 22. The incident angle of the incident secondary index light to the light receiving element 22 and the index light generated from the corner portion of the upper right corner of the fluorescent screen 14 correspond to the corner portion of the upper right corner of the screen of the light receiving plate 21. The incident angle of the secondary index light incident on the light receiving element 23 to the light receiving element 23, which is generated from the portion of the light emitting element 23, is the conventionally proposed beam index type color cathode ray tube device shown in Fig. 6 (Fig. 7). The light-receiving element 42 is generated from a portion corresponding to the upper left and right corners of the screen of the light receiving plate 41 by the index light generated from the upper left and right corners of the fluorescent screen 14. Compared with the incident angle to the light-receiving element 42 of the secondary index light incident on the light source, it is significantly smaller.

Therefore, FIG. 6 differs depending on the generation position of the secondary index light in the light receiving plate 21 of the incident angles of the secondary index light into the light receiving elements 22 and 23, and thus the generation position of the index light in the fluorescent surface 14. FIG. The incident angle to the light-receiving element 42 of the secondary index light in the conventionally proposed beam index type color cathode ray tube device shown in FIG. 7 is significantly smaller than that. As a result, the lowest level of the index signal is significantly higher than that of the conventionally proposed beam index type color cathode ray tube apparatus shown in FIG. 6 (FIG. 7). The level difference is significantly smaller than that of the conventionally proposed beam index type color cathode ray tube apparatus shown in FIG. 6 (FIG. 7).

When the color cathode ray tube 10 is 4 inches, the light receiving portion is configured as shown in FIGS. 7, 5, and 4, and the highest and lowest levels of the index signal are actually measured. In the case of the configuration as shown in FIG. 7, the highest level is 100 and the minimum level is 7, and in the case where the light receiving unit is configured as shown in FIG. 5, the highest level is 92 and the minimum level is 40. In the case of the configuration as shown in Fig. 4, it was confirmed that the highest level was 86 and the minimum level was 78. However, the level here is a relative value when the maximum level in the case where the light receiving unit is configured as shown in FIG.

As described above, in the beam index type color cathode ray tube device according to the present invention, an index signal of a substantially uniform high level is obtained in each portion including the corner portion of the fluorescent surface 14, so that the index signal in each portion of the screen is obtained. Of red, green, and blue primary color signals that density-modulate the electron beam corresponding to the positions of the red, green, and blue color phosphor stripes R, G, and B of the electron beam on the fluorescent surface 14 It is done accurately and stably. In addition, since the lowest level of the index signal is sufficiently high, the index phosphor layer 32 is excited to reduce the dark beam current for obtaining the index signal of the required level, thereby reducing the lump level of the image, and having high contrast. The image of can be obtained.

[Effects of the Invention]

According to the beam index type color cathode ray tube device according to the present invention, the diameter of the beam spot is increased, and the amount of index light generated from the index phosphor and incident on the light receiving plate is reduced, thus reducing the amount of secondary index light generated in the light receiving plate. In the corner portion of the screen of the fluorescent screen, the incident angle is sufficiently small in the first or second light receiving element of the secondary index light, and in the light receiving plate of the incident angle of the secondary index light in the first or second light receiving element. Since the difference due to the position where the secondary index light is generated, and thus the position where the index light is generated on the fluorescent surface, becomes significantly smaller, the lowest level of the index signal is sufficiently high, and the difference of the level on each part of the fluorescent surface of the index signal is significantly different. Becomes small.

Therefore, in each part of the screen, the switching of the primary color signal of each color which densely modulates the electron beam in accordance with the position of the color phosphor strip of each color of the electron beam on the fluorescent surface based on the index signal is performed accurately and stably. Lose. In addition, since the minimum level of the index signal is sufficiently high, it is possible to reduce the lump level of the image by reducing the dark beam current that excites the index phosphor to obtain the index signal of the required level, thereby obtaining a high quality image with high contrast. .

Claims (5)

And a plurality of color phosphor stripes (G, R, B) having an index phosphor (32) on the inner surface facing the front panel (11) and allowing color light to pass therethrough. A color cathode ray tube (10) having a screen panel (12) having a square fluorescent surface (14); A light receiving plate 21 arranged to face the outer surface of the screen panel 12 so as to receive index light from the index phosphor 32 and generate secondary index light corresponding to the incident index light; In the beam index type color cathode ray tube device including light receiving elements 22 and 23 configured to detect the secondary index light generated by the light receiving plate 21, the light receiving plate 21 has upper and lower sides of the fluorescent surface, respectively. It is formed to have inclined first and second end surfaces 21x and 21y positioned adjacent to each corner portion of the fluorescent surface 14 including one end portion in the direction; The light receiving elements 22 and 23 are attached to the inclined first end surface 21x and inclined with the first light receiving element 22 positioned near the extension line position of the left edge 14x of the fluorescent surface 14. A beam index type color cathode ray tube device, characterized in that it comprises a second light receiving element (23) attached to the second end face (21y) and located in the vicinity of the extension line position of the right edge (14y) of the fluorescent surface (14). The beam according to claim 1, wherein the light receiving plate (21) is rectangular and extends to cover the fluorescent surface (14) by the screen panel (12) between the light receiving plate (21) and the fluorescent surface (14). Indexed color cathode ray tube device. 3. The light receiving plate (21) according to claim 1 or 2, wherein the light receiving plate (21) is formed of a plastic material having fluorescent materials dispersed therein, and the fluorescent materials are applied to the index light from the index phosphor layer (32) of the fluorescent surface (14). Irradiated to generate secondary index light, wherein the beam index type color cathode ray tube device is characterized by the above-mentioned. The beam-indexed collar according to claim 1 or 2, wherein the first and second light receiving elements (22, 23) are attached to the first and second end surfaces (21x, 21y) by a transparent adhesive, respectively. Cathode ray tube device. The light receiving plate 21 has a metal reflective layer covering portion except for the first and second end surfaces 21x21y to which the first and second light receiving elements 22 and 23 are respectively attached. Beam index type color cathode ray tube device, characterized in that.

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