JPH09320498A - Color picture tube device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To form the picture indicated over the screen so as not to be cut in by each boundary between adjacent areas in the color picture tube the integrated screen of which is divided into plural areas so as to be scanned. SOLUTION: Each strip-shaped fluorescent substance layer B, G and R and each beam absorbing layer 4 are formed in parallel, a screen part 14 on which index signal fluorescent layers 2 are formed, is formed in a place where the beam absorbing layers are piled up over the aforesaid fluorescent substance layers, and the screen part is divided into plural areas so as to be scanned. In this case, a plurality of the areas of the fluorescent substance layers in the parallel direction, are turned out to be each boundary 1 to the adjacent area of the selected beam absorbing layer, and each index signal fluorescent substance layer is thereby formed while each position overlapped with each beam absorbing layer to be turned out its boundary, is being avoided.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an index type color picture tube apparatus, and more particularly to a color picture tube apparatus which divides a screen portion into a plurality of areas for scanning.

[0002]

2. Description of the Related Art Conventionally, a picture tube apparatus for arranging a plurality of independent small picture tubes to form a large screen with high resolution has been disclosed in Japanese Patent Laid-Open Nos. 48-90428 and 49-21.
No. 019, Japanese Utility Model Publication No. 53-117130, and the like. This type of picture tube device is effective when constructing a huge screen with a large number of divisions that is arranged outdoors, but when constructing a medium-sized display screen with a screen size of about 40 inches, The joints of the images displayed in the area are conspicuous and the screen becomes a strange screen. Therefore, especially when it is used as a television receiver for home use or a terminal device for graphic display of computer-aided design (CAD), the appearance of a joint on the screen is a fatal defect.

As a solution to the problems of the picture tube device, US Pat. No. 3,071,706,
Japanese Utility Model Publication No. 39-25641, Japanese Patent Publication No. 42-4928.
Japanese Patent Laid-Open No. 50-17167 and Japanese Patent Laid-Open No. 50-17167 propose a multi-neck type picture tube device in which a plurality of independent picture tube screens are integrated. This multi-neck type picture tube device can eliminate the seams of images when a plurality of independent small picture tubes are arranged, and can form a screen that is considerably easy to see. However, in this picture tube device, since the areas to be divided and scanned are located very close to each other, a slight difference between images in adjacent areas becomes conspicuous.

On the other hand, color picture tube devices require color selection. Therefore, Japanese Patent Application No. 4-169005
In the specification and Japanese Patent Application No. 5-168262,
As a color selection electrode, a multi-neck type color picture tube device using a shadow mask is shown. However, when a shadow mask is used, due to mechanical misalignment between the shadow mask and the screen portion, mislanding occurs in which the electron beam passing through the electron beam passage hole of the shadow mask does not collide correctly with the phosphor layer of the screen portion. There's a problem.

As a picture tube apparatus which solves the problems of the multi-neck type color picture tube apparatus using this shadow mask, Japanese Patent Publication No. 4-53067 discloses an index phosphor layer provided on the screen portion of the index phosphor layer. There is disclosed a multi-neck type color picture tube device (index type color picture tube device) that does not use a shadow mask for controlling a signal to an electron beam by feeding back signal light obtained from a phosphor layer.

According to this index type color picture tube device, it is possible to solve the mislanding of the multi-neck type color picture tube device using the shadow mask. However, in this index type color picture tube device, as shown in FIG. 6, an index phosphor layer 2 is provided up to a boundary 1 of a region which is divided and scanned by electron beams emitted from a plurality of electron guns. Therefore, when this color picture tube device is actually operated, it is difficult to clarify the boundary 1 thereof, that is, to accurately control the joints of the images displayed in the adjacent areas, and it is difficult to control the screen portion. There is a problem that the displayed image is divided at the boundary of each area.

In FIG. 6, B, G, and R are three-color phosphor layers that emit blue, green, and red, respectively, and 4 is its three.
The light absorption layers 5 provided between the color phosphor layers B, G and R are
The aluminum film, 6 is an arrow indicating the scanning direction.

[0008]

As described above, in the multi-neck type color picture tube device having the integrated screen portion, the screen portion is provided with the index phosphor layer, and the index phosphor layer is provided. The index method of controlling the signal to the electron beam by feeding back the signal light obtained from the above is effective. However, in this index type color picture tube device, since the index phosphor layer 2 is provided up to the boundary of the region divided and scanned by the electron beams emitted from the plurality of electron guns, the joint between adjacent regions is formed. It is difficult to control with high precision, and there is a problem that the image displayed on the screen portion is divided at the boundary of each area.

The present invention has been made in order to solve the above-mentioned problems, and the integrated screen portion is divided into a plurality of regions and scanned by an electron beam emitted from a plurality of electron guns. In the color picture tube device, the joint with the image displayed in the adjacent area is accurately controlled,
The object is to configure so that the image displayed on the screen unit is not divided at the boundary with the adjacent region.

[0010]

Means for Solving the Problems A continuous or discontinuous stripe-shaped phosphor layer of a plurality of colors and a light absorption layer are formed in parallel at a predetermined arrangement pitch, and in parallel with the phosphor layer at a position overlapping the light absorption layer. A continuous or discontinuous stripe-shaped index signal phosphor layer has a screen portion formed at a predetermined array pitch, and the screen portion is arranged in at least the parallel direction of the phosphor layers by an electron beam emitted from a plurality of electron guns. In a color cathode ray tube device which divides into a plurality of regions and scans, a plurality of regions in the parallel direction of the phosphor layers are used as boundaries between adjacent regions with a light absorbing layer selected from the above light absorbing layers, and an index signal The phosphor layer is provided so as to avoid a position overlapping with the light absorption layer which is the boundary with the adjacent region.

Further, an envelope having a face plate and a support plate for supporting the face plate and the rear plate is disposed between the face plate and the rear plate facing the face plate, and an inner surface of the face plate is provided with a plurality of colors. A continuous or discontinuous stripe-shaped phosphor layer and a light absorption layer are formed in parallel at a predetermined arrangement pitch, and a continuous or discontinuous stripe-shaped index signal phosphor layer is formed in a position overlapping the light absorption layer in parallel with the phosphor layer. Are provided with a predetermined array pitch, and the screen portions are formed by a plurality of electron beams emitted from a plurality of electron guns arranged on the rear plate side in at least a plurality of regions in the parallel direction of the phosphor layers. In a color picture tube device which divides into two and scans, a plurality of regions in the parallel direction of the phosphor layer are selected from the light absorption layer. The light absorption layer as a boundary with the adjacent area, the index signal phosphor layer is provided so as to avoid a position overlapping with the light absorption layer as a boundary with the adjacent area, and the support is provided on the light absorption layer as a boundary with the adjacent area. Placed in.

In each of the color picture tube devices,
The array number of the phosphor layers of a plurality of colors was set to be a multiple of 2.

[0013]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a perspective view of the color picture tube device as one form thereof as seen from the front side, FIG. 2 is a perspective view as seen from the rear side, and FIG. 3 is a sectional view taken along line III-III in FIG. .

As shown in FIGS. 1 to 3, the color picture tube device includes a face plate 10, a rear plate 11 facing the face plate 10, and a plurality of funnels 1 provided on the rear plate 11.
2 and a vacuum envelope composed of a plurality of necks 13 connected to each funnel 12 thereof. In the example shown,
A total of 12 funnels 12 are provided, four in the horizontal direction and three in the vertical direction. The face plate 10
A screen portion 14 described later is provided on the inner surface of the. An electron gun 16 for emitting a single electron beam 15 is arranged in each neck 13 connected to the plurality of funnels 12. Further, the rear plate 11 is provided with transparent light receiving windows (not shown) vertically and horizontally with the funnels 12 interposed therebetween, and a light receiving portion 17 is provided outside the light receiving windows. Furthermore, each funnel 12
A deflection yoke 18 is mounted on the outer side of the.

As shown in FIG. 4, the screen portion 14 is formed on the inner surface of the face plate 10 in parallel in the horizontal direction at a predetermined arrangement pitch, and has a vertically elongated stripe shape that emits blue, green and red light. Three-color phosphor layers B, G, R
And a vertically elongated striped light absorbing layer 4 provided between these phosphor layers B, G, R, and thin aluminum provided on these phosphor layers B, G, R and light absorbing layer 4. The film 5 and the vertically elongated stripe-shaped index formed in parallel in the horizontal direction at a predetermined arrangement pitch in parallel with the phosphor layers B, G, and R at a position overlapping the light absorption layer 4 via the aluminum film 5. And the signal phosphor layer 2.

The horizontal array pitch PHI of the index signal phosphor layer 2 is set to PHI = 2/3 × PH with respect to the horizontal array pitch PH of the trio of the three-color phosphor layers B, G, and R. For example, when the widths of the three-color phosphor layers B, G, R and the light absorption layer 4 are 0.100 mm, PH = 0.600 mm PHI = 0.400 mm.

For the three-color phosphor layers B, G, and R, a p22 phosphor used in a normal color picture tube or a phosphor for a projection tube is used, and the index signal phosphor layer 2 is formed of p22 phosphor.
36 (ZnCdS: Ag, Ni), p37 (ZnS: A
g, Ni), p46 (Y ₂ SAl ₅ O ₁₂ : Cs), p4
6 (Y ₂ S: SiO ₅ : Cs) or the like is used.

In this color picture tube device, the signal light obtained from the index signal phosphor layer 22 controls the signal to the electron beam to perform color switching.

In this picture tube device, the electron beam 15 emitted from the electron gun 16 provided in each neck 13 is provided.
A deflection yoke 18 mounted on the outside of each funnel 12.
The screen portion 14 is deflected horizontally and vertically by a plurality of rectangular regions, that is, in the illustrated example, as shown by the broken line in FIG. 1, four in the horizontal direction and three in the vertical direction. A total of 12 rectangular areas A1 to A4, B1 to B
4. Divide into 4 and C1 to C4 and scan. Then, each area A1 to A4 is scanned by the electron beam to which the video signal is input.
, B1 to B4, and C1 to C4 are imaged. This image shows each area A1 to A4, B1 to B4, C1 to
By receiving the signal light from the index signal phosphor layer 2 provided on C4, the signal output to the light receiving portion 17 controls the signal to the electron beam 15 to perform color switching, and each area A1 ... A4, B1 to B4, C1
An image divided into C4 is displayed. Then, the images drawn in the respective areas A1 to A4, B1 to B4, C1 to C4 are connected to each other so that the entire surface of the screen portion 14 is seamless.
It is intended to display two large composite images. The aspect ratio of the image obtained on the entire surface of the screen portion 14 is 4: 3 or 16: 9.

The broken line shown in FIG. 1 is shown for the sake of convenience and does not actually exist. In particular, among the boundaries of the areas A1 to A4, B1 to B4, C1 to C4 shown by the broken lines, the areas A1 to A4 and B1 which are horizontally adjacent to each other
The boundaries between .about.B4 and C1 to C4 are located on the light absorption layer selected from the light absorption layers 4 provided between the three color phosphor layers B, G and R shown in FIG. The index signal phosphor layer 2 is provided in each of the areas A1 to A4, B1 to B4, C.
Areas A located within 1 to C4 and adjacent in the horizontal direction
It is not provided on the boundary of 1 to A4, B1 to B4 and C1 to C4 at a position overlapping with the light absorption layer 4.

Here, the respective areas A1 to A4 and B1 to B
4, the electron beam scanning with respect to C1 to C4 will be described in more detail with respect to the first and second regions that are horizontally adjacent to each other with the boundary 1 shown by the dashed line in FIG. 4 as the boundary. The electron beam 15a that scans the first region on the left side of the boundary 1 is horizontally deflected in the direction indicated by the arrow 20a, and scans the first region from left to right until it reaches the boundary with the second region. , The three-color phosphor layers B, G, in the first region
The R and index signal phosphor layers 2 are made to emit light, and the second
Light is emitted up to the last phosphor layer B adjacent to the boundary with the region. When scanning the first region, the electron beam may be over-deflected. In this case, a shield for shielding the over-deflected electron beam is provided in the envelope so that the adjacent region is not scanned. Or the phosphor layers B, G, R
A threshold value is set for the amount of electron beams that emit light, so that the three-color phosphor layers B, G, R and the index signal phosphor layer 22 in the adjacent regions do not emit light. On the other hand, with respect to the second area on the right side of the boundary 1 shown by the alternate long and short dash line, the electron beam 15b for scanning this second area is horizontally deflected in the direction shown by the arrow 20b, and the second area is moved. Start scanning from the boundary with the first area from left to right and
The three-color phosphor layers B, G, and R and the index signal phosphor layer 2 in the region (1) are caused to emit light, and the first phosphor layer R adjacent to the boundary with the first region is caused to emit light. In the scanning of the second region, too, the electron beam may be excessively deflected, but in this case, as in the case of the first region, in the envelope, the scanning is performed so as not to scan the adjacent region. A shield for blocking the over-deflected electron beam is provided, or a threshold value is set for the amount of electron beams that cause the phosphor layers B, G, R to emit light, and the three-color phosphor layers B, G, R in the adjacent regions. The index signal phosphor layer 2 is prevented from emitting light.

By thus scanning the first and second regions, the electron beam 15a for scanning the first region is
Electrons for scanning the first region are made to emit light up to the last index signal phosphor layer 2 in the first region, and as a result, a signal obtained from a light receiving portion provided corresponding to the first region is scanned. It is possible to surely feed back the control to the electron gun and the deflection yoke that emit the beam 15a. Further, the electron beam 15b for scanning the second region causes the first index signal phosphor layer 2 in the second region to emit light, and as a result, the light receiving portion provided corresponding to the second region The obtained signal can be reliably fed back to the control unit of the electron gun or the deflection yoke that emits the electron beam 15b that scans the second region.

That is, as in the conventional case, when the index signal phosphor layer is provided at a position overlapping the light absorption layer on the boundary of the adjacent region, the electron beam scanning the first region is on the boundary. It is difficult to distinguish the signal light generated when the index signal phosphor layer is bombarded from the signal light generated when the electron beam scanning the second region is bombarded, and it is difficult to operate the feedback system correctly. However, the conventional problems can be solved by configuring as described above.

Therefore, with the above-mentioned structure, the composite image drawn on the entire screen portion by connecting the images divided into the respective areas and connecting the images is the same as the image displayed on the ordinary color picture tube. It is possible to create an image with no discomfort, and by drawing the image in each area at the same time, it is possible to secure the brightness equal to or higher than that of a normal color picture tube,
It is possible to provide a high-resolution, high-luminance color picture tube device that is lightweight and has a short depth.

It is to be noted that forming the index signal phosphor layer at a predetermined array pitch at a position overlapping with another light absorbing layer while avoiding the light absorbing layer on the boundary between the horizontally adjacent regions is described, for example, in the following. It becomes possible by designing as.

That is, if the horizontal length of the region divided and scanned by a plurality of electron beams is LH, and the number of trios of the tricolor phosphor layer in the horizontal direction is nH, then nH = LH / PH NH is an integer. Therefore, assuming that the array pitch of the index signal phosphor layers is PHI = 2/3 × PH and 2/3 of PH, as shown in FIG. 4, the index signal phosphor layers for the tri-color phosphor layer trio are The array is a repetition of the two patterns indicated by a and b.

That is, in order to prevent the index signal phosphor layer from being located on the boundary between the horizontally adjacent regions, the number nH of the tri-color phosphor layer trio in one region in the horizontal direction is a multiple of 2. Therefore, the two patterns shown by a and b are completed in the area, and in the adjacent area, the light absorption on the boundary of the horizontally adjacent areas starts from the a pattern. It can be formed avoiding layers.

Incidentally, such an arrangement of the index signal phosphor layer is added to the vacuum envelope between the face plate and the rear plate, as shown in Japanese Patent Application No. 3-182741. It is suitable for a color picture tube device in which a support for supporting an atmospheric pressure load is arranged.

That is, as shown in FIG. 5, the support 22 supporting the atmospheric pressure load applied to the vacuum envelope overlaps with the light absorption layer 4 on the boundary 1 shown by the alternate long and short dash line in the horizontally adjacent region. It is provided in the position. Therefore, when the index signal phosphor layer 2 is provided on this boundary, the index signal phosphor layer 2 is damaged by the contact with the support 22. Also, near the support 22, the electron beam is blocked by the support 22. Further, even if the index signal phosphor layer 2 can be impacted, it is difficult for the resulting signal light to reach the light receiving section sufficiently, and there arises a problem that a necessary index signal cannot be sufficiently secured.

However, when the index signal phosphor layer 2 is provided while avoiding the light absorption layer 4 on the boundary 1 as described above,
The index signal phosphor layer 2 can be prevented from being damaged by the support 22, the electron beam can be prevented from being blocked, and the signal light from the index signal phosphor layer 2 can sufficiently reach the light receiving portion. An index type color picture tube device having the body 22 can be properly constructed.

The index signal phosphor layer described in the above embodiment is for obtaining a control signal for performing color switching of the electron beam for horizontal scanning of the three color phosphor layers arranged in parallel in the horizontal direction. So, it has nothing to do with the vertical direction.

Regarding the connection of images between vertically adjacent regions, the technique disclosed in Japanese Patent Publication No. 4-53069 may be used, or the electron beam scanning each region may be over-deflected in the vertical direction. The over-deflected electron beam is shielded by a shield provided in the tube, or a threshold value is set for the amount of electron beam that causes the three-color phosphor layer to emit light, and the three-color phosphor layer in an adjacent region is Can be controlled by a method that does not cause light to be emitted.

In the above embodiment, the three-color phosphor layers are provided in the order of red R, green G, and blue B from the left side of the drawing (FIG. 4), but the order of the three-color phosphor layers is as follows. It is not limited.

Further, in the above-described embodiment, the case where the stripe-shaped three-color phosphor layer which is elongated in the vertical direction is scanned in the horizontal direction and the horizontal scanning is repeated to perform the vertical scanning has been described. The present invention is also applicable to a case where a vertically elongated striped three-color phosphor layer is scanned in the vertical direction, and the vertical scanning is repeated to perform horizontal scanning.

Further, in the above-described embodiment, the screen portion is provided with the striped three-color phosphor layer which is elongated in the vertical direction. The three-color phosphor layer is a striped three-color phosphor layer which is elongated in the horizontal direction. It may be a layer.

Furthermore, in the above-described embodiment, the stripe-shaped three-color phosphor layer and the index signal phosphor layer have a continuous and elongated shape, but these three-color phosphor layer and index signal phosphor layer are not formed. It may be a continuous stripe shape.

[0038]

EFFECTS OF THE INVENTION A continuous or discontinuous stripe-shaped phosphor layer and a light absorption layer of a plurality of colors are formed in parallel at a predetermined arrangement pitch, and are continuous or discontinuous parallel to the phosphor layer at a position overlapping the light absorption layer. Has a screen portion in which the stripe-shaped index signal phosphor layers are formed at a predetermined array pitch, and the screen portions are arranged at least in a direction parallel to the phosphor layers by electron beams emitted from a plurality of electron guns. In a color picture tube device which divides into regions and scans, a plurality of regions in the parallel direction of the phosphor layer are used as boundaries between adjacent regions with a light absorption layer selected from the above light absorption layers, and an index signal phosphor layer Is provided so as to avoid the position where it overlaps with the light absorption layer which is the boundary with the adjacent region, the combined image drawn on the entire screen portion by joining the images drawn divided into each region, Similar to the image displayed on the color picture tube normally be a no feeling of strangeness image, and by drawing the image at the same time in each area, it can be secured ordinary color picture tube least equivalent brightness. Therefore, with the above-described configuration, a color picture tube device that is lightweight and has a short depth, high resolution, and high brightness and is highly practical can be obtained.

Further, an envelope having a face plate and a support plate supporting the face plate and the rear plate is disposed between the face plate and a rear plate facing the face plate, and an inner surface of the face plate is provided with a plurality of colors. A continuous or discontinuous stripe-shaped phosphor layer and a light absorption layer are formed in parallel at a predetermined arrangement pitch, and a continuous or discontinuous stripe-shaped index signal phosphor layer is formed in a position overlapping the light absorption layer in parallel with the phosphor layer. Are provided with a predetermined array pitch, and the screen portions are formed by a plurality of electron beams emitted from a plurality of electron guns arranged on the rear plate side in at least a plurality of regions in the parallel direction of the phosphor layers. In a color picture tube device which divides into two and scans, a plurality of regions in the parallel direction of the phosphor layer are selected from the light absorption layer. The light absorption layer serving as the boundary with the adjacent region, the index signal phosphor layer provided so as to avoid the position overlapping the light absorption layer serving as the boundary with the adjacent region, and the support serving as the boundary with the adjacent region. By arranging it above, even if the support is arranged, damage to the index signal phosphor layer due to this support can be avoided, the electron beam is not blocked, and the signal light from the index signal phosphor layer is prevented. It is possible to sufficiently reach the light receiving portion, and an index type color picture tube device having a support can be properly configured.

[Brief description of drawings]

FIG. 1 is a perspective view of a color picture tube device according to an embodiment of the present invention as viewed from the front side.

FIG. 2 is a perspective view of the color picture tube device as viewed from the back side.

[FIG. 3] III-II in FIG. 1 of the color picture tube device
It is a line sectional view.

FIG. 4 is a diagram showing a screen portion of the color picture tube device.

FIG. 5 is a diagram for explaining an arrangement of a support with respect to a screen unit.

FIG. 6 is a view showing a screen portion of a conventional color picture tube device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Boundary 2 ... Index signal fluorescent substance layer 4 ... Light absorption layer 10 ... Face plate 11 ... Rear plate 14 ... Screen part 15 ... Electron beam 16 ... Electron gun 22 ... Supports A1 to A4 ... Region B1 to B4 ... Region C1 ~ C4 ... area B, G, R ... three-color phosphor layer

Claims (3)

[Claims] 1. A continuous or discontinuous stripe-shaped phosphor layer of a plurality of colors and a light absorption layer are formed in parallel at a predetermined arrangement pitch, and are continuous or discontinuous parallel to the phosphor layer at a position overlapping the light absorption layer. A continuous stripe-shaped index signal phosphor layer has a screen portion formed at a predetermined array pitch, and the screen portion is formed by a plurality of electron beams emitted from a plurality of electron guns at least in the parallel direction of the phosphor layers. In a color picture tube device that divides into individual areas and scans, a plurality of areas in the parallel direction of the phosphor layer have a light absorption layer selected from the light absorption layers as a boundary with an adjacent area, and the index signal A color picture tube device, wherein the phosphor layer is provided so as to avoid a position where it overlaps with the light absorption layer serving as the boundary. 2. An envelope having a face plate and a support plate supporting the face plate and the rear plate between the face plate and a rear plate facing the face plate, the envelope having a plurality of colors on the inner surface of the face plate. Continuous or discontinuous stripe-shaped phosphor layers and light absorption layers are formed in parallel at a predetermined array pitch, and continuous or discontinuous stripe-shaped index signal fluorescence is formed in a position overlapping with the light absorption layers in parallel with the phosphor layers. A screen portion in which body layers are formed at a predetermined arrangement pitch is provided, and the screen portion is at least arranged in the parallel direction of the phosphor layers by an electron beam emitted from a plurality of electron guns arranged on the rear plate side. In a color picture tube device that divides into a plurality of regions and scans, a plurality of regions in the parallel direction of the phosphor layer are The light absorption layer selected from the condensing layer is used as a boundary with the adjacent region, and the index signal phosphor layer is provided so as to avoid a position overlapping the light absorption layer serving as the boundary, and the support serves as the light absorption serving as the boundary. The color picture tube device according to claim 1, wherein the color picture tube device is arranged on a layer. 3. The number of arranged phosphor layers of a plurality of colors in each region is 2
3. The color picture tube device according to claim 1, wherein the color picture tube device is provided in a multiple of.