JPH08153480A - Light emitting element - Google Patents

Abstract

PURPOSE: To prevent short circuit and electric discharge between an acceleration positive electrode and a control grid, to be generated caused by dispersion of a getter film. CONSTITUTION: A first partition plate 6a bent approximately perpendicular to a cylindrical side plate 4 is provided inside a vacuum envelope 1 by partially using an acceleration positive electrode group 6 near the inner surface side of the cylindrical side plate 4. A getter film 14 flashed and spattered from a getter groove 13a of a getter 13 attached on one part of the acceleration positive electrode group 6 through a getter attaching plate 18 is deposited on the first partition plate 6a.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a large-screen display device, and more particularly to a light-emitting element that constitutes a pixel of a color large-screen display device.

[0002]

2. Description of the Related Art When a large-screen display device is constructed by arranging single-color display tubes using the light emission of a phosphor as one pixel in a matrix, a space is formed at the connection portion of each single-color display tube and the resolution is improved. However, it is difficult to perform, and the cost may increase due to the high resolution. Therefore, conventionally, for example, a composite type light emitting device disclosed in JP-A-62-10849 has been proposed. 11 and 1
2, FIG. 13 is a front view showing the basic structure of this composite type light emitting device and its sectional view taken along line XII-XII, and FIG. 14 is an exploded perspective view of a part thereof, showing R (red), G (green) and B
A case is shown in which the phosphor screen having each of the (blue) phosphors as one pixel is arranged in a matrix of 3 × 3 pixels with the number of pixels. Further, FIG. 15 is a partial cross-sectional side view in which the light emitting element is partially cross-sectioned.

In these drawings, reference numeral 1 denotes a vacuum envelope as a glass tube which is hermetically sealed by a front panel 2, a back plate 3 and a tubular side plate 4, and the inner surface of the front panel 2 has three Each of the color phosphors R, G, and B is applied as a unit pixel in a matrix, and the phosphor screen 5R of 3 × 3 pixels is arranged.
A fluorescent display portion 5 composed of 5G and 5B is formed. Here, the suffixes of the phosphor screens 5R, 5G and 5B correspond to red (R), green (G) and blue (B), respectively. 6 is each fluorescent screen 5R, 5G and 5B of the fluorescent display unit 5.
Is a group of acceleration anodes 6 ₁ , 6 ₂ , ...
External terminals 16 are provided on these accelerating anodes 6 ₁ , 6 ₂ , ...
And a high voltage is applied to the accelerating anode of the accelerating anode electrode group 6 facing the tubular side plate 4 and close to the inner surface side of the tubular side plate 4 as shown in FIG. A getter 13 is attached to a part of the getter mounting plate 18 via a getter mounting plate 18. By flushing the getter 13 from the getter groove 13a by high-frequency induction heating or the like at the time of assembly, the getter film 14 having the adsorptivity is attached to the cylindrical side plate. 4 is attached to the inner surface of the vacuum envelope 4 to increase the degree of vacuum in the vacuum envelope 1. In addition, Japanese Patent Application Laid-Open No. 1-253148 discloses a structure shown in FIG.
As shown in FIG. 3, the shadow mask accelerating anode electrode 21 is arranged so as to face the fluorescent display portion 5 from the shape of the side plates of the accelerating anodes 6 ₁ , 6 ₂ , ...
A conventional example in which the shape of a flat plate provided with an opening 22 having a square small hole is changed is shown.

Hereinafter, each fluorescent screen 5 of the fluorescent display section 5 of FIG.
A plurality of acceleration anodes 6 ₁ , 6 ₂ , fixed vertically to the front panel 2 so as to surround R, 5G, 5B, ...
There is a difference in shape and arrangement between the accelerating anode electrode group 6 configured as described above and the shadow mask accelerating anode electrode 21 configured as a shadow mask-shaped flat plate facing the fluorescent display portion 5 in FIG. However, all other configurations are the same.

Reference numeral 7 denotes each of the fluorescent screens 5R, 5G of the fluorescent display unit 5.
5B is a cathode electrode group in which electron emission cathodes 7 _{11 to} 7 ₃₃ are independently arranged, and these cathodes 7 _{11 to} 7 ₃₃ are a pair of both ends fixed on the back plate 3. Is supported between the supports 17a and 17b. The first and second subscripts of the cathodes 7 _{11 to} 7 ₃₃ correspond to the 1st to 3rd rows and the 1st to 3rd columns, respectively. Note that the cathodes 7 _{11-7 33,} for example, a straight thermal coated with oxide oxide coated indirectly heated or tungsten on the Ni sleeve can be used. Also, 8 is a grid electrode group composed of a control grid 8 _{1-8 3} for arrangement row selection between the cathode electrode group 7 and the fluorescent display portion 5, these control grids 8 ₁
˜8 ₃ corresponds to each of the fluorescent screens 5R, 5G and 5B of the fluorescent display unit 5, and the cathodes 7 ₁₁ ˜
Electron passing holes 9 _{1 to} 9 ₃ are provided to pass the electron beam 11 from the light source 7 ₃₃ as a non-focused beam.

Reference numeral 10 denotes the rear surface side of the cathode electrode group 7, that is, on the rear plate 3 forming a part of the vacuum envelope 1, corresponding to the respective fluorescent screens 5R, 5G and 5B of the fluorescent display section 5.
A back electrode group comprising a back electrode 10 ₁ to 10 ₃ for each oppositely disposed stripe-shaped column selection to the column direction, these back electrode 10 ₁ to 10 ₃ is formed of a conductor layer such as Ag There is. Then, each of the back electrodes 10 ₁
10 _3, by applying a positive potential of the negative and 0V or several V relative to the potential of the cathode 7 _{11-7 33,} a controls the electron beam 11 to be emitted from their cathode 7 _{11-7 33} ing. In addition, 12 is the cathode plate group 7, the grid electrode group 8 and the back electrode group 1 from the back plate 3.
It is a lead wire as an external terminal for pulling out each electrode of 0 to the outside. Next, the operation will be described. First, when the back electrode 10 ₁ to 10 ₃ is a negative potential relative to the potential of the cathode 7 _{11-7 33,} because around these cathode 7 _{11-7 33} is surrounded by a negative potential, the cathode 7 ₁₁ ~ 7 ₃₃
From the control grids 8 ₁ to 8 ₃ and the accelerating anodes 6 ₁ , 6 ₂ , ..., Or the shadow mask accelerating anode electrode 21 and is cut off.

[0007] Therefore, the addition of positive potential of 0V or several V relative to the potential of the cathode 7 _{11-7 33} to the back electrode 10 ₁ to 10 _3, the electron beam 11 emitted from the respective cathodes 7 _{11-7 33} There flows toward the control grid 8 _{1-8 3.} At this time, when the potentials of the control grids 8 ₁ to 8 ₃ are negative with respect to the cathodes 7 _{11 to} 7 ₃₃ , the electron passage holes 9 _{1 to} 9 _{3 of} these control grids 8 ₁ to 8 ₃ are discharged. The electron beam 11 cannot pass therethrough, and the acceleration anodes 6 ₁ , 6 ₂ , ...
......, or the electron beam 11 does not flow to the shadow mask accelerating anode electrode 21 and each phosphor screen 5R of the phosphor display unit 5
5G and 5B do not emit light. When the potentials of the control grids 8 ₁ to 8 ₃ are positive with respect to the cathodes 7 _{11 to} 7 ₃₃ , the electron beam 11 is emitted from the electron passage holes 9 _{1 to} 9 _{3 of} these control grids 8 ₁ to 8 _3. Respectively pass through and cause each of the fluorescent screens 5R, 5G, and 5B to emit light. Therefore, the control grids of the grid electrode group 8 and the back electrodes of the back electrode group 10 arranged in a matrix corresponding to the phosphor screens 5G, R, and B are selectively driven and controlled (dynamic drive). As a result, only the fluorescent screens 5R, G, B where the two electrodes intersect can be selectively caused to emit light.

As described above, the phosphor screen 5R made of phosphors of three colors is provided on the inner surface of the front panel 2 constituting the vacuum envelope 1.
G and B are arranged in a matrix of 3 × 3 pixels, and the cathode electrode group 7, the grid electrode group 8 and the back electrode group 10 are provided in correspondence with each of the phosphor screens 5R, G and B, so that high-luminance light emission is achieved. Can be obtained. Therefore, when assembling a large-screen color display monitor device using this display element as one cell, the space of each pixel tube becomes narrower than that of one using a single color tube with one pixel, and the resolution can be improved. The number of parts and the number of manufacturing steps can be reduced. Also,
Not only can the structure be simple and low cost,
The weight of the display device can also be reduced.

Although the illustrated example shows the case where the phosphor screens of the R, G and B tricolor phosphors are arranged in a matrix of 3 × 3 pixels on the inner surface of the front panel 2, the invention is not limited to this. However, the fluorescent screens 5R, G, and B each having one phosphor as one pixel in the vacuum envelope 1 may have any m ×
It is also possible to arrange them in a matrix of n pixels (however, m and n are arbitrary integers) and change the arrangement configuration of the grid electrode group 8 and the back electrode group 10 accordingly.

[0010]

Since the conventional light emitting device is constructed as described above, the accelerating anode which faces the cylindrical side plate 4 of the vacuum envelope 1 and is close to the inner surface side of the cylindrical side plate 4 is provided. When the getter 13 attached to a part of 6 is flushed, the getter film 14 is scattered and attached to the inner surface of the tubular side plate 4 in a wide range, and the getter film 14 and the back plate 3 are arranged in front of the getter film 14. control grid near the inner surface of the cylindrical side plate 4 8 ₁
8 ₃ distance Ki not a near-between, there is a risk of causing an electrical troubles such as short-circuit or discharge between both. In addition, the control grids 8 ₁ to 8 ₃ close to the inner surface side of the tubular side plate 4
There is a possibility that field emission may occur from the end portion of the above and unnecessary light may be emitted in addition to the fluorescent screen that should emit light.

The present invention has been made to solve the above-mentioned problems, and the getter film is formed on the tubular side plate by changing the shape of a part of the accelerating anode near the inner surface of the tubular side plate. 4 does not diffuse to the control grid side close to the inner surface side. Therefore, it is an object of the present invention to provide a light emitting device that prevents an electrical trouble such as a short circuit or discharge between the getter film and the control grid and prevents unnecessary light emission from the phosphor screen. Further, it is an object of the present invention to provide a light emitting device similar to that described above even when an accelerating anode electrode for a shadow mask is used.

[0012]

A light emitting device according to the present invention comprises a vacuum envelope in which a front panel is joined to a front surface of a tubular side plate and a rear panel is joined to a rear surface of the tubular side plate in an airtight manner, and a fluorescent screen is provided on an inner surface of the front panel. An accelerating device comprising a fluorescent display unit arranged in a matrix and a plurality of accelerating anodes for accelerating an electron beam fixed vertically to the front panel so as to surround the fluorescent screen of the fluorescent display unit. An anode electrode group,
A grid electrode composed of a cathode electrode group in which electron emission cathodes are independently arranged corresponding to the phosphor screen, and a plurality of control grids arranged between the cathode electrode group and the phosphor screen. Group and a back electrode group in which a plurality of back electrodes are provided on the back side of the cathode electrode group, and a getter mounting plate is provided on a part of the accelerating anode so as to face the inner surface of the tubular side plate. With a getter disposed through the above structure, a part of the acceleration anode electrode group near the inner surface of the tubular side plate is used, and the getter is disposed on the inner side of the vacuum envelope with respect to the tubular side plate. The first partition plate bent at a right angle is provided.

Further, by using a part of the accelerating anode electrode group near the inner surface of the tubular side plate, the inner side of the vacuum envelope is approached from substantially parallel to the tubular side plate to a substantially right angle ( 0
It is provided with a second partition plate that can be bent.

Further, a field emission prevention plate is provided by utilizing a part of the first partition plate and further bending it at a substantially right angle in a direction approaching the control grid side.

The getter is attached to the accelerating anode electrode group, one side of which is located near the inner surface of the tubular side plate, via a getter mounting plate, and the other side of which is located on the control grid side. It is close to the inner surface of the tubular side plate and spreads toward the inner side of the vacuum envelope from the other side at an inclination angle θ with respect to the inner surface of the tubular side plate.

Further, a vacuum envelope in which a front panel is attached to the front surface of the cylindrical side plate and a back panel is attached to the back surface of the tubular side plate in an airtight manner, and a fluorescent display section formed by arranging fluorescent surfaces in a matrix on the inner surface of the front panel And a shadow mask accelerating anode for accelerating the electron beam, which is composed of a flat plate in the shape of a shadow mask in which a plurality of square openings for transmitting the electron beam are arranged in front of the fluorescent display portion. An electrode, a cathode electrode group in which electron emission cathodes are independently arranged corresponding to the phosphor screen, and the cathode electrode group and the shadow mask accelerating anode electrode. In a light emitting device including a grid electrode group including a plurality of control grids and a back electrode group in which a plurality of back electrodes are provided on the back side of the cathode electrode group, in the vicinity of the inner surface of the tubular side plate. The shadow mask is provided using a part of the accelerating anode for the shadow mask 1
A partition plate which is bent in the direction of the front panel parallel to and close to the inner surface of the tubular side plate, and a getter is arranged on the first partition plate for the shadow mask via a getter mounting plate. Is.

Further, in a part of the first partition plate for the shadow mask, a part where the getter is arranged is cut out to near the bent part, and the getter is arranged in the cutout part through the getter mounting plate. It was set up.

Furthermore, the cutout portion of the first partition plate for the shadow mask is arranged in a portion corresponding to the opening for passing the electron beam.

Further, the first partition plate for the shadow mask is provided near the inner surface of the cylindrical side plate by using a part of the acceleration anode electrode for the shadow mask. A getter is arranged via a getter mounting plate, and the first partition plate for the shadow mask is parallel along the inner surface of the tubular side plate from the shadow mask acceleration anode electrode to the vicinity of the phosphor screen. The second partition plate for the shadow mask, which is provided by using a part of this extended portion, extends to the control grid side, and its end portion is the inside of the vacuum envelope. It is bent substantially at right angles to the tubular side plate.

The shadow mask first partition plate is provided in the vicinity of the inner surface of the tubular side plate by using a part of the shadow mask acceleration anode electrode. A getter is arranged via a getter mounting plate, and the first partition plate for the shadow mask is parallel along the inner surface of the tubular side plate from the shadow mask acceleration anode electrode to the vicinity of the phosphor screen. The third partition plate for the shadow mask, which is provided by using a part of this extended portion, extends on the opposite side to the control grid side, and its end portion is the inside of the vacuum envelope. It is configured such that it can be bent from substantially parallel to the cylindrical side plate to a substantially right angle (more than 0 degrees and less than 90 degrees) to the side.

Further, a part of the second partition plate for the shadow mask is used to further provide a field emission prevention plate for the shadow mask, which is bent at a substantially right angle in the direction approaching the control grid side.

[0022]

In the light emitting device according to the present invention, since the first partition plate is provided by using a part of the accelerating anode electrode group near the inner surface of the tubular side plate, the getter film is formed on the inner surface of the tubular side plate and the first partition plate. It adheres to the inside of partition plate 1.

Further, since the second partition plate is provided, the getter film adheres to the inner surface of the tubular side plate and the inner side of the second partition plate.

Further, since the field emission prevention plate is provided, the field emission generated from the end portion of the control grid near the inner surface side of the tubular side plate is blocked by the field emission prevention plate provided in front of it.

Further, since the getter spreads toward the inside of the vacuum envelope at an inclination angle θ with respect to the inner surface of the cylindrical side plate, the getter film scatters in a direction substantially perpendicular to the inclined surface of the getter. Adheres to the inner surface of the side plate.

Further, since the getter is provided on the first partition plate for shadow mask via the getter mounting plate, the getter film adheres to the inner surface of the tubular side plate and the inside of the first partition plate for shadow mask.

Furthermore, since the notch is provided in a part of the first partition plate for the shadow mask, a getter having a large outer diameter can be attached.

Furthermore, since the cutout portion of the first partition plate for the shadow mask is arranged at the portion corresponding to the opening for passing the electron beam, the getter film is provided in the fluorescent display portion. It adheres to the part between the fluorescent screens where there is no fluorescent screen.

Since the second partition plate for the shadow mask is provided, the getter film adheres to the inner surface of the cylindrical side plate and the inside of the second partition plate for the shadow mask.

Since the third partition plate for the shadow mask is provided, the getter film adheres to the inner surface of the tubular side plate and the inner side of the third partition plate for the shadow mask.

Further, since the shadow mask field emission prevention plate is provided, the field emission generated from the end portion of the control grid near the inner surface side of the tubular side plate is provided in front of the shadow mask field emission prevention plate. Blocked.

[0032]

【Example】

Example 1. An embodiment of the present invention will be described below with reference to the drawings. 1 to 1 in FIGS. 1 (A), (B), and (C)
Reference numerals 5 and 18 have the same or the same functions as those of the conventional light emitting element, and the description thereof will be omitted. 6a is a first partition plate provided using a part of the accelerating anode electrode group 6 on the inner surface near the cylindrical side plate 4, the control grid 8 ₁ side closer to the inner surface of the cylindrical side plate 4 The end of is bent inside the vacuum envelope 1 substantially at right angles to the tubular side plate 4.

Next, the operation of the first embodiment will be described.
In FIG. 1 (C), the getter 13 is flushed from the getter groove 13a by high-frequency induction heating or the like at the time of assembly, so that the gas-adsorptive getter film 14 is removed from the tubular side plate 4.
The inner surface of the vacuum envelope 1 is scattered and adhered to increase the degree of vacuum in the vacuum envelope 1. When the getter 13 is flushed from the getter groove 13a, the getter film 14 is allowed to adhere to the inner surface of the tubular side plate 4 and the first partition plate 6a of the acceleration anode of the acceleration anode electrode group 6 so that the grid electrode group 8 is formed. The cylindrical side plate 4 was prevented from adhering to the end portion on the control grid 8 ₁ side close to the inner surface side. Accordingly, the getter film 14 which has been a problem of conventional adhesion or close to the end of the control grid ₈₁ side close to the inner surface of the cylindrical side plate 4, there is electrical troubles such as short-circuit or discharge between both You can eliminate the trouble.

Embodiment 2 FIG. Example 2 is shown in FIGS. 2 (A) and 2 (B).
As shown in FIG. 6, 6b is a second partition plate provided near the inner surface side of the tubular side plate 4 by using a part of the accelerating anode electrode group 6, and is close to the inner surface side of the tubular side plate 4. Control grid 8
The end on the ₁ side is placed inside the vacuum envelope 1 from approximately parallel to the cylindrical side plate 4 until it approaches a substantially right angle (exceeding 0 degrees and exceeding 90 degrees).
(Less than a degree).

With this configuration, the first embodiment
And likewise, it is possible getter film 14 to prevent a short circuit or discharge because not approach attached or the end of the control grid ₈₁ side close to the inner surface of the cylindrical side plate 4.

Example 3. In FIGS. 3A and 3B,
6c is a field emission prevention plate,
7 shows another embodiment in which a part of the partition plate 6a is used to be bent at a substantially right angle in the direction approaching the control grid 8 ₁ side.

With this structure, the field emission generated from the end portion of the control grid 8 ₁ near the inner surface of the tubular side plate 4 is blocked by the field emission prevention plate 6c provided in front of the control grid 8 ₁ to cause fluorescence. Display unit 5
Since the field emission does not reach the fluorescent screen 5G or the like, unnecessary light emission can be prevented.

Example 4. In FIGS. 4A and 4B,
Getter 13 in accelerating anode electrode group 6 in which one side is located near the inner surface of the cylindrical side plate 4 is attached via a getter mounting plate 18, together with other side is located on the control grid ₈₁ side, It is near the inner surface of the tubular side plate 4, and spreads toward the inner side of the vacuum envelope 1 at an inclination angle θ with respect to the inner surface of the tubular side plate 4 from the other side toward one side.

With this structure, the getter film 14 scatters in a direction substantially perpendicular to the inclined surface of the getter film 13 and adheres to the inner surface of the cylindrical side plate 4. Therefore, similarly to the first embodiment, it is possible to prevent short circuit or discharge.

Example 5. In FIGS. 5A, 5B, and 5C, reference numeral 21a denotes a shadow mask first partition provided by using a part of the shadow mask acceleration anode electrode 21 near the inner surface of the tubular side plate 4. A tubular side plate 4
It is bent in the direction of the front panel 2 in parallel with the inner surface of the front panel. At least one or a plurality of getters 13 (three examples are shown in the drawing) in a horizontal row are arranged on the first partition plate 21a for the shadow mask via the getter mounting plate 18.

With this structure, the getter film 14 scatters and adheres to the inner surface of the tubular side plate 4 and the inside of the first partition plate 21a for the shadow mask.
Since it does not adhere to or approach the end portion of the control grid 8 ₁ side closer to the inner surface side, it is possible to prevent short circuit or discharge.

Example 6. In FIGS. 6A, 6B, and 6C, 21e is a first partition plate 21a for shadow mask.
Is a cutout portion provided in a part of the above, and the portion where the getter 13 is arranged is cut out to the vicinity of the bent portion.

With this structure, a large capacity getter 13 having a large outer diameter can be attached,
The degree of vacuum in the vacuum envelope 1 can be maintained with a small number.

Example 7. 7A and 7B, the cutout portion 21e of the first partition plate 21a for the shadow mask shown in the sixth embodiment is formed with the opening 22 and the opening 22 of the acceleration anode electrode 21 for the shadow mask. The getter 13 is provided in a corresponding portion between the two.

With this structure, the getter film 14 is formed in the opening 2 of the shadow mask accelerating anode electrode 21.
2 does not adhere to the respective fluorescent screens such as the fluorescent screen 5G because they scatter and adhere between the respective fluorescent screens such as the fluorescent screen 5G provided opposite to 2. Therefore, the getter film 14 does not cause defective light emission such as the fluorescent screen 5G.

Further, FIG. 7B shows an example in which the first partition plate 21a for the shadow mask on which the getter 13 is arranged has one bent surface, but two or three surfaces are all bent surfaces. May be provided.

Further, the number of getters 13 arranged in the cutout portion 21e is not limited to two, and may be one or plural.

Example 8. FIGS. 8A and 8B show another embodiment in which the space between the shadow mask-shaped accelerating anode electrode 21 and the fluorescent display portion 5 is so narrow that the getter 13 cannot be arranged between the two. Shown above is the getter 13
Is arranged on the first partition plate 21a for the shadow mask via the getter mounting plate 18. 21b extends the first partition plate 21a for the shadow mask parallel to the vicinity of the fluorescent screen 5G along the inner surface of the tubular side plate 4, and the opposite side thereof extends to the control grid 8 ₁ side. It is a second partition plate for a shadow mask provided by using a part thereof, and its end portion is bent toward the inside of the vacuum envelope 1 substantially at right angles to the tubular side plate 4.

[0049] With this configuration, it is possible to prevent short-circuiting or discharge because the getter film 14 does not approach attached or the end of the control grid ₈₁ side close to the inner surface of the cylindrical side plate 4.

Example 9. 9A and 9B show another embodiment in which the space between the shadow mask accelerating anode electrode 21 and the fluorescent display portion 5 is so narrow that the getter 13 cannot be arranged between them. The getter 13 is arranged on the first partition plate 21a for the shadow mask via the getter mounting plate 18. 21c extends the first partition plate 21a for the shadow mask parallel to the vicinity of the fluorescent screen 5G along the inner surface of the tubular side plate 4, and the opposite side thereof extends to the control grid 8 ₁ side. It is a third partition plate for a shadow mask which is provided by using a part thereof, and the end portion of the third partition plate approaches the inside of the vacuum envelope 1 from approximately parallel to the tubular side plate 4 to approximately a right angle ( The angle is more than 0 degrees and less than 90 degrees).

By constructing in this way, Example 8
Similarly, the short circuit or the discharge can be prevented.

Example 10. In FIG. 10, 21d is a shadow mask field emission prevention plate,
Said by utilizing a part of the second partition plate 21b for a shadow mask, it is further formed by bending substantially at a right angle in a direction approaching to the control grid ₈₁ side.

With this configuration, the third embodiment
Similarly to the control grid 8 ₁ close to the inner surface side of the tubular side plate 4,
The field emission generated from the end of the is blocked by the field emission prevention plate for shadow mask 21d provided in front of the field emission, and the field emission does not reach the fluorescent screen 5G of the fluorescent display unit 5 or the like, and thus unnecessary light emission occurs. Can be prevented.

[0054]

As described above, according to the present invention, a part of the accelerating anode electrode group in the vicinity of the inner surface of the tubular side plate is used, and the inner side of the vacuum envelope is provided with respect to the tubular side plate. Since the getter film is attached to the inner surface of the tubular side plate and the inside of the first partition plate by providing the first partition plate that is bent at a substantially right angle, the getter film is attached to the inner surface of the tubular side plate of the grid electrode group. Close to the edge of the control grid side does not stick to or approach. Therefore, it is possible to prevent an electrical trouble such as a short circuit or a discharge between a part of the acceleration anode electrode group and the end portion on the control grid side.

Further, since the field emission prevention plate, which is bent at a substantially right angle in the direction approaching the control grid side, is provided by using a part of the first partition plate, the field emission can reach the fluorescent surface of the fluorescent display portion. Absent. Therefore, it is possible to prevent unnecessary fluorescence on the phosphor screen.

Further, since the cutout portion of the first partition plate of the shadow mask is arranged in the portion corresponding to the opening for passing the electron beam, it is possible to prevent the fluorescent screen from emitting light. It can be prevented.

[Brief description of drawings]

FIG. 1 is a partial cross-sectional side view of a light emitting device showing a first embodiment of the present invention.

FIG. 2 is a partial cross-sectional side view of a light emitting device showing a second embodiment of the present invention.

FIG. 3 is a partial cross-sectional side view of a light emitting device showing a third embodiment of the present invention.

FIG. 4 is a partial cross-sectional side view of a light emitting device showing a fourth embodiment of the present invention.

FIG. 5 is a partial cross-sectional side view of a light emitting device showing a fifth embodiment of the present invention.

FIG. 6 is a partial cross-sectional side view of a light emitting device showing Embodiment 6 of the present invention.

FIG. 7 is a partial cross-sectional side view of a light emitting device showing Embodiment 7 of the present invention.

FIG. 8 is a sectional side view of a light emitting device showing an eighth embodiment of the present invention.

FIG. 9 is a sectional side view of a light emitting device showing an embodiment 9 of the present invention.

FIG. 10 is a sectional side view of a light emitting device showing an Embodiment 10 of the present invention.

11A and 11B are a front view showing a light emitting element composed of a conventional acceleration anode electrode group and a front view showing a light emitting element composed of a conventional shadow mask acceleration anode electrode.

FIG. 12 is a cross-sectional view taken along the line XII-XII showing a light emitting device formed of a conventional acceleration anode electrode group.

FIG. 13 is a cross-sectional view taken along line XII-XII showing a light emitting device that is configured by a conventional shadow mask accelerating anode electrode.

FIG. 14 is a partial perspective view showing a conventional light emitting device.

FIG. 15 is a partial cross-sectional side view showing a conventional light emitting device.

[Explanation of symbols]

1 Vacuum Envelope 2 Front Panel 3 Back Plate 4 Cylindrical Side Plate 5 Fluorescent Display 5G Fluorescent Surface 6 Accelerating Anode Electrode Group 6a First Partition Plate 6b Second Partition Plate 6c Field Emission Prevention Plate 7 Cathode Electrode Group 8 Grid electrode group 10 Back electrode group 13 Getter 18 Getter mounting plate 21 Accelerating anode electrode for shadow mask 21a First partition plate for shadow mask 21b Second partition plate for shadow mask 21c Third partition plate for shadow mask 21d Shadow Mask for field emission prevention 21e Cutout 22 Opening

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kozaburo Shibayama 6-14 Maruo-cho, Nagasaki City Mitsubishi Electric Corporation Nagasaki Works (72) Inventor Zenichiro Hara 6-14 Maruo-cho, Nagasaki City Mitsubishi Electric Corporation Nagasaki (72) Inventor Yoji Yamaguchi 6-14 Maruo-cho, Nagasaki-shi Mitsubishi Electric Corporation Nagasaki Works

Claims (10)

[Claims] 1. A vacuum envelope in which a front panel is attached to a front surface of a tubular side plate and a rear panel is attached to a rear surface of the tubular side plate in an airtight manner, and a fluorescent display portion formed by arranging fluorescent surfaces in a matrix on an inner surface of the front panel. And an accelerating anode electrode group consisting of a plurality of accelerating anodes for accelerating an electron beam that is vertically fixed to the front panel so as to surround the fluorescent screen of the fluorescent display unit, and corresponding to the fluorescent screen. A cathode electrode group in which cathodes for electron emission are independently arranged, a grid electrode group including a plurality of control grids arranged between the cathode electrode group and the phosphor screen, and the cathode electrode group And a back electrode group in which a plurality of back electrodes are provided on the back side, and a getter is provided on a part of the acceleration anode via a getter mounting plate so as to face the inner surface of the tubular side plate. For light emitting element Then, a part of the accelerating anode electrode group near the inner surface of the tubular side plate is used, and the first partition is bent inside the vacuum envelope at a substantially right angle to the tubular side plate. A light emitting element characterized by having a plate. 2. A vacuum envelope in which a front panel is attached to the front surface of a tubular side plate and a back panel is attached to the back surface of the tubular side plate in an airtight manner, and a fluorescent display portion formed by arranging fluorescent surfaces in a matrix on the inner surface of the front panel. And an accelerating anode electrode group consisting of a plurality of accelerating anodes for accelerating an electron beam that is vertically fixed to the front panel so as to surround the fluorescent screen of the fluorescent display unit, and corresponding to the fluorescent screen. A cathode electrode group in which cathodes for electron emission are independently arranged, a grid electrode group including a plurality of control grids arranged between the cathode electrode group and the fluorescent screen, and the cathode electrode group And a back electrode group in which a plurality of back electrodes are provided on the back side, and a getter is provided on a part of the acceleration anode via a getter mounting plate so as to face the inner surface of the tubular side plate. Smell of light emitting element Then, using a part of the accelerating anode electrode group near the inner surface of the tubular side plate, the inside of the vacuum envelope is approached until it approaches from the substantially parallel to the tubular side plate to a substantially right angle ( A light-emitting element characterized by being provided with a bendable second partition plate (more than 0 degree and less than 90 degrees). 3. A light emitting device according to claim 1, further comprising a field emission prevention plate which is formed by using a part of the first partition plate and is bent substantially at a right angle in a direction approaching the control grid side. . 4. A vacuum envelope in which a front panel is attached to a front surface of a tubular side plate and a back panel is attached to a rear surface of the tubular side plate in an airtight manner, and a fluorescent display portion formed by arranging fluorescent surfaces in a matrix on an inner surface of the front panel. And an accelerating anode electrode group consisting of a plurality of accelerating anodes for accelerating an electron beam that is vertically fixed to the front panel so as to surround the fluorescent screen of the fluorescent display unit, and corresponding to the fluorescent screen. A cathode electrode group in which cathodes for electron emission are independently arranged, a grid electrode group including a plurality of control grids arranged between the cathode electrode group and the phosphor screen, and the cathode electrode group And a back electrode group in which a plurality of back electrodes are provided on the back side, and a getter is provided on a part of the acceleration anode via a getter mounting plate so as to face the inner surface of the tubular side plate. For light emitting element The getter is attached to the accelerating anode electrode group, one side of which is located near the inner surface of the tubular side plate, via the getter mounting plate, and the other side of which is located on the control grid side. A light emitting element which is close to the inner surface of the side plate and spreads toward the one side from the other side toward the inner side of the vacuum envelope at an inclination angle θ with respect to the inner surface of the cylindrical side plate. . 5. A vacuum envelope in which a front panel is attached to a front surface of a cylindrical side plate and a rear panel is attached to a rear surface of the tubular side plate in an airtight manner, and a fluorescent display portion formed by arranging fluorescent surfaces in a matrix on an inner surface of the front panel. And a shadow mask accelerating anode for accelerating the electron beam, which is composed of a flat plate in the shape of a shadow mask in which a plurality of square openings for transmitting the electron beam are arranged in front of the fluorescent display portion. An electrode, a cathode electrode group in which electron emission cathodes are independently arranged corresponding to the phosphor screen, and the cathode electrode group and the shadow mask accelerating anode electrode. A grid electrode group consisting of a plurality of control grids,
In a light emitting device including a back electrode group in which a plurality of back electrodes are arranged on the back side of the cathode electrode group, a part of the shadow mask acceleration anode electrode is used in the vicinity of the inner surface of the tubular side plate. A first partition plate for a shadow mask provided, which is bent in the direction of the front panel in parallel with the inner surface of the tubular side plate in close proximity to the first partition plate for a shadow mask and a getter mounting plate. A light emitting device having a getter. 6. A part of the first partition plate for the shadow mask in which a part where the getter is arranged is cut out to near the bent part, and the getter is arranged in the cutout part through a getter mounting plate. The light emitting device according to claim 5, wherein the light emitting device is provided. 7. The first partition plate for a shadow mask is provided with a cutout portion at a portion corresponding to an electron beam passage opening and a corresponding portion. Light emitting element. 8. A vacuum envelope in which a front panel is attached to a front surface of a tubular side plate and a rear panel is attached to a rear surface of the tubular side plate in an airtight manner, and a fluorescent display portion formed by arranging fluorescent surfaces in a matrix on an inner surface of the front panel. And an anode electrode for accelerating a shadow mask for accelerating an electron beam formed of a flat plate of a shadow mask in which a plurality of square openings for transmitting an electron beam corresponding to the phosphor screen are arranged in front of the fluorescent display portion. And a cathode electrode group in which cathodes for electron emission are independently arranged corresponding to the phosphor screen, and a plurality of cathode electrode groups are provided between the cathode electrode group and the shadow mask accelerating anode electrode. In a light emitting device comprising a grid electrode group consisting of the control grid and a back electrode group in which a plurality of back electrodes are arranged on the back side of the cathode electrode group, a light emitting device is provided near the inner surface of the tubular side plate. A first partition plate for a shadow mask provided by using a part of an accelerating anode electrode for a shadow mask, in which a getter is arranged on the first partition plate for the shadow mask via a getter mounting plate. The first partition plate for the shadow mask is extended in parallel along the inner surface of the tubular side plate from the shadow mask accelerating anode electrode to the vicinity of the phosphor screen, and the opposite side to the control grid side. It is a second partition plate for a shadow mask that extends and is provided by using a part of this extended portion, the end of which is substantially perpendicular to the inner side of the vacuum envelope with respect to the tubular side plate. A light-emitting device characterized by being bent into. 9. A vacuum envelope in which a front panel is attached to the front surface of a tubular side plate and a rear panel is attached to the back surface of the tubular side plate in an airtight manner, and a fluorescent display portion formed by arranging fluorescent surfaces in a matrix on the inner surface of the front panel. And an anode electrode for accelerating a shadow mask for accelerating an electron beam formed of a flat plate of a shadow mask in which a plurality of square openings for transmitting an electron beam corresponding to the phosphor screen are arranged in front of the fluorescent display portion. And a cathode electrode group in which cathodes for electron emission are independently arranged corresponding to the phosphor screen, and a plurality of cathode electrode groups are provided between the cathode electrode group and the shadow mask accelerating anode electrode. In a light emitting device comprising a grid electrode group consisting of the control grid and a back electrode group in which a plurality of back electrodes are arranged on the back side of the cathode electrode group, a light emitting device is provided near the inner surface of the tubular side plate. A first partition plate for a shadow mask provided by using a part of an accelerating anode electrode for a shadow mask, in which a getter is arranged on the first partition plate for the shadow mask via a getter mounting plate. The first partition plate for the shadow mask is extended in parallel along the inner surface of the tubular side plate from the shadow mask accelerating anode electrode to the vicinity of the phosphor screen, and the opposite side to the control grid side. It is a third partition plate for a shadow mask that extends and is provided by using a part of this extended portion, and its end is substantially parallel to the inner side of the vacuum envelope with respect to the tubular side plate. A light-emitting element characterized in that it is configured to be bendable from a position close to a right angle (more than 0 degree and less than 90 degrees). 10. A field emission prevention plate for a shadow mask, which is formed by using a part of the second partition plate for the shadow mask and is further bent substantially at a right angle in the direction approaching the control grid side. Item 9. The light emitting device according to item 8.