JPH0627986B2 - Image display device - Google Patents

Description

The present invention relates to a high-luminance light-emission image display device, and more particularly to its display drive.

[Conventional technology]

For example, a large number of light-emitting display cells each having a so-called phosphor trio composed of phosphor layers of red, green, and three colors are arrayed to form, for example, 40 pixels wide.
There has been proposed a huge image display device capable of obtaining a large screen of m and 25 m in length.

The light emitting display cell used in this image display device is, as shown in FIGS. 25 and 26, a glass panel (1) front panel (1A).
The fluorescent layer (2) [(2R), (2G), (2B)] of three colors of red, green and blue is deposited and formed on the inner surface of the so that it is surrounded by the carbon layer (3). Each fluorescent layer (2R), (2G), (2B)
Facing the three wire cathodes (K) [(K _R ),
_(K G), _{(K B)]} and a first grid (control electrode)
(G ₁ ) [(G _1R ), (G _1G ), (G _1B )] and a common second grid (accelerating electrode) (G ₂ ) are arranged.

Each color phosphor layer (2R), (2G), and (2B) is surrounded by a separator (3), and an electron beam from each wire cathode (K) irradiates the corresponding phosphor layer (2). To be done. In this case, the anode terminal (5) that supplies the anode voltage to the fluorescent material layer (2) is a glass casing via the separator (3).
Derived from between the front panel (1A) and side plate (1C) of (1),
Each terminal (6) of the other cathode (K), the first grid (G ₁ ) and the second grid (G ₂ ) has a rear panel (1B) and a side plate (1).
It is derived from between C). In this light emitting display cell, the anode voltage is supplied to the phosphor layer (2) through the anode terminal (5), and the voltage of the anode side and the second grid (G ₂ ) is fixed to the first grid (G ₁ ). It is selectively turned on or off depending on the applied voltage.

[Problems to be solved by the invention]

While an image display device using such a light emitting display cell can obtain a huge screen, it is unsuitable for obtaining an image display device with a large screen of an appropriate size. Therefore, when considering practical use,
It is desired that the size be appropriately reduced.

The present invention provides a high-luminance light-emission image display device that enables miniaturization, suppresses heat generation of a display cell, and simplifies a drive circuit.

[Means for solving problems]

The present invention comprises a phosphor trio consisting of phosphor layers of three colors of red, blue and green, which is a plurality of sets of picture elements, and a plurality of sets of cathodes and control electrodes corresponding to the respective phosphor trios. An image display device is configured by arranging a large number of display cells each having a first grid and an electrode unit including a second grid as an acceleration electrode in a matrix in the vertical and horizontal directions. In this image display device, the cathodes in each electrode unit are connected in common in the horizontal direction, the first grids are connected in common in the vertical direction, and line switching in the horizontal direction of the picture elements is performed by the cathode to perform display switching, that is, image display. Control is done on the first grid. Then, a horizontal line is selected by sequentially applying a switching voltage from the upper row to the lower row of the cathodes commonly connected in the horizontal direction, and the drive voltage is sequentially provided to each first grid commonly connected in the vertical direction to sequentially generate the cathodes. An electron beam from the device controls the corresponding trio of phosphors, and the pixels are sequentially luminescently displayed to form an image.

[Operation] According to the above-described image display device, the cathodes of the respective electrode units are commonly connected in the horizontal direction, and line switching in the horizontal direction of the picture elements is performed by the cathodes, whereby heat generation of the display cell is reduced. Further, since the first grids are commonly connected in the vertical direction, the driving IC module for the first grids is saved and the driving circuit is simplified.

Then, by arranging a large number of display cells in which a plurality of picture elements, that is, phosphor trios are integrally incorporated, a large-screen display device can be manufactured that is miniaturized to a practical level.

〔Example〕

Hereinafter, embodiments of the image display device according to the present invention will be described in detail with reference to the drawings.

FIG. 1, FIG. 2, and FIG. 3 show a front view, a side view, and a perspective view, respectively, with one part broken away showing an example of a fluorescent display tube used in the present invention, that is, a unit cell.

In the figure, (11) is the front panel (11A) and the rear panel (11A).
Shown is a glass enclosure consisting of B) and side plates (11C). This glass enclosure (11) is placed vertically on the front panel (11A), for example.
The size is 41 mm x 86 mm. In this glass housing (11), there are a plurality of groups of fluorescent display portions each consisting of a fluorescent material layer, that is, eight sets of so-called fluorescent material trios (12) [(12
a), (12b), (12c), (12d), (12e), (12f
), (12g), (12h)] and these phosphor trios (1
8 sets of electrode units (13) [(13a
), (13b), (13c), (13d), (13e), (13f
), (13g), (13h)] are arranged facing each other.

Eight sets of fluorescent trios (12) are formed by applying a fluorescent layer to the inner surface of the front panel (11A), and four sets of each are placed above and below 2
Arranged in rows, in which case each phosphor trio (12) has three phosphor layers (14R), (14G) that emit red, green and blue light.
), (14B). Specifically, as shown in FIG. 8, a carbon layer (15), which is a conductive layer, is printed in a frame shape on the inner surface of the front panel (11A), and each of the red folds corresponds to each void in the frame shape. A phosphor layer (14R), a green phosphor layer (14G), and a blue phosphor layer (14B) are formed by printing so as to partially extend over the carbon layer (15), and an intermediate film is formed on the front surface of the phosphor layer (14R). As a result, a metal back layer (16) made of, for example, aluminum is deposited. And in this case, in the fluorescent trio (12), the red fluorescent layer (14R) is provided at the center,
Green phosphor layer (14G) and blue phosphor layer (14B) on both ends
However, in particular, the green phosphor layer (14G) and the blue phosphor layer (14B) are arranged side by side in opposite directions (see FIG. 10).

An electrode unit (13) is arranged on the rear panel (11B) side so as to face each of the phosphor trios (12). This electrode unit (12) has three red fluorescent material layers (14R), green fluorescent material layers (14G) and blue fluorescent material layers (14B) facing each other of the fluorescent material trio (12). Wire cathode (K)
[(K _R ), (K _G ), (K _B )] and three first grids (G ₁ ) [G ₁ ] [G _R ] facing the wire cathodes (K _R ), (K _G ), and (K _B ), respectively. (G _1R ), (G _1G ), (G _1B )]
And the second grid (G ₂ ) is arranged in common to the three first grids (G ₁ ).

The specific assembly and configuration of this electrode unit (13) is the fourth
This is as shown in FIGS. That is, as shown in FIG. 4, it has three square openings (17), and each opening (17)
An insulating substrate, for example, a ceramic base (19) having a pair of terminal pins (18a) and (18b) penetratingly planted is provided at a position sandwiching. The E-shaped conductive support pieces (20a) and (20b) respectively paired with the terminal pins (18a) and (18b) of this pair.
) Are commonly spot welded, that is, one conductive support piece (20a) is commonly spot welded to the three terminal pins (18a) of one row, and the other conductive support piece (20b) is the other row. After being commonly spot-welded to the three terminal pins (18b) of the above, the wire cathodes (K _G ), (K _R ), and (K _B ) are connected between the conductive support pieces (20a) and (20b). Be stretched. One support piece (20a) fixes one end of the wire cathode (K) and the other support piece (20a).
b) is provided with a bent spring portion (21) at its tip, and each wire cathode (K) is attached to this spring portion (21).
The other end of is fixed. As a result, even if the wire cathode (K) expands due to temperature rise, the expansion is absorbed by the spring portion (21) and the wire cathode (K) does not loosen. Reference numeral (22) is a terminal led out from the support piece (20a). Each wire cathode (K) is formed, for example, by coating a surface of a tungsten heater with a carbonate serving as an electron emitting substance.

Next, the first grids (G _1G ), (G _1R ) (G _1B ) are supported by the openings (17) of the ceramic base (19). Each first grid (G _1G ), (G _1R ), (G _1B ) has a curved kamaboko having a cylindrical surface facing each wire cathode (K _G ), (K _R ), (K _B ). A plurality of slits (23) are formed on the cylindrical surface at a predetermined pitch along the longitudinal direction, and each of the curved ends has a leg portion (width approximately equal to the width of the opening portion (17)). 24) and (25) are provided. These legs (24) and (25)
Is inserted into the opening (17) of the ceramic base (19). At this time, both legs (24) and (25) are inserted so as to be narrowed in the opposite direction. By the force of returning to (2), both legs (24) and (25) come into pressure contact with the inner wall of the opening (17), thereby temporarily supporting. One leg (24) is long because it is used as a terminal,
The other leg (25) is formed to be short, and when inserted into the opening (17), one leg (24) penetrates the opening (17) and the other leg (25) opens. (17) It is made to stop inside.

On the other hand, the casing (26) of the electrode unit is provided. The housing (26) constitutes a part of the second grid (G ₂ ), is made of a conductive material, and has three openings (27) [(27G) facing the first grid (G ₁ ) on the front surface. ), (27R),
(27B)] is provided, and a separator (28) for partitioning the openings (27) from each other is integrally extended inward. This case (26) is made by drawing and barrel polished,
It is configured to be difficult to discharge. The common second grid (G ₂ ) is inserted and arranged in the housing (26). The second grid (G ₂ ) is the first grid (G _1G ), (G _1R ),
The slit-like mesh portions (29G), (29R), and (29B) are formed at the same corresponding positions as the slits (23) of the first grid (G ₁ ) in the portion corresponding to (G _1B ).
In this case, the mesh part (29G), (29R), (29B).
A groove (30) through which the separator (28) is inserted is provided between the two. And each slit part (29G), (29R),
The second grid (G ₂ ) is arranged in the casing (26) such that the (29B) faces the openings (27G), (27R), (27B), and the separator (28) is inserted into the groove (30). To be done. This second grid (G ₂ ) is spot-welded to a part of the housing (26) and is mechanically and electrically connected to the housing (26). Therefore, the housing (26) is It will also serve as 2 grids (G ₂ ).

Next, a pair of insulative separators (31A) and (31B) is inserted along one of the facing inner wall surfaces of the casing (26). The inner surfaces of the separators (31A) and (31B) are provided with three groove portions (32) [(32G), (32R), (32B)] into which the side portions of the first grid (G ₁ ) can be fitted. ing. (33) is a through hole. This separator (31A),
(31B), when inserted into the case (26), the case (2
It is inserted into the gap between the wall of (6) and the separator (28) and held in a sandwiched manner. Also separators (31A), (31B)
The upper end of the abuts on the second grid (G ₂ ).

Then, in the casing (26) in which the second grid (G ₂ ) and the separators (31A) and (31B) are assembled as described above, the wire cathode (K) and the first grid (G ₁ ) are attached to the ceramic base ( 17) with a separator (31A
), (31B) are inserted so that the rear end faces are in contact with each other. At this time, each 1st grid (G _1G ), (G _1R ),
Both ends of (G _1B ) are fitted to the separators (31A), (31B grooves (32G), (32R), (32B), respectively.
Each of the first grids (G ₁ ) has its legs (24), (25) inserted into the openings (17) of the ceramic base (19), and both sides of the first grid have separators (31A).
By fitting the groove portion (32) of (31B), the positioning is accurately performed. In addition, the terminal (22) bent and extended from the one support piece (20a) on which the wire card (K) is stretched has a ceramic base (19) and a separator (31a).
It is led out to the outside through a notch in the housing (26). Next, one frame-shaped retainer (34A) of the retainer structure (34) made of a conductive material is fitted into the housing (26) to form a bent portion (34a) of the retainer (34A). The ceramic base (19) is held by spot welding with the casing (26) to form the electrode unit (13) shown in FIGS. 5 to 7.

As shown in FIG. 4, the conductive retainer structure (34) includes retainers (34) that can be inserted into the casings (26) of four sets of electronic units.
A), (34B), (34C), and (34D) are integrally connected to each other by the conductive connecting part (35), and this connecting part (35) is exactly in the notch (36) of the housing (26). Configured to mate.
Reference numeral (36) is an attachment portion spot-welded to a lead frame (not shown), and (37) is an attachment portion attached to the glass casing (11). Configuration in which the common connection of the second grid (G ₂₎ to one another in each electrode unit (13a) ~ (13h) is taken. For example, as shown in FIGS. 11 to 13, a common conductive auxiliary member (68) is provided, and this auxiliary member (68) is provided.
Each electrode unit (13a) ~ (13h) is the retainer structure (3
4) Spot welded. Alternatively, although not shown, the notch portion of each electrode unit housing (26) when the notch (86) is formed is bent, and the auxiliary member (68) is spot-welded to this bent portion to form each second grid ( G ₂ ) are commonly connected.

On the other hand, each color phosphor phase (14R of 8 pairs of phosphor trio (12)
), (14G) and (14B) are surrounded by a separator structure (40) made of a conductive material as shown in FIG. The separator structure (40) prevents the electron beam from the wire cathode from striking the first grid (G ₁ ) and the second grid (G ₂ ) so that secondary electrons from the second grid (G ₁ ) do not emit light to the adjacent phosphor layer. It also has the function of spreading the electron beam from each wire cathode (K) so that the electron beam from each wire cathode (K) is irradiated to the entire corresponding phosphor layer (14), that is, forming a so-called diffusion lens. ,
At the same time, it is used as a power supply means for applying a high voltage, for example, 8 KV, to each fluorescent trio (12). When assembling this separator structure (40), the glass housing (1
It is supported between the front panel (11A) and side plate (11C) of 1) and fixed by a glass frit. That is, this separator structure (40) has a separator part (41) divided into three so as to surround each fluorescent substance layer of each of eight sets of fluorescent substance trios (12). The parts (41) are integrally connected to each other via the electrode plate (42), and the upper ends thereof are provided with the supporting claws (43) protruding outward, respectively. Further, elastic bending pieces (44) for positioning are cut and raised on the side portions of the separator structure (40). Therefore, the separator structure (40) is attached to the side plate (11C) of the glass casing (11).
When it is inserted into the side plate (11C) from above, the supporting claw (43) just comes into contact with the upper end surface of the side plate (11C) to support the separator assembly (40), and at the same time, the bending piece (44) is attached to the inner wall of the side plate (11C). The separator structure (40) is held in place by abutting. Further, a protrusion (45) (see FIG. 8) is provided on a portion of the separator structure (40) corresponding to the electrode plate, and the protrusion (45) accommodates the separator structure (40) in the side plate (11C). When the front panel (11A) is overlaid and sealed on the side plate (11C), it is just in contact with the metal back layer (16) or the carbon layer (15). This allows the high voltage from the high voltage terminal or anode lead (46) to be supplied to each phosphor trio (12) in common. As shown in FIG. 8, one end of the anode lead (46) to which a high voltage is applied is connected to the electrode plate (42) of the separator assembly (40) and the other end thereof is a glass back panel (11B). ) Is exhausted to the outside through an exhaust pipe (47) attached to (). At this time, the anode lead (46) is made of glass-wrapped Dumet wire (Cu alloy) around the exhaust pipe (47). Therefore, the airtightness between the anode lead (46) and the exhaust pipe (47) is maintained. A high pressure cover (48) is fixed to the outside of the exhaust pipe (47) via an adhesive (49), and an anode lead (46) is soldered to an external terminal plate (50) provided on the high pressure cover (48). Attached. Then, the external lead (52) is electrically connected to the terminal plate (50) via the spring (51), and the high-voltage cover (48) is protected by a detachable cover (53) made of, for example, silicon rubber. It

In the electrode unit (13), eight sets of electrode units (13a) to (13h) are fixed via the retainer structure (34) and the common conductive auxiliary member (68), and then on the lead frame (60). Retainer structure placed in place (34)
The mounting portion (36) and the lead frame (60) are spot-welded. Then, wire cathode (K) terminal pin (1
8), the lead portion (24) of the first grid (G ₁ ) and the retainer structure (34) on the side of the electrode units (13a) to (13d) respectively correspond to the lead portions of a predetermined lead frame, for example, lead wires ( (Not shown). At this time, as described above, the second grid (G ₂ ) has eight sets of electrode units (13a) to (13h) each having a conductive auxiliary member (68).
Connected in common by being connected by. The first grid (G ₁ ) is between two electrode units arranged in each longitudinal direction, that is, between the electrode units (13a) and (13e),
Between the electrode units (13b) and (13f), the electrode unit (13
c) and (13g) and electrode unit (13d) and (13h)
Commonly connected between. That is, between vertically arranged electrode units, the G _{1Rs at the} center are commonly connected, (G _1B ) and (G _1G ) at the right end are commonly connected, and (G _1G ) and (G _1B ) at the left end are commonly connected. And are commonly connected. The wire cathode (K) has electrode units (13a) to
The wire cathodes (K) of (13d) are commonly connected, and the wire cathodes (K) of the electrode units (13e) to (13h) are commonly connected.

Then, the lead of the wire cathode (K), the lead of the first grid (G ₁ ) and the lead of the second grid (G ₂ ) are respectively sealed between the rear panel (11B) and the lower end surface of the side plate (11C). It is led to the outside through the section.

(61F) is a wire cathode lead commonly connected between the electrode units (13e) to (13h), (62F) is a wire cathode lead commonly connected between the electrode units (13a) to (13d), (63G) ₂ ) is the lead of the second grid (G ₂ ), (64G ₁ ) is the lead of the three first grids (G ₁ ) commonly connected between the electrode units (13a) and (13e),
(65G ₁ ) is a lead of three first grids (G ₁ ) connected in common between the electrode units (13b) and (13f), (66G ₁ )
G ₁ ) is a lead of three first grids (G ₁ ) commonly connected between the electrode units (13c) and (13g), (67G ₁ )
Are leads of the three first grids (G ₁ ) commonly connected between the electrode units (13d) and (13h).

The electrode units (13a) to (13d) and the electrode units (13e) to (13h) held by the retainer structure (34).
) Is a retainer structure (3) when sealing the glass enclosure (11).
It is fixed by sandwiching the mounting parts (37) at both ends of 4) between the rear panel (11B) and the side plate (11C).

Next, the operation of such a configuration will be described. Each fluorescent trio (12)
Red, green and blue phosphor layers (14R) (14G) (14B
) Is supplied with an anode voltage of, for example, about 8 KV through the anode lead (46). On the other hand, in each of the commonly connected wire cathodes (K) in the upper row and the lower row,
With this turned on, a switching voltage of, for example, 0 V to 5 V or less is applied to each column selection voltage, and each first grid (G _1R ) (G _1G ) ( _1B ) has, for example, 0 to 5 V.
The following drive voltage is given, and the second grid (G ₂ ) of each electrode unit (13a) to (13h) is commonly connected.
A fixed voltage of 20V or less is applied.

In this configuration, the voltage on the anode side is fixed, the column is selected by the switching voltage applied to the wire cathode (K), and the on / off display is selectively performed by the voltage applied to the first grid (G ₁ ). It is a thing. That is, for example, the upper row electrode units (13a) to (13d
) Is applied with 0 V to the wire cathode (K), and the wire cathodes (K) of the lower row electrode units (13e) to (13h) are applied with a cutoff of 5 V, for example, through the lead (64G ₁ ). 5V for 1 grid (G ₁ )
Is selected, the first phosphor trio (12a) is selected,
The electron beam from the cathode (K) in the electrode unit passes through the first grid and is accelerated by the second grid (G ₂ ) and hits the corresponding phosphor layers (14R) (14G) (14B) to emit light. Display it. At this time, the first grid (G
_The emission brightness is controlled by controlling the pulse width (application time) of the voltage (5 V) applied to ( ₁ ).

Then, when 0 V is applied to the first grid (G ₁ ), the electron beam from the cathode is cut off and the corresponding phosphor layer does not emit light. And the lead (64G ₁ )
If a voltage is sequentially applied to the first grid (G ₁ ) through (65G ₁ ), (66G ₁ ) and (67G ₁ ), the fluorescent trio (12
a) to (12d) are lit, the voltage of the wire cathode (K) is switched next, 0 V is applied to the wire cathode (K) in the lower row, and the leads (64G ₁ ) to (67G ₁ ) are similarly sequentially turned to the first position. When a voltage of 5 V is applied to the grid (G ₁ ), the fluorescent trios (12e) to (12h) in the lower row are luminescently displayed.

The electron beam from the wire cathode (K) is spread by the first grid (G ₁ ) and the separator (41) and is applied to the entire surface of the phosphor layer (14). In addition, the electron beam from the wire cathode (K) is transmitted to the first grid (G ₁ ) and the second grid (G ₁ ).
Hitting the grid (G ₂ ), the first grid (G ₁ ), the second grid
Secondary electrons from the grid (G ₂ ) are generated.
Next electron is the separator (28) of the second grid case (26)
And the adjacent phosphor layer is not hit by the separator (41) on the anode side. In this way first
By selectively controlling the voltages of the grid (G ₁ ) and the second grid (G ₂ ), each phosphor trio (12) is sequentially illuminated and displayed with high brightness.

Thus, in this embodiment, the fluorescent display circle (71) as described above is used.
A plurality of units are assembled in a unit case in a matrix in the vertical and horizontal directions to form one unit, and a large number of these units are arranged in a matrix in the vertical and horizontal directions to form a large-screen image display device. Then, in this image display device, horizontal line switching of the picture elements is performed by sequentially applying a switching voltage from the upper row to the lower row of the cathodes commonly connected in the horizontal direction, and the first grids commonly connected in the vertical direction are formed. By sequentially applying the drive voltage, the picture elements are sequentially displayed by light emission, that is, the image display control is performed.

In this fluorescent display cell (71), eight picture elements, that is, the phosphor trio (12) are compactly built in one cell, and therefore the picture elements are downsized as a whole.

Also, three wire cathodes (K) and a first grid (G
₁ ) and a common second grid (G ₂ ) are unitized so that the unit housing (26) also serves as the second grid (G ₂ ), and this electrode unit (12) is made into each phosphor trio (1).
Since it is arranged corresponding to 2), such display cell (7
Assembling and manufacturing of 1) is easy. The second grid (G
_{Since the} unit housing (26) that also serves as ₂ ) is made by so-called drawing, the corners are rounded and the discharge withstand voltage increases,
Accidents due to discharge are prevented.

In addition, in the electrode unit (13), each first grid (G ₁ ) does not use spot welding or the like, and the opening (17) provided in the ceramic base (19) and the insulating separator (31).
Since it is positioned and supported by the groove portions (32) of A) (31B), the electrode unit (13) can be assembled in a sufficiently small size.

Further, when a large screen is formed by arranging a large number of display cells (71), the fluorescent trio (12) on the fluorescent surface is moved upward, downward, left,
Since the right side is arranged at an equal pitch, the adjacent display cells (7
Almost no gap can be made between 1) and the display cell (71). However, in this display cell (71), the anode lead (46) is located at the exhaust pipe (4) from the rear panel (11B) side of the glass casing (11).
Since it is derived through 7), the adjacent display cells (71)
Can be placed close to each other.

Furthermore, in the trio of fluorescent trio (12) on the fluorescent surface, the red fluorescent layer (14R) is arranged in the center and the green and blue fluorescent layers (14G) and (14B) are arranged on both sides. In particular, the apparent resolution can be increased by changing the arrangement of the green and blue phosphor layers (14G) and (14B) between the upper row and the lower row.

In the above example, eight sets of fluorescent trio were arranged, but the number of sets is not limited to this and can be selected as appropriate.

Further, the respective terminals of the electrode unit and the lead frame can be connected by a method of directly connecting the two without using lead wires. Particularly in the case of the wire cathode (K) terminal, the terminal (22) of the supporting piece (20a) can be bent and extended and directly connected to the lead frame.

Also, in the upper electrode unit (13), the terminal pins (18a) and (18b) are planted in the ceramic base (19). For example, as shown in FIG. 15 and FIG.
It is also possible to omit a) (18b). 15th
In FIG. 16 and FIG. 16, a through hole (83a) for supporting a pair of conductive support pieces (20a) and (20b) at positions sandwiching three openings (17) for supporting the first grid (G ₁ ), respectively. And (83b) forming ceramic base (19) is provided. On the other hand, a pair of conductive support pieces (20a) and (20b)
As a support part (84G) for mounting each wire cathode
(84R) and (84B) are connected to each other, and the rear end (85R) that serves as a lead of the central support portion is extended, and the rear ends (85G) and ((B) of both support portions (84G) and (84B) are 85
B) is folded back to have elasticity. The support part (84G) (84G) of one conductive support piece (20a)
R) (84B) is configured as a fixed support part, but the support part (84G) (84R) (84B) of the other conductive support piece (20b)
) Is formed as a spring portion (21 ') as a whole by providing a notch in the base portion. (86) is a fall prevention portion of the conductive support pieces (20a) and (20b). End support portion (84G) (84R) each wire cathode _{(K B)} of (84B) (K R) ( k G) is stretched, the cuts for perform center out of the wire cathode (K) is And has a bent shape. Both support pieces (20
a) and (20b) are inserted into the through holes (83a) and (83b) respectively, and the supporting pieces (20a) and (20b) are attached to the ceramic base (19) by the folded back ends (85G) (85B) on both sides. Then, the wire cathodes (K _G ) (K _R ) (K _B ) are stretched between the support pieces (20a) and (20b). At this time, each lead (85R) is led out through the ceramic base (19). According to this structure, the terminal pins (18a) and (18b) can be omitted, and the electrode unit (1
It is possible to reduce the number of parts that make up 2).

Also, in the above example, the mesh part of the second grid G ₂ (29G)
(29R) and (29B) are slit-shaped, but in this case, the slits have a large opening in the longitudinal direction, so Figs. 17 and 18
As shown in the figure, there is rubbing that constitutes an electronic lens by the entry of high electrolysis (80). On the other hand, if the mesh part (29G) (29R) (29B) is made into a fine turtle shape as shown in Fig. 19, the entry of high electric field is eliminated (see Fig. 20), and the electron lens is formed. Not done.

21 and 22 show another embodiment of the display cell used in the image display device of the present invention having two sets of fluorescent trio.

In this example, the front panel (11A) is 39 mm long and 86 mm wide.
2 sets of electrode units (90) [(90a), (90b)] are placed in the glass enclosure (11) of the size, and the front panel (11A) is placed so as to face these electrode units (90). Two sets of fluorescent trio on the inside (12) [(12a), (12b)]
It is configured by arranging. On the fluorescent surface side, as in the above, each color fluorescent layer (14R), (14G), of each fluorescent trio (12),
A separator structure (40) made of a conductive material is arranged so as to surround (14B).

The electrode unit (90) in this case is a unit case (26) in which the second grid (G ₂ ) having fine mesh-shaped mesh parts (29B), (29R), and (29G) is spot-welded.
And the three first grids (G _1B ), (G _1R ), (G _1G ).
If, consisting a conductive support piece pair (20a) and (20b) stretched by three wire cathodes between _{(K B) (K R)} (K G). Then, the unit casing (26) forming a part of the second grid (G ₂ ) and each first grid (G ₁ ).
And the pair of supporting pieces (20a) and (20b) are spot-welded directly and electrically and mechanically to the lead frame (60) arranged on the inner surface of the rear panel (11b) of the glass housing (11). Supported.

In the E-shaped conductive supporting piece (20) for supporting the wire cathode (K), one has a fixed supporting piece (20a) and the other has a spring portion (21 ') as shown in FIG. The support piece (20b) is made. Support piece (20a) (20b)
End each wire cathode _{(K B) (K R)} (K G) is stretched is made with bent shape with center out of the wire cathode (K) has a notch for perform the .

On the other hand, in this example, a conductive getter container (70) electrically and mechanically supported on a part of the separator structure (40) is arranged at a position near the front panel (11A).
The anode lead (46) is connected to 0).

Further, regarding the holding of the separator structure (40), the supporting claw (43) is omitted, and the separator structure (40) is directly fixed to the front panel (11A) of the glass frame (11) with the frit glass (81). It That is, an opening (80) is provided in the electrode plate of the separator assembly (40), and this opening (8
0) The extension part (82) to be extended and the front panel (11A) are fixed by the frit glass (81). In this case, on the front panel (11A) side, the carbon layer (15) and the metal back layer are not formed in the portion where the frit glass (81) is bonded. Therefore, the pattern of the carbon layer (15) is formed as shown in FIG. In addition, the separator structure (4
A plurality of cut-out portions (83) are integrally provided from the side of the opening (80) of (0) and elastically folded back to contact the metal back layer (16) and the carbon layer (15) to form the cut-out portions. Origin (8
By 3), the fluorescent surface and the separator structure (40) are electrically connected. When the image display device is configured, the frit glass portion is hidden because the front surface of the glass housing (11) is further covered with a frame body for shielding external light except for the fluorescent trio. When the separator structure (40) is thus directly fixed to the front panel (11A) of the glass housing (11), the supporting claws (43) are omitted, so that the discharge and the glass housing outside the glass housing are prevented. So-called creeping discharge along the inner surface of the side plate (11C) in the body is prevented. The method of holding the separator structure (40) and the contact between the separator structure (40) and the fluorescent surface can be applied to the examples of FIGS. 1 and 2 described above. In addition, in this embodiment, as shown in FIG.
A large-screen image display device is constructed by arranging a large number of display cells (71 ') shown in FIG. Display cell (7
When arranging 1 '), the columns (horizontal lines) are the same as above.
The green and blue phosphor layers (14G) and (14B) can be placed on the left and right to increase the apparent resolution.

Further, also in the image display device using this display cell (71 '), it is possible to adopt the driving method in which the horizontal line is switched by the cathode and the image display is controlled by the first grid as described above. . In this case, for example, when two or two rows of display cells (71 ') arranged vertically are combined, the cathode (K) is commonly connected to each of the upper row and the lower row, and the upper and lower display cells (71') are connected. The first grids (G ₁ ) corresponding to each other in the vertical direction are commonly connected.

〔The invention's effect〕

According to the present invention described above, it is possible to obtain a miniaturized high-luminance light-emitting display cell in which a plurality of groups of phosphor trio to be picture elements and corresponding electrode units are incorporated in a single cell. By arranging a large number of cells, it is possible to obtain a large-screen display device that is downsized to a degree suitable for practical use.

In particular, the cathodes of the electrode units are commonly connected in the horizontal direction, the first grid is commonly connected in the vertical direction, and horizontal line switching is performed by the cathode, and image display control is performed by the first grid. Therefore, the driving circuit is simplified and the driving IC module in the first grid is saved. Since this drive IC module is expensive, it is extremely useful in practice to be saved. Further, since the horizontal line switching is performed at the cathode, heat generation of the display cell is reduced. For example, when switching the upper and lower two rows of the embodiment, the heat generation is reduced to 1/2, and the life of the display cell can be extended.

Further, when the display cell incorporating the eight fluorescent trio shown in FIGS. 1 and 2 is used, as shown in FIG. The second grid is connected. Therefore, the conductive auxiliary member improves the positional accuracy of each electrode unit. Also, this conductive auxiliary member serves to prevent discharge when the same potential as that of the second grid is applied. That is, the conductive auxiliary member prevents the anode electric field from seeping out to the low voltage side, and prevents discharge between the separator to which the anode voltage is applied and the first and second grid leads and the cathode lead on the low voltage side. To be done. Therefore, stable driving can be performed.

[Brief description of drawings]

1 and 2 are a plan view and a side view with a part broken away showing an embodiment of a fluorescent display tube used in an image display device of the present invention, and FIG. 3 is a perspective view with a part broken away. 4 is an exploded perspective view of the electrode unit, FIG. 5 is a plan view of the electrode unit, FIG. 6 is a sectional view taken along the line AA of FIG. 5, and FIG. 7 is a sectional view taken along the line BB of FIG. Fig. 8 is an enlarged cross-sectional view of the main part of Fig. 2, Fig. 9 is a perspective view of the separator structure on the anode side, and Fig. 10 is a plan view showing the arrangement state of fluorescent substance trios.
11 is a perspective view showing a plurality of electrode unit parts connected,
12 and 13 are plan views and cross-sectional views thereof, FIG. 14 is a diagram showing a method of connecting cathodes, and FIGS. 15 and 16 show another example of a wire cathode supporting structure of an electrode unit. FIG. 17 is an exploded view and a sectional view, FIGS. 17 and 18 are a plan view of a second grid G ₂ used for explaining the present invention and a sectional view taken along the line CC, and FIG. 19 is another view of the second grid G ₂ . FIG. 20 is a cross-sectional view of an essential part showing an example, and FIGS. 21 and 22 are partially cutaway plan views showing another embodiment of the fluorescent display tube used in the image display device of the present invention. Figures and side views, FIG. 23 is a plan view showing a pattern of a carbon layer, FIG. 24 is a perspective view showing an example of a supporting piece of a wire cathode, and FIGS. 25 and 26 are examples of conventional display cells. It is a top view and its sectional view. (11) glass enclosure, (12) [(12a) ~ (12h)] is fluorescers trio, (13)) [(13a) ~ (13h)] is the electrode _unit, (K G) _{(K R} ) _{(K B)} is a wire _{cathode, (G 1G) (G 1R} ) (G 1B) first grid, _{(G 2)} and the second grid (17) is a ceramic base, (26) the electrode unit enclosure, (31A) (31B) are insulating separators,
(46) is an anode lead, and (47) is an exhaust pipe.

Claims (1)

[Claims] 1. A phosphor layer of three colors, red, blue and green,
A plurality of sets of phosphor trio serving as picture elements, and a plurality of sets of cathodes corresponding to the respective phosphor trios, an electrode unit including a first grid as a control electrode and a second grid as an accelerating electrode are provided. And a plurality of display cells arranged in a matrix in the vertical and horizontal directions, wherein the cathodes of the electrode units are connected in the horizontal direction in common and the first grids in the vertical direction are connected in common. The line switching in the horizontal direction of the picture elements is performed by the cathode, and the image display control is performed by the first grid. The switching voltage is sequentially applied from the upper row to the lower row of the cathodes commonly connected in the horizontal direction. The horizontal line is selected by applying the drive voltage to the first grids connected in common in the vertical direction. Ri image display device the electron beam is controlled corresponding phosphor trio, characterized by sequentially forming such picture elements is an image formed by the light emitting display from the cathode.