JPH0550091B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a vacuum container constituted by a glass face plate provided with phosphor dots and a rear container portion formed of metal; A counter electrode divided into segments placed opposite the plate, a periodic array of cathode filaments placed in front of the counter electrode, and an aperture for electron flow extraction placed in front of the cathode filament. The invention relates to a flat display device comprising an extraction anode and a control electrode structure disposed between the extraction anode and the faceplate.

[Prior Art] Such a flat, vacuum-sealed display device is described in German Patent No. P3622259.3. A planar cathode formed by a periodic array of cathode filaments was chosen because less power is required to cause the phosphor dots to emit uniform, high-intensity light. However, this specification does not provide a detailed explanation of the assembly and attachment of the electrode components located in the rear container section.

[Problems to be Solved by the Invention] It is an object of the present invention to provide a robust structure to a component consisting of various electrodes arranged in the rear container part of such a flat display device, and at the same time to simplify its manufacture. That's true.

[Means and effects for solving the problem] This object is such that a counter electrode divided into segments is arranged on a base plate attached to a rear container, an extraction anode and a control electrode structure are supported on a support frame, are mounted on the base plate with a narrow spacing between them, rod-shaped retaining members are mounted on opposite side edges of the support frame, and the cathode filament is fixed on the extraction anode and the base plate supported by the support frame. This is achieved by a flat display device having a plurality of lead-in conductor terminals that are stretched between the rod-shaped holding members in a space between the counter electrode and the rear container and hermetically sealed by a through bushing. Ru.

With such a configuration, a segmented counter electrode is supported on a base plate attached to the rear vessel, and the extraction anode and control electrode structures are supported on a support frame that maintains a narrow spacing to the base plate. The cathode filament is suspended between a pair of rod-shaped holding members, and the rod-shaped holding members are attached to opposite side edges of the support frame, so that the whole is combined into a single structural unit. can be done. Therefore, since it can be assembled in advance on the outside of the rear container portion, assembly is easy and a sturdy structure can be achieved. This not only simplifies the assembly of the flat display, but also greatly facilitates repair, since in the event of a failure this structural unit can be easily replaced.

[Example] The present invention will be explained in further detail by means of an example shown in the following accompanying drawings.

FIG. 1 shows a longitudinal section of a flat display device. The glass face plate 1 and the rear container part 2 form a vacuum container. A phosphor dot array 3 is provided inside the face plate 1, but the individual phosphor dots are not shown. The phosphor dots are preferably surrounded by a black matrix. The rear container part 2 is made of pure iron,
Preferably, the entire structure is covered with a protective nickel film.

The electrodes required for operating the flat display device, namely a periodically arranged cathode filament 4, a segmented counter electrode 5 on the base plate 10 located on the opposite side of the face plate of the cathode filament 4, for extracting the electron current; The extraction anode 6 with multiple apertures and the control electrode structure 7 are combined into one structural unit. This structural unit consists of the holding element 1
3 in the rear container part 2 (FIG. 3). Conductor terminals, which are hermetically sealed with through bushings 8 (only two are shown in detail) for leading out the terminals of the individual electrodes, are attached to the side walls of the rear container part 2. The face plate 1 can be soldered directly to the peripheral flange 9 of the rear container part 2. During this soldering of the face plate 1 to the rear container part 2, the flat display container is simultaneously evacuated. Since no heat treatment is performed thereafter, a solder glass that softens again can be used. A suitable solder glass is, for example, Schott type 4210. This has the advantage that in case of a failure, it is easily possible to repair the glass face plate 2 with the phosphor coating 3.

The rear container part 2 contains four getter wires 22 below the counter electrode 5, which are manufactured by the Italian SAES
Preferred is the company's product, which is activated by passing an electric current and evaporates without leaving any residue. Several getter wire pairs are connected to pins 21 whose first terminals are vacuum sealed by through bushings 23. The second terminal of the getter wire is fixed to the bottom of the rear container part 2, so that this getter wire is energized by connecting the pin 21 through the power supply and to the rear container part 2. The evaporated getter material of the getter wire is attached to the base plate 10.
and the bottom of the rear container part in such a way that it occupies the largest possible spatial area. It is also possible to use a non-vaporizable getter strip, such as SAES' product St101, which is energized by passing an electric current through it.

The structural unit fixed in the rear container part 2 (FIG. 2) comprises a base plate 10 and a frame 11, to which an insulating bar-shaped retaining element 12 is attached. The base plate 10 is the holding element 1
3 and is fixed to the rear container part 2 by means of this retaining element 13 (FIG. 3).
The frame 11 is supported on the base plate 10 via an insulating spacer 14. base plate 10
This frame is permanently connected to the base plate by a screw or rivet joint 15 surrounded by a ceramic bushing 16 in the region of . Desirably, these joint portions are located near the corners of the base plate. A rod-shaped retaining member 12 made of an insulating material such as glass is attached to two mutually opposite side edges of the frame 11 via a connecting member 19.

A counter electrode 5 divided into segments is attached to the side surface of the base plate 10 facing the phosphor coating 3. The segments of the counter electrode are connected to the base plate 1 through an insulator or an insulator strip.
Combined with 0. In front of it (in the direction of the face plate) is a periodic array of cathode filaments 4 arranged side by side in a plane parallel to the face plate, which form a surface cathode. One end of each cathode filament 4 is firmly attached to a contact member 17 fixed to the rod-shaped holding member 12. The other end of each cathode filament 4 is attached to a rod-shaped holding member 12 by a spring 20. If the contact members 17 and the springs 20 are arranged alternately in the longitudinal direction of the rod-shaped retaining member 12 (i.e. each filament in parallel has an alternating fixed end and a spring-supported end opposite each other). ) the spacing can be reduced.
The contact member 17 and the spring 20 extend through the bar-shaped retaining member 12 and are provided with a wire 18 which is connected to a pin in the through bushing 8.

An extraction anode 6 with apertures is mounted on the side of the frame 11 facing the periodic array of cathode filaments 4. It is, for example, a perforated metal plate joined to the frame 11 by soldering glass. The extraction anode 6 has a rectangular opening pattern with a size of 400 micrometers by 100 micrometers and a pitch of 1.14 mm in the horizontal direction (line direction) and 0.6 mm in the vertical direction. The extraction anode 6 is adjusted so that the center of the hole is horizontally aligned with the center of the segment strip. There are therefore as many apertures in the extraction anode line as there are segment strips.

Preferably, the extraction anode 6 is mounted in the frame 11 in such a way that it is under slight mechanical tension at the operating temperature, so that sagging is avoided. The frame is therefore constructed of a material with a coefficient of expansion such that the extraction anode is kept in a stretched state due to the difference in coefficient of thermal expansion after the soldering process.
In this way, displacement of the hole pattern during operation is completely avoided. Soldering is carried out using, for example, Corning type 7598 solder glass at a temperature of approximately 450°C.

The control electrode structure 7 is bonded to the extraction anode 6 by an insulating adhesive or solder glass. It consists of two layers of crossed metal conductors insulated from each other. The resulting aperture is the extraction anode 6
Adjusted to align with the aperture therein. In the layer of metal conductor closer to the extraction anode, the metal conductor is provided with holes. The number and location of these holes is equal to the number and location of the apertures in the extraction anode. This conductor is connected by a wire 18 to a pin in the feedthrough bushing 8.

FIG. 3 shows a cross section of the flat display device, but the rod-shaped holding member 12 is removed. The structural units fixed in the rear container part 2 are mounted, for example, by L-shaped retaining members 13 attached to the sides of the rear container part 2 and one Z-shaped retaining member 24 each fixed to the base plate 10. support. Such retaining devices are provided near each of the four corners of the base plate 10. The joining between the holding member 24 and the holding member 13 can be performed by welding or soldering, but for example, non-permanent joining,
Preferably, it is also possible to join by interlocking joint. The latter type of connection has the advantage that the structural unit fixed in the rear container part 2 can be easily removed from the rear container part 2 if a fault is detected during the test. However, the base plate 10 may also be directly connected to the holding member 13.

In FIG. 3, the segments of the counterelectrode 5, one behind the other in the plane of the paper, extend to the edge of the frame 11 and are connected by wires 18 to pins in the through bushing 8.

FIG. 4 shows an enlarged view of the contact portion of the segments of the counter electrode 5. FIG. Contact may be made by wire as shown in FIG. 3, but the segments may also be extended to project beyond the base plate 10 as shown. Penetration bushing 8
The pins inside are bent so that their ends lie in the plane of the segment, so that this pin is connected directly to the segment.

The metal parts of the counter electrode 5, the extraction anode 6 and the control electrode structure 7 are made of pure iron and, if necessary, are entirely covered with a nickel film.

This flat display device is constructed as follows. The face plate 1 has a phosphor dot array 3
The phosphor dots are surrounded by a black matrix. Bushing 8 and 2
3, the getter wire 22 and the retaining member 13 are fixed into the rear container part 2. The electrodes fixed to the rear container part 2 are assembled as a structural unit. These three parts are then assembled together.

After the structural unit to be incorporated into the rear container part has been inserted and fixed in the rear container part 2,
Electrical connections are made between the vacuum-sealed pins and the individual electrodes by vacuum-sealed feed-through bushings 8 as shown by wires 18. Then, a face plate 1 having a phosphor dot array 3 is formed.
are placed on the rear container part 2, aligned and vacuum sealed to the rear container part 2. At the same time, the flat display device is evacuated.

[Brief explanation of drawings]

FIG. 1 is a longitudinal sectional view of a flat display device. Second
The figure is a detailed view of the X section in FIG. FIG. 3 is a cross-sectional view of the flat display device. FIG. 4 is a detailed view of a portion of FIG. 3. DESCRIPTION OF SYMBOLS 1... Face plate, 2... Rear container part, 3... Phosphor dot array, 4... Cathode filament, 5... Counter electrode, 6... Extraction anode, 7
... Control electrode structure, 10 ... Base plate, 1
1... Support frame, 12... Rod-shaped holding member.

Claims (1)

[Scope of Claims] 1. A vacuum container constituted by a glass face plate 1 provided with phosphor dots and a rear container portion 2 made of metal, and disposed inside the vacuum container facing the glass face plate. a counter electrode 5 divided into segments, a periodic array of cathode filaments 4 arranged in front of the counter electrode, an extraction anode 6 with apertures for extraction of electron flow arranged in front of the cathode filament; and a control electrode structure 7 arranged between the extraction anode and the face plate, wherein the segmented counter electrode 5 is arranged on the base plate 10 mounted on the rear container part 2. The extraction anode 6 and the control electrode structure 7 are mounted on a support frame 11
The support frame 11 is supported by the base plate 1
A rod-shaped holding member 12 is attached to opposite side edges of the support frame 11, and the cathode filament 4 is connected to the extraction anode 6 supported by the support frame 11. The rear container portion 2 is provided with a plurality of lead-in conductor terminals that are stretched between the rod-shaped holding members 12 in the space between the counter electrode 5 fixed on the base plate 10 and hermetically sealed by a through bushing 8. A flat display device characterized by: 2. A flat display device according to claim 1, characterized in that the support frame (11) is made of a metal having an expansion coefficient such that the extraction anode (6) soldered thereto is stretched in the operating state. 3. A flat display device according to claim 2, characterized in that the control electrode structure 7 is joined to the extraction anode 6 by an insulating adhesive or solder glass. 4 One end of each cathode filament 4 is connected to the spring 2
2. The flat display device according to claim 1, wherein the flat display device is attached to the rod-shaped holding member 12 by a screw. 5. A flat display device according to claim 1, wherein the base plate (10) has a holding member (13) fixed to the rear container part (2) at its spacing. 6 Below the base plate 10 the rear container part 2 includes at least one getter wire 22 , which getter wire 22 is energized by the passage of an electric current and whose first terminal is connected to the bottom of the rear container part 2. 2. A flat display device as claimed in claim 1, characterized in that the second terminal is connected to a pin (21) hermetically sealed by a through bushing (23) attached to the rear container part (2). 7 Rear container part 2, counter electrode 5, extraction anode 6,
2. A flat display device according to claim 1, wherein each of the metal parts of the control electrode structure and the control electrode structure is made of pure iron. 8. The flat display device according to claim 7, wherein the pure iron portion is coated with a thin nickel coating.