EP0031921A1 - Gas discharge display device comprising at least one spacer frame limiting the post-acceleration space - Google Patents

Abstract

A gas discharge panel consists of a gas discharge and a post-acceleration chamber (1), which are separated from each other by a perforated control disc (5) with row and column conductors and are delimited by a spacing frame (2). With this panel, a high post-acceleration voltage should be used in the post-acceleration room (1) without electrical flashovers. For this purpose, the post-free post-acceleration space (1) is limited in its lateral boundary by at least one spacer frame (2), the inner boundary of which largely corresponds to the outer boundary of the active fluorescent screen surface and which is designed in such a width that the inner framework is free of remains the materials producing a gas-tight connection and which separates the outer edge regions of the potential layers delimiting the post-acceleration space 1.

Description

The invention relates to a gas discharge display device with a gas-filled space, which is sealed gas-tight on one side by a front plate and on the opposite side by a rear plate and is divided by a control disk into a gas discharge space and a post-acceleration space, which is on one side as a line conductor and on it on the other side, as a column conductor, carries a matrix path that can be controlled separately and is broken together with these paths in the intersection points of the matrix, and on the front plate side there is a luminescent screen provided with an anode layer and delimiting the post-acceleration space, and on the rear plate side one or more insulated from one another , The gas discharge space delimiting cathodes, with spacing frames being provided between the control disk and the fluorescent screen and between the control disk and cathode (s).

A gas discharge display device with a cathode, which consists of cathode strips which are isolated from one another, parallel to one another and can be controlled separately, is known from DE-OS 26 43 915. The division of the cathode into individual cathode strips isolated from one another is a further development of a surface cathode, as is known from DE-OS 24 12 869 is and is used for image reproduction in so-called flat screens or gas discharge displays.

Such a display device works on the principle of the spatial separation of electron generation and electron acceleration. The tube used for this is divided into two chambers, which are connected to each other via a conductor matrix (control disk) perforated at the intersection of their rows and columns. The chamber between the cathode or cathodes on the back plate and the strip-shaped auxiliary anodes as rows of the conductor matrix is the space for the gas discharge. The other chamber is the post-acceleration space between the column level of the conductor matrix (control disk) and a surface anode, which represents a fluorescent screen electrode. By driving one of the auxiliary anodes, a wedge-shaped gas discharge occurs between the cathode and the auxiliary anode over their entire line length. With simultaneous activation of one of the strip-shaped control electrodes serving as matrix gaps, plasma electrons generated in the gas discharge are drawn through the opening at the intersection of row and column into the post-acceleration space and accelerated onto the anode. At the point of impact, a light spot is then formed on a phosphor layer located in front of the anode as an image of the controlled crossing point of the matrix. With appropriate matrix control according to the time sequence and strength, characters and pictures can be displayed on the fluorescent screen.

Furthermore, from DE-OS 27 50 587 a gas discharge display device with spacer elements is known, in which webs with constant wall thickness are provided between the control disk and the post-acceleration anode, which extend in the plane of the control disc, are guided past the control disc holes and, in sections, run alternately parallel and at an angle to the conductors facing them.

For a spacer in a gas discharge display device, it has also already been proposed to arrange several stacked perforated glass foils between the control disc (control perforated plate) and the fluorescent screen, which have metal layers on their surfaces. The metal layers carry floating potentials and thereby homogenize the acceleration field (patent application P 28 55 108.8).

The present invention is based on the object of creating a gas discharge display device which makes it possible to use a high post-acceleration voltage in the post-acceleration space without causing electrical flashovers. To achieve this object, it is proposed according to the invention in a gas discharge display device of the type mentioned at the outset that the post-free post-acceleration space 1 is limited in its lateral boundary by at least one spacing frame 2, the inner boundary of which largely corresponds to the outer boundary of the active luminescent screen surface and the width thereof It is designed that the inner frame edge remains free of the materials that produce a gas-tight connection and that separates the outer edge regions of the potential layers delimiting the post-acceleration space 1.

The spacer frame is preferably surrounded by a second, outer spacer frame, the vacuum tight sealing of the post-acceleration room. The spacing frames are expediently made of glass, which is adapted in its thermal expansion coefficient to that of the fluorescent screen glass.

Further advantageous embodiments of the invention are contained in the characterizing features of subclaims 5 to 16.

The gas discharge display device according to the invention has the advantage that a high post-acceleration voltage can be used in the post-acceleration space without causing electrical flashovers. Electrical flashovers on insulators in vacuum occur compared to the breakdown field strength in vacuum at significantly lower field strengths. It is therefore expedient to use a support-free post-acceleration space so that the critical area in which insulator flashovers can occur is limited to the lateral boundary of the post-acceleration space.

Further details of the invention will be explained in more detail with reference to exemplary embodiments shown in the figures of the drawing. Parts which do not necessarily contribute to an understanding of the invention are not shown in the figures or are omitted.

• Fig. 1 ein Ausführungsbeispiel einer erfindungsgemäßen Gasentladungsanzeigevorrichtung schematisch als Ausschnitt,
• Fig. 2 eine schematische Darstellung des Aufbaues des inneren Teiles des Abstandsrahmens einer Gasentladungsanzeigevorrichtung,
• Fig. 3 eine schematische Darstellung des Aufbaues eines inneren und eines äußeren Abstandsrahmens einer Gasentladungsanzeigevorrichtung,
• Fig. 4 eine schematische Darstellung einer weiteren Ausführungsform des Aufbaues eines inneren und äußeren Abstandsrahmens,
• Fig. 5 eine schematische Darstellung des Aufbaues des Nachbeschleunigungsraumes für ein Leuchtschirmglas mit integriertem Abstandsrahmen und
• Fig. 6 eine schematische Darstellung des Aufbaues eines zu einer Einheit kombinierten inneren und äußeren Abstandsrahmens einer Gasentladungsanzeigevorrichtung.

Show:

• 1 shows an exemplary embodiment of a gas discharge display device according to the invention schematically as a detail,
• 2 shows a schematic representation of the structure of the inner part of the spacer frame of a gas discharge display device,
• 3 shows a schematic representation of the structure of an inner and an outer spacer frame of a gas discharge display device,
• 4 shows a schematic representation of a further embodiment of the structure of an inner and outer spacing frame,
• Fig. 5 is a schematic representation of the structure of the post-acceleration space for a fluorescent screen glass with an integrated spacer frame and
• Fig. 6 is a schematic representation of the structure of an integrated inner and outer spacer frame of a gas discharge display device.

The gas discharge display device shown schematically in FIG. 1 essentially consists of a post-acceleration chamber 1 with an excessively wide spacing frame 2 between the luminescent screen 4 and control disk 5 to increase the high-voltage strength of the device. The adhesive seams between the spacer frame 2 and the control disk 5 or fluorescent screen 4 are provided with the reference number 6. The spacer frame 2 projects beyond the adhesive seams 6 laterally. The high-voltage strength of a 1 mm long acceleration path based on electrical arcing at the edge of the post-acceleration space 1 is increased, for example, from 2.5 kV to 6 kV when the 0.8 mm high glass spacer frame 2 laterally projects over the adhesive seam 6 by about 5 mm in each case.

Fig. 2 shows a schematic representation of the structure of the inner part of the spacer frame 2 in the gas ..Discharge display device with post-acceleration space 1. The spacer frame 2 extends close to the active part of the with a potential layer 7 and a light Layer 8 provided fluorescent screen 4. The potential layers 7 of the post-acceleration space 1 are separated from one another in their edge regions by the inner part of the spacing frame 2. The inner edge of the spacer frame 2 is free of sealing material, for example glass solder. The part of the spacer frame 2 which is directed towards the outer edge of the gas discharge display device is used for vacuum-tight sealing.

When setting up the displays, you have more scope for optimization if you divide the spacing frame into an inner and an outer frame according to these two functions. Adjusting pins 9 are attached to the glass of the fluorescent screen 4 and remain there during the manufacturing process including the glass soldering technique. which are used to adjust the phosphor grid 8, photo-form plate and control disc 5.

Figures 3 to 5 show examples of construction variants. 3, the height of the second, outer spacing frame 3 is greater than the height of the post-acceleration space 1 in order to be able to also seal additional control grids in a vacuum-tight manner without additional glass solder seams. When building the outer spacer frame 8 you can now depending on the requirements. Requirements use pre-sintered glass solder rods, which are brought into the correct shape in the glass solder process by the plastic deformation of the glass solder that takes place.

However, if particularly high demands are placed on the strength of the glass solder seams, it is advantageous to design the largest part of the thickness range of the outer spacing frame 3 as a glass part (e) in order to choose the thickness of the glass solder seam as small as possible. Transitions between the two construction variants described are also possible.

In the embodiment shown in FIG. 3, an additional control grid 10 provided with a potential layer 7 is arranged in the post-acceleration chamber 1 between the phosphor screen 4 provided with a potential layer 7 and a phosphor layer 8 and the control disk 5 provided with a potential layer 7. I.

When assembling the device, the control grid 10 is first brought into the correct position on the control disc 5 and fixed with a high-temperature adhesive at some points (adhesive seams 6) in relation to the control disc 5. Then the inner spacer frame 2 is also fixed on the control grid 10 with a few drops of a high-temperature adhesive. For the vacuum-tight sealing of the structure, four presintered glass soldering rods with a width of approx. 1 mm and a thickness of 2.5 mm to 3 mm are placed around the inner spacing frame 2. The entire structure is then subjected to an annealing process. The glass solder initially present in excess fills when the fluorescent screen 4 drops to the level determined by the control grid 10 and inner spacing frame 2, and thus creates a tight connection between the control disk 5 and the fluorescent screen 4. Adjusting pins 9 are again provided for adjusting the arrangement.

In the embodiment shown in FIG. 4, two spacer frames are used again. The inner spacing frame 2 delimits the post-acceleration space 1 between the fluorescent screen 4 provided with a potential layer 7 and a phosphor grid 8 and the control grid 10 provided with a potential layer 7, which is arranged on the control disk 5 provided with the potential layer 7 (column conductor). Spacer frame Men 2, control grid 10 and control disc 5 are adjusted by means of adjusting pins 9 and fixed by adhesive seams 6 from a high temperature adhesive. The outer spacer frame 3 consists on two opposite sides of glass strips pasted with glass solder 11 and on both other sides of glass solder. It is advisable to use the glass strips where the control disc extends far from the display and must be supported.

Fig. 5 shows the structure of the post-acceleration room 1 for a fluorescent screen ^g las with an integrated spacer frame. Since in contrast to the screen structure with a flat front glass in the structure according to FIG. 5, the conductive layer (potential layer 7) of the fluorescent screen 4 and so that the high voltage is only present within the screen glass, the outer part of the wide spacing frame can be dispensed with. Therefore, you can place the high-voltage flashover preventing and protruding into the interior part of the spacer frame 2 in the form of glass strips in the screen pan and attach it to the edge of the integrated spacer frame, for example with glass solder 11, after all layers important for the function of the screen have been applied to the screen glass. The adjustment pin 9 attached to the screen 4 in turn serves to adjust the control disk 5, the control electrode 10, which is provided with a metallization (potential layer 7) and the spacer frame 2.

6 shows a schematic representation of the structure of an inner and outer spacer frame 2 combined into one unit in a gas discharge display device with a post-acceleration space 1, that of the control disk 5 provided with a potential layer 7 and that with a potential layer 7 and one Fluorescent layer 8 provided fluorescent screen 4 is limited. The adjusting pin 9 extends from the fluorescent screen 4 through the spacer frame 2 and the control disk 5. The spacer frame 2 is connected to the control disk 5 and the fluorescent screen 4 in a gas-tight manner via glass solder layers 11.

Claims (16)

1. Gas discharge display device with a gas-filled space, which is sealed gas-tight on one side by a front plate and on the opposite side by a rear plate and is divided by a control disk into a gas discharge space and a post-acceleration space, which is on one side as a line conductor and on the other side As a column conductor, it forms a matrix path that can be controlled separately and is broken together with these paths in the intersection points of the matrix, and which has a luminescent screen provided on the front plate side with an anode layer that delimits the post-acceleration space, and one or more insulated ones on the back plate side The gas discharge space delimiting cathodes lie opposite, spacing frames being provided between the control disk and the fluorescent screen and between the control disk and cathode (s), characterized in that the post-free post-acceleration space ( 1). is limited in its lateral border by at least one spacer frame (2), the inner border of which largely corresponds to the outer border of the active fluorescent screen surface and which is designed in its width so that the inner border remains free of the materials which produce a gas-tight connection and which separates the outer edge regions of the potential layers delimiting the post-acceleration space (1). 2. Device according to claim 1, characterized
characterized in that the spacer frame (2) is surrounded by a second, outer spacer frame (3), which serves for the vacuum-tight sealing of the post-acceleration chamber (1). 3. Device according to claim 1 or 2, characterized
characterized in that the spacer frame (2) consists of glass. 4. The device according to claim 3, characterized
characterized in that the glass's thermal expansion coefficient is adapted to that of the fluorescent screen glass. 5. Device according to one of claims 1 to 4,
characterized in that the spacer frame (2) is assembled from individual glass strips. 6. Device according to one of claims 1 to 5, characterized in that the spacer frame (2) is fixed in its position by a high-temperature adhesive. 7. Device according to one of claims 1 to 6,
characterized in that the spacer frame (2) formed from individual parts forms overlaps at the butt joints. 8. Device according to one of claims 1 to 7,
characterized in that the outer spacer frame (3) consists of a material which plastically deforms in a temperature process and forms a firm and vacuum-tight connection with the components between which it is arranged. 9. Device according to one of claims 1 to 8,
characterized in that the outer spacing frame (3) consists of presintered glass solder strips. 10. The device according to one of claims 1 to 9,
characterized in that parts of the outer spacing frame (3) are formed from glass strips. 11. The device according to one of claims 1 to 10,
characterized in that the height of the outer spacer frame (3) is such that not only the support-free post-acceleration space (1) but also one or more control grids following in the direction of the gas discharge space are enclosed by it. 12. The device according to one of claims 1 to 11,
characterized in that the glass parts of the outer spacer frame (3) form a unit with the adjacent parts of the inner spacer frame (1). 13. The device according to one of claims 1 to 12,
characterized in that the outer and inner spacer frames (2, 3) each consist of one piece. 14. The device according to one of claims 1 to 12,
characterized in that the outer and inner spacer frames (2, 3) consist of one piece. 15. The device according to one of claims 1 to 14,
characterized in that openings are provided in the inner spacing frame (2) at the corresponding points for adjusting pins fitted inside the gas discharge display device. 16. The device according to one of claims 1 to 14,
characterized in that openings are provided in the outer spacing frame (3) for the adjustment pins attached to the outer edge of the gas discharge display device at the appropriate locations.

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