KR200225266Y1 - Flat panel display with spacer support structure - Google Patents

Abstract

A face plate serving as the front substrate of a flat panel display, on which a plurality of spacers are arranged on a substrate in contact with a discontinuous pattern over the black matrix, the spacers being connected to and fixed to a structure selectively disposed over the black matrix. Is installed. Such a face plate has an effect of preventing image distortion due to the spacer by making the spacer not easily visible to the user's field of view from the outside of the display when the flat panel display is constructed.

Description

Flat panel display with spacer support structure

The present invention relates to a flat panel display, and more particularly, to a face plate and a flat panel display having a spacer for maintaining a cell gap of the flat panel display so as not to adversely affect the image implemented in the display.

In a flat panel display, a spacer is disposed between both substrates to maintain the cell gap of the flat panel display.

In particular, in field emission displays (FEDs), the function of the spacers is important, which means that the spacing between the faceplate and the backplate must be maintained uniformly by the spacers in order to improve the uniformity of the image. It is because it can obtain favorably.

However, a display that maintains an internal space formed between the two substrates in a vacuum state of approximately 10 ^-7 torr, such as a field emission display, has a higher pressure than the other display due to the pressure difference between the internal pressure and the external atmospheric pressure between the two substrates. It is difficult to keep the above spacing uniform.

Thus, in flat panel displays, including field emission displays, spacers play an important role, which is more so with larger displays.

Such spacers typically require: 1) non-conductive properties to prevent electrical breakdown between the anode and cathode array, and 2) mechanical to prevent the flat panel display from collapsing under atmospheric pressure. Strength, 3) stability by electron collision, 4) ability to withstand high temperatures (approx. 400 ° C) to achieve high vacuum in the substrate, 5) formed with a sufficiently small width to be invisible on the display screen Etc.

In consideration of this, a conventionally proposed technique is disclosed in US Pat. No. 5,650,690 by mounting a spacer wall between a gripper provided on a face plate and a locator provided on a back plate. A technique for manufacturing a field emission device) is disclosed.

In this technique, a spacer wall for effectively maintaining the internal space of the device is made of a material such as ceramic or glass, and fixedly disposed between the face plate and the back plate by the gripper and the locator described above.

By the way, the spacer wall disclosed in the above technique has a sheet shape which is disposed long on both plates in the longitudinal direction and is in contact with the inner surface of the both plates. In particular, in the case of still images, there is a high possibility of easily entering the consumer's field of view and causing distortion of the implemented image.

In addition, if the spacer maintaining the cell gap of the device has a structure that is blocked between the two plates as described above, the device to prevent oxidation of the emitter tip during sealing during the manufacturing process of the device The smooth flow of argon (Ar) gas to be injected into the internal space may also be disturbed to reduce the effect of the argon gas, and also to make it difficult to smoothly exhaust the device internal space in the heat exhaust process.

Accordingly, the present invention has been devised in view of such a problem, and an object of the present invention is to provide a flat panel having a structure such that a spacer for maintaining a cell gap of the flat panel display does not interfere with image implementation when the flat panel display is operated. The present invention provides a face plate for a flat panel display and a flat panel display having the face plate to be disposed in an interior space of the display.

In order to realize the above object,

A substrate;

A plurality of anode electrodes formed on one surface of the substrate with an arbitrary pattern;

A black matrix formed between the anode electrodes with an arbitrary pattern on the substrate;

A plurality of spacers in contact with one surface of the substrate at predetermined intervals along a length direction of the substrate;

A face plate for a flat panel display was configured to include a spacer fixing structure connected to the spacer while being fixed to one surface of the substrate.

In the above configuration, the spacer is formed in a rectangular thin plate shape having a recessed portion on one side, or a body portion disposed along the longitudinal direction of the substrate; It may be provided in a shape including a plurality of support portions formed by projecting at predetermined intervals on both sides of the body portion.

In addition, the structure may be formed as a bar-shaped structure formed on the black matrix by forming a spacer insertion recess at a predetermined interval on one long side, or a spacer insertion recess at a predetermined interval on one long side. It may be formed of a bar-shaped structure fixedly installed so that the recess is disposed on the black matrix located on both sides of the substrate.

In addition, the present invention to realize the above object,

A face plate substrate; A plurality of anode electrodes formed on one surface of the substrate with an arbitrary pattern; A phosphor formed on the anode electrode with an arbitrary pattern; A black matrix formed on the substrate with an arbitrary pattern between the anode electrodes; A substrate for a back plate; A plurality of cathode electrodes formed on one surface of the substrate with an arbitrary pattern; A plurality of gate electrodes formed on the substrate with an arbitrary pattern on the cathode; A field emission cathode electrically connected to the cathode electrode; Side walls disposed between the substrates and connected to the substrates; A spacer support selectively fixedly disposed on the black matrix; A flat panel display was configured by including a plurality of spacers coupled to the spacer support and disposed on the black matrix at predetermined intervals and supported and bonded to the inner surfaces of both substrates.

In addition, the present invention to realize the above object,

A face plate substrate; A plurality of anode electrodes formed on one surface of the substrate with an arbitrary pattern; A phosphor formed on the anode electrode with an arbitrary pattern; A black matrix formed on the substrate with an arbitrary pattern between the anode electrodes; A substrate for a back plate; A plurality of cathode electrodes formed on one surface of the substrate with an arbitrary pattern; A plurality of gate electrodes formed on the substrate with an arbitrary pattern on the cathode; A field emission cathode electrically connected to the cathode electrode; Side walls disposed between the substrates and connected to the substrates; A pair of spacer supports fixedly disposed on a black matrix formed on both sides of the face plate substrate; A body portion selectively disposed on the black matrix in an orthogonal state with respect to the two spacer supports, the both ends being coupled to the spacer support, and formed on both sides of the body portion at protruding intervals at predetermined intervals to form an inner surface of the substrate; The flat panel display was configured to include a spacer including a plurality of support parts coupled to each other.

1 is a cross-sectional view showing a flat panel display according to a first embodiment of the present invention,

2 is a perspective view illustrating a face plate of a flat panel display according to a first embodiment of the present invention,

3 and 4 are perspective views illustrating a method of coupling the spacer to the structure according to the first embodiment of the present invention,

5 is a cross-sectional view showing a flat panel display according to a second embodiment of the present invention,

6 is a perspective view illustrating a face plate of a flat panel display according to a second exemplary embodiment of the present invention.

Hereinafter, on the basis of the accompanying drawings preferred embodiments for clarifying the present invention.

1 is a cross-sectional view illustrating a flat panel display according to a first embodiment of the present invention, and the flat panel display to be described in the present embodiment uses a field emission display as an example.

As shown in the drawing, the field emission display has a back plate 1 on which a cathode 1a for field emission is disposed, and a face plate 3 on which a fluorescent layer 3a is disposed, as in a normal field emission display. Are arranged in parallel at a predetermined interval, and a plurality of spacers 5 are arranged between them to maintain the cell gap of the display.

In the above, both plates (1,3) are sealed in a sealed form to maintain the inner space 7 in a vacuum state, where the side walls (side) therebetween when the plates (1,3) are sealed A wall 9 is interposed.

In such a structure, the back plate 1 has a plurality of cathode electrodes 1c, field emission cathodes 1a, insulating films 1d, and gate electrodes 1e on one surface of a substrate 1b. The face plate 3 is formed by holding a pattern, and a plurality of fluorescent layers 3a and an anode electrode 3c are formed on one surface of a substrate 3b while maintaining a predetermined pattern. The black matrix 3d is also formed between the fluorescent layers 3a by maintaining a predetermined pattern to improve the contrast of the display.

In addition, while the spacer 5 is disposed in the space portion 7, both sides of the spacer 5 are supported toward the plates 1 and 3 to maintain the cell gap of the display. That is, the spacer 5 is disposed close to the one side end of the black matrix (3d) of the face plate 3, the other end is in close contact with the gate electrode (1) of the back plate (1). While being arranged in the space 7.

At this time, the spacer 5 is formed in a rectangular thin plate shape, as shown in Figs. 2 to 3, the substrate of the face plate (3) when bonded to the face plate (3) side ( It is connected to the structure 11 fixed on 3b).

Herein, the structure 11 is a bar-shaped structure selectively disposed on the black matrix 3d and fixed to the substrate 3b, similarly to the spacer 5, and has a predetermined distance to the substrate 3b. In other words, it is provided to stably fix the plurality of spacers 5 which are disposed in contact with each other.

As shown in FIG. 3, the coupling between the spacer 5 and the structure 11 is such that the spacer 11 enters the structure 11 into the recess 5a formed at one side of the spacer 5. 5) is made by fitting to the structure (11).

In the above coupling structure, as shown in FIG. 4, the recess 11a is formed on the structure 11 at the coupling portion with the spacer 5, and the spacer 5 and the structure 11 are as described above. ) Can be combined to achieve a more stable state of bonding.

Meanwhile, in the above, the spacer 5 is formed with the so-called high aspect ratio and basically the conditions that the spacer should have—physical chemical and electrical properties—and the structure 11 is made of alumina. It consists of (alumina) or zirconia (zirconia) as a main component.

In addition, as one long side portion 11b of the structure 11, a charge accumulation preventing electrode 13 disposed along the length direction of the structure 11 and electrically grounded is fixed. It works.

That is, when the display is in operation, some of the electrons emitted from the field emission cathode 1a may be accumulated on the surface of the spacer 5 or the structure 11 while being scattered without being properly guided to the phosphor 3a. If the electrons continue to accumulate on the surface of the spacer 5 or the structure 11, this adversely affects the operation of the display, which is guided out of the display and remains in the space 7. It is desirable to avoid.

The charge accumulation preventing electrode 13 is provided for such a function, which is to be formed by printing with silver on a ceramic sheet constituting the structure 11 during the manufacturing of the structure 11. do.

In the field emission display configured as described above, the spacer 5 holding the cell gap is disposed discontinuously on both substrates 1b and 3b, so that the display of the field emission display becomes relatively less noticeable to the consumer, and also the operation of the display. When the picture to be implemented in time is a still picture, in particular, it becomes effective to prevent the picture distortion thereof.

5 is a cross-sectional view showing a flat panel display according to a second embodiment of the present invention. In this embodiment, the field emission display is applied as an example of the flat panel display.

The field emission display also includes a side wall 24 interposed between the back plate 20 and the face plate 22 so that both plates 20 and 22 are in a vacuum state. Sealed to the side wall 24 is made.

Here, the back plate 20 includes a plurality of cathode electrodes 20b, a field emission cathode 20c, a gate electrode 20d, and an insulating film 20e which maintain a predetermined pattern on one surface of the substrate 20a as usual. Is formed, and the face plate 22 is coated with a phosphor 22c on a plurality of anode electrodes 22b holding a predetermined pattern on one surface of the substrate 22a, and the anode electrode 22b. The black matrix 22d is formed in between.

In addition, the spacers 28 disposed in the internal space 26 are in discontinuous contact with the inner surfaces of the substrates 20a and 22a along the length direction of the substrates 20a and 22a, and the cell gap of the display. Will be maintained.

The spacer 28 is fixed to the plate 22 at the time of manufacturing the face plate 22, the structure thereof is as follows.

As shown in FIG. 6, first, the spacer 28 includes a body portion 28a disposed in a bar shape along the length direction of the substrate 22a of the face plate 22, and the body portion 28a. It comprises a support portion 28b is formed by projecting at predetermined intervals on the upper and lower long sides of the).

The spacer 28 is selectively disposed on the black matrix 22d, and the support 28b of one long side portion is coupled to contact and be supported by the black matrix 22d. At the time of coupling, the supporting part 22b of the other long side part is brought into contact with and supported by the gate electrode 20d of the back plate 20.

When the spacer 28 is fixed to the substrate 22a of the face plate 22, it is coupled to and fixed to the structure 30 fixedly installed on the substrate 22a, where the structure 30 is provided. Is a bar-shaped structure disposed on the black matrix 30d at a predetermined interval by the length of the spacer 28.

When the structure 30 is arranged in the above-described shape, the recesses 30a formed at predetermined intervals on one long side of the structure 30 are arranged to face each other, and the sides of the structure 30 are also opposite to each other. Further connection of the auxiliary structure 32 to the end, it is possible to achieve a stable state of the structure 30.

The spacer 28 and the structure 30 are coupled to each other by fitting the two end portions of the body portion 28a of the spacer 28 to the recessed portions 30a of the structure 30 as shown in the drawing. After coupling, the height h1 of the spacer 28 is greater than the height h2 of the structure 30.

On the other hand, in the field emission display, the above-described charge accumulation preventing electrodes 34 and 36 are provided. In this embodiment, the electrodes 34 and 36 are formed on the body portion 28a of the spacer 28. It is arrange | positioned along the longitudinal direction and is arrange | positioned along the longitudinal direction of this one surface to one surface of the said structure 30. Of course, when the spacer 28 is coupled to the structure 30, these electrodes 34 and 36 must be electrically connected to each other.

In the field emission display formed as described above, the support 28b of the spacer 28 is discontinuously contacted with the inner surfaces of the substrates 20a and 22a at predetermined intervals, thereby performing the first embodiment. Image distortion can be prevented without being easily seen by the consumer, such as an example field emission display.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications can be made within the scope of the utility model registration claims and the detailed description of the invention and the scope of the accompanying drawings. This also belongs to the scope of the present invention.

For example, in the present embodiment, the field emission display is an example of a flat panel display to which the present invention is applied, but the present invention can be applied to various flat panel displays such as thin CRT.

As can be seen from the above-described configuration and operation of the present invention, the flat panel display of the present invention has an effect of minimizing image distortion caused by the spacer due to the spacer discontinuously contacting the substrate.

In addition, in the flat panel display of the present invention, it is possible to have an advantage in the exhaust process and the shiling process during the manufacturing process, which is due to the air flowing through the internal space of the display or the argon gas for oxidation prevention due to the spacer which is in discontinuous contact with the substrate Because you can proceed smoothly.

Claims (14)

A substrate; A plurality of anode electrodes formed on one surface of the substrate with an arbitrary pattern; A phosphor formed on the anode electrode with an arbitrary pattern; A black matrix formed on the substrate with an arbitrary pattern between the anode electrodes; A plurality of spacers in contact with one surface of the substrate discontinuously along the longitudinal direction of the substrate; A face plate for a flat panel display comprising a structure fixed to one surface of the substrate and connected to the spacer to fix the spacer. The method of claim 1, wherein the spacer, Face plate for a flat panel display, characterized in that formed in a thin plate form a recessed portion on one side. The method of claim 2, wherein the spacer, Face plate for flat panel display, characterized in that formed in a rectangle. The method of claim 1, wherein the spacer, A body portion disposed along the longitudinal direction of the substrate; Flat plate face plate including a plurality of support parts are formed by projecting at predetermined intervals on both sides of the body portion, The method of claim 1, wherein the structure, Face plate for a flat panel display, characterized in that consisting of a bar-shaped structure disposed on the black matrix. The face plate for a flat panel display according to claim 5, wherein a recess for inserting the spacer is further formed at one long side of the structure at predetermined intervals. The method of claim 1, wherein the structure, Forming recesses for inserting spacers at predetermined intervals at one long side portion, for the flat panel display, characterized in that the rod-shaped structure is fixedly installed so that the recesses are opposed to the black matrix positioned on both sides of the substrate Face plate. 8. The face plate of claim 7, wherein the structure is formed to have a height smaller than that of the spacer. The face plate for a flat panel display according to claim 7, wherein the structure is connected to and supported by an auxiliary structure arranged at a right angle to the structure. The face plate for a flat panel display according to claim 5 or 6, wherein an electrode for inhibiting charge accumulation is formed along a longitudinal direction of the one surface on one surface of the structure. The face plate for a flat panel display of claim 4, wherein an electrode for preventing charge accumulation is formed along a length direction of the one surface on one surface of the body. The face plate for a flat panel display of claim 7, wherein an electrode for preventing charge accumulation is formed along a length direction of the one surface on one surface of the structure. A face plate substrate; A plurality of anode electrodes formed on one surface of the substrate with an arbitrary pattern; A phosphor formed on the anode electrode with an arbitrary pattern; A black matrix formed on the substrate with an arbitrary pattern between the anode electrodes; A substrate for a back plate; A plurality of cathode electrodes formed on one surface of the substrate with an arbitrary pattern; A plurality of gate electrodes formed on the substrate with an arbitrary pattern on the cathode; A field emission cathode electrically connected to the cathode electrode; Side walls disposed between the substrates and connected to the substrates; A spacer support selectively fixedly disposed on the black matrix; And a plurality of spacers coupled to the spacer support at a predetermined interval and disposed over the black matrix, the spacers being supported to the inner surfaces of both substrates. A face plate substrate; A plurality of anode electrodes formed on one surface of the substrate with an arbitrary pattern; A phosphor formed on the anode electrode with an arbitrary pattern; A black matrix formed on the substrate with an arbitrary pattern between the anode electrodes; A substrate for a back plate; A plurality of cathode electrodes formed on one surface of the substrate with an arbitrary pattern; A plurality of gate electrodes formed on the substrate with an arbitrary pattern on the cathode; A field emission cathode electrically connected to the cathode electrode; Side walls disposed between the substrates and connected to the substrates; A pair of spacer supports fixedly disposed on a black matrix formed on both sides of the face plate substrate; A body portion selectively disposed on the black matrix in an orthogonal state with respect to the two spacer supports, the both ends being coupled to the spacer support, and formed on both sides of the body portion at protruding intervals at predetermined intervals to form an inner surface of the substrate; A flat panel display comprising a spacer including a plurality of supports coupled to each other.