KR20050082414A - Liquid crystal display panel - Google Patents

Abstract

The wide view liquid crystal display panel provided by the present invention includes a first compensation substrate having a first surface and a second surface, a first alignment layer provided on the first surface, a first polarizing plate provided on the second surface, And a second compensation substrate having a third surface and a fourth surface, a second alignment film provided on the third surface, a second polarizing plate provided on the fourth surface, and a liquid crystal molecule layer, wherein the first compensation substrate is provided. And the second compensation substrate is disposed at a position relative to each other of the first surface and the third surface, and the liquid crystal molecule layer is disposed between the first compensation substrate and the second compensation substrate. It is characterized by.

Description

Wide view liquid crystal display panel {LIQUID CRYSTAL DISPLAY PANEL}

The present invention relates to a liquid crystal display panel, and more particularly, to a liquid crystal display panel having a wide view.

An active thin film transistor is an element that actively controls the amount of light passing through each pixel, and the generation of the image causes each independent pixel on the panel to generate a desired color. To achieve this goal, multiple gold cathode tubes should be used as the backlight source of the indicator. In addition, in order for light to pass through each pixel, the panel must be manufactured in one small gate or switch to pass the light. A liquid crystal display (LCD) is a screen which modulates light using this liquid crystal element, and since the liquid crystal can modify its molecular structure, it can pass itself with different amounts of light. Conversely, you can block the light completely. This liquid crystal display includes two polarizing plates, a color filter array, and an alignment film, and can determine the maximum value of light passing amount and generation of color. The liquid crystal layer is located between two glasses, and when a voltage is applied to the alignment layer, an electric field is generated, and the liquid crystals at the interface of the alignment layer are arranged in a certain direction. Each element is composed of three subpixels, red, green, and blue, like a video tube.

Currently, the most commonly used liquid crystal mode is a twisted nematic liquid crystal TFT, and its operation principle is that a transistor applies zero voltage to a subpixel so that a liquid crystal (and polarized light controlled by it) is transferred between two substrates. Is based on a horizontal 90-degree turn at. In this case, since the deflection filter of the second substrate is shifted by 90 degrees with respect to the first substrate, the light beam passes through it and is sufficiently irradiated if it is a red, green, and blue subpixel, and they mix to generate one white point on the screen. . However, applying a voltage to ITO results in a vertical electric field and destroys the spiral structure of the liquid crystal. The liquid crystal molecules then attempt to align themselves in the same direction as the electric field. This means that the liquid crystal molecules are finally perpendicular to the second filter. Under this condition, the incident light is polarized so that they cannot pass through the entire subpixel, and the white point of the subpixel becomes black and the entire screen becomes black. It is.

Comparing the conventional CRT indicator with the twisted nematic liquid crystal TFT (TFT-TN), there is a problem of viewing angle as one of several serious defects in the TFT-TN. In other words, when the TFT-LCD is observed from an angle, the brightness of the indicator decreases rapidly, and a severe color change phenomenon is found. Since the TFT-TN usually has only a 90 degree viewing angle, that is, a 45 degree viewing angle on both the left and right sides, it is a problem that the LCD industry has been trying to overcome in the past.

Currently, the wide angle technology mainly includes (1) optical compensation film method (TN + Film), (2) multi-domain vertical alignment (MVA), and (3) lateral field effect method (In Plan). It is largely divided into three types, Switching and IPS. Among them, the methods (2) and (3) are relatively complicated with respect to the manufacturing process in the liquid crystal box, while the optical compensation film method of the method (1) may be made by depositing an optical compensation film on the current TFT-LCD. In addition to being easier to apply, the technology is cheaper and more productive than the other two technologies, and the current wide view liquid crystal display market mainly adopts the method of optical compensation film, accounting for about 80% of the entire market. .

1 is a diagram showing a wide view LCD panel structure manufactured using the method of the optical compensation film. The wide view LCD panel structure includes a liquid crystal layer interposed between a first transparent substrate 11, a second transparent substrate 12, and the first transparent substrate 11 and the second transparent substrate 12. (13), a first optical compensation film 14 attached to the first transparent substrate 11, and a second optical compensation film 15 attached to the second transparent substrate 12. . Naturally, for practical application, the structure further includes a first polarizing plate 16 attached to the first optical compensation film 14 and a polarizing plate 17 attached to the second optical compensation film 15. . The structure further includes a first alignment layer 18 attached to the first transparent substrate 11 and a second light distribution film 19 attached to the second transparent substrate 12. Among them, the first transparent substrate 11 and the second transparent substrate 12 are both made of a glass substrate or a plastic substrate that is non-stretchable, and the first polarizing plate 16 ) And the second polarizing plate 17 are all made of a polyvinyl alcohol (PVA) film interposed between 2TAC (triacetyl-cellulose) films, and the first and second optical compensation films 14 and 15. ) Provides the function of increasing the LCD panel viewing angle contrast, and improves the viewing angle of the LCD to 100 to 140 degrees. Therefore, an optical compensation film, i.e., a wide view film (WVF), is a representative material element in the industrial area of liquid crystal displays. Since the liquid crystal display utilizes the characteristics and optical properties of the liquid crystal between the solid and the liquid, and combines with the optical film to show the contrast significantly, the final display quality is affected by the combination with various optical films. However, at present, the world does not provide optical compensation for increasing the TFT-LCD viewing angle contrast but only Fuji Photo (Japanese manufacturer), and perhaps by providing the maker of the polarizing film with a wide view film produced by Fuji Photo. Since it is sold to a TFT-LCD maker after being bonded by a maker, the price increases two to three times as much as the polarizing film without a wide view film, and the cost increases, and the production time becomes longer. In addition, since the bonding quality of the wide view film is various for each polarizing film maker, there arises a problem of productivity decrease due to adhesion of compensation films of different makers.

Accordingly, the present inventors have carefully tested and studied in view of the drawbacks of the prior art, and eventually came up with a wide view liquid crystal display panel which can be easily and easily manufactured according to the present invention.

It is a main object of the present invention to provide a wide view liquid crystal display panel which has a stretchability and a compensation film function instead of the glass or plastic substrate which has been conventionally used and can be manufactured simply and easily.

The compensation substrate manufactured by the present invention is not only built into a display panel with a traditional optical compensation film in wide view, but also reduces and reduces the thickness and cost of the panel, and reduces productivity caused by adhesion of different manufacturers' compensation films. You can solve the problem. In addition, since the thickness of the panel is reduced and the light passing rate is reduced, the light consumption rate is also reduced to improve the image quality displayed on the display panel.

In order to achieve the above object, a wide view liquid crystal display panel of the present invention includes a first compensation substrate having a first surface and a second surface, a first alignment layer provided on the first surface, and a first polarizing plate provided on the second surface. And a second compensation substrate having a third surface and a fourth surface, a second alignment film provided on the third surface, a second polarizing plate provided on the fourth surface, and a liquid crystal molecular layer. The first compensation substrate and the second compensation substrate are disposed at mutually opposite positions of the first surface and the third surface, and the liquid crystal molecule layer is disposed between the first compensation substrate and the second compensation substrate. It is characterized in that it is installed in (corresponding to claim 1).

In the wide view liquid crystal display panel of the present invention, the first compensation substrate and the second compensation substrate are both flexible plastic substrates having stretchability and compensation film functions. (Corresponding to claim 2)

Further, in the wide view liquid crystal display panel of the present invention,

The first compensation substrate and the second compensation substrate are both biaxial compensation substrates,

The biaxial compensation substrate further has In plan Retardation Value (Ro) and Out of Plan Retardation Value (Rth), wherein Ro is in the range of 0 to 400 nm, and The Rth is in the range of 0 to 300 nm, and the biaxial axis compensation substrate is an optically anisotropic substrate having a first X-direction optical axis and a second Y-direction optical axis. (Corresponding to claim 3)

Further, in the wide view liquid crystal display panel of the present invention,

The wide view liquid crystal display panel further includes a first transparent electrode disposed between the first surface and the first alignment layer.

The first transparent electrode is a transparent conductive thin film,

The transparent conductive thin film is made of a metal oxide (corresponding to claim 4).

Further, in the wide view liquid crystal display panel of the present invention,

The wide view liquid crystal display panel further includes a second transparent electrode disposed between the third surface and the second alignment layer,

This second transparent electrode is a transparent conductive thin film made of a metal oxide (corresponding to claim 5).

Further, in the wide view liquid crystal display panel of the present invention,

The wide view liquid crystal display panel further includes a color filter disposed between the first compensation substrate and the liquid crystal layer,

The wide view liquid crystal display panel further includes a thin film transistor layer disposed on the second compensation substrate and the third surface.

The first alignment layer and the second alignment layer are made of a polyimide resin,

The first polarizing plate and the second polarizing plate are formed by extending a film from a PVA (polyvinyl alcohol) substrate and then bonding one layer of a triacetylcellulose (TAC) film to each of the two sides (corresponding to claim 6).

Furthermore, in order to achieve the object, the wide view liquid crystal display panel of the present invention includes a first compensation substrate having a first surface and a second surface, a second compensation substrate having a third surface and a fourth surface, and a liquid crystal molecular layer. And the first compensation substrate and the second compensation substrate are disposed at positions opposite to each other on the first surface and the third surface, and the liquid crystal molecular layer is formed on the first compensation substrate and the second compensation substrate. It is provided between a board | substrate, It is characterized by the above-mentioned. (It responds to Claim 7).

In the wide view liquid crystal display panel of the present invention,

The wide view liquid crystal display panel further includes a first alignment layer disposed on the first surface,

The wide view liquid crystal display panel further includes a second alignment layer disposed on the third surface,

The wide view liquid crystal display panel further includes a first polarizing plate disposed on the second surface, and / or

The wide view liquid crystal display panel further comprises a second polarizing plate provided on a fourth surface. (Corresponding to claim 8)

The wide view liquid crystal display panel of the present invention can be fully understood by the description of the following embodiments.

2 is a view showing a suitable embodiment of a wide view liquid crystal display panel according to the present invention. As shown in the figure, the wide view liquid crystal display panel includes a first compensation substrate 21 having a first surface 211 and a second surface 212, and a first alignment layer formed on the first surface 211 ( 213, a second compensation substrate 22 having a first polarizing plate 214 provided on the second surface 212, a third surface 221, and a fourth surface 222, and the third surface ( A second alignment layer 223 provided on 221, a second polarizing plate 224 provided on the fourth surface, and a liquid crystal molecular layer 23 are provided. Among them, the first compensation substrate 21 and the second compensation substrate 22 are disposed at positions of the first surface 211 and the third surface 221 opposite to each other, and the liquid crystal molecular layer ( 23 is provided between the first compensation substrate 21 and the second compensation substrate 22. The first compensating substrate 21 and the second compensating substrate 22 are both flexible plastic substrates having stretchable and compensating film functions and are biaxial axis compensating substrates. The substrate has an in plan retardation value (Ro) and an out of plan retardation value (Rth), wherein Ro is in a range of 0 to 400 nm, wherein Rth is 0 to 400 nm. It is in the range between 300 nm. That is, the substrate is an optically anisotropic substrate having a first X-direction optical axis and a second Y-direction optical axis. In other words, the compensation substrate manufactured by the present invention has a larger elasticity than that of the conventional substrate having the optical compensation film in addition to the optical compensation film in the wide view function, and thus has a higher elasticity in application. It can replace the glass or plastic substrate which attached.

Furthermore, in a practical application, the wide view liquid crystal display panel further includes a first transparent electrode 24 provided between the first surface 211 and the first alignment layer 213, which is first transparent. The electrode 24 is a transparent conductive thin film made of a metal oxide. Similarly, the wide view liquid crystal display panel further includes a second transparent electrode 25 provided between the third surface 221 and the second alignment layer 223, and the second transparent electrode 25 is provided. It is a transparent conductive thin film manufactured by silver metal oxide. The wide view liquid crystal display panel further includes a color filter 26 provided between the first compensation substrate 21 and the liquid crystal layer 23. When the wide view liquid crystal display panel is applied to a thin film transistor liquid crystal display, the wide view liquid crystal display panel further includes a thin film transistor layer 25 provided on the third surface 221 of the second compensation substrate 22. The liquid crystal molecules in the liquid crystal layer 23 can be controlled. In addition, the first alignment film 213 and the second alignment film 223 are used to position the liquid crystal molecules before generating the electric field, and these alignment films 213 and 223 are made of polyimide resin. As an example, a plurality of slits can be printed onto a film by a roller printing method so that liquid crystal molecules can be placed horizontally in the slits in the same direction. The first polarizing plate 214 and the second polarizing plate 224 extend from a polyvinyl alcohol (PVA) substrate to a film, and are then manufactured by bonding one layer of a triacetyl cellulose (TAC) film to both sides. The polarizing plate is limited to allow transmission only in light beams in any direction. For example, in actual production, the first polarizing plate 214 is shifted from the second polarizing plate 224, and the deflection plate is driven by an electric field to drive letters or characters. It is limited to displaying patterns.

Next, FIG. 3 is a diagram showing another suitable embodiment of the wide view liquid crystal display panel according to the present invention. As shown in the figure, the wide view liquid crystal display panel includes a first compensation substrate 31 having a first surface 311 and a second surface 312, a third surface 321, and a fourth surface 322. And a second compensation substrate 32 having a second liquid crystal molecular layer 33, wherein the first compensation substrate 31 and the second compensation substrate 32 are formed on the first surface 311. ) And the third surface 321 are disposed relative to each other, and the liquid crystal molecular layer 33 is disposed between the first compensation substrate 31 and the second compensation substrate 32. It is done. As described above, the main feature of the wide view liquid crystal display panel of the present invention is to replace the conventional non-stretchable glass substrate or plastic substrate using an optical compensation substrate. Accordingly, the first compensation substrate 31 and the second compensation substrate 32 are both flexible plastic substrates having a stretchable and compensation film function and are biaxial axis compensation substrates. In addition, the substrate has an in-plane retardation value (Ro) and an out-of-plane retardation value (Rth). Among them, Ro is in the range of 0 to 400 nm, and Rth is in the range of 0 to 300 nm. That is, the substrate is an optically anisotropic substrate having a first X-direction optical axis and a second Y-direction optical axis. In other words, the compensation substrate manufactured by the present invention and the liquid crystal molecular layer embedded therein are the basic structures of the wide view liquid crystal display panel of the present invention, and the display panel is a wide view function and a flexible material having it. Properties can replace traditional substrates with sufficient optical compensation films.

Furthermore, in a practical application, the wide view liquid crystal display panel further includes a first transparent electrode 34 provided between the first surface 311 and the first alignment layer 313, which is first transparent. The electrode 34 is a transparent conductive thin film made of a metal oxide. Similarly, the wide view liquid crystal display panel further includes a second transparent electrode 35 provided between the third surface 321 and the second alignment layer 323, and the second transparent electrode 35 is made of metal. It is a transparent conductive thin film made of an oxide. The wide view liquid crystal display panel further includes a color filter 36 disposed between the first compensation substrate 31 and the liquid crystal layer 33. In addition, in the present embodiment, the wide view liquid crystal display panel further includes a first alignment layer 313 disposed on the first surface 311 and a second alignment layer 323 disposed on the third surface 321. It is used for positioning liquid crystal molecules before electric field generation, and these alignment films 313 and 323 are manufactured by polyimide resin. As an example, a plurality of slits can be rolled over the membrane by a rotating roller engraving method so that the liquid crystal molecules can be laid horizontally in the slits in the same direction. In addition, the wide view liquid crystal display panel further includes a first polarizing plate 314 provided on the second surface 312 and a second polarizing plate 324 provided on the fourth surface 322, and these polarizing plates PVA (polyvinyl). After extending from the substrate (alcohol) to the membrane, it is made by bonding one layer of triacetyl cellulose (TAC) to each side. The polarizing plate is limited to allow transmission only in light beams in any direction. For example, in actual production, the first polarizing plate 314 is shifted from the second polarizing plate 324, and the polarizing plate is driven by an electric field to drive letters or patterns. Is limited to display. However, since the liquid crystal display produced using the wide view liquid crystal display panel of the present invention is thinner than the conventional one, the passing route of the light is reduced, and the consumption rate of light is also reduced accordingly. Moreover, the wide view effect is also favorable compared with the method of attaching an optical compensation film to a conventional non-stretchable glass substrate or a plastic substrate.

In other words, in the wide-view liquid crystal display panel, which is easy and quick to manufacture, provided by the present invention, the compensation substrate is stretched in addition to the conventional substrate having an optical compensation film in the wide view function. The use of materials allows for greater elasticity in applications, thereby replacing glass or plastic substrates with optical compensation films, and in addition to simplifying the manufacturing process and reducing manufacturing costs. Can be further reduced to increase the optical effect.

The above embodiments are exemplified in order to explain the present invention in more detail. Naturally, the technical idea of the present invention is not limited to the above embodiments, and simple design changes and additions by those skilled in the art do not depart from the scope of the claims. , Modifications, substitutions and the like all belong to the technical scope of the present invention.

1 is a view showing a conventional wide view liquid crystal display panel.

2 is a view showing a preferred embodiment of a wide view liquid crystal display panel according to the present invention.

3 is a diagram showing another suitable embodiment of the wide view liquid crystal display panel according to the present invention.

<Description of the symbols for the main parts of the drawings>

11: first transparent substrate

12: second transparent substrate

13: liquid crystal layer

14: first optical compensation film

15: second optical compensation film

16: first polarizer

17: second polarizing plate

18: first alignment layer

19: second alignment layer

21: first compensation substrate

211: first surface

212: second surface

213: first alignment layer

214: first polarizing plate

22: second compensation substrate

221: third surface

222: fourth surface

223: second alignment layer

224: second polarizer

24: first transparent electrode

25: second transparent electrode

26: color filter

27: thin film transistor layer

31: first compensation substrate

311: first surface

312: second surface

313: first alignment layer

314: first polarizing plate

32: second compensation substrate

321: third surface

322: fourth surface

323: second alignment layer

324: second polarizer

34: first transparent electrode

35: second transparent electrode

36: color filter

Claims (8)

A first compensation substrate having a first surface and a second surface, A first alignment layer provided on the first surface, A first polarizing plate provided on the second surface; A second compensation substrate having a third surface and a fourth surface, A second alignment layer provided on the third surface; A second polarizing plate provided on the fourth surface; It is made with a liquid crystal molecular layer, The first compensating substrate and the second compensating substrate are disposed at positions of the first surface and the third surface that are opposite to each other, and the liquid crystal molecular layer is formed of the first compensation substrate and the second compensation substrate. The wide view liquid crystal display panel which is provided in between. The wide view liquid crystal display panel of claim 1, wherein both of the first compensation substrate and the second compensation substrate are flexible plastic substrates having a stretchable and compensation film function. The method of claim 1, wherein the first compensation substrate and the second compensation substrate are both biaxial compensation substrates, The biaxial axis compensation substrate further has an in-plane retardation Ro and an out-of-plane retardation Rth, wherein Ro is in a range of 0 to 400 nm, and Rth is in a range of 0 to 300 nm, And said biaxial compensation substrate is an optically anisotropic substrate having a first X-direction optical axis and a second Y-direction optical axis. The liquid crystal display panel of claim 1, wherein the wide view liquid crystal display panel further includes a first transparent electrode disposed between the first surface and the first alignment layer. The first transparent electrode is a transparent conductive thin film, The transparent conductive thin film is a wide view liquid crystal display panel is made of a metal oxide. The display device of claim 1, wherein the wide view liquid crystal display panel further includes a second transparent electrode disposed between the third surface and the second alignment layer. And the second transparent electrode is a transparent conductive thin film made of a metal oxide. The liquid crystal display panel of claim 1, wherein the wide view liquid crystal display panel further comprises a color filter disposed between the first compensation substrate and the liquid crystal layer. The wide view liquid crystal display panel further includes a thin film transistor layer disposed on the third surface of the second compensation substrate. The first alignment layer and the second alignment layer is made of a polyimide resin, The first polarizing plate and the second polarizing plate are formed by bonding a TAC film of one layer to each of the two sides after extending from the PVA substrate to the film. A first compensation substrate having a first surface and a second surface, A second compensation substrate having a third surface and a fourth surface, It is made with a liquid crystal molecular layer, The first compensation substrate and the second compensation substrate may be disposed at positions of the first surface and the third surface that are opposite to each other, and the liquid crystal molecule layer may be formed of the first compensation substrate and the second compensation substrate. The wide view liquid crystal display panel which is provided in between. The display device of claim 7, wherein the wide view liquid crystal display panel further comprises a first alignment layer disposed on the first surface. The wide view liquid crystal display panel further includes a second alignment layer disposed on the third surface, The wide view liquid crystal display panel further includes a first polarizing plate disposed on the second surface, and / or And the wide view liquid crystal display panel further comprises a second polarizing plate provided on a fourth surface.