JP2003075819A - Color filter for ips mode liquid crystal display device and ips mode liquid crystal display device using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a color filter for an IPS mode liquid crystal display device having a conductive thin film formed for preventing the adverse effect of static electricity and free from elution of an alkali metal ion and the like into a liquid crystal material resulting in an obstacle to operation of a liquid crystal and reduction of display quality and to provide the IPS mode liquid crystal display device using the same. SOLUTION: A transparent conductive film 70 and an overcoat layer 14 are successively stacked so as to cover a black matrix layer 12 and a color filter layer 13 formed on one surface of a transparent substrate 10. The color filter for the IPS mode liquid crystal display device is used.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color filter for a liquid crystal display device, and more particularly, to an IPS (In Plane Switch) which has improved display quality by preventing alkali metal ions from eluting into a liquid crystal material.
The present invention relates to a color filter for a ching) mode liquid crystal display device and an IPS mode liquid crystal display device using the same.

[0002]

2. Description of the Related Art Generally, a color filter for a liquid crystal display device is one in which a black matrix layer and a color filter layer formed as a pixel are provided on a transparent substrate. The black matrix layer is a matrix having a light shielding property, and the color filter layer formed as a pixel has, for example, a red, green, and blue filter function. The black matrix layer has a uniform size with the pixel position of the color filter layer being a fixed position, and when used in a liquid crystal display device, it blocks undesired light to display an image on the liquid crystal display device. It has the function of producing a uniform and even image with improved contrast. It also has a function of blocking light to the TFT element that drives the liquid crystal.

As a method of forming a color filter layer as a pixel on a transparent substrate, a method of dyeing a dyeable medium formed by photolithography, a method of using a photosensitive pigment-dispersed resin composition, and a non-photosensitive method. In addition to the method of etching the pigment-dispersed resin composition, the electrodeposition method using a patterned electrode, and the like, there are methods of forming pixels by a printing method or an inkjet method as a low-cost manufacturing method. In addition, the black matrix layer is formed by finely patterning the metal thin film using a photoetching method,
Alternatively, it is often formed by patterning a resin colored with a light shielding agent using a photolithography method.

A conventional liquid crystal display device has a structure in which such a color filter and another transparent substrate are attached to each other, and liquid crystal is twisted by 90 degrees or more in the gap between them for orientation. As another transparent substrate, a thin film transistor (T
FT), a thin film diode, a stripe of transparent electrodes, and a matrix of stripe-shaped transparent electrodes formed on the color filter side.

FIG. 3 shows a TN (Twisted Nema).
FIG. 3 is an explanatory view showing a pixel portion of an example of a tic) mode liquid crystal display device (2) in a cross section. As shown in FIG. 3, the TN mode liquid crystal display device (2) comprises a polarizing layer (17), a color filter (4), a liquid crystal material (19), a TFT substrate (6) and a polarizing layer (18). There is. Color filter (4)
Has a black matrix layer (12) formed as a light-shielding portion and a color filter layer (13) formed as a pixel on one surface of the transparent substrate (10), and an overcoat layer (14) thereon. , A transparent common electrode layer (15) is formed in this order. The transparent common electrode layer (15) is in contact with the liquid crystal material (19). Also, T
The FT substrate (6) has a TFT (50) and a transparent pixel electrode (16) formed on the surface of the transparent substrate (11) facing the color filter (4).

In such a TN mode liquid crystal display device (2), the liquid crystal material (19) has a transparent common electrode layer (15) on the color filter (4) and a transparent common electrode layer on the TFT substrate (6). Responsive to a vertical electric field (20) between the pixel electrode (16). That is, illumination light (40)
Is a transparent pixel electrode (16) on the TFT substrate (6),
It is turned on / off through the transparent common electrode layer (15) on the color filter (4).

Such a TN mode liquid crystal display device (2)
The drawback is that the viewing angle is narrow, and up to now, many methods have been proposed for improving the viewing angle of the TN mode liquid crystal display device (2).
IPS (In Plane Switchin)
g) There is a mode liquid crystal display device.

FIG. 2 shows an IPS mode liquid crystal display device (1).
It is explanatory drawing which represented the pixel part of an example by the cross section. As shown in FIG. 2, the IPS mode liquid crystal display device (1) includes a polarizing layer (17), a color filter (3), a liquid crystal material (29),
It is composed of a TFT substrate (5) and a polarizing layer (18).
The color filter (3) includes a black matrix layer (12) formed as a light shielding portion and a color filter layer (1 formed as a pixel on one surface of the transparent substrate (10).
3) on which the overcoat layer (14) is formed. The overcoat layer (14) is in contact with the liquid crystal material (29). The TFT substrate (5) is provided on the surface of the transparent substrate (11) facing the color filter (3) with the TFT (50) and the metal pixel electrode (2).
6), the metal common electrode (25) is formed.

In such an IPS mode liquid crystal display device (1), the liquid crystal material (29) is the TFT substrate (5).
Responsive to a horizontal electric field (30) between the upper metal pixel electrode (26) and the metal common electrode (25). That is, the transparent common electrode layer (15) and the transparent pixel electrode (16) as in the TN mode shown in FIG. 3 are not required, and the illumination light (40) is applied to the horizontal electric field (30) to the liquid crystal material (30). Two
9) will rotate in response and will be turned on / off.
Further, in order not to disturb the electric field (30) in the horizontal direction, the material of the black matrix layer (12) is not a metal thin film of chromium or the like but a resin in which a light shielding agent such as a black pigment is dispersed is often used.

As described above, since the color filter (3) is not provided with conductivity, it may be affected by static electricity, which may adversely affect the yield during manufacturing and the display quality of the liquid crystal display device. For example, static electricity during the manufacturing process causes particles of the spacers to aggregate, and when the liquid crystal display device is touched by hand, the static electricity may disturb the alignment of the liquid crystal, resulting in uneven display. In the color filter (4) used in the TN mode liquid crystal display device (2), the transparent common electrode layer (15) is provided, and the conductivity is imparted to the color filter (4). Will never occur.

In order to solve the problem caused by static electricity in the color filter (3) used in the IPS mode liquid crystal display device (1), the color filter is electrically conductive in JP-A-10-160920 and 2000-39509. A technique of forming a conductive film to remove static electricity is disclosed. FIG. 4 is a cross-sectional view showing the structure of the color filter for an IPS mode liquid crystal display device disclosed in the above-mentioned JP-A-10-160920.

As shown in FIG. 4, the color filter for an IPS mode liquid crystal display device is formed as a pixel with a black matrix layer (12) formed as a light shielding portion on one surface of a transparent substrate (10). It has a color filter layer (13) and an overcoat layer (14) is formed thereon. In addition, a conductive thin film (4
5) is formed, and the conductive thin film (45) removes static electricity. Then, when it is bonded to another transparent substrate, it is bonded so that the overcoat layer (14) on one surface of the transparent substrate (10) is in contact with the liquid crystal material.

Since the conductive thin film (45) is formed on the other surface of the transparent substrate (10) in the color filter for the IPS mode liquid crystal display device, the color filter is stuck to another transparent substrate and the IPS mode liquid crystal. When it is used as a display device, for example, the particles of the spacer are not aggregated by static electricity during the manufacturing process, and even if the manufactured liquid crystal display device is touched by hand, the alignment of the liquid crystal is disturbed due to the influence of static electricity. Problems such as unevenness do not occur.

However, when the color filter having such a structure is used in the IPS mode liquid crystal display device, for example, when a photosensitive pigment-dispersed resin composition is used as a material for forming the color filter layer, the formed color filter is used. A trace amount of alkali metal ions, nitrate ions, chlorine ions, etc. from the filter layer, or, for example, a trace amount of alkali metal ions from the residue of the material used in the patterning process for forming the color filter layer as a pixel, etc. Permeates the coat layer (14) and elutes into the liquid crystal material,
The operation of the liquid crystal is disturbed and the display quality is adversely affected.
The degree to which such a small amount of alkali metal ions interferes with the operation of the liquid crystal is particularly remarkable in the IPS mode liquid crystal display device.

This is due to the difference between the liquid crystal material used in the TN mode liquid crystal display device and the liquid crystal material used in the IPS mode liquid crystal display device. That is, TN
Fluorine-based liquid crystal materials are mainly used as liquid crystal materials used in mode liquid crystal display devices. However, as liquid crystal materials used in IPS mode liquid crystal display devices, fluorinated liquid crystal materials are used in order to obtain high-speed response. A liquid crystal material is mixed and used. This cyano liquid crystal material is easily affected by the above-mentioned alkali metal ions and the like, and the display quality is remarkably deteriorated.

[0016]

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an IP having a conductive thin film formed thereon for preventing the adverse effect of static electricity.
In the color filter for S-mode liquid crystal display device, for the IPS mode liquid crystal display device, in which alkali metal ions, etc. penetrate into the overcoat layer and elute into the liquid crystal material, which hinders the operation of the liquid crystal and deteriorates the display quality. It is an object to provide a color filter. Another object is to provide an IPS mode liquid crystal display device using the same.

[0017]

The present invention relates to a color filter for an IPS mode liquid crystal display device, which comprises a transparent conductive film and a transparent conductive film so as to cover a black matrix layer and a color filter layer formed on one surface of a transparent substrate. It is a color filter for an IPS mode liquid crystal display device, which is formed by sequentially laminating coat layers.

Further, the present invention is an IPS mode liquid crystal display device characterized by using the color filter for the IPS mode liquid crystal display device according to the above invention.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below based on an embodiment. FIG. 1 is an explanatory view showing a cross section of a pixel portion of an embodiment of a color filter for an IPS mode liquid crystal display device according to the present invention.

As shown in FIG. 1, a color filter (60) for an IPS mode liquid crystal display device comprises a black matrix layer (12) made of a black resin formed as a light shielding portion on one surface of a transparent substrate (10). A color filter layer (13) formed as a pixel is provided, and the transparent conductive film (70) and the overcoat layer (14) are provided so as to cover the black matrix layer (12) and the color filter layer (13). ) Are sequentially laminated.

Since the transparent conductive film (70) is provided in the color filter for the IPS mode liquid crystal display device, it is affected by static electricity and adversely affects the yield during manufacturing and the display quality of the liquid crystal display device. There is no. Further, the color filter for the IPS mode liquid crystal display device is provided with a transparent conductive film (70) so as to cover the color filter layer (13) formed as a pixel, and on the transparent conductive film (70). Since the overcoat layer (14) is laminated and provided, the transparent conductive film (70) is provided with the overcoat layer (14) that does not sufficiently shield alkali metal ions and the like.
Will be the supplement.

Therefore, alkali metal ions and the like are not dissolved in the liquid crystal material, which hinders the operation of the liquid crystal and adversely affects the display quality. This transparent conductive film (70)
Also, the effect of shielding alkali metal ions and the like by the overcoat layer (14) does not adversely affect the IPS mode liquid crystal display device. As the transparent conductive film (70), for example, ITO (Indium Ti)
If n oxide) is used, the film thickness may be 200 nm or less.

In addition, since the color filter for the IPS mode liquid crystal display is provided with the overcoat layer (14) laminated on the transparent conductive film (70), the transparent conductive film (70) is additionally provided. Even if partial peeling occurs in (), the fragments of the transparent conductive film (70) do not flow out to the outside, and the occurrence of short circuit can be prevented. Similarly, even if the transparent conductive film (70) is partially damaged due to the biting of the spacer beads, it is possible to prevent the occurrence of a short circuit.

[0024]

The present invention is a color filter formed by sequentially laminating a transparent conductive film and an overcoat layer so as to cover a black matrix layer and a color filter layer formed on one surface of a transparent substrate. A color filter for an IPS mode liquid crystal display device, in which the adverse effect of static electricity is prevented, and alkali metal ions and the like are eluted into the liquid crystal material to hinder the operation of the liquid crystal and reduce the display quality.

Further, by using the color filter for the IPS mode liquid crystal display device, the adverse effect of static electricity is prevented, and alkali metal ions and the like are eluted in the liquid crystal material, which hinders the operation of the liquid crystal and deteriorates the display quality. This enables an IPS mode liquid crystal display device that does not operate.

[Brief description of drawings]

FIG. 1 is a cross-sectional explanatory view of a pixel portion of an embodiment of a color filter for an IPS mode liquid crystal display device according to the present invention.

FIG. 2 is an explanatory diagram showing a cross section of a pixel portion of an example of an IPS mode liquid crystal display device.

FIG. 3 is an explanatory diagram showing a cross section of a pixel portion of an example of a TN mode liquid crystal display device.

FIG. 4 is a cross-sectional view showing a structure of a color filter for an IPS mode liquid crystal display device having a conductive film formed thereon.

[Explanation of symbols]

1 ... IPS mode liquid crystal display device 2 ... TN mode liquid crystal display device 3, 4 ... Color filter 5, 6 ... TFT substrate 10, 11 ... Transparent substrate 12 ... Black matrix layer 13 ... Color filter layer 14 ... Overcoat layer 15 ... Transparent Common electrode layer 16 ... Transparent pixel electrodes 17, 18 ... Polarizing layers 19, 29 ... Liquid crystal materials 20, 30 ... Electric field 25 ... Metal common electrode 26 ... Metal pixel electrode 40 ... Illumination light 45 ... Conductive thin film 50 ... TFT 60 ... Color filter 70 for IPS mode liquid crystal display device according to the present invention ... Transparent conductive film

Claims (2)

[Claims] 1. A color filter for an IPS mode liquid crystal display device, wherein a transparent conductive film and an overcoat layer are sequentially laminated so as to cover a black matrix layer and a color filter layer formed on one surface of a transparent substrate. A formed color filter for an IPS mode liquid crystal display device. 2. An IPS mode liquid crystal display device using the color filter for an IPS mode liquid crystal display device according to claim 1.