JPH06337308A - Color filter for liquid crystal display device - Google Patents

Abstract

PURPOSE:To omit a transparent protective layer to protect a filter color pattern by eliminating reduction of mutual joining strength and a liquid crystal sealing strength between a color filter glass substrate and a glass substrate for electrodes confronting the color filter by the omission of the transparent protective layer (overcoating layer) and to efficiently produce a color filter for a liquid crystal display device at low cost. CONSTITUTION:This color filter for a liquid crystal display device is equipped with a black matrix pattern 2 having an insulating property or electrical conduction cutting off property, a filter color pattern 5 comprising blue, green and red colored patterns formed on a transparent glass substrate 1, and a transparent conductive layer 4 formed on these patterns 2, 5. The transparent conductive layer 4 is directly formed on the patterns 2, 5. An anchor layer 3 for connection comprising a metal thin film is formed along the sealing part of a liquid crystal on the transparent glass substrate 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a black matrix pattern on a glass substrate, and blue, green, and
d The present invention relates to a color filter for a liquid crystal display device, which includes a filter color pattern composed of each colored pattern and a transparent conductive film as appropriate.

[0002]

2. Description of the Related Art As shown in the side sectional view of FIG. 3, a conventional color filter for a liquid crystal display device or the like has an appropriate shape such as regular parallel lines or a grid on a glass substrate 11 for the color filter. A black matrix pattern 12 having a light-shielding (or light absorbing) pattern is provided, and between the black matrix patterns 12, Blue, Green, and Red are provided.
Filter color pattern 13 composed of each color pattern
A transparent protective layer 14 (transparent overcoat layer) is provided on the upper side of the black matrix pattern 12 and the filter color pattern 13 by using an appropriate transparent resin such as epoxy resin, and the transparent protective layer 14 is provided on the transparent protective layer 14. A transparent conductive layer 15 such as an ITO thin film is laminated in a wiring pattern.

In the above color filter, it is necessary to arrange the black matrix pattern 12 and the filter color pattern 13 so as to be in close contact with each other so that no void is formed in the adjacent portion between the black matrix pattern 12 and the filter color pattern 13. Therefore, the filter color pattern 13 is provided so as to overlap the black matrix pattern 12.

The black matrix pattern 12 is
When forming a pattern on the glass substrate 11, a chromium vapor deposition thin film formed on the glass substrate 11 by a metal vapor deposition method is patterned by a pattern etching method, or
Pattern formation is performed by a photofabrication (photolithography) method using a pigment dispersion photoresist in which black and dark color pigments are dispersed in a photoresist, or pattern formation is performed by a intaglio offset printing method using a printing ink.

In the conventional color filter for a liquid crystal display device shown in FIG. 3, a transparent glass substrate 18 for a counter electrode is arranged so as to face the transparent conductive layer 15 formed on the glass substrate 11 in parallel with each other. Then, a transparent conductive layer 19 such as an ITO thin film is formed in a wiring pattern on the opposing inner surface of the transparent glass substrate 18.

The transparent glass substrate 1 and the transparent glass substrate 18 for the counter electrode are filled with the liquid crystal 17 in the space facing each other, and an epoxy resin adhesive or the like in which glass powder or the like also serving as a spacer is mixed as a compound. The peripheral end portions of the glass substrates 11 and 18 are bonded to each other in a hermetically sealed state by the adhesive sealing material 6 (bonding sealing material). Transparent protective layer 14 made of an epoxy resin or the like having good adhesiveness to the transparent protective layer 14, a transparent conductive layer 15 made of an ITO thin film having good adhesiveness to the transparent protective layer 14, the transparent conductive layer 15 and a glass substrate. 18 is bonded and sealed by an adhesive sealing material 16 made of an epoxy resin adhesive having good adhesiveness, and its adhesive strength is kept good.

[0007]

In recent years, a technique for simplifying the manufacturing process of a color filter for a liquid crystal display device so that the color filter can be manufactured efficiently and at a relatively low price is being developed. In the above color filter for liquid crystal display device, the transparent protective layer 14 (transparent overcoat layer) for protecting the filter color pattern 13 is omitted.

However, in the case where the transparent protective layer 14 is omitted in FIG. 3, the glass substrate 11 and the transparent conductive layer are connected to the glass substrate 11 for the filter and the glass substrate 18 for the counter electrode at the joint portion of the liquid crystal encapsulation seal ends. Layer 15 (ITO
Since a bonded state is formed by direct contact with (thin film),
On the bonding surface of the glass substrate 11, Blue, Green
Fine processing residues that occasionally occur in the process before the bonding such as the process for forming the n and Red filter color patterns 13 adhere to the bonding strength between the glass substrate 11 and the transparent conductive layer 15, and thus the glass substrate 11, The joint sealing strength of 18 (filter panel assembly strength) and the liquid crystal encapsulation sealing strength are reduced.

According to the present invention, the transparent protective layer (transparent overcoat layer) for protecting the filter color pattern is omitted, and the bonding strength between the glass substrate for the color filter and the glass substrate for the counter electrode and the liquid crystal sealing seal. The purpose is to eliminate the reduction in strength and realize the omission of the transparent protective layer, thereby enabling efficient manufacture of a color filter for a liquid crystal display device at a relatively low price.

[0010]

According to the present invention, an insulating or energizing black matrix pattern 2 and a filter color pattern 5 composed of blue, green and red color patterns are provided on a transparent glass substrate 1. In the color filter for a liquid crystal display device, which includes a transparent conductive layer on the black matrix pattern 2 and the filter color pattern 5, the transparent conductive layer 4 is provided so as to directly contact the black matrix pattern 2 and the filter color pattern 5, A color filter for a liquid crystal display device, characterized in that a bonding anchor layer 3 made of a chromium film or a chromium oxide film is provided along a liquid crystal enclosing seal portion of a transparent glass substrate 1.

[0011]

EXAMPLE A color filter for a liquid crystal display device according to the present invention,
A detailed description will be given below according to one embodiment of FIGS.

As shown in the side sectional view of FIG. 1, the color filter for a liquid crystal display device of the present invention has an appropriate shape pattern such as regular parallel lines or a lattice on a transparent glass substrate 1 for the color filter. The black matrix pattern 2 having the light shielding property (or light absorption property) is provided, and a metal thin film such as chromium or chromium oxide formed by a vapor deposition method, a sputtering method, or the like is appropriately provided on the outer periphery of the area where the black matrix pattern 2 is formed. A bonding anchor layer 3 having a width (width of a bonding seal portion for a liquid crystal encapsulating seal described later) is provided.

A filter color pattern 5 composed of blue, green and red color patterns is provided between the black matrix patterns 2 and black is directly provided on the black matrix pattern 2 and the filter color pattern 5. A transparent conductive layer 4 such as an ITO thin film is laminated in a wiring pattern so as to contact the matrix pattern 2 and the filter color pattern 5.

In the above color filter, it is necessary to arrange the black matrix pattern 2 and the filter color pattern 5 so as to be in close contact with each other so that no void is formed in the adjacent portion between the black matrix pattern 2 and the filter color pattern 5. Therefore, the filter color pattern 5 is provided so as to overlap the black matrix pattern 2.

When the black matrix pattern 2 is formed on the glass substrate 1, the glass substrate 1 is used.
A light-shielding (semitransparent or opaque) chromium vapor-deposited thin film formed by a metal vapor deposition method or a sputtering method, or a light-shielding chromium oxide vapor-deposited thin film, or these chromium,
A composite metal thin film (laminated film) of chromium oxide or the like is patterned by a pattern etching method, and the black matrix pattern 2 itself is a conductive material capable of conducting electricity.

In the present invention, the black matrix pattern 2 having a current-carrying cutoff property means a pattern in which the current-carrying state is cut off from the other on the insulating glass substrate 1.

In the present invention, the insulating black matrix pattern 2 is made of a material such as a metal oxide which is not an electrically good conductor, in addition to a simple metal material such as chromium which is an electrically good conductor. It means the formed black matrix pattern.

As shown in FIG. 1, the color filter for a liquid crystal display device of the present invention comprises an ITO thin film formed on the black matrix pattern 2 and the filter color pattern 5 formed on the transparent glass substrate 1 for the color filter. Etc., a transparent conductive layer 4 (solid in the case of the TFT array liquid crystal display system) is formed.

Further, as shown in FIG. 1, the color filter for a liquid crystal display device of the present invention is used for a counter electrode so as to face the transparent conductive layer 4 side formed on the transparent glass substrate 1 in parallel with each other. The transparent glass substrate 8 is disposed, and a transparent conductive layer 9 such as an ITO thin film for a counter electrode is formed in a TFT array on the opposing inner surface of the transparent glass substrate 8.

The conductive wiring pattern formed by the transparent conductive layer 4 on the color filter glass substrate 1 side and the conductive wiring pattern formed by the transparent conductive layer 9 on the glass substrate 8 side for the counter electrode are appropriately set according to the display format of the liquid crystal display device. (Design change) is possible. For example, in the case of the XY drive display method, stripe-shaped wiring patterns are arranged in a direction orthogonal to each other, and each filter color pattern is directly below the mutually orthogonal point portions. In the case of the TFT display system, the transparent conductive layer 4 formed on the color filter glass substrate 1 side is solid, and the transparent conductive layer 9 on the counter electrode glass substrate 8 side is the TFT array. Pattern. In the present invention, when the seal portion is a conductive film such as a chrome film, in the XY drive display system, a short circuit between lines may occur and display may not be possible. Therefore, it is appropriate to adopt the TFT display system. Is.

As shown in FIG. 1, the transparent glass substrate 1 for the color filter and the transparent glass substrate 8 for the counter electrode.
The liquid crystal 7 is filled in the gaps facing each other, and the areas outside the area where the black matrix pattern 2 and the filter color pattern 5 are formed are mutually separated by an adhesive sealing material 6 (bonding sealing material) such as an epoxy resin adhesive. Glass substrate 1,
The liquid crystal is bonded along the bonding seal portion 8 to hermetically seal the liquid crystal.

The liquid crystal encapsulation seal joint ends of the glass substrates 1 and 8 are joined to the glass substrate 1 for one color filter by a thin metal film such as chromium or chromium oxide formed by a vacuum deposition method or the like. Anchor layer 3
Transparent conductive layer 4 made of an ITO thin film with good adhesion to
And the transparent conductive layer 4 and the glass substrate 8 for the counter electrode are bonded and sealed by an adhesive sealing material 6 (bonding sealing material) such as an epoxy resin adhesive having good adhesiveness, and the glass substrates 1 and 8 are sealed. The interlaminar adhesive strength of is maintained well.

In the color filter according to the present invention, as shown in FIG.
A filter color pattern 5 including each of the ue, green, and red color patterns is provided, and a transparent conductive film or the like is appropriately provided on the black matrix pattern 2 and the filter color pattern 5 (for example, an indium tin-doped wiring pattern or A transparent conductive film 4 such as a solid ITO film is laminated.

In the color filter according to the present invention, as in the conventional case, the black matrix pattern 2 and the filter color pattern 5 are in close contact with each other so that no void is formed in the adjacent portion between the black matrix pattern 2 and the filter color pattern 5. So that the edge portions of the black matrix pattern 2 and the filter color pattern 5 are adjacent to each other, or the edge portions of the filter color pattern 5 overlap the black matrix pattern 2. It is provided.

In the color filter for a liquid crystal display device of the present invention, the bonding anchor layer 3 is formed around the outer edge of the arrangement region of the black matrix pattern 2 in a suitable bonding shape such as a rectangular shape or a circular shape and with a suitable width. The bonding anchor layers 3 are arranged adjacent to each other across the arrangement area of the black matrix pattern 2 as shown in the side sectional view of FIG. 1 and the plan view of FIG. It is possible to continuously and adjacently arrange the portion and the seal joint portion formed by the adhesive sealing material 6 without providing a gap. In addition, m shows each line width (drawing line width) of the black matrix pattern 2, s shows the joining width of the seal joining part by the adhesive sealing material 6, and w
₁ is the length of the upper and lower horizontal seal joints, w ₂ is the length of the left and right vertical seal joints, and a is the black matrix pattern 2 at the outer end of the black matrix pattern placement area and the anchor for joining. The line width including layer 3 is shown.

In the color filter for liquid crystal display device of the present invention, the bonding anchor layer 3 is arranged adjacent to the black matrix pattern 2 outer end and the bonding anchor layer 3 end are not necessarily continuous to each other as a pattern. Between the outer end of the black matrix pattern 2 and the end of the bonding anchor layer 3 is, for example, 0.1 mm.
It is also possible to provide a small interval of about 1 mm and to dispose them adjacent to each other.

To manufacture the color filter for a liquid crystal display device of the present invention, first, on the glass substrate 1 for the color filter,
Depending on the vacuum deposition method, the sputtering method, etc., for example, the film thickness: 300Å to 2000Å or more (preferably 600Å
~ 2000Å), optical density: 1.5 or more (preferably 2.0 or more), a light-shielding (semi-transparent or opaque) chromium layer or chromium oxide layer, or a metal thin film formed by a composite lamination thereof.

Subsequently, a positive photosensitive photoresist (for example, an alkali-soluble polymer such as a novolac-type phenol resin or a methylmethacrylate-maleic anhydride copolymer) and an alkali-soluble polymer by light irradiation are formed on the metal thin film. A positive photoresist containing an increasing amount of an alkali dissolution inhibitor such as quinonediazide) is applied over the entire surface and dried to form a photosensitive resin layer which becomes an etching resist.

Specifically, for example, a positive photoresist containing a novolac type phenol resin and an alkali dissolution inhibitor such as quinonediazide is applied over the entire surface and dried.
A photosensitive resin layer serving as an etching resist (for example, coating thickness; 0.5 μm to 1 μm) is provided.

Next, the photosensitive resin layer is subjected to a photofabrication (photolithography) method by using ultraviolet rays, and the pattern shape of the black matrix pattern 2 and the anchor layer 3 for bonding having an appropriate shape as shown in FIG. Then, pattern exposure (exposure using an original plate such as a photomask or electron beam exposure) is performed to make the exposed portion of the photosensitive resin layer soluble in alkali (photolysis), and the black matrix pattern 2 on the unexposed portion. And an alkali-insoluble region in the shape of the bonding anchor layer 3 is formed.

Subsequently, the photosensitive resin layer in the exposed portion (photolysis area) is treated with an alkaline solution (sodium hydroxide, for example, pH).
(Value = about 10) is developed to form a resist pattern (etching resist pattern) having a shape corresponding to the black matrix pattern 2 and a shape corresponding to the bonding anchor layer 3.

Then, using the resist pattern as an etching mask, the lower metal thin film (chromium film, chromium oxide film) is appropriately etched with an etching solution (cerium nitrate-based etching solution or the like).

After that, the resist pattern is stripped with a stripping solution which is more alkaline than the alkaline solution used for the development (for example, an alkaline solution having a pH of 11 or more) or an organic solvent (acetone series, methyl ethyl ketone series, etc.) as appropriate. By doing so, the black matrix pattern 2 and the bonding anchor layer 3 made of a light-shielding metal thin film are formed on the glass substrate 1 of FIG. 1 in a pattern shape as shown in the plan view of FIG.

The color filter for a liquid crystal display device according to the present invention, as shown in FIG. 1, has a black matrix pattern 2 formed on the glass substrate 1 in a pattern blank portion in the black matrix pattern 2 formation region.
The filter color pattern 5 including blue, green, and red color patterns is formed, and the transparent conductive film 4 is directly applied from the upper side.

Blue, Gr are formed on a portion of the glass substrate 1 other than the formation region of the black matrix pattern 2.
When the filter color pattern 5 consisting of een and Red colored patterns is formed, for example, a transparent photosensitive liquid having good dyeability such as gelatin and Blue, Green are used.
A relief dyeing method similar to the conventionally known method of forming a filter color pattern of a color filter using each of n and Red dyes is used to improve the adhesiveness of a residual component generated in a filter color pattern forming process to an ITO thin film. It is suitable because there is little decrease.

In addition, as a method for forming the filter color pattern 5, in addition to the method by the dyeing method, a blue color is used.
e, Green, Red pigment dispersion photoresist method using each color pigment dispersion photoresist, Blue, G
1. Organic filter color pattern forming method by printing method such as intaglio offset printing method using each color printing ink of reen and Red, or titanium oxide (TiO ₂ , light refractive index;
40) and silicon oxide (SiO ₂ , optical refractive index; 1.46) and other dielectric films are laminated by vapor deposition, and the interference color filters (polarization filters) of Blue, Green, and Red depending on the layer thickness and combination. It is possible to form an inorganic filter color pattern forming method by a dielectric multilayer film forming method, and the black matrix pattern 2 and the filter color pattern 5 are closely adjacent to each other at their edge portions, or the filter color pattern 5 is The filter color pattern 5 is formed on the black matrix pattern 2 so that the edges thereof overlap.

[0037]

The color filter for a liquid crystal display device of the present invention comprises a transparent conductive layer 4 so as to be in direct contact with the black matrix pattern 2 and the filter color pattern 5 on the transparent glass substrate 1, and the liquid crystal encapsulation seal of the transparent glass substrate 1 is provided. Since the bonding anchor layer 3 made of a metal thin film is provided along the portion, the respective liquid crystal encapsulation seal bonding ends of the glass substrates 1 and 8 are vacuum-deposited or the like with respect to the glass substrate 1 for one color filter. The transparent conductive layer 4 made of an ITO thin film having good adhesiveness to the bonding anchor layer 3 made of a metal thin film such as chromium or chromium oxide formed by the above, and the transparent conductive layer 4 and the glass substrate 8 for the counter electrode. In order to maintain a facing distance by an epoxy resin adhesive or the like having excellent adhesiveness, an adhesive seal material 6 (bonding seal material) such as an epoxy resin adhesive or the like is held. Are joined sealed by interlayer adhesion strength between the glass substrate 1 and 8 has the effect to be better retained.

[0038]

According to the color filter for a liquid crystal display device of the present invention, the glass substrate for a color filter and the transparent conductive layer are provided at the joint portions of the glass substrate for a color filter 1 and the glass substrate for a counter electrode at the end portions of the liquid crystal encapsulation seal. Since it is not directly bonded to the glass substrate and is bonded while maintaining good strength via a bonding anchor layer, the glass substrates are not bonded to each other when the transparent protective layer for protecting the color filter color pattern is omitted. The joint seal strength and the liquid crystal encapsulation seal strength can be prevented from decreasing, and the transparent protective layer can be omitted so that the color filter for liquid crystal display device can be manufactured efficiently and at a relatively low price. is there.

[Brief description of drawings]

FIG. 1 is a side sectional view of an embodiment of a color filter for a liquid crystal display device of the present invention.

FIG. 2 is a plan view of a black matrix pattern and a bonding anchor layer formed on a glass substrate for a color filter used in an embodiment of a color filter for a liquid crystal display device of the present invention.

FIG. 3 is a side sectional view of a conventional color filter for a liquid crystal display device.

FIG. 4 is a plan view of a black matrix pattern formed on a glass substrate for a color filter used in a conventional color filter for a liquid crystal display device.

[Explanation of symbols]

1 ... Glass substrate for color filter 2 ... Black matrix pattern 3 ... Anchor layer for bonding 4 ... Transparent conductive film 5 ... Filter color pattern 6 ... Adhesive sealing material 7 ... Liquid crystal 8 ... Glass substrate for counter electrode 9 ... Transparent for counter electrode Conductive layer a ... Pattern line width including the anchor layer for bonding and black matrix pattern s ... Bonding seal width m ... Black matrix pattern width 11 ... Color filter glass substrate 12 ... Black matrix pattern 13 ... Filter color pattern 14 ... Transparent protection Layer 15 ...
Transparent conductive layer 16 ... Adhesive sealing material 17 ... Liquid crystal 18 ... Glass substrate for counter electrode 19 ... Transparent conductive layer for counter electrode

Claims (1)

[Claims] 1. A transparent glass substrate 1 on which a black matrix pattern 2 having an insulating property or a current-carrying property and a blue,
A color filter for a liquid crystal display device, comprising a filter color pattern 5 composed of green and red color patterns, and a transparent conductive layer on the black matrix pattern 2 and the filter color pattern 5. A liquid crystal display comprising a transparent conductive layer 4 so as to be in direct contact with the color pattern 5 and a bonding anchor layer 3 made of a chromium film or a chromium oxide film provided along the liquid crystal encapsulation sealing portion of the transparent glass substrate 1. Color filter for equipment.