TWI252936B - Displacement-designed color filter structure and method of forming the same - Google Patents

Abstract

The present invention provides a color filter structure and a forming the same. The structure comprises a transparent substrate, a black matrix and a plurality of color regions separated by the black matrix. The black matrix grid is formed by a plurality of horizontal black matrix strips and a plurality of vertical black matrix strips. These color regions are formed by red, green or blue color resin forming in corresponding matrix grids. In each matrix grid, the resin is positioned to cover a larger area on an adjacent vertical black matrix strip than to cover an area of the other adjacent vertical black matrix strip. The structure can prevent the problem of corner image sticking in a frame of the liquid crystal display device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device (LCD device), and more particularly to a liquid crystal display device and has an offset or displacement design. Color Filter Structure (CF structure) 〇 [Prior Art] A color filter is a key component for coloring a liquid crystal display device. Since the liquid crystal display device is mainly a thin film transistor (TFT) liquid crystal display device, the color filter substrate for TFT LCD is the most potential and development in the current market. A conventional liquid crystal display includes two substrates, a color filter substrate and an active panel or TFT panel, and a liquid crystal layer is sandwiched between the two substrates. As shown in FIG. 1A, the structure of a conventional color filter substrate includes a transparent substrate 1 , a black matrix 104, and a plurality of color regions separated by the black matrix 1〇4. 102. The black matrix 1〇4 is composed of a plurality of horizontally arranged black matrix strips 104b, and a plurality of vertically arranged black matrix strips 104a, horizontally arranged black matrix strips. L〇4b and the vertically arranged black matrix strips l〇4a intersect each other to form a grid structure, and separate a plurality of color regions 102. These color regions 丨〇2 are used to respectively place 1252936 layers of different colors, red (red), green (green) and blue (blue) colors chromospheres 102R, 102G and 102B. A common electrode (common eleCtr〇de) 106 is formed on the color layers i 〇 2R, i 〇 2G and 102B. The common electrode 106 is one of the two electrodes' and the two electrodes are used to generate an electric field across the liquid crystal layer when the liquid crystal display device is operated. Figure 1B shows a plan view of a conventional color filter substrate, and Figure 2A shows a cross-sectional view of the substrate of the i-th image along the cutting line v_v, which is used to illustrate a conventional color filter substrate. There may be disadvantages. In Fig. 1B, the black matrix 104 is formed between the color filters in a grid pattern. This black matrix 1〇4 is composed of a plurality of horizontal black matrix strips 104b and a plurality of vertical black matrix strips 104a. The horizontal black matrix strips 104b and the vertical black matrix strips 1〇4a are respectively disposed on the gate lines (source Hne) and the source lines corresponding to the TFT substrate. Referring to Fig. 2A, in the conventional color filter structure, the respective color layers 102R 1 〇 2G and 102B are partially overlapped over the adjacent vertically arranged black matrix strips 104a to avoid light leakage. After a conductive layer (not shown) as an electrode is formed on the transparent substrate 1 〇〇 and the respective color layers 102R, 10 〇 2G and 102B, alignment processing is required, for example, brushing treatment 0-bbing). Before the brushing treatment, it is necessary to apply the alignment film (4) and then add the film), while the main component of the product is polyacrylimide (p〇iyimide), and the LCD industry is referred to as PI. The alignment treatment is a metal cylinder roller with a felt, and the surface of the alignment film 1252936 formed on the TFT substrate and the color filter substrate is rotated and rubbed back and forth so that the liquid crystal molecules can be directed in a predetermined direction. As shown in FIG. 2A, since the overlapping portion of the blue color layer 1 〇 2B and the two adjacent black matrix strips 1 〇 4a has a particularly convex shape, when the alignment direction is from left to right, the height difference of the overlapping portions is\ When y will cause alignment, there will be a region where the alignment film is not brushed, that is, the alignment abnormal zone 丨〇8 and the rich alignment direction are changed from right to left, and the alignment abnormal zone is in the alignment different suspension zone 1 08 and 11 The opposite side of the cockroach. Similarly, the red color layer i 〇 2R and the green color layer 102G also cause an alignment abnormal region. The above-mentioned alignment anomaly area causes a problem of the angle residual image (c〇rner iniage sticking. The alignment abnormal area 11 遮 is covered by the vertical black matrix strip 丨〇 4a, so it is opaque, but the alignment abnormal area 丨〇8 is In the display area, light leakage will occur, resulting in angular residual images. For the phenomenon of angular afterimages, please refer to Figure 28. When the panel is lit, the corners of the corners of the inspection surface 200 have strip-shaped white areas 2〇2 and 2〇. 4. After the corner residual inspection screen 200 is switched to the full black screen 2〇6, the original strip-shaped white area 202 may have a phenomenon that the black surface cannot be restored, and the corner afterimage 208 is generated. The mating film coated on the peripheral edge is thicker, and the weight of the alignment film is not brushed in the opposite-direction f region, so the angular residual image is more likely to occur. [Inventive content] Therefore, the purpose of H% is to provide The color is suitable for a liquid crystal display device for solving the problem of an angular residual image. Another trick of the present invention is to provide a color filter for forming a liquid crystal, > + 曰曰., The method of using the negative structure is used to solve the problem of the residual image of the angle. 1252936 According to the above (4) of the present invention, a color filter structure suitable for a liquid crystal display is proposed, which comprises a transparent substrate, a black matrix, and a plurality of color regions separated by the black matrix. a matrix is formed on the substrate and is composed of a plurality of waters intersecting each other; a black matrix strip and a plurality of vertically arranged black matrix strips are arranged, and a grid structure is formed to separate a plurality of color regions for respectively Configuring a corresponding red, blue or green color layer formed by the resin material, wherein the resin formed by the corresponding color in each grid covers one of the two adjacent vertical black moment strips a region, and a vertically spaced black matrix strip covering another smaller area. Further, the present invention is directed to a method of forming a color filter structure of a liquid crystal display device. The method comprises the steps of: On a transparent substrate, a plurality of black matrix strips arranged in a permanent arrangement and a plurality of vertically arranged black matrix strips are formed, wherein the horizontal arrays are arranged horizontally a black matrix strip and vertically arranged black matrix strips intersect each other to form a grid structure to separate a plurality of colored regions; and a color layer forming a corresponding color in each of the grids, wherein the color layer will be two One of the adjacent vertical black matrix strips covers a larger area, and the other adjacent vertically arranged black matrix strip covers a smaller area. The present invention has the following advantages. The color filter structure proposed by the present invention The height difference between different portions of the color filter can be reduced to solve the problem of poor brushing during the alignment, so that the occurrence of the angular afterimage can be avoided. [Embodiment] 8 1252936 The present invention provides a color filter structure. Suitable for liquid crystal display devices. Fig. 3A shows a plan view of a color filter structure according to a preferred embodiment of the present invention, and Fig. 3B shows a cross-sectional view of the structure taken along line 3A. Referring to Figures 3 and 3, the color filter structure comprises a transparent substrate 3〇〇, a black matrix 3〇4, and a plurality of color regions 3〇2 separated by the black matrix. The black matrix (Mack matrixp04 is formed on the transparent substrate 3〇〇, which is composed of a plurality of horizontally arranged black matrix strips 304b and a plurality of vertically arranged black matrix strips 3〇4a intersecting each other, wherein the cross-arranged The matrix strips 3〇4a and 3〇4b form a grid structure to separate a plurality of color regions 3〇2. Color filters of various color layers, red color layer 302R, blue color layer 3〇2B or green The color layer 302G is disposed in the corresponding color region 3〇2, wherein each color layer is formed of a resin material, and the transparent substrate 3 is formed, for example, by glass or quartz, and the black matrix is formed. 3〇4 is composed of an opaque metal such as chrome deposited on the transparent substrate 300. In the embodiment of forming a color filter, first a red resin is coated on a horizontal black. The matrix strips 3 〇 4b and the vertical black matrix strips 3 04a of the transparent substrate 3 are patterned and patterned to form a plurality of red color layers 302R. Then a green resin is coated on the transparent substrate 3 Patterning to form complex A green color layer 302G is located adjacent to the plurality of red color layers 302R. Finally, a blue resin is coated on the transparent substrate 3〇〇 and patterned to form a plurality of blue color layers 302B, which are located in a plurality of red color layers. 3 02R and a plurality of green color layers 3 〇 2G. It is noted that the above 1252936 is only one of various embodiments for forming a color filter, and the present invention is not limited to the above embodiments. As shown, these color layers 3〇2R, 302G, and 302B partially overlap to cover adjacent vertical black matrix strips 304a to avoid light leakage. In Figure 3B, dashed line 315 represents color in the prior art. The outline of the layer. An important feature of the present invention is that each color layer covers a larger area of one of two adjacent vertical black matrix strips, and a smaller coverage of another adjacent vertically arranged black matrix strip. Such a color layer may be referred to as an eccentric design, that is, a portion of each of the color layers covering the two black matrix strips on each side is asymmetrical. For example, the blue color layer 302Β The portion of the black matrix strip 3〇4a overlaid to the left is smaller than the portion of the black matrix strip 3〇4a overlapping the right side, as shown in the πth figure. Therefore, compared with the contour of the color filter of the prior art, this Besch The color filter in the example appears to be shifted to the right, so it is called eccentric design. Then 'a conductive layer (not shown) as an electrode also needs to be formed on the transparent substrate 300 and 4匕彩劳洛® u lL _ , a color layer. This conductive layer is usually an indium tin oxide (ITO) layer. Then it needs to be aligned, for example, rubbing. It needs to be coated before the alignment treatment. The alignment film of the cloth. Further, the color filter of the eccentric design in the 3B diagram reduces the difference in height between the portion of the color layer covering the black matrix strip 304a and the other adjacent portions. Take the blue color layer 302B for your 丨 廿 & field. In the brother-month, the overlap with the two adjacent black matrix strips 304a has no obvious convexity, and the shape of the bellows is as shown in Fig. 3B, so it corresponds to the previous art in the matching of F' " Region 316 and 10 1252936 318 of color layer 302B have a substantially reduced height difference. When the alignment direction is from left to right, the region 316 in the display region is still brushed to obtain an alignment film because there is a greatly reduced height difference, and no alignment abnormal region is caused. The area 318 also has a greatly reduced height difference, and is still covered by the black matrix strips 3〇4a, so that even some of the distributions do not leak light, so the display quality is not affected. Similarly, when the alignment direction is from left to right, the red color layer 3〇2R and the green color layer 302G can also avoid the occurrence of angular afterimages. In accordance with the above, the present invention is also directed to a method of forming a color filter structure for a liquid crystal display device. As shown in FIG. 3A and FIG. 3B, the method comprises the steps of: forming a black matrix 304 on a transparent substrate 1 , wherein the black matrix 3〇4 is arranged in a plurality of horizontally arranged blacks by intersections. The matrix strip 304b and the plurality of vertically arranged black matrix strips 3〇4a are formed, and the intersecting horizontally arranged black matrix strips 3 and the vertically arranged black matrix strips 304a form a grid structure to separate a plurality of colored regions. 302, and forming a color layer of a corresponding color in each of the grids, wherein the color layer is an eccentric structure, that is, when formed, a large area is covered by one of the two adjacent vertical black matrix strips, The other adjacent vertically arranged black matrix strips cover a smaller area. It will be apparent from the above-described preferred embodiments of the invention that the application of the invention includes the following advantages. The color filter structure proposed by the invention can reduce the height difference between different portions of the color light-passing sheet to solve the problem of poor brushing during the alignment, so that the occurrence of the angular afterimage can be avoided. Although the present invention has been disclosed in the above preferred embodiments, it is not intended to limit the present invention, and any skilled person skilled in the art can make various modifications and refinements without departing from the spirit of the invention and 11 1252936. The scope of the invention is defined by the scope of the appended claims. BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features, and advantages of the present invention will become more apparent and understood. A structure of a conventional color filter substrate is shown. Fig. 1B shows a plan view of a conventional color filter substrate. Fig. 2A shows a cross-sectional view of the substrate of the first ? map along the cutting line v_v. Figure 2B shows the phenomenon of angular afterimage. Color Filter 苐 3 A is a plan view of a structure in accordance with a preferred embodiment of the present invention. Section 3B of the structure of the figure shows a side view along the cutting line χ_χ. [Simplified Description of Component Symbols] 100: Transparent Substrate 102G: Green Color Layer 104: Black Matrix 1 04b · Horizontal Black Matrix Strips 108 and 11〇: Alignment Anomalous Areas 202 and 204: Strip White Area 102: Color Area 102R : red color layer 103B: blue color layer l〇4a: vertical black matrix strip 10 6 · electrode 200: angular residual inspection surface 12 1252936 208: angular afterimage 302: color area 302G: green color layer 3 04 : black matrix 3〇4b: horizontal black matrix strip 206: full black surface 300: transparent substrate 302R: red color layer 302B: blue color layer 3 04a: vertical black matrix strip 3 16 and 3 1 8 : corresponding to the prior art 3 1 5: Color filtering in previous techniques

The contour of the blue color patch in the anomaly zone of the art layer The area of the layer 302B X, Y·· height difference

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Claims (1)

1252936 A conductive layer is on the transparent substrate and the grids. 11. The method of claim 1, wherein the conductive layer comprises a layer of indium tin oxide. 12. The method of claim 9, wherein the transparent substrate is a glass substrate. The method of claim 9, wherein the transparent substrate is a quartz substrate. The method of claim 9, wherein the material of the black matrix is an opaque metal. The method of claim 9, wherein the material of the black moment drop is an opaque resin. The method of claim 9, wherein the material of the black matrix is chrome metal. 1 7 · A liquid crystal display structure comprising at least: a thin film transistor substrate; a color filter substrate 'where the color filter substrate comprises: a transparent substrate; 16 1252936 a black matrix 'in a plurality of vertical directions And a plurality of matrix strips horizontally intersecting each other to form a plurality of grids; and a plurality of color regions, which are repeatedly arranged in each of the grids in red, green, and blue, wherein each grid is formed The resin material of each color of the color region covers a larger area in a matrix strip adjacent to a vertical direction on one side, and the resin material covers a smaller area on a matrix strip adjacent to the vertical direction on the other side; a knives layer, the structure of the thin film transistor substrate and the color filter of the present invention, wherein the structure is as described in claim 17, wherein the transparent substrate is a quartz substrate 2 The structure of claim 17, wherein the material of the black matrix is an opaque metal. 21. The structure of claim 17 wherein the material of the black matrix is chrome metal. 17