Color filter of liquid crystal display panel and method of fabricating the same

A color filter of liquid crystal display (LCD) panel is described. A surface property of a black matrix is changed by coating with an ink-repellent layer formed of cheap materials, to provide better separation between portions of a colored layer, thus reducing the cost of the ink-repellent layer and avoid overflowing while color ink drops are attaching onto a transparent substrate. In addition, a method of fabricating a color filter of LCD panel is described. The ink-repellent layer is transferred onto the black matrix, and then the colored layer is formed thereon. The ink-repellent layer effectively separates the colored layer. This method of the invention greatly diminishes the usage of the ink-repellent layer, steps of exposure and development, and the cost and time of fabricating the color filter.

FIELD OF THE INVENTION

The present invention relates to a color filter of a liquid crystal display (LCD) panel, and more particularly, to an ink-repellent layer on a black matrix of the color filter.

BACKGROUND OF THE INVENTION

A liquid crystal display (LCD) panel is mainly colorized by a color filter. The liquid crystal (LC) molecules, which are arranged in rows or twists by changing the voltage of the driver integrated circuit (IC), can form gates to determine whether a backlight can pass through the LC molecules or not, so as to generate pictures on the LCD panel. However, the LCD panel shows only two colors in black or white due to the difference in levels of the light penetration. If the LCD panel is to show colors, it needs a combination of three light sources of red (R), green (G), and blue (B). Hence, a color filter with three colored layers of red, green, and blue is a key component of the LCD panel.

Reference is made toFIG. 1, which illustrates a cross-sectional diagram showing a color filter in the prior art. The color filter100comprises a transparent substrate100made of, for example, glass. A black matrix103is disposed on the transparent substrate101. The black matrix103is used as a light-shielding, anti-reflection layer to avoid color mixing and color contrast enhancement. A plurality of apertures105is located in the black matrix103to expose a part of the transparent substrate101. The colored layers107of transparent red, green, and blue are formed in the apertures105, respectively. The colored layers107are covered with a protective layer109and a transparent ITO (Indium-Tin Oxide) conductive film111in turn.

The color filter usually has properties of high color purity, high transparency, high contrast, low reflectivity, and must be stably resistant to heat, light and chemicals. There are currently are four common methods of coating the colored layers on the color filter, a dyeing method, a pigment dispersion method, an electro-deposition method, and a printing method. However, the above methods require complicated processes and expensive equipment, and have limitations regarding the size of the color filter. In addition, the increase in processes and the size causes the yield to be decreased, and results in wasting a great quantity of material and increasing the cost of the production. To solve the problems of fabricating the colored layers of the foregoing color filter, the ink-jet technique has been recently developed to reduce the consumption of negative photoresists as well as steps of exposure and development.

The ink-jet technique is excellent because it uses small-sized equipment, less process time and less ink. Generally, the ink-jet technique is divided into Piezoelectric ink-jet and thermal bubble ink-jet methods, and it may replace the conventional method of fabricating the color filter in the future. However, the ink-jet technique is applied to produce the colored layer of the color, and the colored ink drops with enhanced diffusibility when injected into the apertures of the black matrix may overflow even to result in color mixing and color contrast deterioration.

Reference is made toFIGS. 2(a) to2(c), which illustrate cross-sectional diagrams of the process of the color filter in the prior art. The process may be a method of manufacturing the color filter disclosed in the U.S. Pat. No. 6,399,257. A photosensitive resin141is formed on the transparent substrate131and the apertures135of the black matrix133, as shown inFIG. 2(a). Next, a step of backside exposure is performed, in which an exposed region of the photosensitive resin141becomes an ink-absorbent layer145and an unexposed region becomes an ink-repellent layer147, as shown in the structure ofFIG. 2(b). Subsequently, colored ink drops are injected into the apertures135of the black matrix133by the ink-jet technique, and then a colored layer149is formed, as shown in the structure ofFIG. 2(c). The aforementioned ink-repellent layer147can separate the portions of colored layer149from each other, thus can reduce the problem of the colored ink drops overflowing.

Reference is made toFIGS. 3(a) to3(c), which illustrate cross-sectional diagrams of the process of another color filter in the prior art. The process may be a color filter and method of manufacturing the same disclosed in the E. P. Pat. No. 1,061,383. An organic photosensitive film155is applied on the transparent substrate151and the black matrix153, as shown in the structure ofFIG. 3(a). Next, steps of exposure and development are performed, and a plurality of apertures157is formed in the photosensitive film155and the black matrix153to expose a part of the transparent substrate151, as shown in the structure ofFIG. 3(b). The organic photosensitive film155is used as an ink-repellent layer. Subsequently, colored ink drops are injected into the apertures157of the black matrix153by the ink-jet technique, and then a colored layer159is formed as shown in the structure ofFIG. 2(c). The aforementioned organic photosensitive film155is used as the ink-repellent layer to separate the portions of colored layer159from each other, thus can reduce the problem of the colored ink drops overflowing.

In brief, the prior solution directed to the problem of the colored ink drops overflowing mainly focuses on changing the surface property of the black matrix. In other words, the problem of the colored ink drops overflowing is improved by adding the ink-repellent layer on the black matrix. However, the cost of fabricating the ink-repellent layer is higher. It is necessary to coat more the ink-repellent layer uniformly over the transparent substrate and the black matrix. Furthermore, the ink-repellent layer must be formed from steps of exposure and development.

SUMMARY OF THE INVENTION

It is an aspect of the present invention to provide a color filter of a LCD panel. The color filter utilizes an ink-repellent layer, which is formed with cheap materials, to change a surface property of a black matrix for better separating portions of a colored layer from each other, so as to decrease the cost of the ink-repellent layer and prevent the colored ink drops from overflowing.

It is another aspect of the present invention to provide a method of producing a color filter of a LCD panel. An ink-repellent layer is transferred onto the black matrix, and then the colored layer is formed thereon. Therefore, the ink-repellent layer can effectively isolate the colored layer. The method of the present invention can greatly reduce the cost of the ink-repellent layer, steps of exposure and development, and the cost and time of fabricating the color filter.

According to the aforementioned aspect of the present invention, a color filter of a LCD panel is provided, which comprises a transparent substrate and a black matrix having a plurality apertures to expose a part of the transparent. An ink-repellent layer is disposed on the black matrix, in which a material of the ink-repellent layer comprises an ester compound and a silicon-containing mixture. A colored layer is formed in the apertures.

In a preferred embodiment of the present invention, a formula (I) of the ester compound is shown as follows:

where the R1is selected from the group consisting of hydrogen and C1-C3 alkyl radical, and the R2is selected from the group consisting of substituted and un-substituted C5-C18 linear and branched alkyl radical, substituted and un-substituted C5-C18 cyclic alkyl radical, and substituted and un-substituted C5-C18 aromatic radical.

In a preferred embodiment of the present invention, a material of the aforementioned silicon-containing mixture is silicon oxide (SiOx).

According to the aforementioned aspect of the present invention, it is further provided a method of fabricating color filter of LCD panel, which comprises steps as follows. A transparent substrate is provided. Next, a black matrix is formed on the transparent substrate, with a plurality of apertures in the black matrix to expose a part of the transparent substrate. An ink-repellent layer is then formed on the black matrix, the black matrix material comprising an ester compound and a silicon-containing mixture. A colored layer is then formed in the apertures by an ink-jet method.

In a preferred embodiment of the present invention, the step of forming the ink-repellent layer further comprises steps as follows. The ink-repellent layer is coated onto a transferred film, then the transferred film is formed with the ink-repellent layer. The ink-repellent layer is then transferred from the transferred film onto the black matrix, for forming the ink-repellent layer on the black matrix.

The color filter utilizes an ink-repellent layer, formed of cheap materials, to change a surface property of a black matrix for better separating portions of a colored layer from each other. Hence, it prevents the colored ink drops from overflowing while the color ink drops are attaching onto the transparent substrate, and greatly reduces the usage of the ink-repellent layer, steps of exposure and development, and the cost and time of fabricating the color filter.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The color filter of the LCD panel of the present invention utilizes an ink-repellent layer, formed of cheap materials, to change a surface property of a black matrix, for better separating portions of a colored layer from each other and preventing the colored ink drops from overflowing while color ink drops are attaching onto the transparent substrate. In order to describe the color filter of the LCD panel of the present invention more explicitly and completely, the following description is stated with reference toFIG. 4.

Reference is made toFIG. 4, which is a cross-sectional diagram of the color filter of the LCD panel in accordance with a preferred embodiment of the present invention. The color filter200of the LCD panel comprises a transparent substrate201made from, for example, glass. A black matrix203, which is disposed on the transparent substrate201, is made of a material such as resin or metal and used as a light-shielding, anti-reflection layer for avoiding color mixing and enhancing color contrast. A plurality of apertures is located in the black matrix203to expose a part of the transparent substrate201, wherein the apertures205is in an array of, for example, mosaic, triangular, or striped patterns. An ink-repellent layer207is disposed on the black matrix203, wherein the material of the ink-repellent layer207comprises an ester compound and a silicon-containing mixture. In addition, a material of the aforementioned silicon-containing mixture is silicon oxide (SiOx).

According to a preferred embodiment of the present invention, a formula (I) of the ester compound is shown as follows:

where the R1is selected from the group consisting of hydrogen and C1-C3 alkyl radical, and the R2is selected from the group consisting of substituted and un-substituted C5-C18 linear and branched alkyl radical, substituted and un-substituted C5-C18 cyclic alkyl radical, and substituted and un-substituted C5-C18 aromatic radical.

A colored layer209is disposed in the apertures205. The colored layer209may be a red, a green, a blue colored layer or any combination thereof. The color filter200of the present invention, which changes a surface property of the black matrix203by applying the ink-repellent layer thereon, provides better separation between the portions of the colored layer209. However, a person skilled in the art can understand that the present invention can be embodied by covering the colored layer209with a protective film (not shown) and a transparent ITO in turn, if necessary, and thus further details do not need to be given herein.

As mentioned above, a method of fabricating a color filter of the LCD panel is further provided in the present invention. In order to describe the method of fabricating the color filter of the LCD panel of the present invention more explicitly and completely, the following description is stated with reference toFIGS. 5(a) to6(b).

Reference is made toFIGS. 5(a) to5(d), which are cross-sectional diagrams in the process of color filter of the LCD panel in accordance with a preferred embodiment of the present invention. Reference is made toFIG. 5(a); a transparent substrate301is provided, and a material of the transparent substrate301is, for example, glass. Next, a black matrix303is formed on the transparent substrate301. A material of the black matrix303is, for example, resin or metal. A plurality of apertures305is located in the black matrix303to expose a part of the transparent substrate301for forming the structure as shown inFIG. 5(b). Subsequently, an ink-repellent layer307is formed on the black matrix303. A material of the ink-repellent layer307comprises an ester compound and a silicon-containing mixture for forming the structure as shown inFIG. 5(c). The ester compound and the silicon-containing mixture, as such, are discussed in details as mentioned in the above, and thus they do not need to be described again. Later, an ink-jet method, such as Piezoelectric ink-jet method or the thermal bubble ink-jet method, is employed to inject color resist ink drops into the aforesaid apertures305for forming a colored layer309therein. The colored layer309may be a red, a green, a blue colored layer or any combination thereof for forming the structure as shown inFIG. 5(d).

According to a preferred embodiment of the present invention, the ink-repellent layer307can be directly formed on the black matrix303. According to another preferred embodiment of the present invention, the ink-repellent layer307can be also indirectly formed on the black matrix303. Reference is made toFIGS. 6(a) to6(b), which are cross-sectional diagrams of the process of color filter of the LCD panel in accordance with another preferred embodiment of the present invention. When the ink-repellent layer307is indirectly formed on the black matrix303, a coating step is first performed, where the ink-repellent layer307is coated onto a transferred film311, and then the transferred film311is formed with the ink-repellent layer307. Subsequently, a transferring step is performed, where the ink-repellent layer307is transferred from the transferred film311onto the black matrix303, thus forming the ink-repellent layer307on the black matrix303so as to form the structure shown inFIG. 6(b).

It is worthy to mention that the color filter of the LCD panel of the present invention, the surface property of the black matrix of which is changed by coating with the ink-repellent layer, provides better separation of the colored layer portions from each other, so as to avoid overflowing while color ink drops are attaching onto the transparent substrate. Moreover, the ink-repellent layer is cheap and less of the same is used, and this method of the present invention greatly diminishes steps of exposure and development. The cost and time of fabricating the color filter can thus be drastically reduced.

Therefore, according to the aforementioned preferred embodiments, one advantage of the color filter of the LCD panel of the present invention is that the color filter utilizes an ink-repellent layer, which is formed with cheap materials, to change a surface property of a black matrix for better separating portions of a colored layer from each other, so as to prevent the colored ink drops from overflowing while color ink drops are attaching onto the transparent substrate.

According to the aforementioned preferred embodiments, another advantage of the method of fabricating the color filter of the LCD panel of the present invention is that, the ink-repellent layer is transferred onto the black matrix, and then the colored layer is formed thereon. Therefore, the ink-repellent layer can effectively isolate the colored layer and prevent the colored ink drops from overflowing during color ink drops attaching onto the transparent substrate in the prior art. Furthermore, the ink-repellent layer is cheap and less in usage, and steps of exposure and development can be reduced, so as to greatly diminish the cost and time of fabricating the color filter.