DE102006020814B4 - Liquid crystal display panel and method for producing a color filter substrate - Google Patents

Abstract

A liquid crystal display panel comprising: a first substrate (210), a second substrate (220), a plurality of first pixel areas (P10), a plurality of second pixel areas (P20) and a plurality of third pixel areas (P30) on the second substrate ( 220) are set; a first color filter pattern disposed on a part of the second substrate (220) to which the first pixel areas (P10) are fixed; a second color filter pattern disposed on a part of the second substrate (220) to which the second pixel areas (P20) are fixed; a third color filter pattern disposed on a part of the second substrate (220) to which the third pixel areas (P30) are fixed; a first alignment tab structure disposed on the first color filter pattern, the first alignment tab structure consisting of a double layer filter pattern and a second top layer tab pattern; a second alignment tab structure disposed on the second color filter pattern, the second alignment tab structure consisting of a lower layer filter pattern and a first upper layer tab pattern; a third alignment tab structure disposed on the third color filter pattern, the third alignment tab structure consisting of a tab pattern, the first alignment tab structure, the second alignment tab structure, and the third alignment tab structure having different heights; and a liquid crystal layer disposed between the first substrate (210) and the second substrate (220).

Description

Background of the invention

Field of the invention

The present invention generally relates to a liquid crystal display panel and a method of manufacturing a color filter substrate. More particularly, the present invention relates to a liquid crystal display panel using a multi-domain vertical alignment technique (MVA) and a method of manufacturing a color filter substrate.

Description of the Prior Art

With great leaps in the art of manufacturing semiconductor devices and optoelectronic devices, high image quality, slim, low power and radiation free displays, such as Liquid Crystal Display (LCD) displays, have gradually become mainstream display products. Additionally, to achieve farsightedness, some displays, such as twisted-nematic (TN) LCDs corresponding to the far-sighted films, have been developed for in-plane switching (IPS) LCD, fringe field switching LCD and multi-range vertical alignment (MVA) LCD to fulfill these purposes.

The EP 1103840 B1 discloses a liquid crystal display (LCD), and more particularly to a vertically oriented (VA) LCD. The LCD is provided with a first substrate and a wide substrate machined for vertical alignment; and a liquid crystal having a negative dielectric constant anisotropy and sandwiched between the first and second substrates, wherein orientations of the liquid crystal to the first and second substrates are vertical when no voltage is applied, to the first and second substrates nearly are horizontal when a predetermined voltage is applied and are oblique to the first and second substrates when an intermediate voltage lower than the predetermined voltage is applied, the first substrate comprises a first domain control means for controlling azimuths of the oblique orientations of the liquid crystal ,

The US 2002/0044118 A1 , especially 59 discloses an LCD display device having a dielectric layer made of a resin and formed on a color filter substrate or the opposite substrate on which a dielectric structure is formed. This arrangement serves to improve the color unit of the LCD display device and reduce the gamma shift.

1 FIG. 12 is a cross-sectional view schematically illustrating a conventional MVA-LCD panel. FIG. In relation to 1 includes the conventional MVA-LCD panel 100 a color filter substrate 110 , a thin-film transistor (TFT) field substrate 120 and a liquid crystal layer 130 , In this case, the color filter substrate 110 a plurality of color filter patterns R10, G10, B10 and an alignment protrusion structure 112 on. The alignment protrusion structure 112 modifies the direction of the near electric field and causes liquid crystal molecules in the liquid crystal layer 130 arranged in several areas.

According to the prior art, the alignment protrusion structure 112 a stationary height, whether in a red, green or blue subpixel. In addition, the liquid crystal molecules are characterized by an effect of the alignment protrusion structure 112 tilt, different transmittances for light with different wavelengths and thus cause a brightness imbalance between the red, green and blue light.

It is referring to 2 taken which is a top view of a pixel of an LCD panel 100 , as in 1 is shown. The pixel of the LCD panel 100 can be divided into three sub-pixels according to the positions of the color filter patterns R10, G10 and B10. Thereby, by the conventional alignment protrusion structure 112 the liquid crystal molecules of the liquid crystal layer 130 aligned only along four different tilting directions and have the same tilt angle, due to the stationary height of the alignment projection structure 112 , Accordingly, a gamma shift problem arises when the LCD panel 100 from different angles. The above problems of gamma shift and brightness imbalance between different color lights result in abnormal display of the LCD panel 100 ,

Summary of the invention

Accordingly, the present invention is directed to an LCD panel which has an improved color unit and can reduce the gamma shift problem.

The present invention is also directed to a method of manufacturing a color filter substrate to improve the color uniformity of the LCD panel and to reduce the gamma shift problem.

The present invention provides a liquid crystal display panel comprising a first substrate, a second substrate, and a liquid crystal layer includes. A plurality of first pixel areas, a plurality of second pixel areas, and a plurality of third pixel areas are fixed to the second substrate. A first alignment protrusion structure is formed in the first pixel regions, a second alignment protrusion structure is disposed in the second pixel regions, and a third alignment protrusion structure is disposed in the third pixel regions. The first alignment protrusion structure, the second alignment protrusion structure, and the third alignment protrusion structure have different heights. The liquid crystal layer is disposed between the first substrate and the second substrate.

In an embodiment of the liquid crystal display panel, the height of the first alignment protrusion structure in each first pixel area is the same as the second alignment protrusion structure in every other pixel area, and the third alignment protrusion structure is variable every third pixel area.

In one embodiment of the liquid crystal display panel, the materials of the first alignment protrusion structure, the second alignment protrusion structure, and the third alignment protrusion structure are selected from the group consisting of a color filter material and a transparent photosensitive material.

In one embodiment of the liquid crystal display panel, a first color filter pattern is disposed in the first pixel regions, and the first alignment protrusion structure is disposed on the first color filter pattern, a second color filter pattern is disposed in the second pixel regions, and the second alignment protrusion structure is disposed on the second color filter pattern and a third color filter pattern is The third alignment projection structure is arranged on the third color filter pattern. For example, the first alignment protrusion structure may include a protrusion pattern, the second alignment protrusion structure may include a lower layer filter pattern and a first upper layer protrusion pattern, and the third alignment protrusion structure may include a double-layer filter pattern and a second upper layer protrusion pattern.

In one embodiment of the liquid crystal display panel, a first color filter pattern is disposed in the first pixel areas, a second color filter pattern is disposed in the second pixel areas, and a third color filter pattern is disposed in the third pixel areas. The first alignment protrusion structure includes a protrusion pattern disposed on the first color filter pattern, the second alignment protrusion structure including a lower layer filter pattern disposed below the second color filter pattern and a first upper layer protrusion pattern disposed on the second color filter pattern. Besides, the third alignment protrusion structure includes a double-layer filter pattern disposed below the third color filter pattern and a second upper layer protrusion pattern disposed on the third color filter pattern.

In an embodiment of the liquid crystal display panel, a plurality of spacers may further be disposed between the first substrate and the second substrate.

In one embodiment of the liquid crystal display panel, the first substrate is a thin film transistor array substrate.

The present invention provides another liquid crystal display panel comprising a first substrate, a second substrate, and a liquid crystal layer. The second substrate is disposed over the first substrate, wherein a plurality of pixel regions are fixed to the second substrate. An alignment protrusion structure is arranged in the pixel areas, and the height of the alignment protrusion structure in each first pixel area is variable. The liquid crystal layer is disposed between the first substrate and the second substrate.

In one embodiment of the liquid crystal display panel, the materials of the alignment protrusion structure are selected from the group consisting of a color filter material and a transparent photosensitive material.

In an embodiment of the liquid crystal display panel, a plurality of spacers may be further disposed between the first substrate and the second substrate.

In one embodiment of the liquid crystal display panel, the first substrate is a thin film transistor array substrate.

The present invention provides a method of manufacturing a color filter substrate. First, a substrate having a plurality of first pixel areas, a plurality of second pixel areas, and a plurality of third pixel areas is provided. Then, correspondingly, a first color filter pattern is formed in each first pixel area, a second color filter pattern in every other pixel area, and a third color filter pattern is formed every third pixel area. Next, a first alignment protrusion pattern is formed on the first color filter pattern in each first pixel area. A second alignment protrusion pattern becomes at the second Color filter pattern formed in every other pixel area. A third alignment protrusion pattern is formed on the third color filter pattern every third pixel area. The first alignment protrusion structure, the second alignment protrusion structure, and the third alignment protrusion structure have different heights.

In an embodiment of the manufacturing method, the materials of the first alignment protrusion structure, the second alignment protrusion structure, and the third alignment protrusion structure are selected from the group consisting of a color filter material and a transparent photosensitive material.

In an embodiment of the manufacturing method, the method of forming the first alignment protrusion structure, the second alignment protrusion structure, and the third alignment protrusion structure comprises forming a first filter pattern on the third color filter pattern in every third pixel area while forming the second color filter pattern in every other pixel area Forming a second filter pattern on the first filter pattern on the third color filter pattern, forming the first color filter pattern in each first pixel region, and forming a protrusion pattern on each first color filter pattern on the lower filter pattern and on the second filter pattern. In addition, the manufacturing method further forms a patterned light shield layer before forming the first color filter pattern, the second color filter pattern, and the third color filter pattern.

The present invention provides another method for producing a color filter substrate. First, a substrate having a plurality of first pixel areas, a plurality of second pixel areas, and a plurality of third pixel areas is provided. Then, a first color filter pattern is formed in each first pixel area, a second color filter pattern is formed in every other pixel area, and a third color filter pattern is formed in every third pixel area accordingly. Next, a protrusion pattern is formed on the first color filter pattern in each first pixel area. A lower layer filter pattern is formed under the second color filter pattern, and a first upper layer projection pattern is formed on the second color filter pattern in every other pixel area. And a double-layer filter pattern is formed under the third color filter pattern, and a second upper layer protrusion pattern is formed on the third color filter pattern every third pixel area.

In an embodiment of the manufacturing method, the materials for the protrusion pattern formed on the first color filter pattern include the first upper layer protrusion pattern formed on the second color filter pattern and the second upper layer protrusion pattern on the third color filter pattern comprise a transparent photosensitive material.

In one embodiment of the fabrication method, the lower layer filter pattern is formed in every other pixel area, and a first filter pattern is formed in every third pixel area, while the first color filter pattern is formed in each first pixel area.

In one embodiment of the manufacturing method, a second filter pattern is formed on the first filter pattern to define the double-layer filter pattern having the first filter pattern in every third pixel area while the second color filter pattern is formed in every other pixel area.

Accordingly, the LCD panel and the method of manufacturing the color filter substrate of the present invention provide a multi-height alignment protrusion structure for improving the color uniformity of the LCD panel and canceling out the gamma-shift problem.

Brief description of the drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

1 Fig. 16 is a cross-sectional view schematically showing a conventional MVA LCD panel.

2 is a plan view of a pixel of the LCD panel 100 , as in 1 shown.

3 FIG. 10 is a plan view schematically illustrating a pixel of an LCD panel according to an embodiment of the present invention. FIG.

4 is a schematic cross-sectional view, taken along the line AA 'in 3 ,

5A to 5F 15 are cross-sectional views showing a method of manufacturing a color filter substrate according to an embodiment of the present invention.

6 FIG. 10 is a cross-sectional view illustrating a color filter substrate according to another embodiment of the present invention. FIG.

7 FIG. 10 is a plan view illustrating a pixel of the LCD panel according to another embodiment of the present invention. FIG.

8A and 8B are cross-sectional views taken along the line II-II and the line III-III in 7 ,

Description of the embodiments

Reference will now be made in detail to the present preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings and the description to refer to the same or like parts.

3 Fig. 10 is a plan view schematically showing a pixel of an LCD panel according to an embodiment of the present invention. 4 is a schematic cross-sectional view, taken along the line II in FIG 3 , In relation to 3 and 4 includes the LCD panel 200 the present invention mainly a first substrate 210 , a second substrate 220 and a liquid crystal layer 230 , The liquid crystal layer 230 is between the first substrate 210 and the second substrate 220 arranged. The second substrate 220 has a plurality of first pixel areas P10, second pixel areas P20 and third pixel areas P30 set thereon, and 3 and 4 only show a first pixel area P10, a second pixel area P20 and a third pixel area P30. In addition, a first alignment protrusion structure 222r disposed in the first pixel regions P10, a second alignment protrusion structure 222g is disposed in the second pixel areas P20 and a third alignment protrusion structure 222b is arranged in the third pixel areas P30. The first alignment protrusion structure 222r , the second alignment protrusion structure 222g and the third alignment protrusion structure 222b have different heights.

In the present invention, the height of the first alignment protrusion structure is 222r smaller than that of the second alignment protrusion structure 222g and the height of the second alignment protrusion structure 222g smaller is the third alignment protrusion structure 222b , Because the different heights of the alignment protrusion structures 222r . 222g and 222b can cause the liquid crystal molecules in the liquid crystal layer in the pixel areas P10, P20 and P30 230 Arrange at different tilt angles, a white light has different wavelength brightness distributions after passing through the liquid crystal layer 230 in each of the pixel areas P10, P20 and P30. In general, the first substrate 210 or the second substrate 220 a red filter pattern R20, a green filter pattern G20 and a blue filter pattern B20 disposed thereon to perform a full-color display. Surely other color filter patterns can be used. Since the red, green and blue filter patterns R20, G20 and B20 have different transmittances, an appropriate wavelength distribution corresponding to the transmittances of the red, green and blue filter patterns R20, G20 and B20 is obtained to thereby form a red light green light and a blue light with uniform brightness after the white light has passed through the pixel areas P10, P20 and P30. Therefore, the color uniformity of the LCD panel can be improved.

In addition, the first substrate 210 or the second substrate 220 an Active Device field, such as a TFT field. In other words, the first substrate 210 or the second substrate 220 have a plurality of active devices such as a TFT formed thereon. The materials of the alignment protrusion structure 222r . 222g and 222b are selected from the group comprising a color filter material and a transparent photosensitive material.

It should be noted that the relationship of the heights of the alignment protrusion structures 222r . 222g and 222b in the above-mentioned embodiment is only an example and can be adjusted according to the characteristics of the red, green and blue filter patterns R20, G20 and B20. Moreover, the brightness distribution of red, green and blue light is not limited to these uniform shapes and can be achieved by modifying the heights of the alignment protrusion structures 222r . 222g and 222b be adapted according to the need of construction. In other words, the present invention can adjust the brightness distribution at different wavelengths after white light has passed through the liquid crystal layer by modifying the heights of the alignment protrusion structure.

The following is an example for illustrating a method for modifying the heights of the alignment protrusion structure in different pixel areas.

5A to 5F 12 are cross-sectional views illustrating a method of manufacturing a filter substrate according to an embodiment of the present invention present invention. First in terms of 5A is there a substrate 310 provided, wherein the substrate 310 may be a glass substrate. In addition, the substrate has 310 a plurality of first pixel areas P40, a plurality of second pixel areas P50, and a plurality of pixel areas P60 defined thereon; and 5A to 5F show only a first pixel area P40, a second pixel area P50 and a third pixel area P60. The pixel areas P40, P50 and P60 may be defined by a patterned light screen layer 320 be set as a black matrix on the transparent substrate 310 is formed.

Then in terms of 5B to 5E For example, the color filter patterns R30, G30 and B30 are correspondingly in the pixel areas P40, P50 and P60 on the substrate 310 educated. A projection pattern 342R is formed on the color filter pattern R30 in each pixel area P40. In each pixel area P50 is a lower layer filter pattern 344g formed under the color filter pattern G30 and a projection pattern 342g is formed on the color filter pattern G30. In each pixel region P60 is a double-layer filter pattern defined by a first filter pattern 346B and a second filter pattern 344B , formed under the color filter pattern B30 and a projection pattern 342B is formed on the color filter pattern B30.

In particular, in relation to 5B the color filter pattern R30 on the entirety of each pixel area P40 of the substrate 310 educated. And the lower layer filter pattern 344g is formed on a part of each pixel area P50 and the first filter pattern 346B is formed on a part of each pixel area P60. Then in relation to 5C the color filter pattern G30 on the entirety of each pixel area P50 of the substrate 310 educated. And the second filter pattern 344B is formed on a part of each pixel area P60. After that, in relation to 5D the color filter pattern B30 on the entirety of each pixel area P60 of the substrate 310 educated. By the above-mentioned manner, stacked structures having different heights can be formed in each pixel area P40, P50 and P60.

Then in terms of 5E protrusion pattern 342R . 342g and 342B selected formed on the color filter patterns R30, G30 and B30. The projection pattern 342g is at the lower layer filter pattern 344 formed and the projection pattern 342B is at the second filter pattern 344B educated. In the embodiment, the projection pattern sets 342R an alignment protrusion structure 340R stuck, the projection pattern 342g and the lower layer filter pattern 344g lay an alignment protrusion structure 340G firm and the projection pattern 342B , the first filter pattern 346B and the second filter pattern 344B lay an alignment tab 340B firmly. The heights of the alignment tab structures 340R . 340G and 340B are formed differently.

So far, the production of color filter substrates 300 almost completed. An LCD panel with better color uniformity than the one in 4 Therefore, after assembly of the color filter substrate 300 with another substrate and forming a liquid crystal layer between the color filter substrate 300 and the other substrate.

Additionally, in relation to 5F there continue to be several spacers 350 on the color filter substrate 300 are formed to form a cell gap between the color filter substrate 300 and to maintain an opposing substrate. In addition, the spacers 350 preferably over the patterned light screen layer 320 formed to maintain the aperture ratio.

Another method for modifying the heights of the alignment protrusion patterns in different sub-pixel areas will be exemplified in the following section. 6 Fig. 10 is a cross-sectional view showing a color filter substrate according to another embodiment of the present invention. First, a color filter pattern B40 is formed on the entirety of each pixel region P90 of a transparent substrate 410 educated. Then, a color filter pattern G40 is formed on the entirety of each pixel area P80 of a transparent substrate 410 formed and a first filter pattern 446B is formed on a part of each pixel area P90. Next, a color filter pattern R40 is formed on the entirety of each pixel area P70 and a lower layer filter pattern 444g and a second filter pattern 444B are formed at a part of each pixel area P80 and P90, respectively. After that, projection patterns become 442R . 442g and 442B selected on the color filter patterns R40, G40 and B40. The projection pattern 442R sets an alignment protrusion structure 440R stuck, the projection pattern 442g and the lower layer filter pattern 444g lay an alignment protrusion structure 440G firm and the projection pattern 442B , the first filter pattern 446B and the second filter pattern 444B lay an alignment protrusion structure 440B firmly. Through a manufacturing process that is different from that of 5A to 5E is formed, further alignment projection structures 440R . 440G and 440B obtained with different heights.

It should be noted that although the above-mentioned manufacturing methods form alignment protrusion patterns having different heights in the pixel areas by stacking the color filter patterns, this is by no means a limitation of the scope of the present invention. Moreover, in the LCD panel of the present invention, the alignment protrusion structure is not limited to being formed on a same substrate with the color filter patterns. In addition, the alignment protrusion structure may be further formed on both substrates of the LCD panel, and the color uniformity of the LCD panel may be improved by modifying the heights of the alignment protrusion structure in different pixel areas on at least one of the substrates.

An LCD panel according to another embodiment of the present invention is shown in the following section.

7 FIG. 10 is a plan view illustrating a pixel of the LCD panel according to another embodiment of the present invention. FIG. 8A and 8B are cross-sectional views along the line II-II and the line III-III in 7 , In relation to 7 . 8A and 8B include differences between the LCD panel 500 in the present embodiment and the LCD panel 200 according to 3 : the registration tab structure 722 which has different heights in each pixel area P110, P120 and P130. In relation to 8A and 8B because the alignment protrusion structure 722 in each pixel region P110, P120 and P130 have different heights at different positions, the liquid crystal molecules in the liquid crystal layer 730 different tilt angles at the positions in 8A and 8B are shown. In other words, the liquid crystal molecules can be formed in multiple regions by the height differences of the alignment protrusion structure 722 in each pixel area P110, P120 and P130. Therefore, the gamma-shift problem can be reduced when looking at the LCD panel 500 viewed from different perspectives.

The alignment protrusion structure 722 can by adjusting the manufacturing process, which in 5A to 5F and the alignment protrusion structure 722 in different positions in each pixel area P110, P120 or P130 can be formed by stacking different amounts of the protrusion pattern and the filter pattern.

The LCD panel of the present invention includes the following features. One is that the alignment protrusion structure has different heights in different sub-pixel areas of each pixel area. The other is that the alignment protrusion structure has different heights at different positions in the same sub-pixel areas. The two features can be used independently or together for an LCD panel. A feature of the method of manufacturing the color filter substrate of the present invention is to modify the height of the alignment protrusion structure by changing the stacked number of the color filter patterns.

In summary, according to the LCD panel and the method of manufacturing the color filter substrate of the present invention, the alignment protrusion structure may have different heights in different pixel areas of each pixel area, and thus the liquid crystal molecules in different pixel areas have different tilt angles to improve the color uniformity of the LCD panel.

Moreover, since the alignment protrusion structure has different heights in different positions in a pixel area, the liquid crystal molecules in each pixel area have different tilt angles to reduce the gamma shift problem.

It will be apparent to those skilled in the art that various modifications and variations can be made in the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they come within the scope of the following claims and their equivalents.

Claims (9)

A liquid crystal display panel comprising: a first substrate ( 210 ), a second substrate ( 220 ), wherein a plurality of first pixel areas (P10), a plurality of second pixel areas (P20) and a plurality of third pixel areas (P30) on the second substrate ( 220 ) are defined; a first color filter pattern formed on a portion of the second substrate ( 220 ) at which the first pixel areas (P10) are fixed; a second color filter pattern formed on a portion of the second substrate ( 220 ) at which the second pixel areas (P20) are fixed; a third color filter pattern formed on a portion of the second substrate ( 220 ) at which the third pixel areas (P30) are set; a first alignment protrusion structure disposed on the first color filter pattern, the first alignment protrusion structure consisting of a double-layer filter pattern and a second upper layer protrusion pattern; a second alignment protrusion structure disposed on the second color filter pattern, wherein the second alignment protrusion structure is composed of a lower layer filter pattern and a first upper layer protrusion pattern; a third alignment protrusion structure disposed on the third color filter pattern, the third alignment protrusion structure consisting of a protrusion pattern, the first alignment protrusion structure, the second alignment protrusion structure, and the third alignment protrusion structure having different heights; and a liquid crystal layer sandwiched between the first substrate ( 210 ) and the second substrate ( 220 ) is arranged. The liquid crystal display panel according to claim 1, wherein the first, second and third alignment protrusion structures each have a first area and a second area and the height of the first area is different from that of the second area. A liquid crystal display panel according to claim 1 or 2, wherein the materials for the first alignment protrusion structure, the second alignment protrusion structure and the third alignment protrusion structure are a color filter material or a transparent photosensitive material. A liquid crystal display panel according to any one of the preceding claims, further comprising: a plurality of spacers interposed between said first substrate (12); 210 ) and the second substrate ( 220 ) are arranged. A liquid crystal display panel according to any one of the preceding claims, wherein the first substrate ( 210 ) is a thin film transistor array substrate. A method of making a color filter substrate comprising: Providing a substrate having a plurality of first pixel areas (P10), a plurality of second pixel areas (P20) and a plurality of third pixel areas (P30), Forming a first color filter pattern in each first pixel area (P10); Forming a second color filter pattern in every other pixel area (P20) and forming a first filter pattern on the first color filter pattern at the same time; Forming a third color filter pattern every third pixel area (P30), forming a lower layer filter pattern on the second color filter pattern, and forming a second filter pattern on the first filter pattern at the same time; Forming a protrusion pattern on every third color filter pattern, on the lower filter pattern and on the second filter pattern, wherein the first filter pattern, the second filter pattern, and the protrusion pattern on the second filter pattern form a first alignment protrusion structure, the lower layer filter pattern and the protrusion pattern on the lower layer filter pattern forming a second alignment protrusion structure, and wherein the protrusion pattern on the third color filter pattern forms a third alignment protrusion structure. The method for producing a color filter substrate according to claim 6, wherein the materials for the first alignment protrusion structure, the second alignment protrusion structure and the third alignment protrusion structure are a color filter material or a transparent photosensitive material. A process for producing a color filter substrate according to claim 6 or 7, further comprising: Forming a patterned light shield layer before forming the first color filter pattern, the second color filter pattern and the third color filter pattern. A liquid crystal display panel comprising: a first substrate ( 210 ), a second substrate ( 220 ), wherein a plurality of first pixel areas (P10), a plurality of second pixel areas (P20) and a plurality of third pixel areas (P30) on the second substrate ( 220 ) are defined; a first color filter pattern formed on a portion of the second substrate ( 220 ) at which the first pixel areas (P10) are fixed; a second color filter pattern formed on a portion of the second substrate ( 220 ) at which the second pixel areas (P20) are fixed; a third color filter pattern formed on a portion of the second substrate ( 220 ) at which the third pixel areas (P30) are set; a first alignment protrusion structure disposed in the first pixel regions (P10), the first alignment protrusion structure consisting of a protrusion pattern on the first color filter pattern; a second alignment protrusion structure disposed in the second pixel regions (P20), the second alignment protrusion structure consisting of a lower layer filter pattern disposed below the second color filter pattern and a first upper layer protrusion pattern disposed on the second color filter pattern; a third alignment protrusion structure disposed in the third pixel regions (P30), the third alignment protrusion structure consisting of a double-layer filter pattern disposed below the third color filter pattern and a second upper layer protrusion pattern disposed on the third color filter pattern, wherein the first alignment protrusion structure , the second alignment protrusion structure and the third alignment protrusion structure have different heights; and a liquid crystal layer sandwiched between the first substrate ( 210 ) and the second substrate ( 220 ) is arranged.

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