KR100582009B1 - Semi-transmission type color liquid crystal device - Google Patents

Abstract

In the semi-transmissive color liquid crystal display device of the present invention, when the light reflection film, the coloring layer 3, the overcoat layer, the transparent electrode, and the alignment film are sequentially stacked on a glass substrate, the light reflection film is lighted for each color layer 3 with respect to the light reflection film. The light transmitting portions 7 having different passage areas are formed. Moreover, the notch part 8 is formed in the reflecting area of each colored layer 3. This configuration makes it possible to independently set the white balance which consists of RGB of a transmission mode and a reflection mode. By performing such white balance adjustment, it is possible to provide a high quality and high performance semi-transmissive color liquid crystal display device.

Description

Transflective color liquid crystal display device {SEMI-TRANSMISSION TYPE COLOR LIQUID CRYSTAL DEVICE}

1 is a schematic cross-sectional view of a transflective color liquid crystal display device A1 according to a first embodiment of the present invention.

2 is a plan view showing the light transmitting portion 7.

FIG. 3 is a cross sectional view taken along a cut line X-X shown in FIG.

FIG. 4 is a cross-sectional view taken along the cut line Y-Y shown in FIG.

5 is a plan view showing a light transmitting portion 7 according to the conventional transflective color liquid crystal display device.

FIG. 6 is a cross-sectional view taken along the cut line Z-Z shown in FIG. 5.

7 is a chromaticity diagram in the transmissive mode of both the transflective color liquid crystal display device A1 and the transflective color liquid crystal display device B1 of the comparative example.

Fig. 8 is a chromaticity diagram in the reflection mode of both the transflective color liquid crystal display device A1 and the transflective color liquid crystal display device B1 of the comparative example.

9A is an explanatory diagram showing a measuring method in the reflection mode, and (b) is an explanatory diagram showing the measuring method in the transmission mode.

10 is a diagram showing a definition of the color gamut area.

FIG. 11 is a cross-sectional schematic diagram showing the relationship between both the light reflection film 2 and the transparent resin layer P of the transflective color liquid crystal display device A2 according to the second embodiment of the present invention.

Fig. 12 is a schematic plan view showing the relationship between both the light reflection film 2 and the transparent resin layer P of the transflective color liquid crystal display device A2 according to the second embodiment of the present invention.

Fig. 13 is a chromaticity diagram in the transmissive mode of both the transflective color liquid crystal display device A2 and the transflective color liquid crystal display device B2 of the comparative example.

Fig. 14 is a chromaticity diagram in the reflection mode of both the transflective color liquid crystal display device A2 and the transflective color liquid crystal display device B2 of the comparative example.

Fig. 15 is a cross-sectional schematic diagram showing the relationship between both the light transmitting portion 7 and the transparent resin layer P of the transflective color liquid crystal display device A3 according to the third embodiment of the present invention.

Fig. 16 is a schematic plan view showing the relationship between both the light transmitting portion 7 and the transparent resin layer P of the transflective color liquid crystal display device A3 according to the third embodiment of the present invention.

Fig. 17 is a chromaticity diagram in the transmissive mode of both the transflective color liquid crystal display device A3 and the transflective color liquid crystal display device B3 of the comparative example.

Fig. 18 is a chromaticity diagram in the reflection mode of both the transflective color liquid crystal display device A3 and the transflective color liquid crystal display device B3 of the comparative example.

Fig. 19 is a schematic cross-sectional view of a semi-transmissive color liquid crystal display device A4 according to the fourth embodiment of the present invention.

FIG. 20 is a schematic plan view showing the relationship between both the colored layer 3 and the notch portion 8 of the transflective color liquid crystal display device A4.

Fig. 21 is a schematic plan view showing the relationship between both the colored layer 3 and the notch 8 in the conventional transflective color liquid crystal display device.

FIG. 22 is a cross-sectional view taken along cut line a-a shown in FIG.

FIG. 23 is a cross sectional view taken along a cut line b-b shown in FIG.

24 is a chromaticity diagram in the transmissive mode of both the transflective color liquid crystal display device A4 and the transflective color liquid crystal display device B4 of the comparative example.

Fig. 25 is a chromaticity diagram in the reflection mode of both the transflective color liquid crystal display device A4 and the transflective color liquid crystal display device B4 of the comparative example.

Fig. 26 is a schematic cross-sectional view of a semi-transmissive color liquid crystal display device A5 according to the fifth embodiment of the present invention.

Fig. 27 is a schematic plan view showing the relationship between both the light transmitting portion H and the notch portion A of the transflective color liquid crystal display device A5.

FIG. 28 is a cross sectional view taken along a cut line X-X shown in FIG.

FIG. 29 is a cross-sectional view taken along cut line Y-Y shown in FIG.

Fig. 30 is a schematic plan view showing the relationship between both the light transmitting portion H and the notch portion A according to the conventional transflective color liquid crystal display device.

Fig. 31 is a chromaticity diagram in the transmissive mode of both the transflective color liquid crystal display device A5 and the transflective color liquid crystal display device B5 of the comparative example.

32 is a chromaticity diagram in the reflection mode of both the transflective color liquid crystal display device A5 and the transflective color liquid crystal display device B5 of the comparative example.

The present invention relates to a transflective color liquid crystal display device having both a reflection mode and a transmissive mode, and more particularly, to a transflective color liquid crystal display device capable of adjusting white balance.

Background Art In recent years, liquid crystal displays have been used in small and medium portable information terminals, notebook computers, and large, high-precision monitors. In particular, in devices used both outdoors and indoors, such as a mobile information terminal, actively use external light as a lighting means of a display device in an environment where external light is strong enough (reflective mode), and use a backlight in an environment with low external light ( Transflective mode), a transflective liquid crystal display device is used in the mainstream.

According to the transflective color liquid crystal display device, it is used in the reflection mode by external light such as sunlight, fluorescent lamps, or the transmissive mode by using the backlight, but it is possible to have both functions in one liquid crystal display device. In order to achieve this, a half mirror semipermeable membrane is used (see Patent Document 1). It is also proposed to use a transflective film for the same purpose in an active matrix transflective color liquid crystal display device (see Patent Document 2).

When such a semi-permeable membrane is used, there is a problem that it is difficult to improve both the functions of both the reflectance and the transmittance, and in order to solve this problem, a semi-permeable semi-permeable membrane is used in place of the semi-transmissive membrane. A transmissive color liquid crystal display device has also been proposed (see Patent Document 3).

In the transflective liquid crystal display device, light passes through the color filter once in the transmissive mode, whereas light passes through the color filter twice in the reflective mode, so that the color purity of the transmissive mode is lower than that in the reflective mode. Therefore, the semi-transparent color improves the color purity of the transmissive mode by spatially dividing the region used in the transmissive mode and the reflective mode, and making the color filter of the transmissive mode region thicker than the color filter of the transmissive mode. Liquid crystal display devices are also proposed (see Patent Documents 4 and 5).

In addition, a semi-transmissive color liquid crystal display device has been proposed in which a pinhole is formed in the color filter in the reflection mode region so that the color purity of the reflection mode is equal to the color purity of the transmission mode.

[Patent Document 1]

Japanese Patent Laid-Open No. 8-292413

[Patent Document 2]

Japanese Patent Laid-Open No. 7-318929

[Patent Document 3]

Japanese Patent No. 2878231

[Patent Document 4]

Japanese Patent Laid-Open No. 2000-298271

[Patent Document 5]

Japanese Patent Laid-Open No. 2001-166289

However, as described above, in the transflective color liquid crystal display device, an LED lamp is used as the light source in the transmissive mode, while in the reflective mode, the fluorescent light is used as the light source when used indoors and the sun as the light source when used outdoors. Light is used, and thus, the light source is different in the transmission mode and the reflection mode.

Therefore, it is necessary to perform color design and white balance design independently for both the transmission mode and the reflection mode.

In addition, the color filter is formed by R (red) G (green) B (blue). However, even with the technique proposed by Patent Documents 4 and 5, a white balance composed of RGB in transmission mode and reflection mode is used. It could not be set independently.

Moreover, even in the structure in which the pinhole was formed in the color filter in the reflection mode region, the white balance composed of the transmission mode and the reflection mode RGB could not be set independently.

Accordingly, it is an object of the present invention to provide a semi-transmissive color liquid crystal display device capable of independently setting white balance composed of RGB in transmissive mode and reflective mode.

It is another object of the present invention to provide a semi-transmissive color liquid crystal display device in which the color purity of the reflection mode is approximately equal to the color purity of the transmission mode, and the white balance composed of the RGB of the transmission mode and the reflection mode can be set independently. Is in.

In the semi-transmissive color liquid crystal display device of the present invention, a light reflection film is formed on a main surface of the substrate, and a colored layer having different colors is formed, and one of the transparent conductive materials is formed on these colored layers. One member formed by sequentially forming the transparent electrode group and the alignment film, the other member formed by forming the other transparent electrode group and the alignment layer formed of the transparent conductive material on the transparent substrate sequentially, and interposed between the one member and the other member A liquid crystal layer is provided, and the light reflection film is provided with light transmitting portions having different light passing areas corresponding to respective colored layers.

According to the above constitution, the light transmissive portion is formed for each pixel in the light reflection film, and the transmissive mode is set in the light transmissive portion, and the reflection mode is set in the regions other than the light transmissive portion, thereby making the transflective color liquid crystal display device. .

In applying to both the transmission mode and the reflection mode, a light transmission portion having a different light transmission area is formed corresponding to each colored layer, thereby independently setting the white balance composed of the RGB of the transmission mode and the reflection mode. To help. By performing such white balance adjustment, a high quality and high performance transflective color liquid crystal display device is obtained.

In addition, in the transflective color liquid crystal display device of the present invention, a light reflection film and a transparent resin layer are sequentially formed on one surface of the substrate, and a colored layer having a different color is formed, and the transparent conductive material is formed on these colored layers. One member formed by forming one transparent electrode group and an alignment film in sequence, the other member formed by forming another transparent electrode group and an alignment layer made of a transparent conductive material on a transparent substrate, and between the one member and the other member A liquid crystal layer interposed therebetween, wherein the light reflecting layer is formed by forming a light transmitting portion corresponding to each colored layer, and the deposition area of the transparent resin layer with respect to the light reflecting layer is different in response to the respective colored layers. It is characterized by one.

According to the semi-transmissive color liquid crystal display device of the present invention, as in the above-described configuration, a light transmitting portion is formed for each pixel of the light reflecting film, and the light transmitting portion is set to the transmissive mode, and the light transmissive portion is set to the reflective mode in a region other than the light transmissive portion. As a result, a transflective color liquid crystal display device is provided.

In addition, according to the semi-transmissive color liquid crystal display device of the present invention, the following effects can be obtained by varying the deposition area of the transparent resin layer with respect to the light reflection film corresponding to each colored layer.

When the area of the light transmitting portion and each element (color density and thickness) of the color filter (coloring layer) are set on the basis of the transmittance and color reproducibility required for the transmission mode, the conventional transflective color liquid crystal display device is used. According to the color filter, a colored layer having the same color and thickness is formed in the reflection area, whereby the display is dark in the reflection mode.

On the other hand, by varying the deposition area of the transparent resin layer with respect to the light reflection film in the reflective area of each colored layer as in the present invention, the amount used as the color filter (colored layer) of the reflective area can be added or subtracted. Can be. That is, the colored layer of the reflecting region can have the same effect as having a thinner thickness than the colored layer of the transmissive region. Therefore, the fall of the brightness in the reflection mode can be reduced or there can be no fall.

According to the present invention, the white balance of the transparent mode and the reflective mode RGB can be set independently by adjusting the deposition area of the transparent resin layer with respect to the light reflection film in the reflection area of each colored layer. By performing such white balance adjustment, a high quality and high performance transflective color liquid crystal display device is obtained.

In the semi-transmissive color liquid crystal display device of the present invention, a light reflection film and a transparent resin layer are sequentially formed on one surface of the substrate, and a colored layer having different colors is formed, and one of the transparent conductive materials is formed on these colored layers. One member formed by sequentially forming the transparent electrode group and the alignment film, the other member formed by forming the other transparent electrode group made of the transparent conductive material and the alignment layer sequentially on the transparent substrate, and interposed between the one member and the other member A liquid crystal layer is provided, and the light reflecting film is formed by providing a light transmitting portion corresponding to each colored layer. The light transmitting portion passes a backlight in a transmissive mode, and in a reflective mode in a reflection region other than the light transmissive portion. The outer surface of the transparent resin layer has a structure that reflects external light, and the deposition area of the transparent resin layer with respect to the light transmitting portion is corresponding to the respective colored layers. It is characterized by a different one.

As described above, according to the semi-transmissive color liquid crystal display device of the present invention, as in the above-described configuration, a light transmitting portion is formed for each pixel with respect to the light reflective metal layer, and the light transmitting portion is made into a transmission mode, and in the region other than the light transmitting portion. In the reflection mode, the transflective color liquid crystal display device is thereby formed.

In addition, according to the transflective color liquid crystal display device of the present invention, the following effects can be obtained by varying the deposition area of the transparent resin layer with respect to the light transmissive portion corresponding to each colored layer.

When the area of the light transmitting portion of the light reflection film and each element (color density and thickness) of the color filter (coloring layer) are set on the basis of the transmittance and color reproducibility required for the transmission mode, a conventional semi-transmissive color liquid crystal According to the display device, in the color filter, a colored layer having the same color density and thickness is formed in the reflection area, whereby the display is dark in the reflection mode.

On the other hand, by varying the deposition area of the transparent resin layer with respect to the light transmitting portion as in the present invention, the amount used as the color filter (coloring layer) in the transmissive region can be reduced or decreased in the transmissive mode. The display can be brought closer to the reflection mode. On the contrary, compared with the colored layer of a transmissive area | region, the colored layer of a reflecting area can obtain the same effect as having formed thin thickness. This is equivalent to reducing the decrease in the brightness in the reflection mode or not causing the decrease.

According to the present invention, in the light reflection film, as described above, the light transmitting portion is formed for each pixel, and when applied to both the transmission mode and the reflection mode, suitable conditions are obtained for the deposition area of the transparent resin layer to the light transmission portion. In this way, it is possible to independently set the white balance which consists of RGB of a transmission mode and a reflection mode. By performing such white balance adjustment, a high quality and high performance transflective color liquid crystal display device is obtained.

In the semi-transmissive color liquid crystal display device of the present invention, a light reflection film is formed on one surface of the substrate, and a colored layer having different colors is formed, and one transparent electrode group and an alignment film made of a transparent conductive material are formed on these colored layers. The one member formed in this order, the other transparent electrode group which consists of a transparent conductive material, and the other member formed in order on the transparent substrate, and the liquid crystal layer interposed between these one member and the other member are provided, The light reflecting film is provided with a light transmitting portion having a different light passing area corresponding to each colored layer, and a notch portion is formed in the reflecting region of each colored layer.

According to this semi-transmissive color liquid crystal display device, a light transmitting portion is formed for each pixel with respect to the light reflecting film in the same manner as described above, and the light transmitting portion is set to a transmissive mode, and the light transmissive portion is a reflection mode in a region other than the light transmissive portion. Thus, a transflective color liquid crystal display device is used.

In addition, according to the semi-transmissive color liquid crystal display device of the present invention, by forming a notch in the reflection area of each colored layer, the following effects can be obtained.

When the area of the light transmitting portion and each element (color density and thickness) of the color filter (coloring layer) are set on the basis of the transmittance and color reproducibility required for the transmission mode, the conventional transflective color liquid crystal display device is used. According to the color filter, a colored layer having the same color and thickness is formed in the reflection region, whereby the display is dark in the reflection mode.

On the other hand, by forming the notch part in the reflection area of each colored layer like this invention, the density and thickness of the color of the color filter (coloring layer) of the reflection area are the same as the transmission area, but are occupied by the colored layer. And the part (notch part of a colored layer) in which a colored layer does not exist, the darkness of a display can be prevented by the notch part. That is, compared with the colored layer of the transmissive region, the colored layer of the reflecting region can obtain the same effect as having a thin thickness. Therefore, the fall of the brightness in the reflection mode can be reduced or there can be no fall.

In addition, a technique for reducing the thickness of the colored layer for reflection mode compared to the thickness of the colored layer for transmission mode has been proposed (see Patent Document 5). However, according to this technique, the portion which becomes the reflecting area before formation of the colored layer is proposed. A transparent layer must be formed beforehand, and the process increases by that much. In the present invention, the notch portion of the colored layer can be formed at the same time, respectively, when forming each colored layer of RGB, whereby there is no increase in the number of steps and the manufacturing cost is reduced.

According to the present invention, as described above, a light transmitting portion is formed for each pixel, and when applied to both the transmission mode and the reflection mode, a light transmission portion having a different light passing area is formed corresponding to each of the colored layers. This makes it possible to independently set the white balance composed of the transmissive mode and the reflective mode RGB, and by performing such white balance adjustment, a high quality and high performance semi-transmissive color liquid crystal display device is obtained.

The semi-transmissive color liquid crystal display device of the present invention comprises a light reflecting film, one transparent electrode group made of a transparent conductive material, one member formed by sequentially forming an alignment film, and colored on a transparent substrate, respectively, on one circumferential surface of the substrate. A colored layer is formed, and the other member which the other transparent electrode group which consists of a transparent conductive material, and an orientation layer are formed one by one on these colored layers is provided, and the liquid crystal layer interposed between these one member and the other member, and The light reflection film is characterized in that a light transmitting portion having a different light passing area is formed corresponding to each colored layer.

According to the transflective color liquid crystal display device of the present invention, the colored layer is different from the transflective color liquid crystal display device described above in that the colored layer is formed on the other member rather than the one member.

As described above, a light transmitting portion is formed for each of the pixels for the light reflecting film, and the light transmitting portion is set to a transmissive mode, and a reflection mode is set in a region other than the light transmissive portion, thereby forming a semi-transmissive color liquid crystal display device. .

In applying to both the transmission mode and the reflection mode, a light transmission portion having a different light transmission area is formed corresponding to each colored layer, thereby independently setting the white balance composed of the RGB of the transmission mode and the reflection mode. To help. By performing such white balance adjustment, a high quality and high performance transflective color liquid crystal display device is obtained.

In the transflective color liquid crystal display device, it is preferable to form a notch in the reflecting region of each colored layer.

By forming the notch in the reflecting region of each colored layer, the following effects can be obtained.

Conventional semi-transmissive type when the area of the light transmissive portion of the light reflective metal layer and each element (color density, thickness) of the color filter (colored layer) are set on the basis of the transmittance and color reproducibility required for the transmission mode. According to the color liquid crystal display device, in the color filter, a colored layer having the same density and thickness is formed in the reflection area, whereby the display is dark in the reflection mode.

On the other hand, by forming a notch in the reflecting region of each colored layer as in the present invention, the color density and thickness of the color filter (coloring layer) of the reflecting region are the same as the transmitting region, but the portion occupied by the colored layer. And the part (notch part of a colored layer) in which a colored layer does not exist, the darkness of a display can be prevented by the notch part. That is, the colored layer of the reflecting region can obtain the same effect as having a thinner thickness than the colored layer of the transmissive region. Therefore, the fall of the brightness in the reflection mode can be reduced or there can be no fall.

In addition, although the technique of making the thickness of the colored layer for reflection mode thin compared with the thickness of the colored layer for transmission mode is proposed (refer patent document 5), according to this technique, the part which becomes a reflective area before formation of a colored layer is proposed. A transparent layer must be formed beforehand, and the process increases by that much.

In the present invention, the notch portions of the colored layer can be formed at the same time when forming each colored layer of RGB, thereby reducing the number of steps and reducing the manufacturing cost.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the transflective color liquid crystal display device of this invention is described in detail, referring an accompanying drawing.

(First embodiment)

Fig. 1 is a schematic cross-sectional view of the transflective color liquid crystal display device A1 of the present invention, and Fig. 2 is a schematic diagram showing the relationship between both the light reflection film and the colored layer of the transflective color liquid crystal display device A1. The transflective color liquid crystal display device A1 is of the STN type simple matrix system.

FIG. 3 is a cross sectional view taken along cut line X-X shown in FIG. 2, and FIG. 4 is a cross sectional view taken along cut line Y-Y shown in FIG.

When the viewer sees the transflective color liquid crystal display device A1, the transflective color liquid crystal display device A1 is a "one side member" on the segment side which is closer to the observer and a "one side" on the common side on the opposite side. Member ”.

In one member of the transflective color liquid crystal display device A1, 1 is a common glass substrate, and a light reflection film 2 made of, for example, an aluminum metal material is formed on the glass substrate 1. On this light reflection film 2, transparent resin layer P which consists of acrylics, such as PHA094X and PHA103X by Shin-Nitetsu Kagaku, is formed, for example. Preferably, the transparent resin layer P may be laminated only on the light reflection film 2 except for the light transmitting portion 7.

Furthermore, on the transparent resin layer P, the colored layer 3 used as a color filter is formed, and the overcoat layer 4 which consists of acrylic resins is coat | covered so that the colored layer 3 may be covered again. Then, on the overcoat layer 4, a transparent electrode 5 made of ITO arranged in many parallel stripes is laminated, and an alignment film 6 made of a polyimide resin rubbed in a predetermined direction is sequentially stacked. Further, an insulating film made of resin, SiO _2, or the like may be interposed between the transparent electrode 5 and the alignment film 6.

In the present embodiment, corresponding to the colored layers 3 of the light reflection film 2, light transmitting portions 7 of different light passing areas are formed in accordance with the difference in colors of red, green, and blue. Although the shape of the light transmission part 7 is an elongate rectangle as shown in FIG. 2, this invention is not limited to this, Any shape may be sufficient. For example, it may be an ellipse. In addition, although the number of the light transmission parts 7 is one corresponding to each colored layer 3 in FIG. 2, it is not limited to one, You may divide and form a plurality of light transmission parts.

Hereinafter, the formation method of the light transmission part 7 is demonstrated. First, an aluminum metal film is uniformly formed on the glass substrate 1 by sputtering. Subsequently, the aluminum metal film is subjected to a series of photos such as resist coating, exposure, development, etching of the aluminum metal film, and resist foil. The light transmission part 7 is patterned and removed so that it may become a predetermined shape by the lithography process.

As the material of the light reflection film 2, instead of the Al material, a metal film such as Al alloy such as AlNd, Ag metal and Ag alloy may be used.

By forming the light transmitting portions 7 for each pixel in this manner, in the transmissive mode, the backlight passes through the light transmitting portions 7 (referred to as transmissive regions). Areas other than the light transmitting portion 7 (referred to as semi-used areas) reflect light from above in the reflection mode.

According to the present invention, the area of the light transmitting portion 7, that is, the light passing area, is set to be different depending on the color difference of red, green, and blue corresponding to the respective colored layers 3.

The colored layer 3 is formed by photolithography by applying a photosensitive resist obtained by dispersing a pigment (red, green, blue) in advance on a substrate (pigment dispersion method).

In forming the colored layer 3, a dyeing method may be used in place of the pigment dispersion method as described above.

Moreover, as shown in FIG. 2 which shows the relationship between both the light reflection film 2 and the colored layer 3, you may make it the structure which each colored layer 3 is surrounded by the black matrix 18. As shown in FIG.

Next, in the other member, 9 is a glass substrate on the segment side, and a stripe transparent electrode group 10 made of ITO arranged in parallel with a plurality on the glass substrate 9 is sequentially formed, and then the stripe transparent electrode is formed again. On the group 10, an alignment film 11 made of a polyimide resin rubbed in a predetermined direction is formed.

Subsequently, the glass substrate 9 and the glass substrate 1 are both stripe-like through a liquid crystal layer 12 made of a chiral nematic liquid crystal twisted at an angle of, for example, 200 ° to 260 °. The transparent electrode groups 5 and 10 are joined to each other by a seal member (not shown) so that they cross (orthogonally). Incidentally, a plurality of spacers are arranged between the two glass substrates 1 and 9 (not shown) in order to make the thickness of the liquid crystal layer 12 constant.

In addition, the first phase difference plate 13, the second phase difference plate 14, and the iodine polarizing plate 15 made of polycarbonate are sequentially stacked on the outer side of the glass substrate 9, A third phase difference plate 16 made of carbonate and an iodine polarizing plate 17 are sequentially stacked. In such arrangement | positioning, it sticks by apply | coating the adhesive material which consists of acrylic materials.

Then, the light source unit such as an LED or a cold cathode tube and a backlight unit made of a light guide plate are brought into close contact with the polarizing plate 17 on the glass substrate 1 side in one member.

In this way, according to the transflective color liquid crystal display device A1 of the present invention, as described above, corresponding to the respective colored layers 3 of the light reflection film 2, different light is produced depending on the difference in the colors red, green, and blue. The light transmitting part 7 of the passage area is formed. Thereby, color design can be performed so that the white balance which consists of RGB of a transmissive mode and a reflection mode can be set independently by varying a transmittance | permeability and a reflectance with respect to each RGB, respectively. By performing such color design and white balance adjustment, a high quality and high performance transflective color liquid crystal display device A1 is obtained.

Next, an Example is described.

For the transflective color liquid crystal display device A1 of the present invention described above, in order to set the color design and the white balance independently of each of the transmission mode and the reflection mode, the transmittance and the reflectance for each color layer 3 are adjusted for each RGB. The decision was made as prescribed.

In other words, in the present embodiment, the light transmissive portions 7 having different light passing areas are formed in accordance with the color difference of red, green, and blue in response to the respective colored layers 3 with respect to the light reflection film 2. As shown in Table 1, the area of the light transmissive portion 7 is 39% of the entire pixel in the R (red) pixel, 39% of the entire pixel in the G (green) pixel, and B (blue). In the pixel of Fig. 2, the structure occupies 27% of the entire pixel.

In addition, as a conventional example (comparative example), in response to each colored layer 3 on the light reflection film 2, a light transmitting portion 7 having a light passing area having the same size for each color of red, green, and blue is provided. And a transflective color liquid crystal display device B1 having the same configuration as that of the transflective color liquid crystal display device A1.

5 and 6 are schematic diagrams showing the relationship between both the light reflection film and the colored layer of the transflective color liquid crystal display device B1. 5 is a schematic diagram corresponding to FIG. FIG. 6 is a cross-sectional view taken along the cut line Z-Z shown in FIG. 5.

According to the semi-transmissive color liquid crystal display device B1, as shown in Table 1, the light passing area of the light transmissive portion 7 of the light reflective film 2 occupies 30% of all pixels.

7 and 8 show chromaticity diagrams in optical characteristics of both the transflective color liquid crystal display device A of the present invention and the transflective color liquid crystal display device B of the comparative example.

Fig. 7 shows chromaticity diagrams in both transmission modes, and Fig. 8 shows chromaticity diagrams in both reflection modes.

7 and 8, in the embodiment according to the present invention, the chromaticity of the white balance W of R, G, and B is (? X,? Y) in the transmission mode as compared with the conventional example (comparative example). (0.016, 0.017) larger, and (Δx, Δy) = (0.010, 0.009) in the reflection mode. That is, according to the embodiment, it can be seen that compared with the conventional example, the white balance is shifted in the yellow direction in the transmission mode and in the blue direction in the reflection mode.

For reference, the evaluation method of the optical characteristic used in the present embodiment will be described with reference to FIG.

In the reflective mode, as shown in Fig. 9A, when light (C light source) is incident on the display surface of the liquid crystal display device from the inclined upper portion 15 °, and the liquid crystal display device is driven (white The evaluation result was obtained by measuring the reflectance, contrast, and color gamut area of the reflected light in the vertical direction (display, black display, red display, green display, blue display).

In the transmissive mode, as shown in Fig. 9B, when light (C light source) is incident on the back surface of the liquid crystal panel from which the backlight is removed, and the liquid crystal display device is driven (white display, black The evaluation results were obtained by measuring the transmittance, contrast, and color gamut area of the transmitted light in the vertical direction (display, red display, green display, blue display).

10, the definition of the color gamut area is shown. The gamut area represents the ratio of the area surrounding each RGB chromaticity point to the NTSC. The larger this area is, the higher the color reproducibility is, and a panel display with high color purity is obtained.

(2nd Embodiment)

Next, a second embodiment of the present invention will be described.

Although the cross-sectional schematic diagram of the transflective color liquid crystal display device A2 in 2nd Embodiment is the same as that of FIG. 1, the transflective color liquid crystal display device A2 is compared with the transflective color liquid crystal display device A1. The following points are different.

In other words, the deposition area of the transparent resin layer P with respect to the light reflection film 2 is different in correspondence with the respective colored layers. In detail, FIG. 11 and FIG.

11 and 12 are schematic diagrams showing the relationship between both the light reflection film 2 and the colored layer P in the transflective color liquid crystal display device A2, Fig. 11 is a sectional view of the main portion, and Fig. 12 is a plan view of the main portion.

In the semi-transmissive color liquid crystal display device A2, the deposition on the light reflection film 2 of the transparent resin layer P corresponds to each of the colored layers 3, that is, in accordance with the color difference of red, green, and blue. Make the area different.

The light reflection film 2 having such a structure is formed by uniformly forming a metal film on the glass substrate 1 by aluminum or the like by sputtering. Subsequently, resist coating, exposure, development and etching of the aluminum metal film are performed on the aluminum metal film. The light transmitting part 7 is patterned and removed so as to have a predetermined shape by a series of photolithography processes called resist foils.

Such light transmitting portions 7 are formed in accordance with the colors red, green, and blue, i.e., pixels, corresponding to the respective colored layers 3, thereby allowing the light transmitting portions 7 to transmit light in the transmissive mode. Light is reflected in the reflection mode in a region other than the light transmitting portion 7.

Thus, according to the semi-transmissive color liquid crystal display device A2 of the present invention, each colored layer (in the region of the light reflecting film 2 other than the light transmissive portion 7), i. Corresponding to 3), the deposition area of the transparent resin layer P with respect to the light reflection film 2 was changed. Thereby, the colored layer 3 of the reflection mode area | region can freely set the ratio of the area of the thin part. When the area of the thin portion is increased, the same effect as that of forming the colored layer 3 thin can be obtained, and the decrease in the brightness in the reflection mode can be reduced or the brightness can be prevented from decreasing.

In this way, for each RGB, the color design can be made so that the white balance composed of the RGB in the transmission mode and the reflection mode can be set independently by setting the transmittance and the reflectance respectively. By performing such color design and white balance adjustment, a high quality and high performance semi-transmissive color liquid crystal display device A2 is obtained.

Next, an Example is described.

For the transflective color liquid crystal display device A2 of the present invention described above, in order to set the color design and the white balance independently of each of the transmission mode and the reflection mode, the transmittance and the reflectance for each color layer 3 are adjusted for each RGB. The decision was made as prescribed.

That is, in the present embodiment, the light reflection film of the transparent resin layer P corresponds to each of the colored layers 3, that is, according to the color difference of red (R), green (G), and blue (B). Although the deposition area with respect to 2) is different, as shown in Table 2, the ratio of this deposition area is 100% with respect to the entire light reflection film 2 in the pixel of R (red) and the pixel of G (green). In this case, the structure of the light reflection film 2 is 100%, and the B (blue) pixel occupies 75% of the light reflection film 2 (the transparent resin / reflection portion in Table 2 is Ratio of deposition area).

In addition, as the conventional example (comparative example), the transparent resin layer P is formed at the same deposition area ratio of 100% for each of the colors red, green, and blue in correspondence with the respective colored layers 3. A transflective color liquid crystal display device B2 was produced in which the configuration was the same as that of the transflective color liquid crystal display device A2.

In addition, the light passing area of the light transmissive portion 7 of the light reflection film 2 occupies 30% of the entire pixel of each pixel.

13 and 14 show the chromaticity diagrams in optical characteristics of both the transflective color liquid crystal display device A2 of the present invention and the transflective color liquid crystal display device B2 of the comparative example.

This evaluation method is the same as that described in 1st Embodiment.

Fig. 13 shows chromaticity diagrams in both transmission modes, and Fig. 14 shows chromaticity diagrams in both reflection modes.

13 and 14, in the embodiment according to the present invention, as compared with the conventional example (comparative example), in the transmission mode, the embodiments according to the present invention and the R, G, Although the chromaticity of the white balance W of B is the same, the reflection mode changes small to (Δx, Δy) = (0.011, 0.011). That is, according to the embodiment, it can be seen that, compared with the conventional example, the white balance is not changed in the transmissive mode, but moves in the blue direction in the reflective mode. Here, the white balance changes in the transmission mode, but it is possible to adjust by changing the balance of CF of RGB.

(Third Embodiment)

Next, a third embodiment of the present invention will be described.

Although the cross-sectional schematic diagram of the transflective color liquid crystal display device A3 in this third embodiment is the same as that of Fig. 1, the transflective color liquid crystal display device A3 is compared with the transflective color liquid crystal display device A1. The following points are different.

15 and 16 are schematic diagrams showing the relationship between both the light reflection film and the colored layer in the transflective color liquid crystal display device A3, and Fig. 15 is a sectional view of the main portion, and Fig. 16 is a plan view of the main portion.

The characteristic of this embodiment is that the deposition area with respect to the light transmitting part of the transparent resin layer is different in correspondence with each colored layer, but is shown in detail in FIGS. 15 and 16.

15 and 16, the transparent resin layer for the light transmitting portion 7 of the transparent resin layer P corresponding to each of the colored layers 3, i.e., according to the color difference of red, green, and blue. Change the deposition area of the window in (P).

Thus, according to the transflective color liquid crystal display device A3 of the present invention, the light transmissive portion 7 of the transparent resin layer P corresponds to each colored layer 3 in the reflection area of each colored layer 3. By varying the deposition area with respect to), the amount to be used as the color filter (coloring layer 3) of the transmission area can be added or subtracted.

In addition, the display in the transmissive mode can be made closer to the reflective mode. On the contrary, compared with the colored layer of the transmissive region, the colored layer in the reflective region can obtain the same effect as having a thinner thickness, and the brightness in the reflective mode can be made closer to the brightness in the transmissive mode. .

In addition, according to the present invention, the light transmitting portion 7 having the light passing area is formed in accordance with the colors red, green, and blue corresponding to the respective colored layers 3 as described above, and the transparent resin layer P By varying the deposition area for the light transmitting part 7 of the light transmission unit, the color design can be made so that the white balance of the RGB in the transmission mode and the reflection mode can be set independently for each RGB. . By performing such color design and white balance adjustment, a high quality and high performance semi-transmissive color liquid crystal display device A3 is obtained.

Next, an Example is described.

For the transflective color liquid crystal display device A3 of the present invention described above, in order to set the color design and the white balance independently of each of the transmission mode and the reflection mode, the transmittance and the reflectance for each color layer 3 are adjusted for each RGB. The decision was made as prescribed.

In the present embodiment, the light transmitting portion 7 of the transparent resin layer P corresponds to each colored layer 3, that is, according to the color difference of red (R), green (G), and blue (B). Different deposition area for. As shown in Table 3, the ratio of the deposition area is 70% of the entire light transmissive portion 7 in the R (red) pixel, and the entire light transmissive portion 7 in the G (green) pixel. In 70% and B (blue) pixels, 100% of the light transmitting part 7 is composed of 100% (the "transparent resin / transmitting part" in Table 3 is expressed as the ratio of the deposition area).

Moreover, as a conventional example (comparative example), the transparent resin layer P is formed in the same adhesion area ratio with respect to each color of red, green, and blue corresponding to each colored layer 3, and the other structure is provided. A transflective color liquid crystal display device B3 was produced in the same manner as the transflective color liquid crystal display device A3.

The light passing area of the light transmissive portion 7 of the light reflection film 2 occupies 30% of the entire pixel of each pixel.

17 and 18 show chromaticity diagrams in optical characteristics of both the transflective color liquid crystal display device A3 of the present invention and the transflective color liquid crystal display device B3 of the comparative example.

Fig. 17 shows chromaticity diagrams in both transmission modes, and Fig. 18 shows chromaticity diagrams in both reflection modes.

As shown in Figs. 17 and 18, in the reflection mode, although the chromaticity of the white balance W of the R, G, and B of the conventional example (comparative example) and the conventional example (comparative example) is almost the same, As for the embodiment according to the present invention, (Δx, Δy) = (0.008, 0.008) is larger than that of the conventional example (comparative example). In addition, according to the embodiment, it can be seen that the white balance is shifted in the yellow direction in the reflection mode without changing the transmission mode, compared with the conventional example. Here, the white balance does not change with respect to the reflection mode, but adjustment is possible by changing the balance of CF of RGB.

(4th Embodiment)

Next, a fourth embodiment of the present invention will be described.

Fig. 19 is a schematic cross-sectional view of the transflective color liquid crystal display device A4 of the present invention, and Fig. 20 is a schematic diagram showing the relationship between both the light reflection film and the colored layer of the transflective color liquid crystal display device A4. The transflective color liquid crystal display device A4 is of the STN type simple matrix method.

The transflective color liquid crystal display device A4 is composed of a "other member" on the side closer to the observer and a "one member" on the opposite side when the viewer sees the transflective color liquid crystal display device A4.

In one member, 1 is a common glass substrate. On this glass substrate 1, the light reflection film 2 which consists of aluminum metal materials etc. is formed, for example. The colored layer 3 is formed on this, and the overcoat layer 4 which consists of acrylic resins is coat | covered so that the colored layer 3 may be covered again. Then, on the overcoat layer 4, a transparent electrode 5 made of ITO arranged in parallel in a plurality of stripes and an alignment film 6 made of a polyimide resin rubbed in a predetermined direction are sequentially stacked. Further, an insulating film made of resin, SiO _2, or the like may be interposed between the transparent electrode 5 and the alignment film 6.

In each colored layer 3, that is, the light transmission part 7 of a different light passing area is formed according to the difference of the color of red, green, and blue.

The manufacturing method of the light reflection film 2 and the colored layer 3 of such a structure is demonstrated.

An aluminum metal film is uniformly formed by sputtering on the glass substrate 1, and subsequently, the aluminum metal film is subjected to a series of photolithography processes such as resist coating, exposure, development, etching of the aluminum metal film, and resist foil. Each light transmission part 7 is patterned so that it may become a shape like a predetermined | prescribed thing.

As the material of the light reflection film 2, instead of the Al material, a metal film such as Al alloy such as AlNd, Ag metal and Ag alloy may be used.

Next, the color filter which is the colored layer 3 is formed by a pigment dispersion method. That is, the photosensitive resist combined with the pigment (red, green, blue) previously is apply | coated on a board | substrate, and is formed by photolithography.

In addition, in forming the color filter which is the coloring layer 3, you may use the dyeing method instead of the pigment dispersion method as mentioned above.

In this way, the light transmission part 7 of a different light passing area is formed in each color layer 3 according to the difference of the color red, green, and blue. The light transmitting portion 7 transmits light, and the light is reflected in a region other than the light transmitting portion 7. The light transmitting part 7 transmits light and is called a transmission area. Areas other than the light transmitting portion 7 reflect light by the light reflection film 2, and thus are called reflection areas.

Further, according to the present invention, the notch portion 8 in which the pigment is not present (or not dyed) is formed in the reflecting region of each colored layer 3.

20 is a plan view showing the arrangement of the notch 8. According to FIG. 20, each colored layer 3 is comprised by the black matrix 18. As shown in FIG. According to this structure, the notch part 8 is formed in the inside of the black matrix 18 by cutting a part of colored layer 3. Although the shape of the notch part 8 is a triangle in FIG. 20, it is not limited to a triangle, Any shape, such as a circle, an ellipse, and a square, may be sufficient.

Next, the other member will be described. In the other member, 9 is a glass substrate on the segment side, and on this glass substrate 9, a stripe-shaped transparent electrode group 10 made of ITO arranged in parallel in parallel is formed sequentially. On the stripe-shaped transparent electrode group 10, an alignment film 11 made of a polyimide resin rubbed in a predetermined direction is formed.

Then, the glass substrate 9 and the glass substrate 1 are both stripe-like through a liquid crystal layer 12 made of a chiral nematic liquid crystal twisted at an angle of 20 ° to 260 °, for example. The transparent electrode groups 5, 10 are attached to each other by a seal member (not shown) so as to cross (orthogonally). Although not shown, a plurality of spacers are disposed between the glass substrates 1 and 9 in order to make the thickness of the liquid crystal layer 12 constant.

Further, the first phase difference plate 13, the second phase difference plate 14, and the iodine polarizing plate 15 made of polycarbonate are sequentially stacked on the outer side of the glass substrate 9.

A third phase difference plate 16 made of polycarbonate and an iodine polarizing plate 17 are sequentially stacked on the outer side of the glass substrate 1 as one member. In such arrangement | positioning, it sticks by apply | coating the adhesive material which consists of acrylic materials.

Then, the polarizing plate 17 on the glass substrate 1 side is disposed in close contact with a light source unit such as an LED or a cold cathode tube and a backlight unit made of a light guide plate.

Thus, according to the transflective color liquid crystal display device A4 of this invention, about the pixel of the substantially same area corresponding to each colored layer 3, about the same area in the reflection area of each colored layer 3 is the same. The notch part 8 of this is formed. By forming this notch part 8, the reflected light amount can be increased in the reflection mode, and the darkness of the display can be prevented. That is, the fall of the brightness in reflection mode can be eliminated or the fall can be reduced.

That is, with the notch part of this invention, the effect similar to forming the thickness thinly in the colored layer of a permeation | transmission area | region can be acquired.

This amount of reflected light becomes a function of the area ratio between the portion where the colored layer does not exist (notch portion of the colored layer) and the portion occupied by the colored layer. The larger the area ratio, the greater the amount of reflected light. However, if the area ratio is too large, the effect of coloring the reflected light is reduced.

In addition, according to the present invention, corresponding to the colored layers 3 of the light reflection film 2 as described above, the light transmitting portions 7 of different light passing areas are formed in accordance with the difference of the colors red, green, and blue. In addition, the notch part 8 makes a color design so that the white balance which consists of RGB of a transmission mode and a reflection mode can be set independently by changing transmittance and a reflectance with respect to each RGB, respectively. By performing color design and white balance adjustment, a high quality and high performance transflective color liquid crystal display device A4 is obtained.

Next, an Example is described.

For the transflective color liquid crystal display device A4 of the present invention described above, in order to set the color design and the white balance independently of each of the transmission mode and the reflection mode, the transmittance and the reflectance for each color layer 3 are adjusted for each RGB. The decision is made as prescribed.

That is, in the embodiment, corresponding to each of the colored layers 3 of the light reflection film 2, light transmitting portions 7 having different light passing areas are formed in accordance with the difference in the colors of red, green, and blue. As shown in Fig. 4, the area of the light transmitting part 7 is 39% of the entire pixel in the R (red) pixel, 39% of the entire pixel in the G (green) pixel, and B (blue). The pixel was set to occupy 27% of the entire pixel. In addition, the area of the notch part 8 of the colored layer 3 was made common for all RGB pixels, and it was set as the structure which occupies 15% with respect to the reflecting area (it shows as CF opening ratio in Table 4).

In addition, as a comparative example, in the transflective color liquid crystal display device A4 having the above configuration, the same color is applied to each of the colors red, green, and blue corresponding to the respective colored layers 3 of the light reflection film 2. A transflective color liquid crystal display device B4 was formed in which a light transmissive portion 7 having a light transmissive area having a size was formed and the other configuration was the same as that of the transflective color liquid crystal display device A4.

21 to 23 show schematic diagrams showing the relationship between both the light reflection film and the colored layer in the transflective color liquid crystal display device B1.

FIG. 21 is a plan view showing the arrangement of the colored layer 3 and the notch 8 of the transflective color liquid crystal display device B1, FIG. 22 is a cross-sectional view taken along the cut line aa of FIG. 21, and FIG. It is sectional drawing by the cutting line line bb shown in FIG.

According to the semi-transmissive color liquid crystal display device B4, as shown in Table 5, the light passing area of the light transmissive portion 7 occupies 30% of all the pixels in the RGB pixels. Moreover, the area of the notch part 8 of the colored layer 3 was made common for all RGB pixels, and it was set as the structure which occupies 15% with respect to the reflecting area (it shows as CF opening ratio in Table 5).

24 and 25 show chromaticity diagrams in optical characteristics of both the transflective color liquid crystal display device A4 of the present invention and the transflective color liquid crystal display device B4 of the comparative example.

24 shows chromaticity diagrams in both transmission modes, and FIG. 25 shows chromaticity diagrams in both reflection modes.

As for the embodiment according to the present invention, the chromaticity of the white balance W of R, G, and B is larger in the transmissive mode (Δx, Δy) = (0.015, O.014) than in the comparative example, and the reflection In the mode, (Δx, Δy) = (0.014, 0.017) is made small. In addition, according to the embodiment, it can be seen that the white balance moves in the yellow direction in the transmission mode and in the blue direction in the reflection mode as compared with the conventional example.

For reference, the evaluation method of the optical characteristic used in the present Example is demonstrated.

In the reflective mode, when light (C light source) is incident on the display surface of the liquid crystal display device from the inclined upper part 15 °, and the liquid crystal display device is driven (white display, black display, red display, green display). Evaluation results were obtained by measuring the reflectance, contrast, and color gamut area of the reflected light in the vertical direction (blue display).

In the transmissive mode, when light (C light source) is incident on the back surface of the liquid crystal panel from which the backlight is removed, and the liquid crystal display device is driven (white display, black display, red display, green display, blue display). Evaluation results were obtained by measuring the transmittance, contrast, and color gamut area of the transmitted light in the vertical direction.

10 shows a definition of the color gamut area. The gamut area represents the ratio of the area surrounding each RGB chromaticity point to the NTSC. The larger the area is, the higher the color reproducibility is, and a panel display with high color purity is obtained.

(5th Embodiment)

Next, a fifth embodiment of the transflective color liquid crystal display device of the present invention will be described.

Fig. 26 is a schematic cross sectional view of a transflective color liquid crystal display device A5. 27 to 29 are schematic diagrams showing the relationship between both the light reflection film and the colored layer in the transflective color liquid crystal display device A5, FIG. 27 is a plan view thereof, and FIG. 28 is a sectional view taken along the cutting line XX. Fig. 29 is a cross sectional view taken along a cut line YY.

In one member of the transflective color liquid crystal display device A5, 1 is a common glass substrate. On the glass substrate 1, a stripe transparent electrode group 5 made of ITO arranged in parallel in a large number is formed, and on the stripe transparent electrode group 5, a light reflection film 2 made of an aluminum metal material or the like is formed. It formed and the alignment film 6 which consists of a polyimide resin rubbed in a fixed direction again was formed.

As the material of the light reflection film 2, instead of the Al material, a metal film such as Al alloy such as AlNd, Ag metal and Ag alloy may be used.

In the other member, 9 is a glass substrate on the segment side, and on the glass substrate 9, an overcoat layer 4 made of acrylic resin is formed so as to form a colored layer 3 and cover the colored layer 3 again. do. Then, on the overcoat layer 4, a transparent electrode 10 made of ITO arranged in parallel in a plurality of stripes and an alignment film 11 made of a polyimide resin rubbed in a predetermined direction are sequentially stacked. Further, an insulating film made of resin, SiO _2, or the like may be interposed between the transparent electrode 10 and the alignment film 11.

In the present invention, corresponding to the respective colored layers 3 of the other substrate, that is, the light transmitting portions H of different light passing areas are formed in accordance with the color difference of red, green, and blue. The shape of the light transmissive portion H is an elongated rectangle as shown in Fig. 27, but the present invention is not limited to this and may be any shape. For example, it may be an ellipse. In FIG. 27, the number of light transmitting parts 7 is one corresponding to each of the colored layers 3, but the number of light transmitting parts is not limited to one but may be formed by dividing a plurality of light transmitting parts.

The light reflection film 2 firstly forms a stripe-like transparent electrode group 5 on the glass substrate 1, and uniformly forms an aluminum metal film by sputtering. Subsequently, a resist coating is applied to the aluminum metal film. The light transmitting portion H is patterned and removed so as to have a predetermined shape by a series of photolithography processes such as exposure, development, etching of aluminum metal film, and resist thin film.

By forming the light transmitting portion H in this manner, light passes through the light transmitting portion H in the transmissive mode and is reflected in a region other than the light transmitting portion H in the reflective mode.

The light transmissive portion H has different light passing areas corresponding to the respective colored layers 3 in accordance with the color difference of red, green, and blue. Thereby, color design can be performed so that the white balance which consists of RGB of a transmissive mode and a reflection mode can be set independently by making transmittance and a reflectance different for each color, respectively. By performing such color design and white balance adjustment, a high quality and high performance transflective color liquid crystal display device A5 is obtained.

The color filter which is the coloring layer 3 may apply | coat a photosensitive resist combined with the pigment dispersion method, ie, the pigment (red, green, blue) previously, and may form it by photolithography. According to this pigment dispersion method, it can form simultaneously in the photolithography.

In addition, in forming the color filter which is the coloring layer 3, you may use the dyeing method instead of the pigment dispersion method as mentioned above.

In addition, the colored layers 3 may be configured to be surrounded by the black matrix 18.

Moreover, according to this invention, the notch part A is formed in the reflection area of each colored layer 3, It is also characteristic.

The notch part A is formed in the inside of the black matrix 18 and the reflection area of each colored layer 3 by cutting a part of colored layer 3. The shape of the notch portion A is a quadrangular shape in FIG. 27, but is not limited to a quadrangular shape, and may be any shape such as a circle, an ellipse, or a triangle.

The notch portion A is also substantially the same area for each pixel of approximately the same area corresponding to each colored layer 3.

By forming the notch portion A, even if the density and thickness of the color of the color filter (coloring layer) of the reflecting region are the same as those of the transmissive region, the portion occupied by the colored layer and the portion where the colored layer does not exist (of the colored layer) Notch portion) can be combined to prevent darkening of the display in the reflection mode with the notch portion A. FIG.

In short, the colored layer of the reflecting region can obtain the same effect as having a thinner thickness than the colored layer of the transmissive region. It is possible to reduce the decrease in the brightness in the reflection mode or to prevent the decrease.

In addition, according to the present invention, in response to the respective colored layers 3 as described above, the light transmitting portions H having different light passing areas are formed in accordance with the color difference of red, green, and blue. With respect to RGB, the color design can be made so that the white balance which consists of RGB of a transmission mode and a reflection mode can be set independently by varying a transmittance | permeability and a reflectance, respectively. By performing such color design and white balance adjustment, a high quality and high performance transflective color liquid crystal display device A5 is obtained.

Next, an Example is described.

For the transflective color liquid crystal display device A5 of the present invention described above, in order to set the color design and the white balance independently of each of the transmission mode and the reflection mode, the transmittance and the reflectance for each color layer 3 are adjusted for each RGB. The decision is made as prescribed.

That is, in the Examples, corresponding to the respective colored layers 3, the light transmitting portions H having different light passing areas are formed in accordance with the differences of the colors red, green, and blue, or as shown in Table 6, The area of the light transmitting portion H is 39% of the entire pixel in the R (red) pixel, 39% of the entire pixel in the G (green) pixel, and about the entire pixel in the B (blue) pixel. In addition, the area of the notch 8 of the colored layer 3 was made to be common to each of the RGB pixels so as to occupy 27%, and the structure occupied 15% of the reflection area (shown as CF opening ratio in Table 6). .

Moreover, as a conventional example (comparative example), corresponding to each colored layer 3, the light transmissive part of the same size of light transmission area is formed about each color of red, green, and blue, and the other structure is transflective type A semi-transmissive color liquid crystal display device B5 was produced in the same manner as the color liquid crystal display device A5.

FIG. 30 is a schematic diagram showing the relationship between both the light reflection film and the colored layer in the transflective color liquid crystal display device B5.

As shown in Table 7, the light passing area of the light transmissive portion of the light reflection film 2 occupies 30% of the entire pixel of each pixel. In addition, the area of the notch part A of the colored layer 3 was made common for all RGB pixels, and it was set as the structure which occupies 15% with respect to the reflecting area (it shows as CF opening ratio in Table 7).

31 and 32 show chromaticity diagrams in optical characteristics of both the transflective color liquid crystal display device A5 of the present invention and the transflective color liquid crystal display device B5 of the comparative example.

Fig. 31 shows chromaticity diagrams in both transmission modes, and Fig. 32 shows chromaticity diagrams in both reflection modes.

As described above, with respect to the embodiment according to the present invention, the chromaticity of the white balance W of R, G, and B in the transmission mode is (Δx, Δy) = (0.015, 0.014) larger and (Δx, Δy) = (0.014, 0.017) in the reflection mode. In addition, according to the embodiment, it can be seen that the white balance moves in the transmissive mode in the yellow direction and in the reflective mode in the blue direction as compared with the conventional example.

As mentioned above, although Embodiment 1-5 of this invention were described, this invention is not limited to said embodiment. For example, the transflective color liquid crystal display device is an STN type simple matrix method, but an active liquid crystal display device having a TFT or a TFD instead of this method has the same effect. In addition, various changes can be made within the scope of the present invention.

 According to the present invention as described above, by performing the white balance adjustment, it is possible to provide a high quality and high performance transflective color liquid crystal display device.

Claims (6)

The light reflection film and the transparent resin layer are formed on the one surface of the board | substrate, and the coloring layer is formed in a different color, respectively, The one member which the one transparent electrode group which consists of a transparent conductive material, and an orientation film is formed in order on these colored layers one by one. ; The other member on which the other transparent electrode group made of a transparent conductive material and an alignment layer are sequentially formed on the transparent substrate; And A liquid crystal layer interposed between these one member and the other member, In the light reflection film, a light transmitting portion is formed corresponding to each colored layer, The light transmitting portion passes the backlight in the transmissive mode and reflects the light in the reflective mode in the reflecting region other than the light transmitting portion. The light transmissive portion has a different light passing area corresponding to each colored layer, wherein the transflective color liquid crystal display device. The light reflection film and the transparent resin layer are sequentially formed on the one main surface of the board | substrate, and the coloring layer from which coloring differs is formed one by one, and one transparent electrode group which consists of a transparent conductive material, and an alignment film are formed sequentially on these colored layers. absence; The other member on which the other transparent electrode group made of a transparent conductive material and an alignment layer are sequentially formed on the transparent substrate; And A liquid crystal layer interposed between these one member and the other member, The light reflection film is formed by forming a light transmitting portion corresponding to each colored layer, The light transmitting portion passes the backlight in the transmissive mode, and reflects external light in the reflective mode in the reflecting region other than the light transmitting portion. A transflective color liquid crystal display device in which the deposition area of the transparent resin layer with respect to the light reflection film is varied in correspondence with the respective colored layers. A light reflection film and a transparent resin layer are sequentially formed on one surface of the substrate, and a colored layer having a different color is formed, and one transparent electrode group made of a transparent conductive material and an alignment film are sequentially formed on these colored layers. absence; The other member on which the other transparent electrode group made of a transparent conductive material and an alignment layer are sequentially formed on the transparent substrate; And A liquid crystal layer interposed between these one member and the other member, The light reflection film is formed by forming a light transmitting portion corresponding to each colored layer, The light transmitting portion passes the backlight in the transmissive mode, and reflects external light in the reflective mode in the reflecting region other than the light transmitting portion. A transflective color liquid crystal display device in which the deposition area of the transparent resin layer with respect to the light transmitting portion is varied in correspondence with the respective colored layers. The semi-transmissive color liquid crystal display device according to claim 1, wherein a notch is formed in the reflecting area of each colored layer. delete delete

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