KR20100114235A - In-plane switching mode liquid crystal display device - Google Patents

Abstract

PURPOSE: An in-plane switching mode liquid crystal display device for improving image display quality and minimizing the variation in which the sudden change of the color temperature in a white area is minimized among gradation and improving the picture display quality are provided to prevent the degradation of temperature color in the white area. CONSTITUTION: A color filter substrate includes a rust and blue color filter pattern. An array panel(101) puts opposite to the color filter substrate. In the array panel, the respective red putting opposite, and the green and blue pixel region defined with the red, and the green and blue color filter pattern. The thin film transistor is formed in the crossing point vicinity of data line and gate wiring(103).

Description

In-Plane Switching mode Liquid crystal display device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, and more particularly, to a transverse electric field type liquid crystal display device which can improve image display quality by minimizing a sudden change of color temperature in a white region during gradation.

Recently, as the information society has progressed rapidly, a display field for processing and displaying a large amount of information has been developed.

In particular, in order to meet the times of thinning, light weight, and low power consumption, there is a need for a flat panel display, and accordingly, a thin film transistor liquid crystal having excellent color reproducibility and thinness display) was developed.

The display method of such a liquid crystal display device uses optical anisotropy and polarization of liquid crystal molecules, because the structure of the liquid crystal molecules is thin and long and has a pre-tilt angle having directionality in the arrangement thereof. By artificially applying a voltage to the liquid crystal, the direction of alignment of the liquid crystal molecules can be controlled by changing the inclination angle of the liquid crystal molecules. The desired image information is expressed by changing the arrangement and arbitrarily modulating the light polarized by the optical anisotropy of such liquid crystals.

Currently, an active matrix LCD in which a thin film transistor and pixel electrodes connected to the thin film transistor are arranged in a matrix manner is attracting the most attention due to its excellent resolution and ability to implement video.

In the liquid crystal panel, which is a basic element of a general liquid crystal display device, an upper color filter substrate and a lower array substrate face each other and are spaced apart at a predetermined interval, and a liquid crystal including liquid crystal molecules is filled between the two substrates. It is a structure.

At this time, the electrode for applying a voltage to the liquid crystal is a common electrode located on the color filter substrate and the pixel electrode located on the array substrate, when the voltage is applied to these two electrodes, the upper and lower sides formed by the difference of the applied voltage It uses a way to control the direction of the liquid crystal molecules between which the vertical electric field is located.

However, as described above, the common electrode and the pixel electrode are vertically formed, and when the liquid crystal is driven by the vertical electric field generated above and below, the characteristics such as transmittance and aperture ratio are excellent, but the viewing angle characteristics are excellent. In order to overcome these disadvantages, a liquid crystal driving method using an in-plane switching (IPS) using a horizontal electric field has been proposed.

Hereinafter, the above-described transverse electric field type liquid crystal display device will be described in detail with reference to FIG. 1.

In a liquid crystal panel of a general transverse electric field type liquid crystal display device, a color filter substrate 9 having a color filter and a thin film transistor array substrate 10 face each other, and the color filter substrate 9 and the thin film transistor array substrate 10 are opposite to each other. The liquid crystal layer 11 is filled in between.

At this time, the common electrode 17 and the pixel electrode 19 are horizontally formed on the thin film transistor array substrate 10 with the same spacing interval on the same plane, and the horizontal electric field L according to the voltage applied thereto. In this case, the liquid crystal molecules in between the horizontal electric field L are influenced and driven.

2A and 2B are cross-sectional views illustrating operations of on and off states of a general transverse electric field type liquid crystal display device, respectively.

First, referring to FIG. 2A, which illustrates an arrangement of liquid crystals in an on state where a voltage is applied, a phase change of a liquid crystal 11a at a position corresponding to the common electrode 17 and the pixel electrode 19 is performed. Although the liquid crystal 11b positioned in the section between the common electrode 17 and the pixel electrode 19 is formed by a horizontal electric field L formed by applying a voltage between the common electrode 17 and the pixel electrode 19, It is arranged in the same direction as the horizontal electric field (L). That is, in the transverse electric field type liquid crystal display device, since the liquid crystal moves by the horizontal electric field, the viewing angle is widened.

Therefore, when the transverse electric field type liquid crystal display device is viewed from the front, it can be seen in the up / down / left / right directions even without reversal in about 80 to 85 degrees.

Next, referring to FIG. 2B, since a horizontal electric field is not formed between the common electrode and the pixel electrode because no voltage is applied to the liquid crystal display, the arrangement state of the liquid crystal layer 11 does not change.

Since the liquid crystal is driven by a horizontal electric field as described above, when the user views the screen displayed through the horizontal field type liquid crystal display from the front, the transverse field type liquid crystal display device moves up to about 80 to 85 degrees in the vertical direction. It has a viewing angle characteristic that can be seen.

Such an array substrate for a transverse electric field type liquid crystal display device will be described with reference to FIG. 3.

3 is a plan view showing a portion of a pixel area of an array substrate of a conventional transverse electric field type liquid crystal display device.

As shown in the drawings, the conventional general horizontal transverse electric field type liquid crystal display array substrate 30 includes a plurality of gate wires 32 arranged in a horizontal direction parallel to each other at predetermined intervals, and in close proximity to the gate wires 32. The common wiring 36 formed in parallel with the gate wiring 32 and the data wiring 40 intersecting with the two wirings 32 and 36, and in particular, defining the pixel region P with the gate wiring 32 are provided. Consists of.

Near the intersection of the gate line 32 and the data line 40, the gate electrode 34, the gate insulating layer (not shown), the semiconductor layer 39, the source and drain electrodes 42 and 44 which are sequentially stacked are disposed. A thin film transistor Tr is formed. At this time, the source electrode 42 branches off the data line 40, and the gate electrode 34 branches off the gate line 32.

In addition, in the pixel region P, a plurality of pixel electrodes 52 branched from the auxiliary line 50 connected to the drain electrode 44 and the pixel electrodes 52 alternately and parallel to each other in parallel with each other. A plurality of common electrodes 38 are spaced apart from each other and branched from the common wiring 36.

However, a liquid crystal display device having an array substrate for a transverse electric field type liquid crystal display device having the above-described structure has a specific azimuth angle due to a change in an azimuth angle at which a user views the liquid crystal display device by forming each pixel region in a single domain. Color shift phenomenon occurs near 0 degree, 90 degree, 180 degree, and 270 degree, and it is a factor which reduces display quality.

Therefore, in order to prevent such a color shift phenomenon, recently, an array substrate for a transverse electric field type liquid crystal display device having a dual domain in one pixel area has been proposed.

FIG. 4 is a plan view of one pixel area of a conventional array substrate for a transverse field type liquid crystal display device having a dual domain in one pixel area, and the same components are added to 30 with reference numerals given in FIG. It was.

As shown in the drawing, one pixel region P has a rectangular shape and has a centrally symmetrically bent structure, and a plurality of pixel electrodes 82 and a common electrode 68 alternately corresponding to each other are configured. It is also characterized by its central part being bent. Accordingly, the direction in which the two electrodes 82 and 68 are disposed on the upper side and the lower side of the pixel region P may be changed based on a portion where the plurality of pixel electrodes 82 and the common electrode 68 are bent. Dual domains are implemented, thus making it possible to suppress the color shift phenomenon at the particular azimuth described above.

However, the transverse field type liquid crystal display device including the array substrate for the transverse field type liquid crystal display device implementing the above-described dual domain has a problem of degrading image quality due to severe color temperature variation due to the gray level change.

FIG. 5 is a graph illustrating a change in color temperature according to a gray scale change of a conventional transverse electric field type liquid crystal display device.

As shown in the figure, in the case of a transverse electric field type liquid crystal display device having a conventional dual domain, 256 gray levels change in total due to the white region (0 to 255 in the drawing) due to the effective Δn (the amount of change in refractive index of the liquid crystal) of the liquid crystal. A liquid crystal display device having a light emitting device is shown in which a zero indicates a perfect black state that can be displayed, a 255 indicates a white state that can be displayed, and an area having a numerical value of 230 or more becomes a normal white area. It can be seen that a phenomenon occurs. The rapid change in color temperature in the white area results in the display of vivid white and reddish yellow or yellowish white, especially in the image expressing white. The situation is declining.

In order to prevent the image quality deterioration due to the sudden change in color temperature, the gamma compensation circuit may be configured independently for each of red, green, and blue to control red, green, and blue pixel areas, but the gamma compensation circuit may be red, green, and blue. The configuration of each of the blue pixel areas causes a problem of significantly increasing the manufacturing cost and lowering the price competitiveness of the display device.

The transverse field type liquid crystal display device according to the present invention for solving the above problems does not require the configuration of a compensation gamma circuit for red, green, and blue, resulting in no increase in cost, and furthermore, a dual domain in one pixel area. The purpose of the present invention is to prevent degradation of image display quality by preventing a sudden change in color temperature in the white region while implementing the same.

In order to achieve the above object, a transverse electric field type liquid crystal display device according to an embodiment of the present invention, the color filter substrate having a red, green, blue color filter pattern; An array substrate facing the color filter substrate and defining red, green, and blue pixel regions respectively facing the red, green, and blue color filter patterns; A gate wiring and a data wiring formed on an inner side of the array substrate and intersecting with each other with a gate insulating film at a boundary of each pixel region; A common wiring formed on the same layer and spaced apart from the gate wiring, and an outermost common electrode branched from the common wiring and formed at the outermost portion of each pixel region; A thin film transistor formed near an intersection point of the gate line and the data line; A plurality of formed substrates having a first width in the red and green pixel regions, the central portion having a first angle with respect to a rubbing direction perpendicular to the gate wiring, and having a symmetrically bent structure; A plurality of second central pixel electrodes formed in the blue pixel region, the second central pixel electrodes having a second width smaller than the first width and a second angle greater than the first angle; A plurality of first central common electrodes connected to the outermost common electrode and having the first width in the red and green pixel areas and alternately formed in parallel with the plurality of first central pixel electrodes; A plurality of second central common electrodes having the second width and alternately formed in parallel with the plurality of second central pixel electrodes; It includes a liquid crystal layer interposed between the color filter substrate and the array substrate.

The first width is 2 μm to 3.5 μm, the second width is 0.5 μm to 1.0 μm smaller than the first width, the first angle is 10 degrees to 20 degrees, and the second angle is It is characterized in that it has a value of 0.5 to 1 degree larger than the first angle.

The widths of the red, green, and blue pixel regions all have the same size, so that the intervals between the adjacent pixel electrodes and the common electrode in the blue pixel region are different from each other in the red and green pixel regions. It has a value larger than the separation interval therebetween or the width of the red and green pixel areas is greater than the width of the blue pixel area so that the pixel electrode and the common electrode are adjacent to each other in the red, green and blue pixel areas. It is characterized in that all the spacing intervals of the same size.

Each of the red, green, and blue pixel areas is connected to the drain electrode, and an outermost pixel electrode is formed to overlap the outermost common electrode, thereby forming a first storage capacitor together with the outermost common electrode.

The outermost pixel electrode and the plurality of first and second center pixel electrodes are connected to the drain electrode by an auxiliary pixel pattern connecting one end thereof, and the auxiliary pixel pattern is formed to overlap the common wiring. In addition to the common wiring, it forms a second storage capacitor. In this case, one end of the plurality of first and second central common electrodes is provided with an auxiliary common pattern connecting the ends thereof to be connected to the outermost common electrode, and the array substrate covers the thin film transistor and covers the thin film transistor. A protective layer having a drain contact hole exposing a drain electrode of the drain electrode and a common contact hole exposing the outermost common electrode, wherein the auxiliary pixel pattern and the drain electrode are connected through the drain contact hole, and the common contact The auxiliary common pattern is connected to the outermost electrode through a hole, wherein the plurality of first and second center pixel electrodes, the plurality of first and second center common electrodes, and the outermost pixel electrode. Silver is characterized in that all formed of a transparent conductive material on the protective layer.

The data line has a zigzag shape with respect to the entire surface of the array substrate by forming a structure symmetrically bent at the center of each pixel region.

In the transverse electric field type liquid crystal display device according to the present invention, in the pixel electrode and the common electrode formed in the red and green pixel areas and the blue pixel area according to the above-described embodiments and modifications, the width and the angle between the rubbing direction By forming differently, it is possible to prevent a sudden drop in the color temperature in the white region, and furthermore, there is an effect of improving the display quality felt by the user due to the prevention of a sudden drop in the color temperature in the white region.

In order to prevent display quality deterioration due to a sudden drop in color temperature, a separate gamma compensation circuit of red, green, and blue pixels is not required, thereby reducing the manufacturing cost and improving the price competitiveness of the display device.

In addition, by implementing a dual domain in one pixel area, there is an effect of preventing color shift and improving the viewing angle.

Hereinafter will be described in detail through a preferred embodiment of the present invention.

FIG. 6 is a plan view of three pixel areas corresponding to the red, green, and blue color filter patterns of the transverse electric field type liquid crystal display according to the exemplary embodiment of the present invention, and FIGS. -It is sectional drawing about the part cut along Ⅷ, Ⅷ-Ⅷ. 6 is a plan view mainly illustrating an array substrate, and pixel areas corresponding to red, green, and blue color filter patterns are referred to as red, green, and blue pixel areas, respectively. In addition, since all the components included in the red and green pixel areas of the array substrate are the same, the same reference numerals are given. In addition, the central pixel electrode and the central common electrode provided in the blue pixel region having the constitutive discrimination point are added to the central pixel electrode and the central common electrode provided in the red and blue pixel regions by adding 100 to them.

As illustrated in FIG. 6, in the transverse electric field type liquid crystal display device 100 according to an exemplary embodiment of the present invention, the array substrate 101 is provided with a plurality of gate lines 103 arranged in the horizontal direction in parallel with a predetermined interval therebetween. And a plurality of common wirings 109 adjacent to each of the plurality of gate wirings 103 and arranged in parallel with the plurality of gate wirings 103 and a plurality of crossings of the plurality of gate wirings 103. A plurality of data wires 135 are defined and define a pixel area P extending in the vertical direction.

In addition, near the intersection point of the gate wiring 103 and the data wiring 135 in each pixel region P, a gate electrode formed of the gate wiring 103 or branched from the gate wiring 103 itself. 106, a semiconductor layer 120 including a gate insulating layer (not shown) over the gate electrode 106, an active layer (not shown) and an ohmic contact layer (not shown) over the gate insulating layer (not shown), A thin film transistor Tr including source and drain electrodes 138 and 141 formed in contact with the semiconductor layer 120 and spaced apart from each other is formed. In this case, the source electrode 138 branches off from the data line 135.

In addition, in each pixel area P, the outermost common electrode 110 branched from the common line 109 formed in parallel with the gate line 103 is parallel to the data line 135. It is formed.

In addition, the outermost common electrode 110 is spaced apart by a predetermined interval and connected to one end of the outermost common electrode 110 and the common contact hole 168, the common auxiliary pattern 172 is formed, A plurality of central common electrodes 173 and 273 are formed by branching from the common auxiliary pattern 172.

 In addition, each pixel region P is connected to the drain electrode 141, overlaps the common wiring 109, and forms a pixel auxiliary pattern 169, and branches from the pixel auxiliary pattern 169. The outermost pixel electrode 170 and the plurality of central pixel electrodes 171 and 271 are alternately formed with the plurality of central common electrodes 173 and 273. In this case, the common wiring 109 and the pixel auxiliary pattern 169 overlap each other to form first and second storage electrodes, respectively, with a gate insulating layer (not shown) and a protective layer (not shown) interposed therebetween as dielectric layers. It forms a storage capacitor (StgC).

In addition, the outermost pixel electrode 170 positioned at the outermost part of the pixel electrodes 170, 171, and 271 is formed to partially overlap the outermost common electrode 110 to form an auxiliary storage capacitor.

On the other hand, as the most characteristic configuration of the present invention, the outermost pixel electrode and common electrode (170, 110) and the central pixel electrode and common electrode (171, 271, (173, 273)) are each pixel region ( When the virtual line is crossed in parallel with the gate line 103 at the central portion of P), it has a structure symmetrically bent with respect to the virtual line, and formed in the red and green pixel areas Pr and Pg. Angles of the pixel electrodes 170 and 171 and the common electrodes 110 and 173 of the plurality of pixel electrodes 170 and 271 and the common electrodes 110 and 273 formed in the blue pixel region Pb. The angle of bending is different.

That is, the angles of bending of the plurality of common electrodes 110, 173, and 273 and the pixel electrodes 170, 171, and 271 in the red, green, and blue pixel regions Pr, Pg, and Pb are respectively θr, θg, and θb. It is characterized by the following equation. θr = θg <θb

In this case, the reference lines serving as reference points of the angles θr, θg, and θb of the common electrodes 110, 173, and 273 and the pixel electrodes 170, 171, and 271 are the electrodes (110, 173, 273, and (b). 170, 171, and 271) is a straight line perpendicular to the gate wiring 103 in the portion bent, and the extending direction of the reference line is a rubbing direction (RD) is another feature.

The angles θr = θg of the plurality of common electrodes 110 and 173 and the pixel electrodes 170 and 171 formed in the red and green pixel regions Pr and Pg with respect to the rubbing direction RD are 10 degrees to 20 degrees. The bent angles θb of the plurality of common electrodes 110 and 273 and the pixel electrodes 170 and 271 of the blue pixel region Pb have a value of 10.5 to 21 degrees, which is about 0.5 to 1 degree greater than θr or θg. Is characteristic. For example, when θr and θg are 15 degrees, the plurality of pixel electrodes 170, 171, and 271 and the common electrodes 110, 173, and 273 are formed to form 15.5 degrees to 16 degrees.

At this time, as described above, the plurality of common electrodes 110, 173, and 273 and the pixel electrodes 170, 171, and 271 form a structure in which the center portion thereof is bent, and thus the data line 135 defining the pixel region P is defined. In addition, the array substrate 101 as a whole has a zigzag shape by forming a structure that is bent with respect to the central portion of each pixel region P. FIG.

Meanwhile, another characteristic part of the transverse electric field type liquid crystal display array substrate 101 according to the present invention is the widths (dr, dg, db) of the center common electrode 173 and 273 and the center pixel electrode 171 and 271. ) Are formed with different sizes in the red and green pixel regions Pr and Pg and the blue pixel region Pb.

More specifically, when the widths of the common electrodes 173 and 273 and the central pixel electrodes 171 and 271 in the red, green, and blue pixel regions Pr, Pg, and Pb are dr, dg, and db, respectively, dr and dg have the same size and db is characterized in that it is formed to have a smaller value than dr and dg. In other words, the center pixel electrodes 171 and 271 and the center common electrodes 173 and 273 are formed to satisfy dr = dg <db. In this case, the outermost common electrode 110 and the outermost pixel electrode 170 overlapping the same may be formed to have the same width in the red, green, and blue pixel regions Pr, Pg, and Pb. This is because the outermost common electrode 110 and the outermost pixel electrode 170 positioned at the outermost portions of the pixel regions Pr, Pg, and Pb overlap with each other to form an auxiliary storage capacitor, particularly in the blue pixel region Pb. This is to prevent this because the total width of the storage capacitor becomes smaller when the width becomes smaller as the width becomes smaller. That is, even if the widths of the outermost common electrode 110 and the outermost pixel electrode 170 formed to overlap each other at the outermost portions of the pixel regions Pr, Pg, and Pb are equal to or different from each other, it is an object of the present invention. In order to have an advantage in terms of the storage capacitor total capacitance, the outermost common electrode 110 and the outermost pixel electrode 170 have the same width in all the pixel regions Pr, Pg, and Pb. It is formed to have.

In more detail, the relationship between the widths of the central pixel electrode and the central common electrode in each pixel region and the separation interval between the common electrode and the pixel electrode adjacent to each other will be described in detail with reference to the drawings.

9A and 9B illustrate an outermost pixel electrode 170 and a center portion formed in the red and green pixel regions Pr and Pg and the blue pixel region Pb in the array substrate for a transverse electric field type liquid crystal display device according to the present invention. Only the common electrodes 173 and 273 and the central pixel electrodes 171 and 271 are simply illustrated. In this case, the widths Pw1, Pw2, and Pw3 of each pixel area are defined as the distance between the data line and the data line which are adjacent to each other in principle. However, in the drawing, the distance between the outermost pixel electrodes is defined as Shown to be width. In addition, since all the components included in the red and green pixel areas of the array substrate are the same, the same reference numerals are given to the pixel electrode and the common electrode for convenience of description.

First, referring to FIG. 9A, in the red, green, and blue pixel regions Pr, Pg, and Pb, the widths Pw1, Pw2, and Pw3 of each pixel region Pr, Pg, and Pb are all the same size (Pw1 =). Pw2 = Pw3)), and the difference between the red and green pixel areas Pr and Pg and the blue pixel area Pb is the center pixel electrodes 171 and 271 and the central common electrode 173 and 273. The widths dr, dg, and db and the spacings wr, wg, and wb between these electrodes 171, 271, and 173, 273 are the size.

In more detail, the widths Pw1, Pw2, and Pw3 of the red, green, and blue pixel regions Pr, Pg, and Pb all have the same size (Pw1 = Pw2 = Pw3) and are provided in the blue pixel region Pb. The width db of the center pixel electrode 271 and the center common electrode 273 are the widths of the center pixel electrode 171 and the center common electrode 173 provided in the red and green pixel regions Pr and Pg. It is characterized in that it is formed to have a size (db <dr, dg) less than, dg). At this time, the widths (dr, dg) of each of the central common electrode 173 and the central pixel electrode 171 provided in the red and green pixel regions Pr and Pg have the same size (dr = dg) and are usually 2 μm. The width db of the center pixel electrode 271 and the center common electrode 273 included in the blue pixel region Pb is 0.5 to the red and green pixel regions Pr and Pg. It is characterized in that the size is determined in the range of 1 μm to 3 μm so as to have a smaller size of 1 μm to 1 μm. In this case, since the outermost pixel electrode 170 and the outermost common electrode (not shown) provided in the red, green, and blue pixel regions Pb have the same size in the entire array substrate, the aforementioned 2 μm to 3.5 μm Its size is determined in the range of. In this case, the widths Pw1, Pw2, and Pw3 of the pixel regions Pr, Pg, and Pb have the same size (Pw1 = Pw2 = Pw3) in the spaced intervals wr wg and wb between adjacent electrodes. Spacing interval between the common electrode and the pixel electrode in the blue pixel region Pb than spacing wr, wg between the common electrode and the pixel electrode adjacent to each other in the red and green pixel regions Pr and Pg. It is characterized by (wb) having a larger size (wr = wg <wb).

Meanwhile, referring to FIG. 9B, widths (dr, dg, and db) of the center pixel electrodes 171 and 271 and the center common electrodes 173 and 273 provided in the red, green, and blue pixel regions Pr, Pg, and Pb are illustrated. ) Has the same configuration as described with reference to FIG. 9A, that is, dr = dg> db, and the difference points are adjacent to the pixel electrodes 170, 171, and 271 and the common electrode (not shown). 273 have the same size (wr = wg = wb) in all of the red, green, and blue pixel regions Pr, Pg, and Pb. Therefore, in each pixel region Pr, Pg, and Pb, the spacings wr, wg, and wb of neighboring pixel electrodes and the common electrode have the same size (wr = wg = wb). The width db of the center pixel electrode and the center common electrode within the region is smaller than the width (dr, dg) of the center common electrode and the center pixel electrode provided in the red and green pixel regions Pr and Pb (db <dr = dg), the width Pw3 of the blue pixel area is smaller than the widths Pw1 and Pw2 of the red and green pixel areas (Pw3 < Pw1 = Pw2).

Hereinafter, the cross-sectional structure of the transverse electric field type liquid crystal display device according to the present invention will be described with reference to FIGS. 7 and 8. For convenience of explanation, the region in which the thin film transistor, which is a switching element, is formed is called a switching region TrA.

As illustrated, the transverse electric field type liquid crystal display device 100 according to the present invention includes an array substrate 101 including a thin film transistor Tr as a switching element, a gate line (not shown), and a data line 135. And a color filter substrate 190 including green, blue color filter patterns 194a, 194b, and 194c, and a liquid crystal layer 188 interposed between the two substrates 101 and 190.

First, the color filter substrate 190 corresponds to a boundary between each pixel region Pr, Pg, and Pb, that is, a portion where the gate and data lines (not shown) 135 and the common wiring 109 of the array substrate 101 are formed. The black matrix 192 is formed, and the red, green, and blue color filter patterns 194a are overlapped with the black matrix 192 and are sequentially repeated to correspond to the pixel regions Pr, Pg, and Pb. The color filter layer 194 including 194b and 194c is formed. The overcoat layer 196 is formed to cover the red, green, and blue color filter patterns 194a, 194b, and 194c.

A gate wiring (not shown) extending in one direction and a common wiring 109 are formed in parallel to the array substrate 101 facing the color filter substrate 190 having the above-described configuration. The gate electrode 106 is connected to the gate line (not shown) in the region TrA. In addition, the pixel electrodes Pr, Pg, and Pb branch from the common line 109 to form the outermost common electrode 110. In this case, the outermost common electrode 110 formed in each of the pixel regions Pr, Pg, and Pb has the same width in all the pixel regions Pr, Pg, and Pb.

In addition, a gate insulating layer 117 is formed on the gate wiring (not shown), the gate electrode 106, the common wiring 109, and the outermost common electrode 110, and the switching region over the gate insulating layer 117. In the TrA, a semiconductor layer 120 including an active layer 120a made of pure amorphous silicon and an ohmic contact layer 120b made of impurity amorphous silicon and spaced apart from each other is formed, and over the ohmic contact layer 120b. Source and drain electrodes 138 and 141 are spaced apart from each other. In addition, the data line 135 is formed in a zigzag form on the front surface of the substrate 101 adjacent to the outermost common electrode 110 at the boundary of each pixel region Pr, Pg, and Pb. 135 and the source electrode 138 are connected. Although the semiconductor pattern 121 of the first pattern 121a and the second pattern 121b made of the same material forming the semiconductor layer 120 is formed under the data line 135, the semiconductor pattern 121 is formed. May be omitted. The reason why the semiconductor pattern 121 is formed below the data line 135 is due to a manufacturing method. Is the semiconductor layer 120 and the source and drain electrodes 138 and 141 formed at one time by a mask process? Alternatively, the semiconductor pattern 121 may be formed or omitted below the data line 135 as shown in FIG.

The protective layer 163 is formed on the data line 135 and the source and drain electrodes 138 and 141. In this case, the passivation layer 163 includes a drain contact hole 165 exposing a part of the drain electrode 141 and a common contact hole (not shown) exposing a part of an end of the outermost common electrode 110.

 In addition, the protective layer 163 is in contact with the drain electrode 141 through the drain contact hole 165 as a transparent conductive material, for example, indium tin oxide (ITO) or indium zinc oxide (IZO). The auxiliary pixel pattern 169 is formed, and branches from the auxiliary pixel pattern 169 to have a structure symmetrically bent in the pixel areas Pr, Pg, and Pb with respect to the center thereof, and has the outermost pixel electrode. The 170 and the plurality of central pixel electrodes 171 and 271 are formed at regular intervals. In this case, the auxiliary pixel pattern 169 overlaps the common wiring 109 to form a storage capacitor StgC together with the common wiring 109, and the outermost pixel electrode 170 is the outermost common. A predetermined width overlaps with the electrode 110 to form an auxiliary storage capacitor.

In addition, the auxiliary common pattern is made of the same transparent conductive material forming the pixel electrodes 170, 171, and 271 on the protective layer 163 and in contact with the outermost common electrode 110 through the common contact hole (not shown). (Not shown) is formed, branched from the auxiliary common pattern (not shown), alternately with the plurality of central pixel electrodes 171 and 271 inside the outermost pixel electrode 170, and are parallel to the central part. The central common electrodes 173 and 273 have a symmetrically bent structure. In this case, the widths (dr, dg, db in FIG. 6) of the plurality of central pixel electrodes 171 and 271 and the central common electrodes 173 and 273 are red and green pixel areas Pr and Pg and blue pixel areas Pb. ) Is formed to satisfy the equation of dr = dg <db (see FIG. 6), and the outermost and center pixel electrodes 170, 171 and 271 and the outermost and center common electrodes 110, 173, The angle of inclination of 273 (θr, θg, θb in FIG. 6) also satisfies the equation of θr = θg <θb in the red and green pixel regions Pr, Pg and blue pixel region Pb (see FIG. 6). It is characterized in that it is formed to. In the red and green pixel areas Pr and Pb and the blue pixel area Pb, the widths of the electrodes (dr, dg, and db in FIG. 6) and the angles of the angles (θr, θg, and θb in FIG. 6) are obtained. Since it has been described in detail already, it will be omitted.

On the other hand, as described above, the angle (θr, θg, FIG. 6, and FIG. The reason why θb) is formed to have a different size in the blue pixel area Pb compared to the red and green pixel areas Pr and Pg is as a result of analyzing the XYZ component (the component constituting the color coordinate system) of the color component that displays white color. This is because it has been found that the display of the white color due to the blue pixel region rather than the red and green pixel regions causes a drastic change in the aforementioned color temperature.

FIG. 10 is a graph illustrating changes in transmittance according to voltages applied to X, Y, and Z components when a white color of a conventional transverse electric field type liquid crystal display device is implemented.

Looking at the graph, the transmittance curves according to the voltage changes of the X and Y components are almost identical, whereas the transmittance curves according to the voltage changes of the Z components do not coincide with the transmittance curves according to the voltage changes of the X and Y components. It can be seen that.

Therefore, when the transverse field type liquid crystal display device implementing the dual domain according to such analysis expresses a white color, the change in transmittance according to the voltage change requires the Z component to be tuned since the Z component is different from the X and Y components. The results are as follows.

On the other hand, Figure 11 shows the change in the transmittance of the Z component according to the voltage applied when expressing the white color of the conventional transverse field-type liquid crystal display device, showing the change in the transmittance of the Z component of red, green, blue It is a graph. In this case, the vertical axis of the graph represents a value transformed and normalized to a value felt by a transmittance measuring device for detecting transmittance.

As shown, the magnitude of the transmittance of the Z component representing the white color may be represented by the sum of the red, green, and blue Z values, of which the blue Z value occupies 90%.

Accordingly, it can be seen from the graphs shown in FIGS. 10 and 11 that a sudden decrease in color temperature can be prevented by tuning the blue pixel area displaying blue.

From this fact, the characteristic structure according to the present invention, i.e., the angle between the common and pixel electrodes in the red and green pixel areas is about 0.5 to 1 degree larger than the angle of bending based on the rubbing direction of the plurality of common electrodes and the pixel electrodes. A plurality of symmetrically bent common electrodes and pixel electrodes are formed in the blue pixel region, and at the same time, a width of 0.5 μm to 1 μm is smaller than that of the plurality of central pixel electrodes and the central common electrode formed in the red and green pixel regions. Forming a central pixel electrode and a central common electrode in the blue pixel region was derived. As a result, the transverse field type liquid crystal display device having a dual domain according to the present invention prevents a sudden drop in color temperature when displaying white in gray scale. I have the characteristics to do it.

12 is a graph illustrating a change in color temperature according to gray level change in a transverse field type liquid crystal display device implementing a dual domain according to the present invention. For comparison with the related art, the color temperature change according to the gradation change of the transverse electric field type liquid crystal display device implementing the conventional dual domain is also shown.

Referring to the drawings, it can be seen that in the transverse electric field type liquid crystal display device according to the present invention, a sudden decrease in color temperature does not occur in the white region having a gray scale value of 230 or more. That is, in the case of the conventional transverse type liquid crystal display, the color temperature of about 873K is abruptly decreased in the white region, but in the case of the transverse field type liquid crystal display according to the present invention, the decrease of about 222K occurs, so the decrease is about the same. It can be seen that four times the relief. Therefore, the transverse field type liquid crystal display device according to the present invention can reduce the color temperature drop in the white region by 75% compared to the conventional art.

In the figure, the color temperature value of the conventional transverse type liquid crystal display device is about 200K to 400K high in the gradation region of 0-230, but the luminance is not lowered due to the high color temperature. Maintaining the color temperature evenly in the range of about 10,500K is the best match for the user's visibility and feels excellent display quality. If the value is higher or lower than this, the user's visibility characteristics are deteriorated.

Based on this fact, the image displayed through the transverse electric field type liquid crystal display according to the present invention has a color temperature of 9,970K to 10,250K in the entire gray scale region including the white region and shows a difference of about 280K. The conventional transverse electric field type liquid crystal display device has a color temperature of 9500K to 10,400K and shows a difference of about 900K. Thus, the visibility characteristics felt by the user by the color temperature change are excellent in the transverse electric field type liquid crystal display device according to the present invention. .

On the other hand, although not shown in the graph, in the transverse electric field type liquid crystal display device according to the present invention and the cited invention, the average luminance value was almost similar. In the conventional case, the luminance value of 0.467313 was measured, and in the present invention, the luminance value of 0.468762 was measured, so that the luminance difference hardly occurred.

Meanwhile, in the embodiments of the present invention, the transverse electric field type liquid crystal display device having the dual domain has been described mainly, but the present invention is not limited to the above embodiments, and various changes and modifications can be made without departing from the spirit of the present invention. . That is, the characteristic configuration of the present invention is not necessarily limited to the transverse electric field type liquid crystal display device having a double domain, and it is obvious that the modification may also be applied to the transverse electric field type liquid crystal display device having a general single domain as a modification. In the case of the example, the effect which can prevent the sudden color temperature fall in a white area can be anticipated.

1 is a cross-sectional view showing a cross section of a portion of a general transverse electric field type liquid crystal display device.

2A and 2B are cross-sectional views showing operations of on and off states of a general transverse electric field type liquid crystal display device, respectively.

3 is a plan view showing a portion of a pixel area of a conventional array substrate for a transverse electric field type liquid crystal display device.

4 is a plan view of one pixel region of a conventional array substrate for a transverse electric field type liquid crystal display device having a dual domain in one pixel region.

5 is a graph showing a change in color temperature according to the gradation change of a transverse field type liquid crystal display device implementing a conventional dual domain.

6 is a plan view of three pixel areas corresponding to red, green, and blue color filter patterns of a transverse electric field type liquid crystal display according to an exemplary embodiment of the present invention;

FIG. 7 is a cross-sectional view of a portion taken along the line VII-VII of FIG. 6. FIG.

FIG. 8 is a cross-sectional view of a portion taken along the line VII-VII of FIG. 6. FIG.

9A and 9B schematically illustrate only the outermost pixel electrode, the central common electrode, and the central pixel electrode formed in the red and green pixel areas and the blue pixel area in the array substrate for a transverse electric field type liquid crystal display device according to the present invention.

FIG. 10 is a graph illustrating changes in transmittance according to voltages applied to X, Y, and Z components when a white color of a conventional transverse electric field type liquid crystal display device is implemented.

FIG. 11 is a graph illustrating changes in transmittance of Z component according to voltage application when white color of a transverse electric field type liquid crystal display device implementing a dual domain is represented, and illustrates changes in transmittance of Z components of red, green, and blue.

12 is a graph showing a change in color temperature according to the gradation change of a transverse electric field type liquid crystal display device implementing a dual domain according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: transverse electric field type liquid crystal display device 101: array substrate

103: gate wiring 106: gate electrode

109: common wiring 110: outermost common electrode

120 semiconductor layer 135 data wiring

138: source electrode 141: drain electrode

165: drain contact hole 168: common contact hole

169: auxiliary pixel pattern 170: outermost pixel electrode

171: center pixel electrode of red and green pixel areas

172: auxiliary common pattern

173: center common electrode of red and green pixel areas

271: center pixel electrode of the blue pixel region

273: center pixel electrode of the blue pixel region

dr: width of the common electrode and the pixel electrode in the center of the red pixel region

dg: width of the common electrode and the pixel electrode in the center of the green pixel region

db: width of the common electrode and the pixel electrode in the center of the blue pixel region

RB: Rubbing Direction

Pr, Pg, Pb: red, green and blue pixel areas

Pw1, Pw2, Pw3: widths of red, green, and blue pixel areas

wr: Spacing between neighboring electrodes in red pixel area

wg: Spacing between neighboring electrodes in green pixel area

wb: Spacing interval between neighboring electrodes in the blue pixel region

Claims (11)

A color filter substrate having red, green and blue color filter patterns; An array substrate facing the color filter substrate and defining red, green, and blue pixel regions respectively facing the red, green, and blue color filter patterns; A gate wiring and a data wiring formed on an inner side of the array substrate and intersecting with each other with a gate insulating film at a boundary of each pixel region; A common wiring formed on the same layer and spaced apart from the gate wiring, and an outermost common electrode branched from the common wiring and formed at the outermost portion of each pixel region; A thin film transistor formed near an intersection point of the gate line and the data line; A plurality of formed substrates having a first width in the red and green pixel regions, the central portion having a first angle with respect to a rubbing direction perpendicular to the gate wiring, and having a symmetrically bent structure; A plurality of second central pixel electrodes formed in the blue pixel region, the second central pixel electrodes having a second width smaller than the first width and a second angle greater than the first angle; A plurality of first central common electrodes connected to the outermost common electrode and having the first width in the red and green pixel areas and alternately formed in parallel with the plurality of first central pixel electrodes; A plurality of second central common electrodes having the second width and alternately formed in parallel with the plurality of second central pixel electrodes; A liquid crystal layer interposed between the color filter substrate and the array substrate Transverse electric field type liquid crystal display device comprising a. The method of claim 1, And wherein the first width is 2 μm to 3.5 μm and the second width has a value of 0.5 μm to 1.0 μm smaller than the first width. The method of claim 1, And wherein the first angle is 10 degrees to 20 degrees, and the second angle has a value of 0.5 degrees to 1 degree larger than the first angle. The method of claim 1, The widths of the red, green, and blue pixel regions all have the same size, so that the intervals between the adjacent pixel electrodes and the common electrode in the blue pixel region are different from each other in the red and green pixel regions. Transverse field type liquid crystal display device characterized in that it has a value larger than the separation interval between. The method of claim 1, The widths of the red and green pixel areas are larger than the widths of the blue pixel areas, so that the spacings between the adjacent pixel electrodes and the common electrode in the red, green, and blue pixel areas have the same size. Phosphorus field type liquid crystal display device. The method of claim 1, Each of the red, green, and blue pixel regions is connected to the drain electrode, and the outermost pixel electrode is formed to overlap the outermost common electrode, thereby forming a first storage capacitor together with the outermost common electrode. Display. The method of claim 6, The outermost pixel electrode and the plurality of first and second center pixel electrodes are connected to the drain electrode by an auxiliary pixel pattern connecting one end thereof, and the auxiliary pixel pattern is formed to overlap the common wiring. A transverse field type liquid crystal display device comprising a common wiring and a second storage capacitor. The method of claim 7, wherein One end of the plurality of first and second central common electrodes is provided with an auxiliary common pattern for connecting the ends of the horizontal field type liquid crystal display device, characterized in that connected to the outermost common electrode. The method of claim 8, The array substrate includes a protective layer covering the thin film transistor and having a drain contact hole exposing the drain electrode of the thin film transistor and a common contact hole exposing the outermost common electrode, wherein the auxiliary contact is formed through the drain contact hole. And a pixel pattern and the drain electrode, and the auxiliary common pattern to the outermost electrode through the common contact hole. The method of claim 9, The plurality of first and second central pixel electrodes, the plurality of first and second central common electrodes, and the outermost pixel electrode are all formed of a transparent conductive material on the protective layer. LCD display device. The method of claim 1, And the data lines are symmetrically bent at the center of each pixel region to form a zigzag shape with respect to the entire surface of the array substrate.

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