KR20130070041A - Liquid crystal display device - Google Patents

Abstract

PURPOSE: A liquid crystal display is provided to improve brightness and 99% of color reproductivity based on an sRGB standard by changing the peak wavelength of green light among LED light spectrum to long wavelength range by using a color filter. CONSTITUTION: RGB(Red,Green,Blue) color filter patterns(126a-126c) are repetitively formed in a liquid crystal panel(110) corresponding to each pixel region. Each LED(Light Emitting Diode) of a backlight unit is white light emitting diodes for blue chips including red and green phosphor. The green phosphor is silicate, silicate or nitride phosphor having the peak wavelength of 532 to 536 nm. The x axis of the green color filter pattern is in a color range of 0.292 to 0.301 in a xy color coordinate. The y axis of the green color filter pattern has the color spot of 0.607.

Description

[0001] LIQUID CRYSTAL DISPLAY DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, and more particularly, to a liquid crystal display device having a high color reproducibility by optimally combining an LED as a light source and a color filter.

A liquid crystal display device (LCD), which is advantageous for moving picture display and has a large contrast ratio and is actively used in TVs and monitors, exhibits optical anisotropy and polarization properties of a liquid crystal, And the like.

Such a liquid crystal display is an essential component of a liquid crystal panel bonded through a liquid crystal layer between two side-by-side substrates, and realizes a difference in transmittance by changing an arrangement direction of liquid crystal molecules with an electric field in the liquid crystal panel. do.

The liquid crystal panel includes a first substrate on which gate wiring, data wiring, and a thin film transistor (TFT) are formed, a color filter including a light blocking pattern for shielding light, and a red, green, and blue color pattern for color implementation. It is made of a second substrate formed.

However, such a liquid crystal panel requires a separate light source to display the difference in transmittance as an image because it does not have a self-luminous element, and for this purpose, a backlight unit in which a light source is embedded is disposed on the back of the liquid crystal panel. .

The backlight unit is classified into a direct type and an edge type according to the position of the light source. The direct type backlight unit directly disposes light emitted from the light source by arranging the light source under the liquid crystal panel. The backlight unit of the side-type type is disposed in the light guide plate below the liquid crystal panel, and the light source is disposed on at least one side of the light guide plate to indirectly emit light emitted from the light source by using the refraction and reflection of the light guide plate. It is a method of supplying to a liquid crystal panel.

Among the above methods, the side type backlight unit is easier to manufacture than the direct type backlight unit, and has been widely used due to its light weight and low power consumption.

Here, as a light source of the backlight unit, fluorescent lamps such as Cold Cathode Fluorescent Lamps (CCFLs) and External Electrode Fluorescent Lamps (EEFLs) have been widely used. In accordance with the trend toward lighter weight, light emitting diodes (LEDs), which have advantages in power consumption, weight, brightness, and the like, are frequently used.

In addition, as the liquid crystal display device becomes large in size, efforts are being actively made to provide various contents such as sports and movies in high definition.

However, in order to realize high quality, a color filter suitable for the LED as well as the LED as a light source has to be researched and developed, which is a difficult problem.

In particular, the specifications are different for each type of liquid crystal display device. For example, the monitor and the printer must consider the color reproducibility of the sRGB standard that represents the standard RGB color space. In particular, it is difficult to match the green color coordinates to the sRGB standard.

Accordingly, an object of the present invention for solving the above problems is, by applying an LED and a color filter suitable for shifting the wavelength band of a specific color by applying an optimal combination of LED and color filter to a liquid crystal display device To provide.

According to a preferred embodiment of the present invention, a liquid crystal display device includes: a liquid crystal panel in which red, green, and blue color filter patterns are repeatedly formed in correspondence with each of a plurality of pixel regions; Including a plurality of LEDs including a backlight unit located on the back of the liquid crystal panel, each of the plurality of LEDs is a white LED applying one or more of the red and green phosphor to a blue chip, the green phosphor is A silicate or nitride phosphor having a peak wavelength between 532 nm and 536 nm, wherein the green color filter pattern has a chromaticity range of 0.292 to 0.301 in the xy chromaticity coordinate system and a chromaticity point of 0.607 in the y axis. It is done.

The green phosphor is M ₂ SiO _4: having a compound structure of Eu ^{2 +} the compound structure of the M is selected from a metal element calcium (Ca), strontium (Sr), zinc (Zn) and barium (Ba) 1 kind or It is characterized by being a silicate phosphor containing two or more kinds.

Or the green fluorescent material is ^{CaSiN: Eu 2 +, CaAlSiN3:} Eu 2 + and _{Sr 2 Si 5 N 8: Eu} 2 + of having a single compound structure of calcium of the compound structure (Ca), strontium (Sr), and aluminum ( It is characterized in that it is a nitride phosphor of the oxy nitride (Oxy-nitride) containing one or two or more selected from metal elements of Al) or elements of silicon (Si), europium (Eu).

The green color filter pattern is formed of a photosensitive material in which G58 pigment and Y150 pigment are mixed at a ratio of 90:10.

The blue color filter pattern is characterized in that the x-axis has a chromaticity range of 0.152 to 0.153 and the y-axis has a chromaticity range of 0.062 to 0.064 in the xy chromaticity coordinate system.

As described above, according to the present invention, the green peak wavelength of the LED's emission spectrum is shifted to a long wavelength by a predetermined value, and the color filter is applied with the appropriate color filter to improve the brightness and at least 99% of the color reproduction rate based on the sRGB standard. Will be achieved.

Accordingly, it is possible to provide a liquid crystal display device of high quality and high quality.

1 is an exploded perspective view showing a liquid crystal display according to a preferred embodiment of the present invention.
2 is a perspective view showing a liquid crystal panel of a liquid crystal display according to a preferred embodiment of the present invention.
3 is a graph for comparing and explaining the emission spectrum of the backlight unit to which the LED according to the present invention is applied and the backlight unit according to the comparative example.
4 is a graph for explaining the spectral transmittance spectrum of the green color filter pattern according to the present invention and the green color filter pattern according to the comparative example.
5 is a graph for explaining the green color coordinate of the liquid crystal display according to the present invention.
6 is a graph for explaining a blue color coordinate of the liquid crystal display according to the present invention.
7A to 7E are views illustrating a manufacturing process of a color filter substrate according to a preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 is an exploded perspective view showing a liquid crystal display according to a preferred embodiment of the present invention, Figure 2 is a perspective view showing a liquid crystal panel of a liquid crystal display according to a preferred embodiment of the present invention.

As shown in FIG. 1, the liquid crystal display device 100 includes a liquid crystal panel 110, a backlight unit 120, and a support main 130 for modularizing the liquid crystal panel 110 and the backlight unit 120. The top cover 140 and the cover bottom 150 is included.

The liquid crystal panel 110 plays a key role in image expression, and is composed of first and second substrates 112 and 114 bonded to each other with the liquid crystal layer 190 therebetween.

Referring to the liquid crystal panel 110 with reference to FIG. 2, under the premise of an active matrix method, the first substrate 112, commonly referred to as a lower substrate or an array substrate, extends in a first direction on the first transparent insulating substrate 112a. A plurality of gate lines 113 and a plurality of data lines 115 extending in a second direction orthogonal to the first direction are formed so that the plurality of gate lines 113 and the data lines 115 intersect with each other. Pixel region P is defined.

Each of the pixel regions P includes a thin film transistor TFT and a pixel electrode 117. The thin film transistor Tr includes a plurality of gate lines 113 and data lines. It is formed at the intersection of 115 so as to be in one-to-one correspondence with the pixel electrodes 117 provided in the pixel regions P.

The gate wiring 113 and the data wiring 115 mainly use a metal having excellent electrical conductivity and relatively low resistivity.

The second substrate 114, which is referred to as the upper substrate or the color filter substrate and faces the first substrate 112 having such a configuration, is disposed below the second transparent insulating substrate 114a and the data wiring 113 and the data wiring. In addition, a grid-like black matrix 122 is formed around each pixel region P to cover non-display elements corresponding to the thin film transistor Tr, and the like. A color filter layer 126 formed of red, green, and blue color filter patterns 126a, 126b, and 126c sequentially and sequentially arranged correspondingly is formed.

Here, the red color filter pattern 126a included in the color filter layer 126 has a chromaticity point of (0.641, 0.332) in the xy chromaticity coordinate system, and the blue color filter pattern 126c has an x-axis in the xy chromaticity coordinate system of 0.152 to 0.153. The y-axis ranges from 0.062 to 0.064. In addition, the green color filter pattern 126b has a x-axis ranging from 0.292 to 0.301 and a y-axis having a value of 0.607 in the xy chromaticity coordinate system.

The red color filter pattern 126a may be formed to have a chromaticity point of (0.641, 0.332) in the xy chromaticity coordinate system by appropriately mixing the R254 pigment, the R177 pigment, and the Y150 pigment in a ratio of 35:54:13. In addition, the blue color filter pattern 126c properly mixes the B15-6 pigment and the V23 pigment in a ratio of 80:20 so that the x-axis ranges from 0.152 to 0.153 and the y-axis ranges from 0.062 to 0.064 in the xy chromaticity coordinate system. Can be formed. In addition, the green color filter pattern 126b may be formed such that the x-axis ranges from 0.292 to 0.301 and the y-axis has a value of 0.607 in the xy chromaticity coordinate system by properly mixing the G58 pigment and the Y150 pigment in a ratio of 90:10. .

By forming the transparent common electrode 128 on the front surface of the color filter layer 126, a vertical electric field is generated between the common electrode 128 on the second substrate 114 and the pixel electrode 117 on the first substrate 112. The common electrode 128 may be formed on the first substrate 112 together with the pixel electrode 117 to generate a horizontal electric field.

In order to prevent leakage of the liquid crystal layer 190 interposed in the spaced apart space between the first substrate 112 and the second substrate 114, the most between the first substrate 112 and the second substrate 114. By including a seal pattern (not shown) printed along the outer edge, the first substrate 112 and the second substrate 114 are joined to form the liquid crystal panel 110.

The outer surfaces of each of the first substrate 112 and the second substrate 114 are provided with first and second polarizing plates (not shown) for selectively transmitting only specific light.

In addition, the printed circuit board 118 is connected through at least one edge of the liquid crystal panel 110 through a connecting member 116 such as a flexible circuit board or a tape carrier package (TCP). At the side of the support main 130 or the cover bottom 150 is properly folded to be in close contact.

In the liquid crystal panel 110 having the above-described structure, the thin film transistor Tr selected for each gate wiring 113 is turned on by an on or off signal of a gate driving circuit transmitted through the printed circuit board 118. When the signal voltage of the data driving circuit is transmitted to the pixel electrode 117 through the data line 115, the arrangement direction of the liquid crystal molecules is changed by the electric field between the pixel electrode 117 and the common electrode 128. Change to show the transmittance difference.

On the rear surface of the liquid crystal panel 110, a backlight unit 120 is provided to supply light so that the difference in transmittance can be displayed as an image.

The backlight unit 120 includes a light source disposed along one inner side surface of the cover bottom 150, a reflection plate 125 mounted on the cover bottom 150, and a light guide plate 123 mounted on the reflection plate 125. [ And a plurality of optical sheets 121 interposed therebetween.

An LED 129a is used as the light source, and each of the plurality of LEDs 129a is spaced apart from each other at a predetermined interval to be mounted on a printed circuit board (PCB) 129b to form an LED assembly 129.

Each LED 129a corresponds to a white LED using a green silicate phosphor on a blue chip, or a white LED using a green nitride phosphor on a blue chip. . At this time, the present invention is not limited thereto, and each LED 129a may be formed by further including not only a green phosphor but also a red phosphor. In this case, it is preferable to include phosphors of the same series (silicate or nitride).

In particular, the green phosphor has, for example, a compound structure of M ₂ SiO ₄ : Eu ²⁺ , wherein M is selected from metal elements of calcium (Ca), strontium (Sr), zinc (Zn), and barium (Ba). It may be a silicate phosphor containing one kind or two or more kinds and having a peak wavelength between 532 nm and 536 nm.

Alternatively, the green phosphor has another compound structure of CaSiN: Eu ²⁺ , CaAlSiN3: Eu ^2+, and Sr ₂ Si ₅ N ₈ : Eu ²⁺ , and among these compound structures, calcium (Ca) and strontium (Sr) And an oxynitride series containing one or two or more selected from metal elements of aluminum (Al) or elements of silicon (Si) and europium (Eu) and having a peak wavelength between 532 nm and 536 nm. It may be a nitride phosphor of.

The LED assembly 129 is fixed in position by an adhesive or the like so that the light emitted from the plurality of LEDs 129a faces the light-incoming portion of the light guide plate 123.

The light emitted from the plurality of LEDs 129a of the LED assembly 129 is indirectly supplied to the liquid crystal panel 110 by using the refraction and reflection of the light guide plate 123. [

Here, the printed circuit board 129b may correspond to a metal core printed circuit board having a heat dissipation function. A heat sink (not shown) may be provided on a rear surface of the metal core printed circuit board. Heat generated from each of the plurality of LEDs 129a may be discharged to the outside.

The reflective plate 125 reflects the light passing through the rear surface of the light guide plate 123 toward the liquid crystal panel 110 to improve the brightness of the light.

The light guide plate 123 guides light emitted from each of the plurality of LEDs 129a to serve as a high quality surface light source.

The light guide plate 123 may be made of polymethyl methacrylate (PMMA) or polymethacrylic styrene (MS) resin in which polymethyl methacrylate (PMMA) and polystyrene (PS) are mixed .

On the other hand, a pattern for guiding light may be formed on the back surface of the light guide plate 123. The pattern may be formed in the form of an embossed or embossed pattern through a printing method or an injection method, and a circular pattern, An elliptical pattern, a polygon pattern, a hologram pattern, and the like.

The plurality of optical sheets 121 interposed on the light guide plate 123 diffuse or condense the light converted into the surface light source by the light guide plate 123 so that a more uniform surface light source is incident on the liquid crystal panel 110. do.

The plurality of optical sheets 121 may be made of, for example, a diffusion sheet for diffusing light, a prism sheet for condensing light, and a protective sheet for protecting the prism sheet and serving to assist light diffusion.

As described above, the liquid crystal panel 110 and the backlight unit 120 are modularized through the support main 130, the top cover 140, and the cover bottom 150.

The top cover 140 has a rectangular frame shape in which a cross section is bent in a-shape so as to cover the front edge of the liquid crystal panel 110 and a part of the side surface of the support main 130, and the front cover 140 is implemented in the liquid crystal panel 110. Allows an image to be displayed.

The support main 130 has a rectangular frame shape and separates the liquid crystal panel 110 and the backlight unit 120 while supporting the rear edge of the liquid crystal panel 110 and covers the cover unit 150 on which the backlight unit 120 is seated. And surround the edge of the liquid crystal panel 110.

In addition, the cover bottom 150 on which the backlight unit 120 is seated and serves as the base of the entire structure of the liquid crystal display device module 100 includes four sides formed at a rectangular plate shape and the edges thereof are vertically bent. Accordingly, the LED assembly 129 is disposed along one inner side surface of the cover bottom 150.

Accordingly, the liquid crystal panel 110 and the backlight unit 120 have a top cover 140 covering the top edge of the liquid crystal panel 110 in a state where the edges are surrounded by the support main 130 having a rectangular frame shape, and the backlight unit 120. The cover bottom 150 covering the rear surface is coupled to each other in front and rear, and is integrated and modularized through the support main 130.

The light emitted from each of the plurality of LEDs 129a of the backlight unit 120 enters the inside of the light guide plate 123 and is refracted toward the liquid crystal panel 110 inside the light guide plate 123, And is supplied to the liquid crystal panel 110 while being processed into a more uniform high-quality surface light source while passing through the plurality of optical sheets 121 together with the light reflected by the plurality of optical sheets 121.

Here, the top cover 140 may be referred to as a case top or a top case, the support main 130 may be referred to as a guide panel or a main support, and a mold frame, and the cover bottom 150 may be referred to as a bottom cover.

Meanwhile, although the liquid crystal display device including the liquid crystal panel in which the color filter layer is formed on the second substrate has been described as an embodiment of the present invention, the present invention is not limited thereto, and the color filter on TFT (COT) structure in which the color filter layer is formed on the first substrate is described. The present invention can also be applied to a liquid crystal panel of the present invention.

Hereinafter, the LED and the color filter layer according to the present invention will be described in more detail with reference to the graph.

3 is a graph for comparing and explaining the emission spectrum of the backlight unit to which the LED according to the present invention is applied and the backlight unit according to the comparative example. Here, the backlight unit according to the embodiment of the present invention includes an LED having a green peak wavelength of 535 nm, and the backlight unit according to the comparative example includes an LED having a green peak wavelength of 530 nm.

As shown in FIG. 3, the emission spectrum of the comparative example shows the first to third peak wavelengths, the first peak wavelength corresponding to blue is 445 nm, and the second peak wavelength corresponding to green is 530 nm, corresponding to red. The third peak wavelength to be obtained is 630 nm.

On the other hand, in the emission spectrum of the embodiment, the first peak wavelength corresponding to blue is 445 nm, the second peak wavelength corresponding to green is 535 nm, and the third peak wavelength corresponding to red is 630 nm.

Accordingly, it can be seen that the second green peak wavelength shifted to the 5 nm long wavelength in the emission spectrum of the example.

As such, by applying the LED (129a of FIG. 2) having the green peak wavelength having a value between 532 nm and 536 nm, more preferably, 535 nm, it is possible to have excellent emission intensity and color purity.

In particular, the present invention is characterized by achieving an improved luminance and color reproducibility by applying the LED (129a of FIG. 1) and the color filter layer (126 of FIG. 2) having the appropriate color coordinates. This enables color reproducibility of over 99% based on sRGB, which represents the standard RGB color space for monitors and printers. This will be described later in detail.

 4 is a graph illustrating spectral transmittance spectra of the green color filter pattern according to the present invention and the green color filter pattern according to the comparative example. Here, the green color filter pattern to which G36 pigment and Y150 pigment were applied as a photosensitive coloring composition is called a comparative example, and the green color filter pattern to which G58 pigment and Y150 pigment was applied as a photosensitive coloring composition is called an Example.

As shown in FIG. 4, the embodiment shows that the peak emission wavelength is shifted by a shorter wavelength than the comparative example, and the spectral transmittance is higher than that of the comparative example.

In this way, the green light emitted from the LED (129a of FIG. 1) according to the present invention has a light emission intensity and color purity superior to that of the comparative example in a state shifted by about 5 nm with a longer wavelength than the green light of the comparative example.

In addition, the green light emitted from the LED (129a of FIG. 1) is shifted by about 5 nm at a short wavelength while passing through the green color filter pattern (126c of FIG. 2), so that the luminance can be improved and the color reproduction rate according to the sRGB standard can be satisfied. do.

At this time, the green color filter pattern (126c of FIG. 2) improves luminance by mixing G58 pigment and Y150 pigment at a ratio of 90:10, and complements the shifted green peak wavelength through the LED (129a of FIG. 1). It can satisfy the color reproduction rate according to sRGB standard. Here, G58 pigment has a higher transmittance than G36 pigment of the comparative example and serves to improve the brightness.

5 is a graph illustrating a green color coordinate of a liquid crystal display according to the present invention, and FIG. 6 is a graph illustrating a blue color coordinate of a liquid crystal display according to the present invention. Here, the standard representing the standard RGB color space for monitors and printers is called sRGB, and the color of green color with 530nm of green color, which is generally applied, is mixed with G36 pigment and Y150 pigment (at ratio of 43 to 57). A liquid crystal display device using a filter pattern is referred to as a comparative example. According to the present invention, a liquid crystal display device using an LED having a green wavelength of 535 nm and a green color filter pattern in which a G58 pigment and a Y150 pigment are mixed (in a ratio of 90 to 10) is applied. It is called an embodiment.

Referring to FIG. 5, the comparative example in the xy chromaticity coordinate system has a green color coordinate g1 having a chromaticity point of (0.311, 0.620) and an x axis at a chromaticity point of (0.300, 0.600) of the green color coordinate G of sRGB. It can be seen that the deviation is more than 100 and the y-axis is more than 2/100.

On the other hand, the embodiment shows that the green color coordinate g2 has a chromaticity point of (0.302, 0.608) in the xy chromaticity coordinate system and is close to the green color coordinate G of sRGB.

This applies to the LED (129a in FIG. 1) for shifting the green peak wavelength to the long wavelength as described above, and the photochromic coloration of the green color filter pattern (126c in FIG. 2) to suit such LED (129a in FIG. 1). It is implemented by formulating a composition.

On the other hand, as shown in Figure 6, the comparative example in the xy chromaticity coordinate system has a blue color coordinate (b1) has a chromaticity point of (0.152, 0.071) and y at the chromaticity point of (0.150, 0.060) of the blue color coordinate (B) of sRGB It can be seen that the axis is off by more than 1/100.

On the other hand, the embodiment shows that the blue color coordinate b2 has a chromaticity point of (0.152, 0.620) in the xy chromaticity coordinate system and is close to the blue color coordinate B of sRGB.

Accordingly, according to the present invention, a green color filter pattern (FIG. 2 of FIG. 1) and a photosensitive color composition formed to suit the LED (129a of FIG. Combining 126c) allows the chromaticity range of not only green but also blue to be closer to sRGB. Accordingly, it is possible to provide a liquid crystal display device that can achieve a color gamut of 99% or more based on the sRGB standard.

Hereinafter, a process of forming a second substrate having a color filter layer according to the present invention will be described with reference to the drawings.

7A to 7E are views illustrating a manufacturing process of a color filter substrate according to a preferred embodiment of the present invention.

As shown in FIG. 7A, after the metal material or the black resin material is coated on the transparent insulating substrate 114a, the first to third openings 160a, 160b, and 160c are sequentially repeated through photolithography. Form a Black Matrix (122).

Subsequently, as shown in FIG. 7B, one of red, green, and blue, for example, red, is formed on the insulating substrate 114a on which the black matrix 122 having the first to third openings 160a, 160b, and 160c is formed. Applying a photosensitive material to the entire surface to form a red photosensitive material layer 133a, by patterning it by proceeding a mask process, a red color on the first opening 160a of the black matrix 122 as shown in Figure 7c The filter pattern 126a is formed. Herein, the red photosensitive material is a material in which R254 pigment, R177 pigment and Y150 pigment are mixed in a ratio of 35:54:13 as a photosensitive coloring composition.

As shown in FIG. 7D, a green photosensitive material is coated on the insulating substrate 114a on which the red color filter pattern 126a is formed, and a mask process is performed on the insulating substrate 114a to pattern the red color filter pattern 126a. The green color filter pattern 126b is formed in the second opening 160b of the neighboring black matrix 122. At this time, the green photosensitive material is a photosensitive material obtained by mixing G58 pigment and Y150 pigment in a ratio of 90:10 as a photosensitive coloring composition.

In addition, the blue color filter pattern 126b is coated by applying a blue photosensitive material on the insulating substrate 114a on which the red color filter pattern 126a and the green color filter pattern 126b are formed. The blue, green, and blue color filter patterns 126a, 126b, and 126c are sequentially formed on the insulating substrate 114 by forming the blue color filter pattern 126c in the third opening 160c of the black matrix 122 adjacent to the black matrix 122. The repeated color filter layer 126 is completed. Here, the blue photosensitive material is a photosensitive material obtained by mixing B15-6 pigment and V23 pigment in a ratio of 80:20.

Subsequently, as illustrated in FIG. 7E, the planarization layer 127 may be formed to compensate for the step difference of the color filter layer 126.

The common electrode 128 of FIG. 2 may be formed on the planarization layer 127, and the common electrode 128 of FIG. 2 may be formed on the first substrate 112 of FIG. 2. .

The embodiments of the present invention as described above are merely illustrative, and those skilled in the art can make modifications without departing from the gist of the present invention. Accordingly, the protection scope of the present invention includes modifications of the present invention within the scope of the appended claims and equivalents thereof.

110: liquid crystal panel 112: first substrate (112a: first insulating substrate)
113: gate wiring 115: data wiring
114: second substrate (114a: second insulating substrate) 122: black matrix
126: color filter layer (126a: red color filter pattern, 126b: green color filter pattern, 126c: blue color filter pattern)
120: backlight unit 121: multiple optical sheets
123: Light guide plate 125: Reflective plate
129: LED assembly (129a: LED, 129b: printed circuit board)

Claims (5)

A liquid crystal panel in which red, green, and blue color filter patterns are repeatedly formed corresponding to each of the plurality of pixel regions;
It includes a backlight unit located on the back of the liquid crystal panel including a plurality of LEDs,
Each of the plurality of LEDs is a white LED applying one or more of red and green phosphors to a blue chip, wherein the green phosphor is a silicate or nitride phosphor having a peak wavelength between 532 nm and 536 nm,
Wherein the green color filter pattern has a chromaticity range of 0.292 to 0.301 in the xy chromaticity coordinate system and a chromaticity point of 0.607 in the y axis.
The method of claim 1,
The green phosphor is M ₂ SiO _4: having a compound structure of Eu ^{2 +} the compound structure of the M is selected from a metal element calcium (Ca), strontium (Sr), zinc (Zn) and barium (Ba) 1 kind or A liquid crystal display device which is a silicate phosphor containing two or more kinds.
The method of claim 1,
The green phosphor is CaSiN: Eu ^{2 +,} CaAlSiN3: Eu ^{2 +} and Sr ₂ Si ₅ N _8: has a single compound structure of Eu ^{2 +} the compound structure of calcium (Ca), strontium (Sr), and aluminum (Al A liquid crystal display device comprising an oxy nitride-based nitride phosphor containing one or two or more selected from metal elements of silicon or elements of silicon (Si) and europium (Eu).
The method of claim 1,
Wherein the green color filter pattern is formed of a photosensitive material obtained by mixing G58 pigment and Y150 pigment in a ratio of 90:10.
The method of claim 1,
The blue color filter pattern has a chromaticity range of 0.152 to 0.153 in the x-axis and a y-axis of 0.062 to 0.064 in the xy chromaticity coordinate system.

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