KR20000046921A - Polarization film using cholesteric liquid crystal and liquid crystal display device - Google Patents

Abstract

PURPOSE: A polarization film using cholesteric liquid crystal and a liquid crystal display device are provided to manufacture a film with lambda/4 phase difference in order to user the film to manufacture the liquid crystal display device according to the present invention. CONSTITUTION: A polarization film using cholesteric liquid crystal according to the present invention is manufactured by accumulating the cholesteric liquid crystal film(5) and a phase difference film(6) with lambda/4 phase difference. The cholesteric liquid crystal film(5) selectively reflects component in the band of visual light. The cholesteric liquid crystal film(5) further is accumulated as one or more than 2 cholesteric liquid crystal film(5) on the polarization film.

Description

Polarizing film and liquid crystal display using cholesteric liquid crystal

The present invention relates to a polarizing film and a liquid crystal display device using a cholesteric liquid crystal, and particularly to a method for preventing color change according to the viewing angle of the cholesteric liquid crystal film using a retardation film and to manufacture a high brightness liquid crystal display device using the same. It is about.

By using the cholesteric liquid crystal, a high brightness liquid crystal display device can be realized by greatly improving the disadvantages of the conventional liquid crystal display device (LCD).

The cholesteric liquid crystal as described above has a selective reflection characteristic in which the twisted direction of the helical structure of the liquid crystal coincides with the circular polarization direction, and the wavelength reflects only light of circular light such as the spiral pitch of the liquid crystal.

In addition, when the polarizing film or the color filter is manufactured using the cholesteric liquid crystal, the light reflected by the selective reflection characteristic may be recycled, thereby enabling the implementation of a high brightness liquid crystal display device.

USP 5506704, USP5691789, Korean Patent Application Nos. 97-38643, 98-498 and 98-14214 describe a method of increasing the light efficiency of a liquid crystal display using cholesteric liquid crystal.

By the way, the cholesteric liquid crystal has a characteristic that the color of the light reflected or transmitted changes depending on the viewing angle.

When light is incident on the cholesteric liquid crystal having a pitch of P, the path difference of the light according to the incident angle θ is expressed as P cosθfh, and the light of the wavelength consistent with this path difference is reinforced and strongly reflected by the Bragg reflection condition. do.

This means that as the angle of incidence increases, the path difference decreases and light of short wavelength is reflected.

Therefore, when a liquid crystal display is manufactured by applying a polarizing film or a color filter made of cholesteric liquid crystal, color change occurs according to a viewing angle.

Currently, liquid crystal displays are becoming larger, and wide viewing angles are indispensable in large liquid crystal displays.

Therefore, a cholesteric liquid crystal polarizing film or color filter in which color change occurs depending on the viewing angle is not applicable to a liquid crystal display device requiring a wide viewing angle.

In the present invention, by producing a λ / 4 retardation film having a function of compensating the color change according to the viewing angle in addition to the function of converting the circularly polarized light to linearly polarized light by a method of adjusting the refractive index of the film, by using a wide viewing angle characteristic is required A cholesteric liquid crystal polarizing film and a color filter which can be used in a liquid crystal display are manufactured.

1 is a reflection UV-VIS spectrum according to the viewing angle of cholesteric liquid crystal

2 is a change of Δn'd with the viewing angle.

3 is a cross-sectional structure diagram of a liquid crystal display of the present invention.

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

1: lamp 2: reflector

3: light guide plate 4: diffuser plate

5: cholesteric liquid crystal film 6: retardation film

7: linear light film 8: liquid crystal cell

Hereinafter, the present invention will be described in more detail.

Since the current liquid crystal display uses linear polarization, a cholesteric liquid crystal polarizing film or a color filter should use a retardation film that converts circular polarization into linear polarization. In the liquid crystal display, the mounting position is directly below the linear polarization film. Becomes

The cholesteric liquid crystal has a characteristic of changing the color of reflected or transmitted light depending on the viewing angle due to the regularity of the spiral structure.

Figure 1 shows the characteristics of such a cholesteric liquid crystal.

A quarter-phase retardation film that converts circular polarized light that has passed through cholesteric liquid crystal into linear polarized light is generally manufactured by biaxially stretching a polymer film having a high light transmittance such as PVA or PC. (n _x ) adjusts the y-direction refractive index (n _y ) to adjust the center wavelength.

At this time, the formula applied is Δnd = λ / 4.

(Where Δn is the birefringence of the film surface, d is the thickness of the film, and λ is the wavelength).

Therefore, when manufacturing the lambda / 4 phase difference film to adjust the biaxial stretching ratio to the desired center wavelength, the refractive index (n _z ) in the film thickness direction is not considered.

In the case of the retardation film manufactured as described above, when the viewing angle is increased, the path difference Δn'd value (where Δn 'represents the birefringence including the film thickness surface and the refractive index n _{z in the} thickness direction) is changed. The circularly polarized light cannot be converted into linearly polarized light, but is converted to elliptical polarized light.

This elliptical polarization causes light loss when passing through the linear polarizing film, thereby lowering the efficiency of the cholesteric liquid crystal polarizing film and causing color change.

In order to prevent this phenomenon, it is important to maintain the Δn'd value, which is related to the refractive index n _{z in the} film thickness direction.

In addition, the direction of refraction of light passing through an anisotropic material such as cholesteric liquid crystal or nematic liquid crystal is affected by n _z .

Therefore, it is possible to prevent the color change according to the viewing angle of the light passing through the cholesteric liquid crystal and to maintain the Δn'd value to increase the efficiency of the retardation film by a method of adjusting the n _z value.

The property of the film having anisotropy can be expressed by the ratio N _r of the birefringence in the thickness direction and the birefringence in the plane as follows.

N _r = (n _x -x _z ) / (n _x -n _y )

2 shows the angle-specific characteristics of Δn'd according to the N _r value.

As can be seen from the figure, the Δn'd value increases or decreases as the viewing angle increases according to the N _r value.

Therefore, by adjusting the N _r value, the wavelength range for converting the circularly polarized light into linearly polarized light can be adjusted according to the viewing angle, and the color change can be compensated for.

Therefore, if the cholesteric liquid crystal polarizing film and the color filter are manufactured using the lambda / 4 phase difference film having an appropriate N _r value, it can be applied to a large area liquid crystal display device requiring a wide viewing angle characteristic, so a large area high brightness liquid crystal display device Can be implemented.

The present invention uses a cholesteric liquid crystal having a left helical structure to produce a color filter such that the color of light transmitted is red, green, and blue.

A cholesteric liquid crystal color filter is prepared by bonding a retardation film having a center wavelength of 530 nm and a N _r value of 0.5, prepared by biaxially stretching a PVA film.

Then, the cholesteric liquid crystal polarizing film in which the selective reflection wavelength region includes the visible light region is laminated by stacking cholesteric liquid crystal films having a preferential spiral structure having different selective reflection wavelength regions.

The prepared cholesteric liquid crystal polarizing film is inserted between the diffuser plate of the liquid crystal display and the lower linear polarizing film, and the cholesteric liquid crystal color filter is attached by bonding to the lower linear polarizing film.

The cross-sectional structure of the liquid crystal label device thus manufactured is shown in FIG. 3.

3 is a cross-sectional structure diagram of a liquid crystal display device manufactured using the present invention, wherein 1 is a lamp, 2 is a reflector, 3 is a light guide plate, 4 is a diffuser plate, 5 is a cholesteric liquid crystal film, and 6 Is a retardation film, 7 is a linear light film, and 8 has shown the liquid crystal cell.

In the case of using the cholesteric liquid crystal color filter, the cholesteric liquid crystal polarizing film having the opposite helical direction must be used together to make the transmitted color clear, and linearly polarized light because the reflected light must be recycled unlike the conventional absorption type color filter. It should be located just below the membrane.

As shown in the figure, when the non-polarization (c) light from the light source passes through the cholesteric liquid crystal film of the preferential spiral structure, the right circular polarization (b) light is reflected and the left circular polarization (c) light is transmitted.

The transmitted left circularly polarized light reflects light of a wavelength not transmitted by the cholesteric liquid crystal color filter and is recycled because the polarization direction is changed in the reflecting plate.

At this time, the light passing through the color filter is converted into linearly polarized light through the retardation film is incident to the liquid crystal cell.

As such, when the cholesteric liquid crystal color filter and the polarizing film are used together, the luminance is increased by 2.5 times or more than the conventional absorption type color filter and the linear polarizing film, and color reversal does not occur to the left and right 45 degrees or more.

As described above, the present invention produces a lambda / 4 phase difference film having a function of compensating for the color change according to the viewing angle in addition to the function of converting the circularly polarized light to linearly polarized light by the method of adjusting the refractive index of the film, The present invention provides an effect of manufacturing a cholesteric liquid crystal polarizing film and a color filter which can be used in a liquid crystal display device requiring viewing angle characteristics.

Claims (8)

A polarizing film, which is prepared by laminating a cholesteric liquid crystal layer and lambda / 4 phase difference film to selectively reflect the visible light region. The polarizing film of claim 1, wherein the cholesteric liquid crystal layer is composed of a single layer or two or more cholesteric liquid crystal layers. The polarizing film of claim 1, wherein the cholesteric liquid crystal layer is made of a material having cholesteric liquid crystalline properties and having a polymerizable functional group. The polarizing film of claim 1, wherein the ratio of the birefringence in the thickness direction to the birefringence in the plane (N _r ) is 0.3 to 0.8. The liquid crystal display of claim 1, wherein the manufactured polarizing film is positioned between a lower linear polarizer of the liquid crystal cell and a backlight including a reflector, a light source, a light guide plate, and a diffuser plate. The liquid crystal display device according to claim 1 or 5, wherein the manufactured polarizing film is bonded to the lower linear polarizer of the liquid crystal cell. Preparing a cholesteric liquid crystal layer to transmit red, green, and blue light, respectively; A color filter is prepared by laminating the? / 4 retardation film thereon; Placing the manufactured color filter under the lower linearly polarizing plate of the liquid crystal cell; Preparing a cholesteric liquid crystal film that selectively reflects a visible light region using a cholesteric liquid crystal having a spiral structure opposite to that of the manufactured color filter; The liquid crystal display device, characterized in that the liquid crystal film is located between the backlight and the color filter consisting of a reflector, a light source, a light guide plate, a diffusion plate. 8. The liquid crystal display device according to claim 7, wherein the ratio of the birefringence in the thickness direction to the birefringence in the plane (N _r ) is 0.3-0.8.