KR100297943B1 - Method for forming multi-domain of liquid crystal alignment layer using interferencing system - Google Patents

Abstract

The present invention discloses a multi-domain alignment method of a liquid crystal alignment film using an interferometer.

The present invention is a method of depositing a transparent electrode on a glass substrate and applying a liquid crystal photoalignment film made of a photofunctional polymer thereon to multi-orientation by a non-contact method, the method comprising the steps of making an interference fringe generated by an interferometer, the direction of the glass substrate Irradiating the interference pattern is adjusted to the optical alignment layer while twisting in any one direction, and irradiating the interference pattern by moving the position of the glass substrate while twisting the glass substrate in the opposite direction.

According to the present invention, the light itself having the interference pattern irradiated on the photo alignment layer serves as a mask, thereby creating a multi-alignment state in which small regions having different alignment directions are periodically generated, thereby widening the viewing angle of the liquid crystal display device.

Description

Multi-area formation method of liquid crystal alignment layer using interferometer {METHOD FOR FORMING MULTI-DOMAIN OF LIQUID CRYSTAL ALIGNMENT LAYER USING INTERFERENCING SYSTEM}

The present invention relates to a liquid crystal alignment layer for orienting liquid crystal molecules of a liquid crystal display device, and more particularly, to a method for forming a multi-region of a liquid crystal alignment layer using an interferometer that can be multi-aligned using a mask through an interference pattern of light. will be.

Currently, the alignment film used in LCD is mostly polyimide, and is manufactured by a rubbing method of rubbing the surface of the alignment film with cotton or nylon fibers. The rubbed alignment film has an anisotropic intramolecular reaction between the alignment film and the liquid crystal molecules to align the liquid crystal molecules in the rubbing direction.

This rubbing method is easy to handle orientation and is suitable for mass production, but it is difficult to finely control the degree of orientation because it is difficult to finely control process variables related to rubbing. And there is a problem of lowering the production rate, such as scratching.

Further, there is a problem that the viewing angle is narrow because the alignment direction of the alignment film is unidirectional or bidirectional.

Recently, in order to solve the problem of the viewing angle, a method of manufacturing an alignment layer that does not include physical contact is OCB (optically compensated birefringence), IPS (in-plan switching), VA (vertical alignment), SEM (surrounding electronic method) The multi-domain method has been studied.

In particular, the multi-region forming method is a process of forming a polyimide film or a photo alignment layer in a predetermined direction, and attaching or detaching a patterned mask in the multi region so that the polyimide layer is oriented by several rubbing and the photo alignment layer is oriented by several exposure processes. It is a method of widening the viewing angle by manufacturing a liquid crystal display device by making a state in which small regions having different directions are periodically generated.

In this case, the rubbing method causes a problem in that the yield decreases due to the direct contact several times, and it is impossible to control the fine pixels, and in the case of the photo-alignment film, it is generally known that the alignment is performed in a multi-step using a patterned mask. When the alignment film is produced by the torsion angle forming method, a desired alignment state cannot be obtained due to diffraction, interference, and scattering effects due to light.

That is, since the polyimide multi-domain alignment layer of the rubbing method uses a mask made of multi-regions, the surface unevenness is caused by rubbing, resulting in a drop in yield and defects in manufacturing a liquid crystal display device. Since the rubbing needs to be performed several times in different directions, the manufacturing process is complicated.

In addition, in the multi-directional alignment method of the optical alignment layer, it is also inconvenient to use a different mask to control the size of the pixel with a number of alignment operations, and even in the case of non-contact optical alignment, the interference of light and diffraction or other causes during exposure are caused. There are many factors that can prevent the smooth alignment process.

Accordingly, an object of the present invention is to provide a method for forming a multi-region of a liquid crystal alignment layer having a wide viewing angle by allowing light to act as a mask by using interference properties of light.

In order to achieve the above object, the present invention provides a method of multi-aligning a liquid crystal photoalignment layer made of a photofunctional polymer by a non-contact method, comprising: irradiating an optical alignment layer by making an interference pattern using an interferometer from a light source, Twisting the direction of the substrate on which the photoalignment film is formed in one direction when irradiating the photoalignment film to form a twist angle θ in the photoalignment film of the portion where the interference pattern is exposed, and exposing the portion where the interference pattern is not exposed. Repositioning the substrate so as to be possible, and then twisting the substrate in an opposite direction to form a twist angle (−θ) in the opposite direction to the photo alignment layer.

According to the present invention as described above, the light having the interference pattern irradiated onto the photoalignment layer serves as a mask, and thus the primary alignment is made in a portion corresponding to the bright portion of the interference pattern, and the position of the glass substrate corresponds to the dark portion. A secondary orientation is made in the part, where multiple orientations are made in which the twist angle is periodically repeated by twisting the glass substrate in the opposite direction.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the invention described below with reference to the accompanying drawings by those skilled in the art.

1 is a chemical structural formula of an alignment material used in the present invention,

2 is an interferometer device for forming an interference fringe according to the present invention;

3 is a conceptual diagram illustrating a method of forming a shape and a twist angle in which an interference fringe is formed on an alignment layer substrate according to the present invention;

4 is a conceptual diagram illustrating, in pixel units, an orientation direction and a twist angle of an upper substrate and a lower substrate according to the present invention;

5A to 5D are micrographs of pixel multi-division liquid crystal devices of various sizes according to the present invention.

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

One ; Light source 10; Board

11; Interference pattern 12; Alignment film

13; Transparent electrode 14; Glass substrate

Hereinafter, a method of forming a multi-region of a liquid crystal alignment layer using an interferometer will be described in detail with reference to the accompanying drawings.

Figure 1 shows the chemical structural formula of the alignment material used in the present invention, which consists of a main chain and a side chain and contains azo benzene (azo-benzene) in the main chain.

It is a structure that can control the magnitude of the pre-tilt angle by adjusting the ratio as a copolymer (copolymer).

Figure 2 is an interferometer device for forming an interference fringe according to the present invention, the interferometer used in the present invention is a Mach Gender interferometer and the interference fringe is caused by the path difference between the two light is divided into two light from one light source It is a two-light interferometer.

Theoretically, the distance between the interference patterns caused by the two lights can be expressed by the following equation.

Where Λ _g ; Distance between interference fringes, λ; Wavelength of the light source, θ; It means the angle where two lights meet.

According to Equation 1, it can be seen that the spacing of the interference fringe can be arbitrarily changed by the wavelength and the incident angle. In the interferometer of the present invention, since the two lights meet at a right angle, the width of the interference fringe becomes very large when the above equation (1) is applied. In order to prevent this, a slight change in the incident angle of the interferometer may be visible. A degree of interference fringe can be obtained. In order to obtain an arbitrary interference fringe or to obtain a submicron interference fringe spacing, the interferometer illustrated in FIG. 2 may be modified, for example, as an interferometer such as a two wave mixing method. An interference fringe of size can be obtained according to the angle of incidence.

On the other hand, the light emitted from the argon laser light source (1) can be adjusted to various polarizations through the wave plate (3, 5) and the polarizing plate (4), the light source is enlarged and the wavefront is arranged through the spatial filter (6) . The light source thus formed is divided into two lights through the first light guide 8, collected at the second light guide 8 ′, and irradiated onto the substrate 10 through the lens 7 ′. When irradiated, interference fringes produce clear stripes in bright and dark areas.

Reference numeral 2,2 'is a pinhole, 7 is a lens, 9,9' is a mirror.

3 is a conceptual diagram illustrating a method of forming a shape and a twist angle at which an interference fringe is formed when an alignment layer substrate is oriented according to the present invention. The transparent electrode 13 is deposited on a glass substrate 14 and the glass substrate ( 14) a substrate 10 having a photo alignment layer 12 formed thereon is prepared.

The bright part of the interference fringe 11 irradiated onto the substrate 10 is an exposed part and the dark part is an unoriented part, and the substrate 10 is turned clockwise or anticlockwise to give the twist angle θ. Keep it twisted clockwise. At this time, the twist angle θ is formed in the twisted direction. After the alignment is completed, the position of the substrate 10 is shifted and exposed again in the same manner for the orientation of the unaligned portion, and twisted in the opposite direction to the existing torsion angle θ direction. Get) As described above, multiple photoalignments are performed in which the twist angles θ and −θ of the opposite directions are periodically intersected with the liquid crystal alignment layer.

4 shows a domain generated when a TN cell is made of a substrate according to the present invention, and shows the orientation direction and the twist angle of the lower substrate and the upper substrate.

Arrow 15 shows the orientation direction and the twist angle direction of the lower substrate, arrow 16 shows the orientation direction and twist angle direction of the upper substrate.

5A to 5D show micrographs of pixel multi-stage liquid crystal devices of various sizes according to the present invention. FIG. 5A is a 50 times magnification of a TN liquid crystal display device, and cross fringes are clearly shown. 5B and 5C are photographs taken of the same display device, each magnified by 50 times so that the size of the pixel can be recognized by attaching a ruler next to each other. 5D is a 50x magnification of the liquid crystal display device.

As described above, since the present invention is made in a non-contact manner compared to the conventional alignment method of attaching or detaching a patterned mask to a multi-region to form a multi-domain orientation by several rubbing processes, the yield is improved and the micro pixels can be controlled. .

In addition, compared to the conventional optical alignment method of forming a multi-domain orientation by multiple exposure processes using a mask patterned into a multi-domain, it is possible to minimize the influence of light interference, diffraction and scattering.

In the above description, it should be understood that those skilled in the art can only make modifications and changes to the present invention without changing the gist of the present invention as it merely illustrates a preferred embodiment of the present invention.

According to the present invention, a light itself having an interference pattern irradiated to the photo alignment layer serves as a mask, thereby creating a multi-alignment state in which small regions having different alignment directions are periodically generated, thereby widening the viewing angle of the liquid crystal display device. The effect is to prevent problems that may occur.

Claims (1)

In the method of multi-aligning the liquid crystal photoalignment film made of a photofunctional polymer by a non-contact method, Irradiating the optical alignment layer by forming an interference fringe using an interferometer from a light source, Twisting the direction of the substrate on which the photoalignment layer is formed in one direction when irradiating the interference alignment layer to form a torsion angle θ in the photoalignment layer of the portion where the interference pattern is exposed; And repositioning the substrate so that the portion where the interference fringe is not exposed is exposed and twisting the substrate in an opposite direction to form a twist angle (−θ) in the opposite direction to the photo alignment layer. Multi-region formation method of the used liquid crystal aligning film.