KR101565010B1 - Polarizer and in-plane switching mode liquid crystal display comprising the same - Google Patents

Abstract

The present invention relates to a polarizing plate comprising a positive biaxial A plate, a negative biaxial A plate designed to be suitable for a vertical alignment (VA) mode, a polarizer and a protective layer in this order, The present invention relates to a planar switching mode liquid crystal display device which is suitable for mass production and which can secure a wide viewing angle compared to the prior art, since the same plate can be used regardless of the mode of a liquid crystal cell.

Plane switching mode, liquid crystal display, polarizer

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a polarizing plate, and a planar switching mode liquid crystal display including the polarizing plate.

The present invention relates to an in-plane switching (IPS) mode in which a negative biaxial A plate designed for a vertical alignment (VA) mode is applied to a planar switching (IPS) mode to simplify a plate production process and secure a wide viewing angle. Quot;) mode liquid crystal display device.

2. Description of the Related Art A liquid crystal display (LCD) is widely used as a popular image display device. However, despite its many excellent properties, a narrow viewing angle has been pointed out as a typical drawback. (VA mode) and a surface-switching mode (IPS mode) in a liquid crystal driving mode of a wide viewing angle, and a technique for securing a wide viewing angle by applying a functional optical film such as a liquid crystal driving mode and a retardation film. Is widely used.

In the vertical alignment mode (VA Mode), a liquid crystal having a negative dielectric anisotropy is injected between upper and lower substrates, and a black is implemented by arranging the liquid crystal in a vertical direction in an electric field non-applied state. The liquid crystal having a negative dielectric anisotropy is realized by being laid down. In this case, since there is almost no influence of the phase difference due to the liquid crystal in the black state at the front, it is possible to realize a full black (black), so that the front contrast ratio is the highest among the existing liquid crystal display devices. On the slope, however, the change of the polarization state due to the liquid crystal is severe, and a compensation film for wide viewing angle is necessarily required.

In the surface switching mode (IPS Mode), a liquid crystal having a positive (+) dielectric anisotropy is injected between the upper and lower substrates to align the liquid crystal in the in-plane direction. In this case, the long axis of the refractive index of the liquid crystal is parallel or orthogonal to the absorption axis of the vertical polarizer in the absence of the electric field, and the white is implemented by switching the liquid crystal by applying the electric field in the diagonal direction. Since the change of the polarization state due to the liquid crystal in the black state in the slope is smaller than that in the other liquid crystal display mode, the slope arm implementation is the most excellent among the existing liquid crystal modes and has the widest viewing angle. Therefore, the liquid crystal display device of the liquid crystal display device can obtain a viewing angle of some degree without using an optical film, and it is possible to realize an excellent image quality even on a sloped surface due to a small change in image quality due to a change in viewing angle. In recent years, since an image display device such as a large-sized TV adopting a surface switching mode is manufactured, a wider viewing angle characteristic is required, and thus the application of a wide viewing angle compensation film is gradually increasing.

In the two liquid crystal display device modes, the retardation film applied to the polarizing plate has completely different optical characteristics for securing a viewing angle. That is, since the liquid crystal mode has a completely different optical characteristic such as the alignment direction of the liquid crystal, it is common to use a retardation film separately for securing an effective viewing angle. In this case, mass production is not easy in manufacturing a composite polarizing plate including a retardation film, and various types of retardation films are applied as much as various liquid crystal modes.

Therefore, it is possible to apply the same polarizing plate regardless of the liquid crystal mode together with various compensation structures for securing an excellent viewing angle, and to easily manufacture a composite polarizing plate including a retardation film by using a roll-to-roll production mode A new polarizing plate structure capable of mass production is desperately required.

The present invention attempts to solve the problem of productivity of the polarizing plate manufactured and used in accordance with the liquid crystal mode, and the light leakage phenomenon that occurs due to the absorption axis compensation of the polarizer in the conventional plane switching liquid crystal display.

Therefore, the present invention introduces a negative biaxial A plate developed to be suitable for a vertical alignment (VA) mode for securing a viewing angle into a planar switching (IPS) mode, and changes polarizations due to the introduced negative biaxial A plate The absorption axis of the polarizing plate according to the present invention can be compensated to an optimum range to reduce the total amount of light leaking from the inclined surface to secure a wider viewing angle than in the prior art. The same plate can be used regardless of the liquid crystal mode, And to propose a polarizing plate which can be mass-produced by using the production mode. Specifically, by using a polarizing plate in which a positive biaxial A plate, a negative biaxial A plate designed to be suitable for the vertical alignment (VA) mode, a polarizer and a protective layer are sequentially laminated from the liquid crystal cell side to the plane switching mode liquid crystal display, And to provide a liquid crystal display device of a planar switching mode which realizes a wider viewing angle and a clearer image than the conventional one.

The present invention relates to a polarizing plate for IPS mode in which a positive biaxial A plate, a negative biaxial A plate, a polarizer and a protective layer are laminated in this order from the liquid crystal cell side, wherein the positive biaxial A plate has a front retardation value R0) is 45 to 65 nm, the refractive index ratio (NZ) is -3? NZ? -1, the slow axis is orthogonal to the absorption axis of the adjacent polarizer; Wherein the negative biaxial A plate has a front retardation value R0 of 40 to 65 nm, a refractive index ratio NZ of 2? NZ? 4 and an average refractive index of (Nx + Ny + Nz) / 3 of 1.45 to 1.55 (550 nm) / R0 (700 nm)] is 0.95 to 1.002, and the slow axis is the absorption axis of the adjacent polarizer and the phase difference wavelength dispersion is [R0 (400 nm) / R0 (550 nm)] is 0.91 to 1.005, And the polarizing plate is configured to be orthogonal to the polarizing plate.

In addition, the present invention is further characterized in that the IPS mode liquid crystal display device includes the polarizing plate as a lower plate or a top plate polarizer.

The planar switching mode liquid crystal display device according to the present invention includes a polarizing plate laminated in order of a positive biaxial A plate, a negative biaxial A plate designed for a vertical alignment (VA) mode, a polarizer and a protective layer from a liquid crystal cell side By making it possible to realize a perfect dark state in all directions, it is possible to have a wider viewing angle than the conventional one, and it is possible to use the same retardation plate in other liquid crystal modes, thereby facilitating raw material supply, process control and mass production, It is easy to adjust the amount of water.

The present invention relates to a polarizing plate in which a negative biaxial A plate developed for a vertical alignment mode is applied to a planar switching mode. By introducing the plate for the vertical alignment mode, the durability of the polarizing plate can be improved, And a positive biaxial A plate having specific physical properties together with the plate developed for the vertical alignment mode is combined to reduce the total amount of light leaking to enable a dark state to be realized at a front viewing angle. This polarizing plate is composed of a positive biaxial A plate, a negative biaxial A plate, a polarizer and a protective layer laminated in this order from the liquid crystal cell side.

The term 'negative biaxial A plate' in this specification refers to a positive (+) biaxial optical element theoretically having a refractive index distribution satisfying Nx> Ny> Nz. Here, the positive (+) biaxial optical element in the present invention means a material having a large refractive index in the stretching direction. Also, 'POSITIVE BIAXIAL A plate' refers to a negative biaxial optical element satisfying Nz> Nx> Ny, which is also referred to as a 'positive B plate'. Herein, the term (-) optical element in the present invention means a material whose refractive index decreases in the stretching direction.

In general, the negative biaxial A plate is stacked on the upper and lower polarizing plates in the vertical alignment mode (VA Mode) liquid crystal display, one between the liquid crystal layer and the polarizer, and the optimal front retardation R0 and NZ The value is determined by? Nd of the liquid crystal layer.

5 is a graph showing the relationship between the retardation value (DELTA nd) of the liquid crystal layer on the light source 589.3 nm, specifically the wavelength of 550 nm at which the human is most bright with respect to 310 nm, (b) 290 nm, The change in polarization state in the direction of the inclined plane [theta] = 60 [deg.] And [Phi] = 45 [deg.] When lamination of the smallest negative biaxial A plate is shown on the Poincare Sphere. This is because the optimal retardation R0 and the refractive index ratio NZ of the negative biaxial A plate in each of (a), (b) and (c) as the cell phase difference value in the current VA mode liquid crystal display ) Values are (a) R0 = 48nm, NZ = 3.5, (b) R0 = 52nm, NZ = 3, (c) R0 = 57nm and NZ = 2.5. At this time, the negative biaxial A plate is used in a vertically aligned mode VA mode liquid crystal display device in which a liquid crystal layer and a polarizer are stacked one by one on a vertical polarizer.

Specifically, when the polarized state changes on the Poincare Sphere of FIG. 5 as it passes through the polarizer of the lower polarizer, it passes through the negative biaxial A plate laminated on the polarizer of the polarizer 1 and the polarizer of the lower polarizer, When passing through the cell, it passes through the polarized state 3, the negative biaxial A plate located between the polarizer of the upper plate polarizer and the liquid crystal cell, and changes into the polarization state 4. The polarization state 4 is a state in which the polarization plane coincides with the absorption axis of the polarizer of the upper plate polarizer It is linearly polarized light, and most of it is absorbed by the polarizer of the top plate polarizer and can realize black. However, by applying the retardation films of (a), (b), and (c) above, excellent blackness can be maintained even on a slope, and the viewing angle is wide. However, since the relative transmittance varies with wavelength, Visibility Maximum transmittance is optimal, but it appears to be colored by light, so use a range slightly out of optimal value. Specifically, in consideration of the wavelength dispersion of the retardation film of the present invention, it is preferable that the front retardation R0 is within ± 10 nm and the refractive index ratio (NZ) is within ± 0.5 at the optimum value of transmittance for visible ray transmittance.

Therefore, it is preferable that the negative biaxial A plate of the present invention also consider optical properties such as average refractive index and wavelength dispersibility in order to offset the color expression in addition to the optimal front retardation (R0) and refractive index ratio (NZ) range. The negative biaxial A plate of the present invention has a retardation value R0 of 40 to 65 nm, a refractive index ratio NZ of 2? NZ? 4 and an average refractive index of (Nx + Ny + Nz) / 3 of 1.45 to (R0 (589 nm) / R0 (700 nm)] is 0.95 to 1.002, and the retardation in the process is in the range of 1.55 to 1.55, and the wavelength dispersibility is 0.91 to 1.005 in [R0 The refractive index ratio (NZ) is preferably 2.5 to 3.5, and the average refractive index [(Nx + Ny + Nz) is preferably in the range of ) / 3] is in the range of 1.47 to 1.54. The slow axis of such a negative biaxial A plate is configured to be orthogonal to the absorption axis of an adjacent polarizer when viewed from the viewer side.

The negative biaxial A plate can use a triacetyl cellulose (TAC) system or a cycloolefin polymer (COP) system. In order to realize a wide viewing angle within the optical property range, the most widely used film material is triacetylcellulose TAC) system. The triacetylcellulose (TAC) system is prepared by adding various additives generally used in the art to facilitate the phase difference development. Preferably, triacetyl cellulose (TAC) is preferably used because it can realize a certain degree of reverse wavelength dispersion and thus has excellent coloring properties. Generally, products such as 'N-TAC' (KONICA, JAPAN) and 'V-TAC' (FUJI, JAPAN) are widely used for securing the viewing angle in the vertical alignment (VA) liquid crystal mode by triacetyl cellulose (TAC) system.

The present invention is based on the idea that a positive biaxial A plate is laminated on the liquid crystal cell side of a composite polarizing plate of the upper plate in which the negative biaxial A plate for the VA mode is stacked to realize a wide viewing angle in the IPS mode Thereby producing a polarizing plate.

FIG. 6 is a graph showing the results of applying a negative biaxial A plate applied to the vertical alignment mode in which the cell retardation values are (a) 310 nm, (b) 290 nm and (c) The polarization state change in the direction of the inclined plane? = 60 占 and? = 45 占 is shown on the Poincare Sphere. The change in polarization state on the Poincare Sphere in Fig. 6 indicates a state of polarization 1 when passing through the polarizer of the lower plate polarizer, a polarization state 2 when passing through the isotropic protective layer of the lower plate polarizer, an alignment direction of the liquid crystal When passing through a 90-degree S-IPS (LG Display) liquid crystal cell, when it passes through the polarized state 3, the positive biaxial A plate of the upper polarizer plate and the negative biaxial A plate of the upper polarizer plate 4, And the polarized state 5 is linearly polarized light whose polarization plane coincides with the absorption axis of the polarizer of the upper plate polarizer, and most of the linearly polarized light is absorbed by the polarizer of the upper plate polarizer to realize black.

(A) R0 = 45 nm, NZ = -2.5, (b) Ro = 50 nm NZ = -2, (c) R0 = 55 nm, and NZ = -1.5. However, when the retardation film is applied as it is, excellent blackness can be maintained even on a slope, and a wide viewing angle can be secured. However, since the relative transmittance varies with wavelength depending on the viewing angle, Use an off value. Specifically, it is preferable that the optimum value is within the range of the frontal retardation R0 within ± 10 nm and the refractive index ratio NZ within ± 0.5.

In the present invention, a polarizing plate in which a negative biaxial A plate designed to be suitable for a positive biaxial A plate and a VA mode from a liquid crystal cell side is laminated is used as a top plate of a liquid crystal display (S-IPS liquid crystal cell) as well as a lower plate polarizing plate (FFS liquid crystal cell). Specifically, when the present invention is applied to a lower plate polarizing plate, it is possible to manufacture a composite polarizing plate having a wide viewing angle for an FFS liquid crystal cell mode having a liquid crystal alignment direction of 0 degrees as viewed from the viewer side. The optical properties required for the positive biaxial A plate are the same as those in Fig. 6, since they have point symmetry with respect to -S2 (Stokes parameter (1,0, -1,0)) in the curved sphere.

The positive biaxial A plate of the present invention has a front retardation (R0) of 45 to 65 nm and a refractive index ratio (NZ) of -3? NZ? -1. The refractive index ratio (NZ) is in the range of -2.5? NZ? -1.0, more preferably the front retardation value (R0) is in the range of 45 to 55 nm, and the refractive index ratio -2.5? NZ? -1.5. The slow axis of this positive biaxial A plate is configured to be orthogonal to the absorption axis of the adjacent polarizer.

The positive biaxial A plate may have a structure in which polymethylmethacrylate (PMMA), polystyrene (PS) and polymethylmethacrylate (PMMA) are sequentially laminated or a structure in which at least one layer is modified polycarbonate (PC) have. Further, the positive biaxial A plate is not limited to the material as long as it satisfies the optical characteristics within the range defined by the present invention, and is applicable to the present invention. Specifically, it is possible to use polyacetal such as triacetylcellulose (TAC), cycloolefin polymer (COP), cycloolefin copolymer (COC), polyethylene terephthalate (PET), polypropylene (PP), polycarbonate (PC) Methyl methacrylate (PMMA) may be used.

In this case, the region that can be compensated when the IPS mode is applied using the negative biaxial A plate and the positive biaxial A plate is shown in Fig. 7 for the S-IPS liquid crystal cell and in Fig. 8 for the FFS liquid crystal cell.

The present invention can produce a wide view angle polarizing plate for a planar switching mode by stacking a positive biaxial A plate on a wide viewing angle polarizer applied to a vertical alignment mode, thereby enabling a wide viewing angle for a planar switching mode in which production control is easy and a wide viewing angle characteristic is required There is an advantage that a polarizing plate can be produced.

The polarizing plate manufactured according to the present invention is laminated on an upper plate or a lower plate to constitute a liquid crystal display of a planar switching (IPS) mode. At this time, the liquid crystal display of the present invention includes aligning the liquid crystal in a multi-domain or dividing the liquid crystal into multiple regions by a voltage applied thereto. In a liquid crystal display device, in-plane switching (IPS) is classified into Super-In-Plane-Switching (FIPS) and Fringe-Field-Switching (FFS) according to modes of active matrix driving electrodes including electrode pairs (Super-In-Plane-Switching), the polarizing plate of the present invention is laminated on the upper plate, and the direction of the liquid crystal is FFS (Fringe-Field-Switching) because the liquid crystal direction is perpendicular to the absorption axis of the polarizer of the upper plate polarizer. The polarizing plate of the present invention is laminated on the lower plate so as to be parallel to the absorption axis of the polarizer of the upper plate polarizing plate.

The polarizing plate structure on the opposite side of the liquid crystal cell in which the polarizing plate according to the present invention is not laminated is generally used in the art, and an isotropic protective layer is applied to secure a wide viewing angle. Specifically, the liquid crystal cell is composed of an isotropic protective layer, a polarizer and a protective layer in this order, and the polarizer absorption axes of the lower plate and the upper plate polarizer are orthogonal to each other.

The isotropic protective layer and the protective layer constituting the polarizing plate, and the protective layer constituting the polarizing plate according to the present invention may be independently used in common use in the art. Specifically, triacetyl cellulose (TAC (PC), polysulfone (PSF), and polymethylmethacrylate (PMMA), as well as polyolefins such as polyethylene terephthalate (PET), polypropylene (PP), polycarbonate May be used. Preferably, the isotropic protection layer has a front retardation (RO) and a thickness direction retardation (Rth) of less than 10 nm, preferably an absolute value of less than 2 nm, and the protective layer of the upper plate and the lower plate polarizer is optically Since the characteristics do not affect the viewing angle, the refractive index characteristics are not particularly limited in the present invention.

A retardation film such as a positive biaxial A plate, a negative biaxial A plate, and an isotropic protective layer constituting the polarizing plate has a thickness direction along the z axis, a direction with a large in-plane refractive index along the x axis and a perpendicular direction and the refractive indexes corresponding to the respective directions are denoted by Nx, Ny, and Nz, the thickness direction retardation (Rth) defined by the following equation (1), the front retardation (R0) defined by the following equation Is specified by the refractive index ratio (NZ) defined by Equation (3). At this time, the characteristics of the retardation film are determined according to the refractive index. In the case where the refractive indices in the three axial directions are different from each other, there are two optical axes in which no retardation occurs, and this is called a biaxial retardation film. Since the optical characteristics of each film to be implemented by the present invention are physical properties at a light source of 589.3 nm and the light source range is a standard when referring to optical characteristics in general, when there is no special description about a light source, the value at a light source of 589.3 nm .

Rth = [(Nx + Ny) / 2 - Nz] xd

(Where Nx and Ny are surface refractive indices Nx > = Ny, Nz is refractive index in the thickness direction of the film, and d is the thickness of the film)

R0 = (Nx - Ny) xd

(Where Nx and Ny are the surface refractive indexes of the retardation film and d is the thickness of the film, where Nx > = Ny)

NZ = (Nx - Nz) / (Nx - Ny) = Rth / R0 + 0.5

(Where Nx and Ny are surface refractive indices Nx > = Ny, Nz is refractive index in the thickness direction of the film, and d is the thickness of the film)

As described above, the present invention is intended to suggest a lower plate polarizing plate which can be practically applied to mass production and has a better viewing angle compensating effect than the conventional concept of viewing angle compensation, and a planar switching mode liquid crystal display using the same. The planar switching liquid crystal display device constructed in accordance with the optical condition of the present invention satisfies the compensation relationship of the maximum transmittance of the visual sensitivity omnidirectional in the dark state of 0.1% or less, preferably 0.05% or less. The front brightness of the currently produced brightest liquid crystal display device is about 10000 nits using the VA mode, and the brightness is about 10000 nits × cos 60 ° at a view angle of 60 ° slope, and 0.05% is 2.5 nits to be. Therefore, the present invention realizes visual sensitivity omnidirectional transmittance comparable to that of the IPS mode and comparable to the VA mode, while achieving a visibility omnidirectional transmittance equal to or greater than that of the liquid crystal display device using the IPS mode.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a basic structure of a planar switching liquid crystal display (IPS-LCD) according to the present invention.

The IPS mode liquid crystal display device according to the present invention is manufactured by stacking the lower plate polarizer 10, the liquid crystal cell 30 and the upper plate polarizer 20 in this order from the backlight unit 40 side to the lower plate polarizer 10 and the upper plate polarizer The protective layers 13 and 23 are located on the opposite sides of the liquid crystal cell of the polarizers 11 and 21 of the liquid crystal display panel 20. 1 (a), the upper plate polarizer 20 has an isotropic protective layer 24 laminated on the liquid crystal cell side of the polarizer 21 and a lower polarizer plate 10 has a positive biaxial A A plate 16, a negative biaxial A plate 14, and a polarizer 11 in this order. In the case of the S-IPS liquid crystal cell (Fig. 1B), the upper plate polarizer 20 is stacked in the order of the positive biaxial A plate 24, the negative biaxial A plate 25 and the polarizer 21, And the lower plate polarizer 10 is formed by laminating an isotropic protective layer 14 on the liquid crystal cell side of the polarizer 11. [

2 schematically shows a method of applying a polarizing plate for a vertical alignment mode liquid crystal display device to a polarizing plate for a planar switch mode liquid crystal display device. Referring to FIG. 2, the two polarizer plates in the vertically aligned liquid crystal mode are applied to the liquid crystal cell of the present invention, and a polarizer plate having a positive biaxial A plate having a specific optical property is laminated on the liquid crystal cell To use.

More specifically, it comprises a lower plate polarizer 10, a horizontally aligned liquid crystal cell 30 filled with liquid crystal having a positive dielectric constant anisotropy (DELTA epsilon > 0) between the two glass substrates, and a top plate polarizer 20, An active matrix drive electrode including an electrode pair is formed on an adjacent surface of the liquid crystal cell 30 in any one of the glass substrates of the liquid crystal cell 30.

The panel retardation value (DELTA n x d) defined by the following equation (4) ranges from 300 to 400 nm at a wavelength of 589.3 nm. Specifically, the panel retardation value of the liquid crystal cell 30 is 300 to 330 nm And the panel retardation value of the FFS mode is about 360 to 400 nm. This is because in order to make the IPS-LCD panel linearly polarized after passing through the liquid crystal cell 30 after passing through the lower plate polarizer 10 and passing through the lower polarizer plate 10 in the horizontal direction, The retardation value of the liquid crystal cell 30 of the LCD panel must be a half wavelength with respect to the light source of 550 nm (the brightest monochromatic light the human senses), and the transmittance becomes maximum at this time. The reason why the optimum retardation value differs between the S-IPS and the FFS is that the electrode structure is different and optical characteristics are different according to the liquid crystal behavior when the maximum voltage is applied.

Δn × d = (n _e - n _o ) × d

(Where n _e is the extraordinary ray refraction index of the liquid crystal, n _o is the normal ray refraction index, d is the cell gap, note Δ n, d is a scalar rather than a vector)

The absorption axis 12 of the lower plate polarizer 10 and the absorption axis 22 of the upper plate polarizer 20 are arranged perpendicular to each other and the absorption axis 22 of the upper plate polarizer 20 and the liquid crystal cell 30 The alignment directions 31 of the liquid crystals are arranged in parallel or orthogonal to each other.

Polyvinyl alcohol (PVA) layers 11 and 21, which are polarizers imparted with a polarizing function through stretching and dyeing, are placed on the lower plate polarizer 10 and the upper plate polarizer 20, and polyvinyl alcohol (PVA) Protective films 13 and 23 are disposed on the opposite side of the liquid crystal cell 30 in the polyvinyl alcohol (PVA) layer 11 and the top plate polarizer. At this time, since the protective film 13 of the lower plate polarizer 10 and the protective film 23 of the upper plate polarizer 20 have no influence on the viewing angle due to the difference in refractive index, the refractive index characteristic is not particularly limited Do not.

The upper plate polarizer 20 and the lower plate polarizer 10 of the present invention are manufactured by applying a roll-to-roll method which is easy to mass-produce. FIG. 4 is a schematic view for explaining the MD direction of the roll-to-roll manufacturing process. Referring to FIG.

The upper plate and lower plate polarizers 10 and 20 are made of a combination of various optical films, and each optical film exists in a roll state before being bonded to the composite polarizer plate. The direction in which the film is unwound or wound in this roll is referred to as the MD (Machine Direction) direction. In the polarizing plate containing the protective layer and the isotropic protective layer, the direction of the layer does not affect the optical performance, so that a roll-to-roll production is possible, and the polarizing plate according to the present invention has no relation with the direction of the protective layer Roll-to-roll production is possible by matching the MD direction of the polarizer, negative biaxial A plate and positive biaxial A plate. Specifically, in each polarizing plate, the absorption axis of the polarizer is in the MD direction, which aligns the PVA in the MD direction through stretching in the MD direction in the PVA fabric used as a polarizer material when the polarizing function is imparted in the polarizing plate, The absorption direction becomes the MD direction.

The positive biaxial A plate can be realized by biaxial stretching and the refractive index can be roll-to-roll bonded in the vertical direction of the MD. This is because it is stretched much in the MD direction relative to the MD direction . The negative biaxial A plate has a positive refractive index characteristic in which the refractive index is increased with respect to the stretching direction and has a biaxial stretching property in which it is uniaxially stretched in the MD direction or both in the MD and MD directions, . In the case of uniaxial stretching in the MD direction, the length in the MD direction is fixed due to the mechanical characteristics of the stretching machine, so Nx is formed in the direction perpendicular to the MD direction. During stretching, Nx becomes larger and Ny becomes smaller. 1. However, in most materials, it is difficult to realize optical properties of NZ = 2 or more through stretching only in the direction perpendicular to the MD direction.

Therefore, it is possible to realize NZ of 2 or more by making the refractive index Nz in the thickness direction relatively smaller than Nx and Ny through stretching in the MD direction and the plane perpendicular to the plane. At this time, in the case of biaxial stretching in which both the MD direction and the MD direction are elongated, since the ground axes are perpendicular to the MD direction, the MD direction and the MD direction Direction, it becomes a phase difference film capable of roll-to-roll bonding.

In the present invention, the absorption axis of the lower plate polarizer polarizer should be positioned in the vertical direction when viewed from the viewer's side. Specifically, when the absorption axis of the lower plate polarizer close to the backlight unit is in the vertical direction, light passing through the lower plate polarizer becomes polarized in the horizontal direction, and when light passes through the liquid crystal cell of the panel, Direction and passes through the upper plate polarizer on the side of the viewer having the absorption axis in the horizontal direction. At this time, a person wearing a polarized sunglass having an absorption axis in the horizontal direction (the absorption axis of the polarized sunglasses is in the horizontal direction) on the viewer side can recognize light emitted from the liquid crystal display device. If the absorption axis of the lower plate polarizer close to the backlight unit is in the horizontal direction, there is a problem that the image is not seen by the person wearing the polarized sunglasses. In addition, in the case of a large-sized liquid crystal display device, in order to make the image clearly visible from the viewer's view, considering that the human's field of view is wider than the vertical direction, the general liquid crystal display device except for the special- Since the main field of view is wider in the horizontal direction than in the vertical direction, it is produced in the form of 4: 3 or 16: 9.

The Slow axis of the positive biaxial A plate and the slow axis of the negative biaxial A plate of the present invention allow the light to move in the normal direction to the negative biaxial A plate and the positive biaxial A plate, , It means the axis through which the light passes the slowest by the retardation film and means the axis having the greatest refractive index and it is distinguished from the optical axis in which the phase difference does not occur when passing through the retardation film. When the liquid crystal displays black, the absorption axis of the polarizer orthogonalized at the viewer-side front face can not maintain the orthogonal state due to the geometrical characteristics on the slope other than the front, so that the light leaks and the viewing angle becomes narrow due to the light. Since the optical system can maintain the absorption axis orthogonal to the slope between the polarizer of the upper plate and the lower plate polarizer, the light does not leak and the viewing angle is not narrowed. The absence of light leakage under the above-mentioned retardation value condition of the present invention can be explained through the Poincare sphere.

7 and 8 are planar switching mode liquid crystal display devices arranged with the configurations shown in Figs. 1 (a) and 1 (b) using a film having optical properties according to the present invention, and these are displayed on a Poincare Sphere 9 shows the change of the polarization state in the direction of θ = 60 ° and φ = 45 ° at the wavelength of light of 550 nm, which is the brightest light of human being. 1 (a), the light passing through the polarizer on the backlight side is polarized in the polarization state 1 on the Poincare Sphere in Fig. 8, and the negative biaxial A plate and the positive biaxial A plate Passes through any one of infinite points connecting R1 and R2 according to each required optical characteristic, and is converged to a polarization state symmetric to the polarization state 1 based on -S2 (1, 0, -1, 0) This polarization state does not change much even though it passes through the FFS liquid crystal cell and the isotropic protective layer, and is largely absorbed by the polarizer of the top plate polarizer, and can represent an excellent black. Similarly, the configuration of FIG. 1 (b) can be explained by the Fujian curry sphere of FIG. 7, and the light passing through the polarizer of the lower plate polarizer is polarized in the polarization state 1, and even when the light passes through the isotropic protection layer and the liquid crystal cell, The positive biaxial A plate of the top plate polarizing plate, the negative biaxial A plate, passing through any one of infinity points connecting R1 and R2 in Fig. 7 and passing through the -S2 (1,0, -1,0) And is converged into a symmetrical polarization state of the polarization state 1, which is mostly absorbed by the polarizer of the top plate polarizer, and can represent an excellent black.

Hereinafter, the effect of implementing the dark state at the full viewing angle when the voltage is applied according to the above configuration is summarized in the embodiment and the comparative example. The present invention can be better understood by the following examples, and the following examples are intended to illustrate the present invention and are not intended to limit the scope of protection defined by the appended claims.

Example

In the following Embodiments 1 to 6 and Comparative Examples 1 to 4, simulation was performed by applying to an LCD simulation program TECH WIZ LCD 1D (MANAI SYSTEM, KOREA) to compare the optical viewing angle effects.

Example  One : FFS mode

Actual data such as each optical film, liquid crystal cell, and backlight according to the present invention were stacked on a TECH WIZ LCD 1D (MANAMA SYSTEM, KOREA) in a structure (FFS mode) as shown in FIG. The structure of FIG. 1 (a) will be described in detail as follows.

The back plate unit 40, the lower plate polarizer 10, the liquid crystal cell 30 and the upper plate polarizer 20 are sequentially laminated. The lower plate polarizer 10 includes a positive biaxial A plate 16, The polarizer 11 and the protective layer 13 in this order from the liquid crystal cell side and the upper plate polarizer 20 is composed of an isotropic protective layer 24, a polarizer 21 and a protective layer 23 ).

At this time, the polarizers 11 and 21 were provided with the function of a polarizer through stretching and dyeing, and the polarizers 10 and 20 were arranged orthogonal to each other on both sides of the FFS mode liquid crystal cell 30. The absorption axis of the polarizer 21 of the upper plate polarizer 20 and the absorption axis of the polarizer 11 of the lower plate polarizer 10 are orthogonal to each other and the absorption axis of the polarizer 22 of the upper plate polarizer and the liquid crystal alignment direction 31 Are arranged in parallel.

Protective layers 13 and 23 are arranged on the opposite side of the liquid crystal cell 30 of the polarizer 11 of the lower plate polarizer 10 and the polarizer 21 of the upper plate polarizer.

On the other hand, each of the optical films and the backlight used in the embodiments of the present invention was made to have the following optical properties.

라고 할 때 하기 수학식 5 내지 9에 의해 정의된다.Polarizers 11 and 21 of the lower plate polarizer 10 and the upper plate polarizer 20 give a polarizer function by dyeing iodine on the stretched PVA and the polarizing performance of the polarizer is measured in the range of visible light of 370 to 780 nm The degree of polarization is not less than 99.9%, and the visible transmittance is 41% or more. The transmittance of the transmission axis according to the wavelength is denoted by TD (λ), the transmittance of the absorption axis with respect to wavelength is denoted by MD (λ), and the visibility correction value defined in JIS Z 8701: 1999

And is defined by the following equations (5) to (9).

The optical characteristics resulting from the difference in internal refractive indexes according to the directions of the respective films were 589.3 nm for the light source, the positive biaxial A plate 16 had a front retardation (R0) of 54 nm and a refractive index ratio (NZ) of -2; The negative biaxial A plate 14 had a front retardation R0 of 50 nm, a refractive index ratio NZ of 3, an average refractive index of (Nx + Ny + Nz) / 3 of 1.48 and a wavelength dispersion of [Rth (400 nm) Triacetylcellulose (TAC) having a ratio of [Rth (589 nm) / Rth (700 nm)] of 0.92; The isotropic protective layer 14 used had a front retardation (R0) of 0 nm and a thickness direction retardation (Rth) of 0 nm. At this time, the direction of the slow axis of each of the positive biaxial A plate 16 and the negative biaxial A plate 14 is orthogonal to the absorption axis 12 of the adjacent polarizer 11.

The composite polarizing plate including the negative biaxial A plate 14, the polarizer 11 and the protective layer 13 was a 3G NTAC polarizer (Dongwoo Fine-Chem, Korea), and the positive biaxial A plate 16 I-Film (OPTES, Japan), a three-layer coextruded phase difference film in which PS having negative refractive index characteristics was disposed between two sheets of polymethyl methacrylate (PMMA) was used.

The outer protective layers 13 and 23 of the upper and lower plate polarizers 10 and 20 were coated with triacetyl cellulose (TAC) having an optical property with a thickness direction retardation (Rth) of 50 nm to the incident light of 589.3 nm Respectively. Actual data mounted on a 32-inch TV Wooo 9000 model (HITACHI, Japan) was used as the backlight unit 50.

The above optical components were stacked as shown in FIG. 1 (a), and a visual sensitivity omni-directional transmittance simulation was carried out. As a result, the results shown in FIG. 10 were obtained. 10 shows the distribution of the visual sensitivity omnidirectional transmittance when the black is displayed on the screen. In the range of scale, the transmittance is in the range of 0% to 0.05%, the portion in which the transmittance exceeds 0.05% Areas with low permeability are indicated in blue. At this time, as the range of the blue color in the center becomes wider, it is possible to secure a wide viewing angle by showing a wide viewing angle.

Embodiment 2: FFS mode

The positive biaxial A plate 16 was fabricated in the same manner as in Example 1 except that the positive biaxial A plate 16 had a front face retardation R0 of 59 nm and a refractive index ratio NZ of -1.9 Respectively.

FIG. 11 shows the result of simulation of the visual sensitivity omnidirectional transmittance of the planar switching liquid crystal display device.

Embodiment 3: FFS mode

The positive biaxial A plate 16 was fabricated in the same manner as in Example 1 except that the positive biaxial A plate 16 had a front face retardation R0 of 64 nm and a refractive index ratio NZ of -1.8 Respectively.

FIG. 12 shows the result of simulation of the visual sensitivity omni-directional transmittance of the planar switching liquid crystal display device.

Example 4: S-IPS mode

Actual data such as each optical film, liquid crystal cell and backlight according to the present invention were laminated on a TECH WIZ LCD 1D (MANAMA SYSTEM, KOREA) as shown in Fig. 1 (b). The structure of FIG. 1 (b) will be described in detail as follows.

The backlight unit 40 , the lower plate polarizer 10, the liquid crystal cell 30 and the upper plate polarizer 20 are sequentially laminated. The lower plate polarizer 10 includes a protective layer 13, The polarizer 21 and the isotropic protective layer 14 in this order from the side of the liquid crystal cell and the upper plate polarizer 20 is composed of the positive biaxial A plate 24, the negative biaxial A plate 25, Layer 23 in this order.

At this time, the polarizers 11 and 21 were given the function of a polarizer through stretching and dyeing, and the polarizers 10 and 20 were arranged orthogonal to each other on both sides of the IPS mode liquid crystal cell 30. The absorption axis 12 of the lower plate polarizer 10 and the alignment direction 31 of the liquid crystal contained in the liquid crystal cell 30 are set so that the absorption axis of the polarizer 21 of the upper plate polarizer 20 and the absorption axis of the polarizer 21 of the lower plate polarizer 10 (11) absorption axes are orthogonal to each other, and the absorption axis of the polarizer (11) of the lower plate polarizer and the alignment direction (31) of the liquid crystal are arranged in parallel.

Protective layers 13 and 23 are arranged on the opposite side of the liquid crystal cell 30 of the polarizer 11 of the lower plate polarizer 10 and the polarizer 21 of the upper plate polarizer. The positive biaxial A plate 24 and the negative biaxial A plate 25 are arranged in this order from the liquid crystal cell 30 side to the liquid crystal cell 30 and the polarizer 21 of the upper plate polarizer 20, An isotropic protective layer 14 is arranged between the polarizer 11 and the liquid crystal cell 30 of the liquid crystal cell 10.

On the other hand, each of the optical films and the backlight used in the embodiments of the present invention was made to have the following optical properties.

라고 할 때 상기 수학식 5 내지 9에 의해 정의된다.Polarizers 11 and 21 of the lower plate polarizer 10 and the upper plate polarizer 20 give a polarizer function by dyeing iodine on the stretched PVA and the polarizing performance of the polarizer is measured in the range of visible light of 370 to 780 nm The degree of polarization is not less than 99.9%, and the visible transmittance is 41% or more. The transmittance of the transmission axis according to the wavelength is denoted by TD (λ), the transmittance of the absorption axis with respect to wavelength is denoted by MD (λ), and the visibility correction value defined in JIS Z 8701: 1999

(5) to (9). &Quot; (5) "

The optical characteristics resulting from the difference in the internal refractive index according to the orientation of each film are 589.3 nm for the light source, the positive biaxial A plate 24 has the front retardation (R0) of 55 nm, the refractive index ratio (NZ) is -2; The negative biaxial A plate 25 had a front retardation R0 of 50 nm, a refractive index ratio NZ of 3, a wavelength dispersion of [Rth (400 nm) / Rth (589 nm)] of 0.92, and [Rth (R) (700 nm)] of 0.96; a triacetylcellulose (TAC) system; The isotropic protective layer 14 used had a front retardation (R0) of 0 nm and a thickness direction retardation (Rth) of 0 nm. At this time, the direction of the slow axis of each of the positive biaxial A plate and the negative biaxial A plate is orthogonal to the absorption axis 22 of the adjacent polarizer 21.

A 3G NTAC polarizer (Dongwoo Fine-Chem, Korea) was used as the composite polarizer including the negative biaxial A plate 25, the polarizer 21 and the protective layer 23, and the positive biaxial A plate 24 I-Film (OPTES, Japan), a three-layer coextruded phase difference film in which PS having negative refractive index characteristics was disposed between two sheets of polymethyl methacrylate (PMMA) was used.

Triacetylcellulose (TAC) having optical characteristics with an Rth of 50 nm with respect to the incident light of 589.3 nm was used as the outer protective layers 13 and 23 of the upper plate and the lower plate polarizers 10 and 20, respectively. Actual data mounted on a 32-inch TV LC320WX4 model (LG.Philips LCD) was used as the backlight unit (50).

The above optical components were laminated as shown in FIG. 1 (b), and a visual sensitivity omni-directional transmittance simulation was performed. As a result, the results shown in FIG. 13 were obtained. 13 shows the distribution of the visual sensitivity omnidirectional transmittance in the case of displaying the black on the screen. In the range of scale, the transmittance is 0% to 0.05%, the portion where the transmittance exceeds 0.05% Areas with low permeability are indicated in blue. At this time, as the range of the blue color in the center becomes wider, it is possible to secure a wide viewing angle by showing a wide viewing angle.

Example 5: S-IPS mode

A positive biaxial A plate 24 at a light source of 589.3 nm was fabricated in the same manner as in Example 4 except that a planar phase switching (IPS) liquid crystal display device having a frontal retardation R0 of 59 nm and a refractive index ratio NZ of -1.9 Respectively.

FIG. 14 shows the result of simulation of the visual sensitivity omni-directional transmittance of the planar switching liquid crystal display device.

Example 6: S-IPS mode

A positive biaxial A plate 24 at a light source of 589.3 nm was fabricated in the same manner as in Example 4 except that a planar phase switching (IPS) liquid crystal display device having a front retardation (R0) of 64 nm and a refractive index ratio (NZ) Respectively.

FIG. 15 shows the results of the visual sensitivity omni-directional transmittance simulation of the planar switching liquid crystal display device.

Comparative Example 1

In the structure of the first embodiment, the positive biaxial A plate 14 and the negative biaxial A plate 16 were removed and an isotropic protective film was substituted to produce a planar switching (IPS) liquid crystal display device as shown in FIG.

As a result of the visual sensitivity omni-directional transmittance simulation of the planar phase switching liquid crystal display device, the results shown in Fig. 17 were obtained.

FIG. 10 of the first embodiment shows a wider viewing angle than that of FIG. 17 because the central blue portion is wider than that of FIG. Also, the maximum transmittance in the forward direction is calculated as 0.019% in Example 1 and 0.34% in Comparative Example 1, which indicates that the maximum transmittance in all directions is about 17.9 times that in Example 1.

This is also true in the case of the configuration of Embodiment 4, in which the positive biaxial A plate and the negative biaxial A plate are removed and the isotropic protective film is replaced with a planar switching (IPS) liquid crystal display device as shown in Fig.

Comparative Example 2

In the configuration of the first embodiment, only the positive biaxial A plate 16 was removed, and a planar phase switching (IPS) liquid crystal display device was manufactured.

The results of the visual sensitivity omni-directional transmittance simulation of the planar switching liquid crystal display device were as shown in Fig. 18, and it can be confirmed that the oblique plane transmittance in the black state is high and the viewing angle is narrow.

Comparative Example 3

The positive biaxial A plate 16 was manufactured in the same manner as in Example 1 except that the positive biaxial A plate 16 had a front face retardation R0 of 66 nm and a refractive index ratio NZ of -2.1 Respectively.

The result of the visual sensitivity omni-directional transmittance simulation of the planar switching liquid crystal display device was as shown in Fig. 19, and it can be confirmed that the oblique plane transmittance in the black state is high and the viewing angle is narrow.

Comparative Example 4

The positive biaxial A plate 24 was manufactured in the same manner as in Example 4 except that the positive biaxial A plate 24 had a front face retardation R0 of 66 nm and a refractive index ratio NZ of -2.1 Respectively.

The results of the visual sensitivity omni-directional transmittance simulation of the planar switching liquid crystal display device were as shown in FIG. 20, and it can be confirmed that the oblique plane transmittance in the black state is high and the viewing angle is narrow.

As described above, the planar switching liquid crystal display device according to the present invention can provide an excellent image quality for all viewing angles, and can be applied to a liquid crystal display requiring high viewing angle characteristics. The polarizing plate used for the conventional vertical alignment mode It is advantageous to simplify the polarizer manufacturing process, ease of mass production, and control the quantity of shipment by applying it to the surface switching.

1 is a perspective view showing a structure of a planar switching liquid crystal display (IPS-LCD) according to the present invention, in which (a) is an FFS mode, (b)

2 schematically shows a method of applying a compound polarizing plate for a vertical alignment mode liquid crystal display device to a compound polarizing plate for a plane-phase switching mode liquid crystal display,

3 is a schematic view for explaining the refractive index of the retardation film according to the present invention,

4 is a schematic view showing the MD direction in the manufacturing process for explaining the stretching direction of the retardation film and the polarizing plate according to the present invention,

5 shows the compensation principle of a VA mode liquid crystal display using a negative biaxial A plate on a Poincare sphere at a viewing angle of? = 60 ° and a viewing angle of? = 45 °,

FIG. 6 is a diagram illustrating a compensation for viewing angles θ = 60 ° and Φ = 45 ° when the positive biaxial A plate is laminated on the negative biaxial A plate of FIG. 5 and then applied to an IPS mode liquid crystal display The principle is shown on the Poincare Sphere,

FIG. 7 shows a region on the Poincare Sphere where the polarizing plate of the present invention can be compensated at the time of θ = 60 ° and φ = 45 ° when the polarizing plate of the present invention is applied to the S-IPS mode,

FIG. 8 shows a region on the Poincare Sphere which can be compensated at the time of θ = 60 ° and φ = 45 ° when the polarizing plate of the present invention is applied to the FFS mode,

9 is a schematic view for explaining the expression of? And? In the coordinate system of the present invention,

10 is a simulation result of the visual sensitivity all-round transmission of the first embodiment of the present invention,

11 is a simulation result of the visual sensitivity all-round transmission of the second embodiment of the present invention,

12 is a simulation result of the visual sensitivity all-round transmission of the third embodiment of the present invention,

13 is a simulation result of the visual sensitivity all-round transmission of the fourth embodiment of the present invention,

14 is a simulation result of the visual sensitivity all-round transmission of the fifth embodiment of the present invention,

15 is a simulation result of the visual sensitivity all-round transmission of the sixth embodiment of the present invention,

16 is a perspective view showing the structure of a planar switching liquid crystal display (IPS-LCD) including an isotropic protective film of Comparative Example 1 of the present invention,

17 is a simulation result of the visual sensitivity all-round transmission of Comparative Example 1 of the present invention,

18 is a simulation result of the visual sensitivity all-round transmission of Comparative Example 2 of the present invention,

19 is a simulation result of the visual sensitivity transmission of Comparative Example 3 of the present invention,

20 shows the result of simulating the visibility all-round transmission of Comparative Example 4 of the present invention.

Claims (10)

(IPS) mode in which a positive biaxial A plate, a negative biaxial A plate, a polarizer and a protective layer are laminated in this order from the liquid crystal cell side, Wherein the positive biaxial A plate has a front retardation value (R0) of 45 to 65 nm and a refractive index ratio (NZ) of -3? NZ? -1, the slow axis being orthogonal to the absorption axis of the adjacent polarizer; Wherein the negative biaxial A plate has a retardation value R0 of 40 to 65 nm, a refractive index ratio NZ of 2? NZ? 4, and an average refractive index defined by (Nx + Ny + Nz) Rth (400 nm) / Rth (589 nm), which is defined by the ratio of the thickness direction retardation value (Rth) at the two wavelengths of 1.55 (Nx, Ny is the surface refractive index, Nz is the thickness direction refractive index) <1.005 and 0.95 <Rth (589 nm) / Rth (700 nm) <1.002, wherein the slow axis is orthogonal to the absorption axis of the adjacent polarizer, Wherein the refractive index ratio (NZ) is defined by the following equation (3): &quot; (3) &quot; &Quot; (3) &quot; NZ = (Nx - Nz) / (Nx - Ny) = Rth / R0 + 0.5 (Where Nx and Ny are surface refractive indexes, Nx &gt; = Ny, Nz is a thickness direction refractive index, R0 is a front retardation value, and Rth is a thickness retardation value) The polarizing plate according to claim 1, wherein the negative biaxial A plate is a triacetyl cellulose (TAC) system or a cycloolefin polymer (COP) system. The positive biaxial A plate of claim 1, wherein the positive biaxial A plate is selected from the group consisting of triacetylcellulose (TAC), cycloolefin polymer (COP), cycloolefin copolymer (COC), polyethylene terephthalate (PET), polypropylene (PC) , polysulfone (PSF), and polymethylmethacrylate (PMMA). The polarizer according to claim 1, wherein the positive biaxial A plate has a structure in which polymethylmethacrylate (PMMA), polystyrene (PS), and polymethylmethacrylate (PMMA) are sequentially laminated. The polarizer according to claim 1, wherein at least one or more layers of the positive biaxial A plate are modified polycarbonate (PC). The protective layer according to claim 1, wherein the protective layer comprises at least one of triacetylcellulose (TAC), cycloolefin polymer (COP), cycloolefin copolymer (COC), polyethylene terephthalate (PET), polypropylene (PP), polycarbonate (PSF) and polymethylmethacrylate (PMMA). &Lt; RTI ID = 0.0 &gt; Polarizer &lt; / RTI &gt; 7. A liquid crystal display device of a planar switching (IPS) mode comprising the polarizing plate of any one of claims 1 to 6 as a lower plate or a top plate polarizing plate. The liquid crystal display device according to claim 7, wherein the maximum sensitivity of the visual sensitivity omnidirectional transmission satisfies a compensation relationship of 0.1% or less. 8. The polarizing plate according to claim 7, wherein the top plate polarizer is the polarizer of claim 1, An isotropic protective layer having a front retardation (R0) and a thickness retardation (Rth) of less than 10 nm from the liquid crystal cell side, respectively; A polarizer; And a protective layer are stacked in this order. The liquid crystal display according to claim 7, wherein the lower plate polarizer is the polarizer of claim 1, Wherein the upper polarizer comprises an isotropic protective layer having a frontal retardation (Ro) and a thickness retardation (Rth) of less than 10 nm from the liquid crystal cell side, respectively; A polarizer; And a protective layer are stacked in this order.

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