KR20030007215A - Circularly polarizing plate and liquid-crystal display device - Google Patents

Abstract

PURPOSE: To obtain a circularly polarizing plate with a pair of rightward and leftward polarizing plates which can produce a preferable black state by superposing rightward and leftward circularly polarized light, and to obtain a liquid crystal display device having high contrast. CONSTITUTION: The circularly polarizing plate consists of a pair of leftward and rightward circularly polarizing plates each having an equal number of birefringent layers. Each circularly polarizing plate has one or more layers of half-wave layers between a polarizing plate and a quarter-wave layer with the optical axes of the half-wave layers crossing the axis of the quarter-wave layer. The birefringent layers in total generate quarter wavelength phase difference in the whole or a part of a 200 to 1000 nm wavelength region. When the pair of circularly polarizing plates are disposed with the polarizing plates outside, the first, second to n-th layers of the birefringent layers from the nearest side to the polarizing plate are arranged in such a manner that the fast phase axes of the first layers, second layers, and n-th layers, and the transmission axes of the polarizing plates tape 80 to 100° cross angles. The liquid crystal display device is obtained by separately disposing the pair of circularly polarizing plates in the above state on both sides of a liquid crystal cell.

Description

Circular polarizer and liquid crystal display {CIRCULARLY POLARIZING PLATE AND LIQUID-CRYSTAL DISPLAY DEVICE}

This application takes priority of Japanese Patent Application No. 2001-216147, which is incorporated herein by reference.

The present invention relates to a pair of left-rotating and right-rotating circular polarizing plates that can provide circular polarization over a wide range of wavelengths and can be combined to form high contrast liquid crystal displays.

As a pair of left-rotating and right-rotating circular polarizing plates each composed of a laminated body of a conventional quarter wave plate and a polarizing plate, an optical axis (a ground axis or a slow axis or a fast axis) of each quarter wave plate is used. An assembly is known in which fast ax)) is used as a fixed system and the absorption axis or transmission axis (polarization axis) of each polarizing plate is rotated by 90 ° from each other. As a quarter wave plate used in each of a pair of circularly polarizing plates, a quarter wave plate which consists of a plurality of birefringent layers laminated so that the optical axes of the birefringent layers cross each other and forms circularly polarized light in a wide wavelength range is known. (Japanese Unexamined Patent Publication No. 93-100114, Japanese Unexamined Patent Publication No. 99-231132, Japanese Unexamined Patent Publication No. 2001-4837, etc.).

The pair of left-rotating and right-turning circular polarizing plates are individually disposed on both sides of the liquid crystal display such as the? Type using a state in which the front phase difference is almost zero, and used to achieve high contrast. However, even when a pair of left-rotating and right-turning circularly polarizing plates are used so that the left-rotating circularly polarized light and the right-rotating circularly polarized light overlap each other, it is difficult to form a black state. Due to this problem, when a pair of circularly polarizing plates are mounted on the liquid crystal display, light leakage occurs in the black display, resulting in lowered contrast.

The present invention provides a pair of left-rotating and right-turning circularly polarizing plates that can form a good black state and form a high-contrast liquid crystal display when the left-rotating circularly polarized light and the right-rotating circularly polarized light overlap each other.

1 shows an example of a pair of circularly polarizing plates.

<Description of Drawing>

1 and 2: Combined left and right turn circular polarizer

11 and 21: polarizer

12, 13, 22, and 23: birefringence layer providing phase difference of 1/2 wavelength

14 and 24: birefringence layer providing phase difference of 1/4 wavelength

3: liquid crystal cell

According to the present invention, a polarizing plate; A birefringent layer providing a phase difference of a quarter wavelength; And a birefringent layer providing a phase difference of 1/2 wavelength, wherein the optical axis of the birefringence layer providing a phase difference of 1/2 wavelength intersects with the optical axis of the birefringence layer providing a phase difference of 1/4 wavelength. A pair of left-rotating and right-turning circularly polarizing plates including one or more birefringent layers disposed between birefringent layers providing a phase difference in wavelength, wherein one of the pair of left-turning and right-turning circular polarizing plates is different from the other. Having the same number of birefringent layers as one birefringent layer of one circular polarizer plate, each of the birefringent layers of each of the pair of circular polarizer plates provides a phase difference of 1/4 wavelength in all or part of a total of 200 to 1,000 nm wavelength range, When the pair of circular polarizers are disposed to face each other such that the polarizers included in the pair of circular polarizers are located on the outside, the birefringence layer included in each of the pair of circular polarizers is used as the polarizer. Numbered from the first layer to the nth layer in order from close to, the pair of circular polarizers, the crossing angle of the fast axis between the first layers, the crossing angle of the fast axis between the second layers, and the truth between the n layers A pair of left-rotating and right-turning circular polarizing plates is provided, wherein the crossing angles of the axes and the crossing angles of the transmission axes between the polarizing plates are in the range of 80 to 100 °, respectively.

In addition, according to the present invention, a liquid crystal cell; And a pair of left-rotating and right-turning circular polarizing plates as defined above, wherein a pair of left-rotating and right-rotating members are disposed on both sides of the liquid crystal cell so that the polarizing plates included in the pair of circular polarizing plates are respectively located outside. In a liquid crystal display device including a circular polarizing plate, when the birefringence layer included in each of the pair of circular polarizing plates disposed on both sides of the liquid crystal cell is numbered from the first layer to the nth layer in order of proximity to the polarizing plate, In the pair of circular polarizers, the crossing angle of the fastening axis between the first layers, the crossing angle of the fastening axis between the second layers, the crossing angle of the fastening axis between the nth layers, and the crossing angle of the transmission axis between the polarizing plates are 80 to 100 °, respectively. There is provided a liquid crystal display characterized in that the range.

According to the present invention, when the left-rotating circularly polarized light and the right-rotating circularly polarized light overlap each other, a pair of left-rotating and right-rotating circular polarizing plates capable of forming an excellent black state and forming a high contrast liquid crystal display can be obtained. Can be. This is based on the fact that the circularly polarized light due to each circularly polarizing plate is prevented from changing to elliptical polarization by slight deformation on both the short wavelength side and the long wavelength side.

That is, the inventors of the present invention have problems of lowering contrast in a liquid crystal display device using a conventional pair of left-rotating and right-turning circular polarizing plates in which only transmission axes of polarizing plates included in the pair of circular polarizing plates are rotated 90 ° from each other. The research was conducted to solve the problem. As a result, the circular polarization caused by each circularly polarizing plate is changed to elliptical polarization by slight deformation on both the short wavelength side and the long wavelength side, so that displacement occurs at its azimuth angle and the orthogonal relationship of the transmission axes is destroyed, causing the decrease in contrast. It turns out that This problem is solved by the configuration of the present invention.

The features and advantages of the present invention will become apparent from the following detailed description of the invention, taken in conjunction with the accompanying drawings.

A pair of circularly polarizing plate according to the present invention is a polarizing plate; A birefringent layer providing a phase difference of a quarter wavelength; And a birefringent layer providing a phase difference of 1/2 wavelength, wherein the optical axis of the birefringence layer providing a phase difference of 1/2 wavelength intersects with the optical axis of the birefringence layer providing a phase difference of 1/4 wavelength. A pair of left-rotating and right-turning circularly polarizing plates comprising at least one birefringent layer disposed between the birefringent layers providing a phase difference in wavelength, wherein one of the pair of left-turning and right-turning circularly polarizing plates is different from the other Having the same number of birefringent layers as one birefringent layer of one circular polarizer plate, each of the birefringent layers of each of the pair of circular polarizer plates provides a phase difference of 1/4 wavelength in all or part of a total of 200 to 1,000 nm wavelength range, When the pair of circular polarizers are disposed to face each other such that the polarizers included in the pair of circular polarizers are located on the outside, the birefringence layer included in each of the pair of circular polarizers is used as the polarizer. When the first layer is numbered from the first layer to the nth layer in the order from close to, from the pair of circularly polarizing plates, the crossing angle of the fast axis between the first layers, the crossing angle of the fast axis between the second layers, and the truth between the n layers The crossing angle of the axis | shaft and the crossing angle of the transmission axis | shaft between polarizing plates are the range of 80-100 degrees, respectively.

1 shows an example of a pair of circularly polarizing plates. In Fig. 1, reference numeral 1 denotes one of a pair of left-rotating and right-turning circular polarizing plates, and reference numeral 2 designates another of a pair of left-rotating and right-turning circular polarizing plates, And (21) denote polarizing plates, reference numerals (12), (13), (22) and (23) denote birefringence layers each providing a phase difference of 1/2 wavelength, and (14) and (24) Each of the birefringent layers provides a phase difference of 1/4 wavelength. In addition, FIG. 1 illustrates a case where a pair of circular polarizing plates are applied to a liquid crystal display. Reference numeral 3 denotes a liquid crystal cell.

As shown in FIG. 1, the pair of left-rotating and right-turning circular polarizing plates 1 and 2 are polarizing plates 11 or 21, birefringent layers 14 or 24 providing a phase difference of 1/4 wavelength, respectively, and 1 One or two or more birefringent layers 12 and 13 or 22 and 23 which provide a phase difference of / 2 wavelength. The birefringent layers 12 and 13 or 22 and 23 have polarizers 11 or 21 and birefringent layers 14 or 24 such that their optical axes intersect the optical axes of the birefringent layers 14 or 24 providing a phase difference of 1/4 wavelength. Is placed in between. One of the pair of left and right rotatable circularly polarizing plates has a plurality of birefringent layers included in each of the pair of left and right rotatable circularly polarizing plates, one quarter of all or part of the total 200 to 1,000 nm wavelength range. It has the same number of birefringent layers as the birefringent layers of the other circularly polarizing plate so as to provide a phase difference in wavelength.

Materials suitable for the polarizing plate and the birefringent layer constituting each circularly polarizing plate can be used. The material is not particularly limited. In addition, a suitable material may be used in the polarizing plate that transmits linearly polarized light but may absorb other light. Examples of such polarizer materials include adsorbing iodine and / or dichroic dyes to hydrophilic polymer films, such as polyvinyl alcohol-based films, especially polyvinyl alcohol-based films or ethylene-vinyl acetate copolymerized partially saponified films. Polarizing films obtained by stretching; And a polarizing film obtained in the above manner and having one transparent protective layer to protect one or both surfaces of both surfaces of the polarizing film.

The transparent protective layer can be formed from a suitable polymer. In particular, the transparent protective layer can be preferably formed from a polymer excellent in transparency, mechanical strength, thermal stability and moisture shielding property. The transparent protective layer can be formed by a suitable method such as applying a polymer liquid or bonding and laminating a material provided as a film.

Additionally, examples of such polymers include cellulose based polymers such as diacetyl cellulose and triacetyl cellulose; Polyester-based polymers such as polyethylene terephthalate and polyethylene naphthalate; Olefinic polymers such as polyolefin and ethylene-propylene copolymers of polyethylene, polypropylene, cyclobased or norbornene structures; Amide based polymers such as nylon and aromatic polyamides; Polycarbonate-based polymers; Acrylic polymers such as polymethyl methacrylate; And styrenic polymers such as polystyrene and acrylonitrile-styrene copolymers.

In addition, examples of the polymer used to form the transparent protective layer include imide-based polymers; Sulfone-based polymers; Polyether-sulfone-based polymers; Polyether-ether-ketone-based polymers; Polyphenylene sulfide-based polymers; Vinyl alcohol-based polymers; Allylate polymers; Polyoxymethylene-based polymers; Epoxy polymers; Vinyl butyral type polymers; Blends of the foregoing polymers; And polymers curable by heat or ultraviolet light such as polyester based polymers, acrylic based polymers, urethane based polymers, amide based polymers, silicone based polymers and epoxy based polymers. In particular, a film having excellent isotropy such as a triacetyl cellulose film can be preferably used.

In contrast, examples of each birefringent layer include a monolayer obtained by orientation fixing of the refractive anisotropic material; And a multilayer obtained by coating an isotropic or anisotropic base material with a refractive index anisotropic material and orientation fixing the refractive index anisotropic material. Examples of refractive anisotropic materials include liquid crystal materials such as discotic liquid crystal polymers, nematic liquid crystal polymers or polymeric liquid crystals; And inorganic materials. Another example of a birefringent layer is a birefringent layer consisting of a suitable oriented process treated film, such as a uniaxial or biaxially stretched polymer film formed from the same polymer used to form the transparent protective layer. Another example of a birefringent layer is a birefringent layer made of a polymer film having a thickness direction refractive index controlled by a method of providing shrinkage force and / or stretching force under adhesion to a heat shrinkable film. The birefringence layer excellent in transparency (light transmittance) is preferable.

Preferred birefringent layers in terms of suppressing the phase difference change caused by stress have a photoelastic coefficient of 5 × 10 ⁻¹¹ m 2 / N or less, in particular 1 × 10 ⁻¹¹ m 2 / N based on light having a wavelength of 633 nm. Hereinafter, more specifically, the birefringence layer formed to be 7 × 10 ^-12 m 2 / N or less. The birefringent layer formed from the above-listed liquid crystal materials is preferable in view of obtaining the above photoelastic coefficient. Since such a birefringent layer generally has a small photoelastic coefficient, the phase difference change or the fast axis change caused by the deformation of the polarizing plate is very low, and the contrast is not lowered. In a birefringent layer formed from a polymer film, an olefinic polymer in view of suppressing interfacial reflection caused by the wavelength dependence of the birefringence of the birefringence layer, the photoelastic coefficient of the birefringence layer, and the refractive index difference between the birefringence layer and the adhesive used for lamination In particular, norbornene-based polymers, acetyl cellulose-based polymers, polymethyl methacrylate-based polymers and the like are preferably used.

As the birefringent layer, a birefringent layer providing a phase difference of 1/4 wavelength and a birefringence layer providing a phase difference of 1/2 wavelength are used in combination. The combination of birefringent layers provides a phase difference of 1/4 wavelength in all or part of the total 200 to 1,000 nm wavelength range. In this case, a birefringent layer providing a phase difference of 1/2 wavelength is disposed between the polarizing plate and a birefringence layer providing a phase difference of 1/4 wavelength. The birefringent layer providing a phase difference of 1/2 wavelength may be composed of one layer or multiple layers. The number of layers of the birefringent layer providing a phase difference of 1/2 wavelength is generally 4 or less, in particular 3 or less, but may be 5 or more.

Each of the birefringent layers constituting the circular polarizing plate may be formed from the same material, or may be formed from different materials. When the birefringence layer is formed from the same material, the laminate of the birefringence layer functioning as a half wave plate for light having a specific wavelength and the laminate of the birefringence layer functioning as a quarter wave plate for light are stacked in two layers. Sieves may be combined such that the wavelength dispersion characteristics of refractive index or birefringence are the same. When the birefringence layers are each formed from different materials, the laminates of the birefringence layers may be combined such that the laminates have different refractive index or wavelength dispersion characteristics of birefringence.

Each birefringent layer can be composed of a single layer or a stack of a plurality of retardation films to adjust the retardation characteristics of the birefringence layer. In the latter case, the retardation films to be laminated may each be formed from one kind of material or may be formed from different kinds of materials. In addition, the phase difference of the quarter wavelength or the half wavelength provided by each birefringent layer can be controlled by a method of changing the layer material, the layer thickness and the orientation conditions of the layer, or a suitable method such as the lamination method. . When the direction of the optical axis changes in the birefringence layer, the slow axis and the like of each birefringence layer is determined based on the average direction of the optical axis.

As described above, a combination of birefringent layers providing a phase difference of 1/4 wavelength in all or part of the total 200 to 1,000 nm wavelength range, for example, provides a phase difference of 1/4 wavelength with respect to wavelengths in the aforementioned wavelength range. Birefringence layer, and one or more birefringence layers that provide a phase difference of one-half wavelength relative to other wavelengths in the wavelength range, especially when a plurality of birefringence layers are stacked in various combinations or when the crossing angles between the optical axes of the birefringence layers change Can be. In addition, in the case of the combination of the birefringent layers which provide a phase difference of 1/4 wavelength in a part of the aforementioned wavelength range, a part of the wavelength range is 50% or more, especially 60% or more, more particularly 70% of the 200 to 1,000 nm wavelength range. The above is preferable in view of display characteristics.

One circular polarizing plate of the pair of circular polarizing plates according to the present invention is used as a combination of left and right rotating circular polarizing plates having the same number of birefringent layers as those of the other circular polarizing plate. Each circularly polarizing plate is arranged such that the optical axis of the polarizing plate, the birefringence layer providing the phase difference of 1/4 wavelength, and the optical axis of the birefringence layer providing the phase difference of 1/2 wavelength intersect the optical axis of the birefringence layer providing the phase difference of 1/4 wavelength. At least one birefringent layer providing a phase difference of one-half wavelength. When the pair of circular polarizers are disposed to face each other such that the birefringent layers included in each of the pair of circular polarizers are located on the outside of the pair of circular polarizers, the nth layer to the nth layer in the order of being close to the polarizer In the case of numbering, the crossing angle of the fastening axis between the first layers, the crossing angle of the fastening axis between the second layers, the crossing angle of the fastening axis between the nth layers and the crossing angle of the transmission axis between the polarizing plates in the pair of circular polarizers Are 80 to 100 degrees, in particular 85 to 95 degrees, respectively. Further, the interrelationship between the fastening axis of the corresponding birefringent layers and the transverse relationship of the transmission axis between the polarizing plates may be replaced by the interrelationship of the slow axis of the corresponding birefringent layers and the absorption axis of the polarizing plates.

The cross relationship can be achieved as follows. For example, θ0 is the angle of the absorption axis of the polarizer, and θ1, ... and θ (n-1) are the individual angles of the slow axis of the birefringence layer providing a phase difference of 1/2 wavelength depending on the number of birefringent layers arranged. Θn is the angle of the slow axis of the birefringence layer providing the phase difference of 1/4 wavelength, one circular polarizer is the angle of the slow axis of each of the birefringence layer providing the phase difference of 1/2 wavelength And the angle of the slow axis of the birefringent layer providing the phase difference of 1/4 wavelength are formed in the state determined by the following equation (3) or (4).

The other circular polarizing plate is formed in a state in which a correction by inversion is applied to the angle after an angle of 80 to 100 ° is added to each of the angle of the absorption axis of the polarizing plate and the angle of the phase difference axis of the birefringent layer in one circular polarizing plate.

Further, for example, when one layer is used as a birefringence layer providing a phase difference of 1/2 wavelength, the angle of the slow axis of the birefringence layer providing a phase difference of 1/2 wavelength in one circular polarizer is expressed by Equation 1 or 2 below. Θ0 + θ1 or θ0-θ1. The angle of the slow axis of the birefringent layer providing a phase difference of 1/4 wavelength is correspondingly calculated as θ0 + 2 × θ1 + 45 ° or θ0-2 × θ1-45 ° by equation (3) or (4). In this case, angle θ0 of the absorption axis of the polarizing plate is arbitrary, and angle θ1 is preferably 5 to 25 °.

On the other hand, when two layers are used as the birefringence layer providing the phase difference of 1/2 wavelength, the angle of the slow axis of the first and second birefringence layers providing the phase difference of 1/2 wavelength in one circular polarizer is 1 or 2 are calculated as θ0 + θ1 or θ0-θ1 (first layer) and θ0 + 2 × θ1 + θ2 or θ0-2 × θ1-θ2 (second layer), respectively. The angle of the slow axis of the (third) birefringent layer, which provides a phase difference of 1/4 wavelength, is correspondingly θ0 + 2 × θ1 + 2 × θ2 + 45 ° or θ0-2 × θ1-2 × Calculated as θ2-45 °. In this case, the angle θ0 of the absorption axis of the polarizing plate is arbitrary, and the angles θ1 and θ2 are preferably 5 to 15 ° and 10 to 30 °, respectively.

In addition, when three layers are used as the birefringence layer providing a phase difference of 1/2 wavelength, the slow axis of the first, second and third birefringence layers providing the phase difference of 1/2 wavelength in one circularly polarizing plate The angles are represented by Equations 1 or 2, respectively, θ0 + θ1 or θ0-θ1 (first layer), θ0 + 2 × θ1 + θ2 or θ0-2 × θ1-θ2 (second layer), and θ0 + 2 × θ1, respectively. + 2 x θ2 + θ3 or θ0-2 x θ1-2 x θ2-θ3 (third layer). The angle of the slow axis of the (fourth) birefringent layer, which provides a phase difference of 1/4 wavelength, is correspondingly θ0 + 2 × θ1 + 2 × θ2 + 2 × θ3 + 45 ° or θ0-2 × by equation (3) or (4). It is calculated as θ1-2 × θ2-2 × θ3-45 °. In this case, angles θ0 of the absorption axis of the polarizing plate are arbitrary, and each of θ1, θ2, and θ3 is preferably 1 to 10 °, 10 to 30 °, and 20 to 60 °, respectively.

Further, in each circularly polarizing plate, the polarizing plate and the individual birefringence layer may be simply stacked or combined with each other in view of preventing contamination due to dust displacement and dust. In addition, integral stacking of materials for forming each circularly polarizing plate is desirable in terms of improving efficiency in assembling the liquid crystal display device, including stabilization of quality due to prevention of displacement of the optical axis.

The bonding process may be carried out by a suitable method such as using a transparent adhesive or a pressure sensitive adhesive. The adhesive is not particularly limited. Adhesives that do not require a high temperature process for curing and drying or that do not require a long time curing and drying treatment are preferred in view of preventing changes in the optical properties of the polarizing plate and the birefringence layer. In addition, adhesives having a refractive index intermediate to the refractive index values of the material laminated through the adhesive are preferred in terms of interfacial reflection inhibition.

If necessary, an adhesive layer may be provided on each circular polarizing plate so that the circularly polarizing plate can be bonded to an adherend such as a liquid crystal cell through the adhesive layer. When the adhesive layer is exposed to the surface, the exposed surface of the adhesive layer may be temporarily covered with a separator for protection purposes such as contamination prevention until the adhesive layer is actually used. When one of the materials for forming each circularly polarizing plate is exposed to the surface, the exposed surface of the material may be adhesively covered with a surface-protective film so that the material is protected from damage.

The pair of circularly polarizing plates according to the present invention can be used for various purposes in the related art. The pair of circularly polarizing plates may be preferably used to form a liquid crystal display device capable of achieving high contrast, such as a τ type, especially using a state in which the front phase difference is substantially zero. The liquid crystal display is individually disposed on both sides of the liquid crystal cell 3 such that the polarizing plates 11 and 21 included in the pair of circular polarizing plates 1 and 2, respectively, are located outside, for example, as shown in FIG. Can be formed in such a way.

The birefringent layers included in each of the pair of circular polarizing plates 1 and 2 are arranged in order of being close to the polarizing plate when the pair of circular polarizing plates 1 and 2 are disposed on both sides of the liquid crystal cell 3 in the manner described above. When numbering from the first layer to the nth layer, the birefringence layer and the polarizing plate in the pair of circularly polarizing plates 1 and 2 are the fast axis (ground axis) between the first layers 12 and 22 in the pair of circularly polarizing plates. ), The intersection angle of the fast axis (ground axis) between the second layers 13 and 23, the intersection angle of the fast axis (ground axis) between the third layers 14 and 24, the The crossing angle of the fastening axis (ground axis) and the crossing angle of the transmission axis (absorption axis) of the polarizing plates are arranged so as to be 80 to 100 °, in particular 85 to 95 °. By this arrangement, high contrast display can be achieved.

The liquid crystal display device using the pair of circularly polarizing plates according to the present invention can be formed as a transmissive liquid crystal display device having a backlight unit or as a reflective liquid crystal display device having a reflective layer on the back thereof. In addition, the liquid crystal display can be formed as an external light / lighting type liquid crystal display having a light source on one side of the liquid crystal cell and a reflective layer on the back thereof. In this case, the liquid crystal display can be formed to have excellent display characteristics for the entire visible light region in high contrast and external light mode (reflective display) in the illumination mode (transmission display).

The anti-glare layer or the anti-reflection layer may be provided on the surface of the circularly polarizing plate provided on the viewing side of the liquid crystal cell in the liquid crystal display device. An anti-glare layer is provided to scatter external light reflected by its surface. An antireflective layer is provided to suppress surface reflection of external light. By means of the anti-glare layer or the anti-reflection layer, the surface reflected light is prevented from acting as the glare light which damages the visibility of the light transmitted through the display device. Thus, both the anti-glare layer and the anti-reflective layer can be provided to further improve that the surface reflected light does not damage the viewer.

The anti-glare layer or the anti-reflection layer may be formed as a suitable exhibiting the above-described function without particular limitation. In addition, the anti-glare layer may be formed as a light scattering reflective fine rough structure. The antireflective layer may be formed from an interference film such as a multilayer coating film of inorganic oxide having a different refractive index or a coating film of a low refractive index material such as a fluorine-based compound by a suitable coating method. Examples of suitable coating methods include deposition methods such as vacuum deposition, ion plating or sputtering; Plating methods and sol-gel methods are included.

Example

Reference Example 1

100 m thick norbornene-based resin film (Arton film manufactured by JSR Corporation) having a photoelastic coefficient of 4.1 × 10 ^-12 m ² / N based on light having a wavelength of 633 nm ) Was stretched 50% at 175 ° C. to obtain a λ / 2 stretched film which provided a phase difference of 1/2 wavelength for birefringent light (hereinafter the same) for light of 550 nm wavelength.

Reference Example 2

The same norbornene-based resin film was stretched 25% in the same manner as in Reference Example 1 to obtain a lambda / 4 stretched film providing a phase difference of 1/4 wavelength.

Reference Example 3

A 50 μm thick polycarbonate film having a photoelastic coefficient of 8 × 10 ⁻¹¹ m ² / N was stretched 5% at 150 ° C. to obtain a λ / 2 stretched film that provided a phase difference of 1/2 wavelength.

Reference Example 4

The same polycarbonate film was stretched 2.5% in the same manner as in Reference Example 3 to obtain a lambda / 4 stretched film providing a phase difference of 1/4 wavelength.

Example 1

The lambda / 2 stretched film obtained in Reference Example 1 and the lambda / 4 stretched film obtained in Reference Example 2 were laminated to each other through an adhesive layer so that the optical axis (ground axis) of the film crossed each other at an angle of 62.5 degrees. Then, a polarizing plate (NPF-HEG1425DU manufactured by Nitto Denko Corporation) was laminated on the λ / 2 stretched film through an adhesive layer. Thus, a right turn circular polarizing plate was obtained. When the absorption axis of the polarizing plate was 0 °, the slow axis of the λ / 2 stretched film was 17.5 ° and the slow axis of the λ / 4 stretched film was 80 °.

On the other hand, a left-rotating circularly polarizing plate was obtained in the same manner as described above except that all optical axes were set to vertically cross the above-described optical axis. That is, when making the absorption axis of a polarizing plate into 90 degrees, the slow axis of (lambda) / 2 stretched film was 107.5 degrees, and the slow axis of (lambda) / 4 stretched film was 170 degrees. Further, in each of the left and right rotating circularly polarizing plates, the laminate of the lambda / 2 stretched film and the lambda / 4 stretched film provided a phase difference of 1/4 wavelength in both the wavelength range of 200 to 1,000 nm.

Example 2

In Example 1, except that the λ / 4 stretched films of the left and right rotatable circularly polarizing plates are respectively formed from oriented and fixed liquid crystal polymers and replaced by λ / 4 films providing a phase difference of 1/4 wavelength. In the same manner, a pair of left and right rotating circularly polarizing plates was obtained. The photoelastic coefficient of the λ / 4 film was 1 × 10 ⁻¹¹ m ² / N. In each of the left and right rotating circularly polarizing plates, the laminate of the lambda / 2 stretched film and the lambda / 4 film provided a phase difference of 1/4 wavelength in both the 200 to 1,000 nm wavelength range.

Comparative Example 1

When the absorption axis of the polarizing plate is 90 °, the difference between the slow axis of the λ / 2 stretched film and the slow axis of the λ / 4 stretched film is 17.5 ° and 80 °, respectively, that is, whether the transmission axis of the polarizing plate is 0 ° or 90 °. A pair of left and right rotating circular polarizing plates was obtained in the same manner as in Example 1 except that the left rotating circular polarizing plate was formed.

Comparative Example 2

A pair of left and right rotating circularly polarizing plates was obtained in the same manner as in Example 1 except that the lambda / 2 stretched film obtained in Reference Example 3 and the lambda / 4 stretched film obtained in Reference Example 4 were used. .

Evaluation test

The pair of left-rotating and right-turning circular polarizing plates obtained in Examples 1 and 2 and Comparative Examples 1 and 2, respectively, and the polarizing plates included in the pair of left-turning and right-turning circular polarizing plates are respectively perpendicular to the absorption axis of the polarizing plate. They were placed opposite each other so as to be provided on the outside while crossing each other. In this state, contrast and black display were evaluated by the following method.

Contrast:

The contrast was calculated under the condition that the transmittance obtained when a pair of left-rotating and right-turning circular polarizing plates was set as a black display and when the two left-rotating circular polarizing plates were combined was set as a white display.

Black display:

The black markings obtained when arranging a pair of left-rotating and right-turning circular polarizing plates were visually judged.

The evaluation results were as shown in Table 1 below.

Example 1 Example 2 Comparative Example 1 Comparative Example 2 Contrast 8,434 6,752 264 50 Black mark Good Good Light leakage and coloring Significant light leakage

While the invention has been described in particularly preferred forms, it should be understood that the disclosure of the preferred forms of the invention may be varied in the combination and arrangement of details and parts of the configuration without departing from the spirit and scope of the invention as hereinafter claimed. do.

According to the present invention, when the left turnable polarization and the right turn polarized light overlap each other, a pair of left turnable and right turn circularly polarizing plates capable of forming an excellent black state and forming a high contrast liquid crystal display can be obtained. .

Claims (3)

Polarizers; A birefringent layer providing a phase difference of a quarter wavelength; And A birefringence layer providing a phase difference of 1/2 wavelength, wherein the optical axis of the birefringence layer providing a phase difference of 1/2 wavelength intersects with the optical axis of the birefringence layer providing a phase difference of 1/4 wavelength. A pair of left-rotating and right-turning circular polarizing plates comprising at least one birefringent layer disposed between birefringent layers providing a phase difference of One of the pair of left and right rotating circularly polarizing plates has the same number of birefringent layers as those of the other circularly polarizing plate, The birefringence layer included in each of the pair of circular polarizers provides a phase difference of 1/4 wavelength in all or part of the total 200 to 1,000 nm wavelength range, When the pair of circular polarizers are disposed to face each other such that the polarizers included in the pair of circular polarizers are located on the outside, the birefringence layers included in each of the pair of circular polarizers are arranged in the first layer in the order in which the polarizers are adjacent to the polarizer. In the case of numbering n-layers, the pair of circular polarizers has the intersection angle of fast axes between the first layers, the intersection angle of the fast axes between the second layers, and the truth between the n layers. A pair of left turnable and right turn circularly polarizing plates, characterized in that the crossing angle of the axes and the crossing angles of the transmission axes of the polarizing plates are in the range of 80 to 100 °, respectively. The method of claim 1, A pair of left-rotating and right-turning circular polarizing plates having a photoelastic coefficient of each birefringent layer of 5 x 10 ^-11 m 2 / N or less based on light having a wavelength of 633 nm. Liquid crystal cell; And A pair of left-rotating and right-turning circular polarizing plates according to claim 1 or 2, wherein a pair of left-turning is arranged separately on both sides of the liquid crystal cell so that the polarizing plates included in the pair of circular polarizing plates are respectively located outside. A liquid crystal display device comprising a polarizer and a right-rotating circularly polarizing plate, When the birefringent layers included in each of the pair of circular polarizers disposed on both sides of the liquid crystal cell are numbered from the first layer to the nth layer in order of proximity from the polarizer, the first layers of the pair of circular polarizers And a crossing angle of the fastening axis, a crossing angle of the fastening axis between the second layers, an crossing angle of the fastening axis between the nth layers, and a crossing angle of the transmission axis between the polarizing plates, respectively, in the range of 80 to 100 °.