JP2010026454A - Polarizing diffusion film and liquid crystal display apparatus using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a polarizing diffusion film which is produced easily and in which specific polarized light, which is made incident by the light entering from the surface thereof, is transmitted and diffused efficiently and the polarized light perpendicular to the specific polarized light is reflected efficiently; and to provide a liquid crystal display apparatus using the polarizing diffusion film. <P>SOLUTION: The polarizing diffusion film is obtained by stretching a sheet, which is formed from a resin having ≥0.1 intrinsic birefringence and has voids on the inside thereof, to a uniaxial direction and exhibits 50-90% whole light transmission to the visible light, 15-90% transmission haze to visible light and 20-90% degree of transmission polarization to visible light. The liquid crystal display apparatus is obtained by using the polarizing diffusion film. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a polarizing diffuser film and a liquid crystal display device using the same.

  Liquid crystal display devices are widely used as display devices for computers, televisions, mobile phones, and the like, but there is a demand for further improvement of display characteristics and reduction of power consumption. As means for satisfying these requirements, it is known that light from a light source is appropriately diffused and light use efficiency of the light source is improved. When the light from the light source is appropriately diffused, it is possible to widen the viewing angle of the liquid crystal display device and to improve in-plane uniformity such as luminance. Further, when the light use efficiency of the light source is increased, it is possible to increase the overall luminance of the liquid crystal display device to obtain a bright image quality and to reduce power consumption.

  For example, Patent Document 1 discloses a reflective polarizer that transmits specific polarized light a and reflects polarized light b orthogonal to the specific polarized light, and a liquid crystal display device including the reflective polarizer. The liquid crystal display device includes a liquid crystal cell, a reflective polarizer, a backlight, and a diffuse reflector in order from the display surface side. In this liquid crystal display device, first, of the light emitted from the backlight, polarized light a is transmitted to become display light, and polarized light b is reflected by the reflective polarizer to become reflected light. Next, the reflected polarized light b is further reflected by the diffuse reflector and the polarization state is randomized. Of the randomized light, the polarized light a is used again as display light, and the polarized light b is used again as reflected light, so that the light use efficiency is increased. This reflective polarizer is formed by laminating a film A made of polyethylene naphthalate and a film B made of copolyester using naphthalenedicarboxylic acid, terephthalic acid or the like as an acid component in multiple layers.

  Patent Document 2 discloses a sheet in which a second transparent resin is dispersed in the form of particles in a continuous phase composed of a first transparent resin, which transmits specific polarized light a and is orthogonal to the specific polarized light. A sheet that reflects polarized light b is disclosed. This sheet is obtained by extrusion molding while mixing two kinds of resins.

Patent Documents 3 and 4 disclose light guide films and sheets having haze anisotropy. Since this film can scatter and emit only the specific polarized light from the non-polarized light from the end face, the use efficiency of the light irradiated from the end face of the film can be improved. This film is obtained by uniaxially stretching a film such as polyethylene naphthalate containing a filler or not containing a filler.
Japanese National Patent Publication No. 9-506985 JP 2000-075643 A JP 11-281975 A JP 2001-264539 A

Since the reflective polarizer described in Patent Document 1 is formed by superimposing films A and films B having different chemical structures on top of each other, the manufacturing method is complicated and it is difficult to reduce the cost. . Moreover, in order to give diffusion performance, it was necessary to further form a member or layer having a diffusion function by bonding or painting.
Since the sheet described in Patent Document 2 is manufactured by a polymer alloy, the manufacturing method is complicated, and it is difficult to precisely control the polarization characteristics and the diffusion performance.
Although the film or sheet described in Patent Documents 3 and 4 can be manufactured by a method in which the optical characteristics are relatively easy to control, the film or sheet is used for an apparatus that guides light incident from an end face. Therefore, the sheet | seat described in patent document 3, 4 is not a sheet | seat which transmits the specific polarization | polarized-light among the light incident from the surface, and reflects the orthogonal | vertical polarization | polarized-light, and does not have a function which expands a viewing angle.

That is, a film that is easy to manufacture, efficiently transmits linearly polarized light in a specific direction out of light incident from the film surface, efficiently reflects linearly polarized light orthogonal thereto, and has a diffusion function. Although desired, there has traditionally been no satisfactory film in both performance and manufacturability.
In view of such circumstances, the present invention is easy to manufacture, and efficiently transmits linearly polarized light in a specific direction out of light incident from the film surface, and efficiently reflects linearly polarized light orthogonal thereto. And it aims at providing the film which has a spreading | diffusion function.

  As a result of intensive studies, the inventors have obtained a resin film that is obtained by stretching a sheet made of a specific resin and containing voids therein mainly in a uniaxial direction, and a film having specific optical characteristics solves the above-described problem. As a result, the present invention has been completed. That is, the said subject is solved by the following this invention.

[1] A resin film obtained by stretching a sheet made of a resin having an intrinsic birefringence of 0.1 or more mainly in a uniaxial direction,
There is a gap inside the film,
50 to 90% of total light transmittance for visible light,
A polarizing diffusion film having a transmission haze with respect to visible light of 15 to 70% and a transmission polarization degree with respect to visible light of 20 to 90%.
[2] The polarizing diffuser film according to [1], wherein the transmission haze is 25 to 60% and the transmission polarization degree is 30 to 90%.
[3] The polarizing diffuser film according to [1] or [2], wherein the total light transmittance for polarized light perpendicular to the stretching axis is 10% or more higher than the total light transmittance for polarized light parallel to the stretching axis.
[4] The polarizing diffusion film according to any one of [1] to [3], wherein the resin is a polyester-based resin, an aromatic polyether ketone resin, or a liquid crystalline resin.
[5] In any one of [1] to [4], obtained through a step of foaming a sheet made of a resin having an intrinsic birefringence of 0.1 or more, and a step of stretching the foamed sheet mainly in a uniaxial direction The polarizing diffuser film described.
[6] The polarizing diffusion film according to any one of [1] to [4], wherein the step of stretching the sheet is a step of stretching the sheet at a temperature T represented by the following formula (1).
Tg−50 ° C. ≦ T ≦ Tg + 10 ° C. (1)
(In formula (1), Tg represents the glass transition temperature of the crystalline resin)
[7] (A) Surface light source for liquid crystal backlight,
(B) at least one optical element and / or an air gap;
(C) a polarizing diffusion film according to any one of [1] to [6], and (D) a liquid crystal panel in which a liquid crystal cell is sandwiched between two or more polarizing plates, and (D) to (D) ) Are arranged in the order described above.
[8] The liquid crystal display device according to [7], wherein the (C) polarizing diffusion film is disposed adjacent to the (D) liquid crystal panel.
[9] The liquid crystal display device according to [7], wherein the (C) polarizing diffusion film also serves as a light source side protective film of a polarizing plate constituting the liquid crystal panel (D).
[10] The stretching axis of the (C) polarizing diffusion film;
The liquid crystal display according to any one of [7] to [9], wherein (D) the polarizing plate constituting the liquid crystal panel is substantially the same as the absorption axis direction of the polarizing plate disposed on the light source side. apparatus.

  According to the present invention, it is easy to manufacture, efficiently transmits linearly polarized light in a specific direction out of light incident from the film surface, efficiently reflects linearly polarized light orthogonal thereto, and has a diffusion function. Can provide film. This film can also provide a liquid crystal display panel with a wide viewing angle and high brightness.

1. Polarizing diffusion film of the present invention A polarizing diffusion film is a film having both polarization reflectivity and diffusibility. Polarization reflectivity refers to a property of transmitting more linearly polarized light in a specific direction than linearly polarized light orthogonal to the specific direction and reflecting more linearly polarized light orthogonal to the linearly polarized light in a specific direction. Diffusivity refers to the property of diffusing transmitted light. In other words, the polarizing diffuser film of the present invention transmits linearly polarized light in a specific direction, but reflects linearly polarized light orthogonal to this and returns it to the light incident side, and diffuses the transmitted light. Have.
The polarizing diffuser film of the present invention is a resin film obtained by stretching a sheet comprising a resin having an intrinsic birefringence of 0.1 or more and containing voids therein, mainly in a uniaxial direction. The total light transmittance for visible light is 50 to 90%, the transmission haze for visible light is 15 to 90%, and the transmission polarization degree for visible light is 20 to 90%. In the present invention, the symbol “˜” includes the range of both ends thereof.

  Intrinsic birefringence is defined by the following equation (2). Specific intrinsic birefringence of the resin is disclosed in, for example, Japanese Patent Application Laid-Open No. 2004-35347.

式（２）において、Δｎ^oは固有複屈折、ｎは平均屈折率、Ｎ_Aはアボガドロ数、ρは密度、Ｍは分子量、α₁は分子鎖方向の分極率、α₂は分子鎖と垂直方向の分極率である。

In the formula (2), Δn ^o the intrinsic birefringence, n represents an average refractive index, N _A is Avogadro's number, [rho is density, M is the molecular weight, alpha ₁ is the polarizability of the molecular chain direction, alpha ₂ is the molecular chains perpendicular The polarizability of the direction.

  In general, a resin having a high intrinsic birefringence exhibits a characteristic that the birefringence increases when the molecular chain is oriented by stretching or other means. Examples of the resin having an intrinsic birefringence of 0.1 or more include polyester resins, aromatic polyether ketone resins, and liquid crystalline resins.

  Specific examples of the polyester-based resin include polyethylene terephthalate, polyethylene-2,6-naphthalate, polypropylene terephthalate, and polybutylene terephthalate.

  Specific examples of the polyester resin include copolymers of the polyester resin and those containing 0.1 mol% or more of isophthalic acid, cyclohexanedimethanol, dimethyl terephthalate, and the like as comonomers in the polyester resin.

  Specific examples of the aromatic polyetherketone resin include polyetheretherketone.

  Specific examples of the liquid crystalline resin include a polycondensate of ethylene terephthalate and p-hydroxybenzoic acid.

The polarizing diffuser film of the present invention has a total light transmittance for visible light of 50 to 90%, a transmission haze for visible light of 15 to 70%, and a transmission polarization degree for visible light of 20 to 90%.
The “total light transmittance with respect to visible light” of the present invention is determined as follows.
1) Set the film on the integrating sphere of the spectrophotometer so that light is incident from the normal direction of the film surface. Next, the film surface is irradiated with light from a spectrophotometer, and the total light transmittance is measured every 10 nm in the wavelength range of 380 to 780 nm.
2) The film is rotated 90 degrees in a plane including the film surface, and the same measurement as in 1) is performed.
3) The data obtained in 1) and 2) above are averaged to obtain total light transmission data.
4) Based on JIS R-3106, the total light transmittance of a visual average value is measured from the total light transmission data obtained in 3).
Thus, when the data obtained in 1) and 2) are averaged, there is an advantage that even if the spectrophotometer's spectroscopic light is polarized to some extent, it can be corrected and the original characteristics of the film can be measured.
The total light transmittance with respect to visible light measured in this way is hereinafter simply referred to as “total light transmittance of the present invention”. The polarizing diffuser film having the total light transmittance of the present invention in the above range gives a liquid crystal display device with high brightness. The total light transmittance of the present invention is 50% or more, preferably 65% or more. The total light transmittance of the present invention is preferably as high as possible, but unless the antireflection film or the like is provided, the transmittance is 90% or less because of surface reflection on both sides of the film.

The polarizing diffuser film of the present invention has a transmission haze for visible light of 15 to 90%. The “transmission haze for visible light” of the present invention is determined as follows.
1) Set the film on the spectrophotometer so that light is incident from the normal direction of the film surface. Next, the film surface is irradiated with light from a spectrophotometer, and the parallel light transmittance is measured every 10 nm in the wavelength range of 380 to 780 nm.
2) The film is rotated 90 degrees in a plane including the film surface, and the same measurement as in 1) is performed.
3) Average the data obtained in 1) and 2) above.
4) Using this average data and the above-mentioned total light transmission data, transmission haze data at each wavelength is obtained from the following equation (3).
(1-parallel line transmittance / total light transmittance) × 100 (3)
5) Based on the transmission haze data obtained in 4), the transmission haze of the visual average value is measured based on JIS R-3106.

  The transmission haze for visible light measured in this way is hereinafter simply referred to as “transmission haze of the present invention”. The polarizing diffusion film having the transmission haze of the present invention in the above range gives a liquid crystal surface display device with less unevenness and uniform brightness. The higher the transmission haze of the present invention, the higher the diffusibility. However, if the transmission haze is too high, the total light transmittance becomes too low due to light loss or the like. .

The polarizing diffusion film of the present invention has a transmission polarization degree with respect to visible light of 20 to 90%. The “transmission polarization degree with respect to visible light” of the present invention is determined as follows.
1) A polarizing plate is set so that light enters from the normal direction of the surface of the polarizing plate before the test piece installation part of the integrating sphere of the spectrophotometer. That is, linearly polarized light perpendicular to the absorption axis of the polarizing plate is incident on the test piece.
2) Set the film in close contact with the polarizing plate so that the stretching axis of the film as the test piece is parallel to the polarization direction of the linearly polarized light. Next, the said linearly polarized light is irradiated, and the total light transmittance for every 10 nm is measured in the wavelength range of 380-780 nm.
3) The film is rotated 90 degrees in a plane including the film surface. Subsequently, the same measurement as in 2) is performed.
4) The data obtained in 2) was divided by the total light transmittance of the polarizing plate, obtaining a total light transmittance T _P of polarization parallel to the stretching axis based on JIS R-3106.
From the data obtained at 5) Similarly the 3) to determine the total light transmittance T _V of stretching axis perpendicular polarization.
Further, the transmission polarization degree is calculated from T _P and T _V based on the following equation (4).

The transmission polarization degree with respect to visible light measured in this way is hereinafter simply referred to as “transmission polarization degree of the present invention”.
The transmission polarization degree of the present invention is an index representing the difference in transmission between “polarized light V perpendicular to the film stretching axis” and “polarized light P parallel to the film stretching axis”. That is, the polarizing diffuser film of the present invention has a characteristic that the polarized light V is selectively transmitted and the polarized light P is selectively returned to the light incident side of the film by reflection.
The transmitted polarization degree of the present invention is 20 to 90%, preferably 30 to 90%. In particular, the T _V is more than 10% greater than T _P, the liquid crystal display device can be obtained more excellent in display characteristics.

  The total light transmittance, the transmission haze, and the transmission polarization degree of the present invention can be measured, for example, using a spectrophotometer U-4100 manufactured by Hitachi High-Technologies Corporation and, if necessary, a 150φ integrating sphere attachment device.

  The thickness of the polarizing diffusion film of the present invention is preferably 20 to 250 μm, and more preferably 30 to 150 μm, from the viewpoints of easy handling as a film and ease of winding. That is, a polarizing diffusion film having a film thickness within the above range while satisfying optical characteristics such as transmitted polarization with respect to visible light is excellent in optical characteristics and handleability.

Although the manufacturing method will be described in detail later, the polarizing diffuser film of the present invention is obtained by stretching a sheet mainly composed of a resin having an intrinsic birefringence of 0.1 or more and including voids inside in a uniaxial direction. . The polarizing diffuser film of the present invention thus obtained has voids inside the film.
A space | gap is also called a cell and is a minute space formed inside a film or the like. The interior of the space may be a vacuum during the film production process or may contain a specific gas, but will eventually be replaced with air.

  The shape of the voids contained in the polarizing diffusion film of the present invention may be a sphere or an ellipsoid, a flat shape thereof, or a needle shape. However, in the present invention, in order to obtain the polarizing diffuser film of the present invention by stretching mainly in a uniaxial direction, the voids extend in the stretching direction (substantially having a major axis in the stretching direction) and an acicular shape. Become. The size of the voids is preferably 0.1 to 2 μm, more preferably 0.1 to 1 μm in terms of an average diameter (also referred to as “average cell diameter”). An average diameter can be calculated | required by measuring the density of a film and calculating the diameter from the volume of the space | gap calculated from a density by making a space | gap into a sphere. In particular, the average cross-sectional diameter of the voids in the cross section perpendicular to the film surface and the stretching direction (perpendicular to the stretching direction) is preferably 1 μm or less, and more preferably 0.1 μm or less. This average cross-sectional diameter (perpendicular to the stretching direction) is obtained by calculating the average area of voids from a cross-sectional image obtained by known cross-sectional observation of the film, and calculating the diameter from the area as a circle.

It is preferable that the voids are uniformly dispersed in the film. The number of voids depends on the desired film thickness, void size, and optical properties such as the degree of transmitted polarization to be obtained, but the number of voids per unit volume of the film (“void density” or “ The cell density is also preferably 1 × 10 ⁶ to 2 × 10 ¹¹ (pieces / cm ³ ).

The reason why the effect of the present invention is obtained is not necessarily clear, but the polarizing diffuser film of the present invention is a molecular chain orientation produced by stretching a sheet made of a resin having a specific birefringence mainly in a uniaxial direction. It is presumed that cells with different refractive indexes existing inside the film coexist.
When the sheet is made of a crystalline resin but is amorphous, microcrystals may be formed in the film as described later. In this case, it is considered that the effect of the present invention is exhibited by the cells having different molecular chain orientations, different refractive indexes, and microcrystals. A non-crystalline sheet made of a crystalline resin is hereinafter also referred to as a “supercooled sheet”.

2. Manufacturing method of polarizing diffuser film of the present invention The polarizing diffuser film of the present invention is preferably manufactured by the following method A or B.
[Method A]
(A1) A step of preparing a sheet made of a resin having an intrinsic birefringence of 0.1 or more and including voids therein,
(A2) A method comprising a step of stretching the sheet mainly in a uniaxial direction.

[Method B]
(B1) a step of preparing a sheet made of a resin having an intrinsic birefringence of 0.1 or more and containing no voids inside,
(B2) A method in which a uniaxial direction is stretched at a relatively low temperature to simultaneously generate voids inside.
That is, the polarizing diffusion film of the present invention is produced through a “step for preparing a sheet” and a “step for stretching the sheet”. Below, each process is demonstrated.

(1) Step of preparing a sheet [Step (A1) of Method A]
In this step, a sheet made of a resin having an intrinsic birefringence of 0.1 or more and including a void inside is prepared. Specifically, this sheet is preferably prepared by any of the following methods.
1) Purchase a commercially available product.
2) A sheet (hereinafter also referred to as “non-foamed sheet”) made of a resin having an intrinsic birefringence of 0.1 or more and having no voids inside is foamed.
3) A resin having an intrinsic birefringence of 0.1 or more is extruded into a single layer or multiple layers while foaming using an extruder to obtain a sheet.

The method 2) may be performed by leaving the unfoamed sheet under high-pressure gas and impregnating the film with the gas. For example, the film may be placed in a high-pressure container, then high-pressure carbon dioxide is injected, and the film is sufficiently impregnated with carbon dioxide. At this time, by appropriately adjusting the pressure and temperature in the container, a void having a desired size and amount can be formed inside the film. The temperature at this time is a temperature suitable for foaming satisfying the cell diameter and cell density of the resin of the present invention to be selected, for example, polyethylene terephthalate resin (also referred to as “PET resin”), 10 to 30 ° C., pressure is 1 to 10 MPa, The impregnation time is preferably 1 to 5 hours.
The unfoamed sheet may be prepared by purchasing a commercially available sheet, or may be obtained by extruding a resin having an intrinsic birefringence of 0.1 or more into a single layer or multiple layers with an extruder.

  The method 3) is a method in which the gas foaming 2) is continuously carried out using an extruder. Specifically, a high-pressure gas is injected into the cylinder of the extruder to sufficiently dissolve the gas in the resin, and the foamed sheet is obtained by extruding from the die outlet while maintaining the pressure. As the known foaming agent, carbon dioxide is preferred.

  The resin having an intrinsic birefringence of 0.1 or more is as described above. Among them, polyethylene terephthalate and polyethylene naphthalate are preferable because they are excellent in processability and optical properties and are low in cost.

The average diameter of the voids contained in the sheet obtained in step (A1) of method A is mainly determined by the size of the voids contained in the polarizing diffusion film to be obtained after step (A2) of method A. 0.1 to 1.3 μm is preferable. Moreover, since the cell density of the sheet | seat obtained at the (A1) process of Method A hardly changes before and after a extending process, it is 1 * 10 < ⁶ > -2 * 10 < ¹¹ > (pieces / cm < ³ >) as mentioned above. Is preferred.

[Step (B1) of Method B]
In this step, a sheet made of a resin having an intrinsic birefringence of 0.1 or more and containing no voids is prepared. Specifically, this sheet is preferably prepared by any of the following methods.
1) Purchase a commercially available product.
2) A resin having an intrinsic birefringence of 0.1 or more is extruded into a single layer or multiple layers using an extruder to obtain a sheet.

The sheet prepared in the step (A1) of the method A or the step (B1) of the method B is preferably amorphous. When this sheet is crystallized, the crystal grains may be large, and when the polarizing diffusion film is obtained, desired optical characteristics cannot be obtained, or the degree of crystallinity is too high, so that step (A2) of Method A Or the extending | stretching in the (B2) process of the method B may become difficult.
In particular, the amorphous sheet prepared in the step (A1) of the method A or the step (B1) of the method B is preferably amorphous because the resin is in a supercooled state. The supercooled sheet may give fine crystals inside the film in the step (A2) of the method A or the step (B2) of the method B. This is because a film containing microcrystals inside can be a polarizing diffuser film having more excellent polarization diffusibility.

  The thickness of the sheet prepared in the step (A1) of the method A or the step (B1) of the method B mainly depends on the thickness and the draw ratio of the polarizing diffusion film to be obtained after the stretching in the step (A2) or (B2). Although it is determined, it is preferably about 50 to 500 μm.

(2) Step of stretching the sheet [Method A, step (A2)]
In this step, the sheet obtained in the method A (1) is stretched mainly in a uniaxial direction. “Mainly stretching in a uniaxial direction” means that although the stretching direction is a uniaxial direction, depending on the equipment to be selected, the same action as that substantially stretched in a direction different from the stretching direction may occur. means. The direction different from the stretching direction means, for example, a direction perpendicular to the stretching direction.
For uniaxial stretching, “lateral free uniaxial stretching” is performed by fixing two opposite sides of the original 4 sides before stretching, and “lateral fixing” is performed by clamping (fixing) 4 sides of the original fabric and uniaxially stretching. In “transverse free uniaxial stretching”, both ends in a direction perpendicular to the stretching direction are in a free state, and thus contract due to Poisson deformation. Therefore, in the transverse free uniaxial stretching, the direction perpendicular to the stretching direction is not stretched. On the other hand, in the “laterally fixed uniaxial stretching”, the end in the direction perpendicular to the stretching direction is fixed and thus cannot be shrunk, and although the direction perpendicular to the stretching direction is slight, it has been substantially stretched. Become. Normally, pure uniaxial stretching often refers to “lateral free uniaxial stretching”, but any method may be used in the present invention.
That is, “stretching mainly in a uniaxial direction” includes lateral free uniaxial stretching and laterally fixed uniaxial stretching. Examples of the transverse free uniaxial stretching include a roll stretching method, and the transverse fixed uniaxial stretching includes stretching using a batch stretching machine and stretching by a tenter method.

  In addition, “mainly stretching in a uniaxial direction” means that biaxial stretching may be intentionally performed by a method other than the above to the extent that the effects of the present invention are not impaired.

In the step (A2) of Method A, it is preferable to stretch the sheet while heating, or to stretch the sheet after preheating. This is because the film can be stretched without applying excessive force. The temperature at this time preferably satisfies the following values with respect to the glass transition temperature Tg of the resin and the melting temperature Tm.
Tg + 10 ≦ T ≦ Tm−10 ° C. (1)

The glass transition temperature is preferably determined by differential scanning calorimetry (DSC) of the sheet or the resin used as its raw material. Differential scanning calorimetry (DSC) may be performed according to JIS K7122.
When the heating temperature T exceeds the upper limit of the above formula, the sheet may be too soft and the molecular chain may not be sufficiently oriented. Moreover, when temperature T exceeds the said upper limit, a space | gap may be damaged. On the other hand, when the temperature T is lower than the lower limit of the above formula, that is, the glass transition temperature + 10 ° C., the stretching load increases, and a uniformly stretched film may not be obtained.

[Step (B2) of Method B]
Method B is a method in which the sheet is heated to a relatively low temperature and stretched so as to develop voids by breaking the structure under conditions having a high yield point. At this time, the sheet may be stretched while being heated, or may be stretched after preheating the sheet. The temperature T preferably satisfies the following value with respect to the glass transition temperature Tg of the resin.
Tg−50 ° C. ≦ T ≦ Tg + 10 ° C. (2)
When the heating temperature T exceeds the upper limit of the above formula, there are many cases where voids are not sufficiently developed, and when the temperature T is lower than the lower limit of the above formula, the stretching load is too high and uniform stretching is impossible. .
The stretching in the step (B2) may be performed as described in (A2).

In the steps (A2) and (B2), when the sheet is in a supercooled state, the sheet may be crystallized by being heated. Crystallization of the sheet is preferable because it can provide a polarizing diffuser film with more excellent polarization diffusibility, but if the crystallization proceeds excessively, the stretching load increases and a uniform film may not be obtained.
Therefore, the crystallinity of the film obtained after the stretching step is preferably 30% or less. The crystallinity can be determined by a density method or an X-ray diffraction method.

The preheating temperature in the steps (A2) and (B2) is not particularly limited as long as it satisfies the above-mentioned formula, but is appropriately selected within a range in which the sheet is not extremely softened particularly at the time of stretching in the step (A2). The
Further, when the sheet is in a supercooled state, the sheet may be crystallized by preheating, and as described above, the preheating temperature needs to be determined within a range in which it is not excessively crystallized. For example, in the case of a sheet made of polyethylene terephthalate, the preheating temperature in the step (A2) is preferably 90 to 240 ° C.

  The time for heating for preheating (also referred to as “preheating time”) may be sufficient as long as the sheet can be heated to a predetermined temperature. However, when heated for a long time, the sheet may deteriorate. In addition, when the sheet is in a supercooled state, if the sheet is heated for a long time, the sheet may be excessively crystallized. From such a viewpoint, for example, in the case of a sheet made of polyethylene terephthalate, the preheating time is preferably 0.1 to 10 minutes.

The stretching speed in the steps (A2) and (B2) is not particularly limited, but is preferably 10 to 500% / sec, and more preferably 20 to 300% / sec. When the stretching speed is high, the stretching stress increases and the burden on the equipment increases, and as a result, uniform stretching may be difficult. On the other hand, when the stretching speed is slow, the production speed is extremely slow, so that the productivity may be lowered.
The stretching speed refers to the deformation speed of the sample. The initial sample length is Lo, and the length of the stretched sample after time t is L, and is expressed by the following formula.
Stretching speed (% / sec) = (L−Lo) / Lo / t × 100 (5)

  The stretching ratio in the steps (A2) and (B2) is also not particularly limited because there is a width depending on the resin to be selected, but in the case of a polyester resin, it is preferably 2 to 10 times. When the draw ratio is large, stretch breakage is likely to occur. When the draw ratio is small, sufficient molecular chain orientation may not be obtained.

3. Liquid crystal display device The liquid crystal display device of the present invention comprises:
(A) a liquid crystal backlight surface light source,
(B) at least one optical element and / or an air gap (C) the polarizing diffusion film of the present invention, and (D) a liquid crystal panel comprising a liquid crystal cell sandwiched between two or more polarizing plates, and (A ) To (D) are arranged in the above order.

(A) Surface light source for liquid crystal backlight As a surface light source for liquid crystal backlight, a sidelight type surface light source in which a known light source is disposed on the side of a light guide plate, or a direct type in which a known light source is arranged under a diffusion plate A surface light source may be used. Examples of known light sources include cold cathode fluorescent lamps (CCFL), hot cathode fluorescent lamps (HCFL), external electrode fluorescent lamps (EEFL), flat fluorescent lamps (FFL), light emitting diode elements (LEDs), organic electroluminescent elements (OLEDs). ) Is included.

(B) Optical element and / or air gap The optical element here is an element that diffuses light from a surface light source for a liquid crystal backlight. Examples include prism sheets, microlens sheets, and diffusion films coated with a filler or bead-containing binder.
An air gap is an air layer provided between the surface light source for liquid crystal backlights and the polarizing diffusion film of the present invention. This air layer provides a reflective interface between the liquid crystal backlight surface light source and the polarizing reflective film, and plays a role of diffusing light from the liquid crystal backlight surface light source. Examples of the air gap include an air layer formed in the concave portion of the prism sheet.

(D) A liquid crystal panel in which a liquid crystal cell is sandwiched between two or more polarizing plates. A liquid crystal cell is a device including liquid crystal sealed between two substrates. The substrate may be made of a known material, and examples thereof include a glass plate and a plastic film.
The polarizing plate may also be made of a known material, and examples thereof include a dichroic polarizing plate using a dichroic dye.

  The members (A) to (D) are preferably arranged in the order of (A) to (D). FIG. 1 is an exploded view showing an example of the liquid crystal display device of the present invention. In FIG. 1, 10 is a liquid crystal cell, 20 is an upper polarizing plate, and 21 is a lower polarizing plate, and these constitute (D) a liquid crystal panel. 30 is (C) a polarizing diffusion film, and 40 is an optical element (B) such as a bead-coated diffusion film. Reference numeral 50 denotes a light guide plate, 60 denotes a reflection sheet, and 70 denotes a light source, which constitutes a (A) side light type liquid crystal backlight surface light source.

FIG. 2 is a diagram illustrating a display mechanism of the liquid crystal display device of the present invention. In FIG. 2, reference numeral 30 denotes a polarizing diffusion film, which is arranged so that the stretching axis is horizontal to the paper surface. In FIG. 2, the polarization parallel to the drawing plane is called “polarization P” because it is parallel to the stretching axis, and the polarization perpendicular to the drawing plane is called “polarization V” because it is perpendicular to the drawing axis.
The polarizing diffusion film 30 in FIG. 2 has the performance of transmitting polarized light perpendicular to the stretching axis and reflecting polarized light parallel to the stretching axis. Reference numeral 21 denotes a lower polarizing plate, which is arranged so that the absorption axis is horizontal to the paper surface. Reference numeral 100 denotes non-polarized light from the light source. 101 is polarization V, 102 is polarization P, 103 is polarization V, and 104 is reflected light.

  First, non-polarized light 100 is emitted from the light source and reaches the polarizing diffuser film 30. The polarized light V included in the non-polarized light 100 passes through the polarizing diffusion film 30 and becomes polarized light V101. The polarized light V101 is transmitted without being absorbed by the lower polarizing plate 21 and becomes display light. Since this polarized light V101 is diffused in the light beam emitting direction while maintaining the polarized light, display light can be obtained in a wide viewing angle.

When the polarized light P included in the non-polarized light 100 reaches the polarizing diffusion film 30, a part of the polarized light P is transmitted by diffusion to become polarized light P102, and the remainder is reflected. Due to this reflection, most of the polarized light P becomes polarized light V103. The polarized light P <b> 102 is absorbed by the lower polarizing plate 21.
On the other hand, the polarized light V103 is further reflected by an optical element and a reflection sheet (both not shown), and the polarized light is eliminated, and becomes reflected light 104. The reflected light 104 is reused as non-polarized light 100.
Since the liquid crystal display device of the present invention can reuse light by such a mechanism, it is possible to increase the luminance while widening the viewing angle.

  In the apparatus shown in FIG. 2, the polarizing diffusion film 30 is preferably installed so that the stretching axis is substantially parallel to the absorption axis of the lower polarizing plate 21. This is because the amount of display light can be increased and the light utilization efficiency can be increased. That is, it is preferable that the polarizing diffuser film 30 of a type that easily transmits polarized light V perpendicular to the stretching axis is disposed so that the stretching axis and the absorption axis of the lower polarizing plate 21 are substantially parallel.

In the liquid crystal display device of the present invention, it is preferable that (C) the polarizing diffusion film is disposed adjacent to the (D) liquid crystal panel. With such a configuration, the “upper diffusion film” between (B) and (D) included in the conventional liquid crystal display device can be omitted. That is, since the polarizing diffusion film of the present invention has excellent polarization diffusibility, it is possible to improve the luminance while providing a liquid crystal display device with little luminance unevenness without including a member such as an upper diffusion film. it can.
Of course, another film may be disposed between (C) the polarizing diffusion film and (D) the liquid crystal panel, but in this case, the other film does not disturb the polarized light V from (C) so much. It needs to be a film.

  Moreover, generally, a polarizing plate has a film in order to protect the surface. However, in the liquid crystal display device of the present invention, (C) the polarizing diffusion film is a polarizing plate constituting the liquid crystal panel, and also serves as a protective film for the polarizing plate (lower polarizing plate) disposed on the light source side. May be used. That is, the (C) polarizing diffusion film of the present invention may be integrated with a polarizing plate to be a “polarizing plate with a polarizing diffusion function”. Usually, the polarizer of the polarizing plate is produced by uniaxial stretching, and the stretching direction is the absorption axis. Therefore, (C) A polarizing plate having a polarizing diffusion function can be easily produced by laminating a polarizing diffusion film and a polarizer by roll-to-roll using a roll.

The conventional liquid crystal display device includes the following members between (A) and (D) in order to achieve any one or all of luminance enhancement, luminance unevenness reduction, and viewing angle enhancement.
One or more diffusion films,
One to a plurality of diffusion films and one to a plurality of prism sheets, or one to a plurality of diffusion films, one to a plurality of prism sheets, and one upper diffusion film.
Alternatively, a conventional liquid crystal display device includes a device using a microlens film instead of a diffusion film, and there is also a device provided with a polarizing reflection film (DBEF manufactured by Sumitomo 3M Co., Ltd.) adjacent to (D). .
However, since the liquid crystal display device of the present invention has an excellent polarization diffusibility, a liquid crystal with high luminance, a wide viewing angle and little luminance unevenness can be obtained at low cost without including a prism sheet, an upper diffusion film, DBEF, or the like. Give a display.

  From the above, when the (C) polarizing diffusion film of the present invention is used, members that have been conventionally used as constituent members of liquid crystal display devices can be omitted. The liquid crystal display device with no members is advantageous in that it is low in cost and thin.

  The polarizing diffuser film of the present invention adjusts the image quality of a known ultraviolet absorber for cutting ultraviolet rays, a known flame retardant for improving flame retardancy, a known light resistant agent for improving light resistance, and a display device. An appropriate amount of colorant may be included. The polarizing diffusion film may be subjected to a known easy adhesion treatment or easy slip treatment on the surface. Further, the polarizing diffusion film may be subjected to antireflection treatment, anti-Newton ring treatment, antistatic treatment, and hard coat treatment by a known treatment method.

Example 1
An original sheet obtained by cutting A-PET sheet FR (no surface treatment, 330 μm thickness) manufactured by Teijin Chemicals into a size of 90 × 90 mm was prepared. This raw fabric sheet was put into a 1 L high pressure vessel, and supercritical CO ₂ having a temperature of 20 ° C. was injected into the high pressure vessel. At this time, the injection amount of supercritical CO ₂ was adjusted so that the pressure in the container was always 5 MPa, and this state was maintained for 2 hours. In order to suppress the temperature change due to the initial pressure increase in the container, the temperature of the container itself was adjusted so that the temperature in the high-pressure container was always 20 ° C.
Thereafter, the discharge port in the container was opened to discharge CO _2, and the pressure in the container was lowered to atmospheric pressure over about 10 seconds. Subsequently, the raw sheet was taken out from the container and cut into a size of 70 × 70 mm. When the foamed state of the original fabric was observed with a scanning electron microscope, the average cell diameter of the voids (cells) was 1 μm, and the cell density was 1 × 10 ¹⁰ cells / cm ³ .
Four sides of the original fabric were sandwiched between clamps, and fixed in a biaxial stretching apparatus (manufactured by Iwamoto Seisakusho, polymer film BIX-703 type) with the MD direction being the stretching direction. Subsequently, the original fabric was preheated at a temperature of 120 ° C. for 2 minutes, and then stretched uniaxially and stretched at a stretching speed of 50 mm / second and a stretching ratio of 4 times to obtain a film having a thickness of 90 μm.

(Example 2)
A foamed A-PET sheet was prepared in the same manner as in Example 1, and cut into a size of 70 × 70 mm. Four sides of the original fabric were sandwiched between clamps, and fixed in a biaxial stretching apparatus (manufactured by Iwamoto Seisakusho, polymer film BIX-703 type) with the MD direction being the stretching direction. Subsequently, this original fabric was horizontally fixed uniaxially stretched at a temperature of 90 ° C. under conditions of a stretching speed of 50 mm / second and a stretching ratio of 4 times to obtain a film having a thickness of 89 μm.

(Comparative Example 1)
A-PET sheet FR manufactured by Teijin Chemicals Ltd. (no surface treatment, 330 μm thickness) was cut into a size of 70 × 70 mm to prepare a raw sheet. Four sides of the original fabric were sandwiched between clamps, and fixed in a biaxial stretching apparatus (manufactured by Iwamoto Seisakusho, polymer film BIX-703 type) with the MD direction being the stretching direction. Subsequently, the raw fabric was preheated at a temperature of 116 ° C. for 4 minutes, and then stretched uniaxially and stretched at a stretching speed of 24 mm / second and a stretching ratio of 4 times to obtain a film having a thickness of 88 μm.

(Comparative Example 2)
In the same manner as in Example 1, a foamed A-PET sheet was prepared. However, the temperature of the supercritical CO ₂ and the high pressure vessel injected into the high pressure vessel was 70 ° C., the pressure was 20 MPa, and the holding time was 3 hours. When the foamed state of this sheet was observed with a scanning electron microscope, the average cell diameter of the voids was 1.5 μm, and the cell density was 2 × 10 ¹⁰ cells / cm ³ .
Subsequently, using this sheet as a raw fabric, it was uniaxially stretched in the same manner as in Example 1 to obtain a film having a thickness of 91 μm. However, the preheating temperature in stretching was 140 ° C.

  The optical properties of the film thus obtained were measured and are shown in Table 1. The optical properties were measured as already described. The measurement was performed as described above using a spectrophotometer U-4100 manufactured by Hitachi High-Technologies Corporation and a 150φ integrating sphere attachment device.

  The polarizing diffuser films obtained in Examples 1 and 2 showed high values for the total light transmittance, the transmission haze, and the transmission polarization degree. On the other hand, the stretched films obtained in Comparative Examples 1 and 2 had a transmission polarization degree of less than 20%.

(Example 3)
A liquid crystal display device is prepared in which the configuration on the main surface of the light guide plate of the backlight unit (cold-cathode tube 2-lamp side light type) of the 10.4 type VA TFT liquid crystal display device (manufactured by Kyocera Corporation) is prepared as follows. did.
A bead-coated diffusion film (total light transmittance of 58% when the surface opposite to the light diffusion surface is the light incident side and transmission haze of 91%) is placed on the light guide plate side, and the polarized light of Example 1 is placed thereon. A sex diffusion film was placed.
At this time, the polarizing diffusion film was disposed at the center of the bead-coated diffusion film such that the stretching axis was substantially the same as the absorption axis of the lower polarizing plate of the liquid crystal panel. The portions of the bead-coated diffusion film other than the one where the polarizing diffusion film was arranged were mask-shielded with a black sheet.

Example 4
A liquid crystal display device was prepared in the same manner as in Example 3 except that the polarizing diffusion film of Example 2 was used instead of the polarizing diffusion film of Example 1.

(Example 5)
A 10.4 type VA system TFT liquid crystal display device (manufactured by Kyocera Corporation) was prepared by changing a part of the liquid crystal display device as follows.
First, the light source side protective film of the lower polarizing plate of the liquid crystal display device panel was peeled off. The polarizing diffusion film of Example 1 was attached to the exposed central portion of the lower polarizing plate via an acrylic transparent adhesive sheet (thickness 15 μm). Except for the part where the film of the lower polarizing plate was attached, the mask was shielded from light with a black sheet. At this time, the absorption axis of the polarizing plate and the stretching axis of the polarizing diffusion film were made substantially the same.

  In addition, the configuration on the main surface of the light guide plate of the backlight unit is a bead-coated diffusion film in order from the light guide plate side. %) Only, a liquid crystal display device was prepared. In this reference liquid crystal display device, a black sheet shading mask having the same opening position and opening size as the liquid crystal display device obtained in each example was disposed on a bead-coated diffusion film.

(Comparative Example 3)
A liquid crystal display device was prepared in the same manner as in Example 5 except that the stretched film of Comparative Example 1 was used instead of the polarizing diffusion film of Example 1.

(Comparative Example 4)
A liquid crystal display device was prepared in the same manner as in Example 5 except that the stretched film of Comparative Example 2 was used instead of the polarizing diffusion film of Example 1.

(Comparative Example 5)
Instead of the polarizing diffusion film of Example 1, a bead-coated diffusion film (total light transmittance 87%, transmission haze 48% when the surface opposite to the light diffusion surface is the light incident side) was used. A liquid crystal display device was prepared in the same manner as in Example 5.

Next, the front luminance and the diagonal luminance of the liquid crystal display devices obtained in Examples 3 to 5 and Comparative Examples 3 to 5 were measured by the following methods.
Specifically, the liquid crystal display device obtained in each example was placed on the X, Y, θ stage of a color luminance meter (BM-7 manufactured by Topcon Technohouse Co., Ltd.), and a display screen central portion on which a polarizing diffusion film was disposed Was measured at a viewing angle of 1 °. At this time, the front luminance when the normal direction of the display surface coincides with the measurement axis of the color luminance meter, and the liquid crystal display device has a normal direction of the display surface and a measurement axis of the color luminance meter of 40 °. The direction luminance, 60 ° luminance, which is 60 °, was measured.

  On the other hand, for the reference liquid crystal display device prepared in Example 5, front luminance, 40 ° direction luminance, and 60 ° direction luminance were measured in the same manner as described above. With these luminances set to 100, the relative values of the respective luminances of the liquid crystal display devices obtained in the examples and the comparative examples were calculated. The results are shown in Table 2.

As shown in Table 2, in the liquid crystal display devices of Examples 3 and 4, the decrease in front luminance was less than 5% compared to the bead-coated diffusion film of Comparative Example 5, the relative luminance in the oblique direction was high, and the viewing angle was It was confirmed that it was improved. In addition, it was confirmed that the liquid crystal display device of Example 5 was higher in all of the front relative luminance, the 40 ° direction relative luminance, and the 60 ° direction relative luminance than the bead-coated diffusion film of Comparative Example 5. In the liquid crystal display devices of Examples 3 to 5, higher values were obtained in all of the front relative luminance, the 40 ° direction relative luminance, and the 60 ° direction relative luminance than the device without the polarizing diffusion film of the present invention. The effect of elevation and viewing angle improvement was confirmed.
On the other hand, the liquid crystal display devices of Comparative Example 3 and Comparative Example 4 have higher relative luminance in the oblique direction than the bead-coated diffusion film of Comparative Example 5, but lower the front luminance by 7% or more, and the effect as a diffusion film is limited. It was also confirmed that

  According to the present invention, it is possible to provide a film that is easy to manufacture and efficiently transmits and diffuses specific polarized light from light incident from the surface of the film, and efficiently reflects polarized light orthogonal to the specific polarized light. This film is useful as a liquid crystal display device.

Exploded view showing an example of a liquid crystal display device of the present invention FIG. 6 illustrates a display mechanism of a liquid crystal display device of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Liquid crystal cell 20 Upper polarizing plate 21 Lower polarizing plate 30 Polarizing diffuser film 40 Optical element 50 Light guide plate 60 Reflective sheet 70 Light source 100 Non-polarized light from light source 101 Polarized light V
102 Polarization P
103 Polarization V
104 Reflected light

Claims (10)

A resin film obtained by stretching a sheet made of a resin having an intrinsic birefringence of 0.1 or more mainly in a uniaxial direction,
There is a gap inside the film,
50 to 90% of total light transmittance for visible light,
A polarizing diffusion film having a transmission haze with respect to visible light of 15 to 70% and a transmission polarization degree with respect to visible light of 20 to 90%.   The polarizing diffuser film according to claim 1, wherein the transmission haze is 25 to 60%, and the transmission polarization degree is 30 to 90%.   The polarizing diffuser film according to claim 1 or 2, wherein the total light transmittance for polarized light perpendicular to the stretching axis is 10% or more higher than the total light transmittance for polarized light parallel to the stretching axis.   The polarizing diffusion film according to claim 1, wherein the resin is a polyester-based resin, an aromatic polyether ketone resin, or a liquid crystalline resin. The polarizing diffusion according to any one of claims 1 to 4, which is obtained through a step of foaming a sheet made of a resin having an intrinsic birefringence of 0.1 or more, and a step of stretching the foamed sheet mainly in a uniaxial direction. the film. The polarizing diffusion film according to claim 1, wherein the step of stretching the sheet is a step of stretching the sheet at a temperature T represented by the following formula (1).
Tg−50 ° C. ≦ T ≦ Tg + 10 ° C. (1)
(In Formula (1), Tg represents the glass transition temperature of the resin) (A) a liquid crystal backlight surface light source,
(B) At least one optical element and / or air gap (C) The polarizing diffusion film according to any one of claims 1 to 6, and (D) A liquid crystal cell is sandwiched between two or more polarizing plates. A liquid crystal display device comprising: a liquid crystal panel comprising: the members (A) to (D) arranged in the order described above.   The liquid crystal display device according to claim 7, wherein the (C) polarizing diffusion film is disposed adjacent to the (D) liquid crystal panel.   The liquid crystal display device according to claim 7, wherein the (C) polarizing diffusion film also serves as a light source side protective film of a polarizing plate constituting the (D) liquid crystal panel. (C) the stretching axis of the polarizing diffusion film;
The liquid crystal display device according to any one of claims 7 to 9, wherein (D) a polarizing plate constituting the liquid crystal panel and substantially the same as the absorption axis direction of the polarizing plate disposed on the light source side.

Images