KR20130126759A - Ethylene-modified polyvinyl alcohol polymer film - Google Patents

Abstract

An ethylene-modified PVA-based polymer film containing an ethylene-modified PVA-based polymer having good stretchability and productivity and having an ethylene unit content of 1 to 4 mol% and satisfying the following formulas (I) and (II).
Δn (MD) _Ave -0.1 × 10 ^-3 ≤ Δn (TD) _Ave ≤ Δn (MD) _Ave + 0.25 × 10 ^-3 (I)
Δn (TD) _Ave ≤ 2.5 × 10 ^-3 (II)
[Wherein, Δn (MD) _Ave represents a value obtained by averaging the birefringence in the machine flow direction of the ethylene-modified PVA-based polymer film in the thickness direction of the film, and Δn (TD) _Ave is the ethylene-modified PVA-based polymer film Represents a value obtained by averaging the birefringence in the width direction in the thickness direction of the film.]

Description

Ethylene-modified polyvinyl alcohol polymer film {ETHYLENE-MODIFIED POLYVINYL ALCOHOL POLYMER FILM}

The present invention relates to a polyvinyl alcohol polymer film (hereinafter sometimes abbreviated as "PVA" in "polyvinyl alcohol") modified with ethylene and a method for producing a polarizing film using the same. More specifically, the present invention does not easily break the film even when stretched at a high speed and at a high magnification, so that the stretched film having excellent optical performance such as polarization performance is high without causing interruption of the stretching operation due to breakage of the film. The present invention relates to an ethylene-modified PVA-based polymer film that can be produced with good productivity and a method for producing a polarizing film using the same.

A polarizing plate having a function of transmitting and shielding light is an important component of a liquid crystal display (LCD) together with a liquid crystal having a switching function of light. The field of application of this liquid crystal display device is also small devices such as electronic desk calculators and wristwatches in the early stages of development, such as notebook PCs, liquid crystal monitors, liquid crystal color projectors, liquid crystal televisions, in-vehicle navigation systems, mobile phones, and measuring instruments used indoors and outdoors. It has been expanded to a wide range of, and in particular, large screens are being progressed in liquid crystal monitors and liquid crystal televisions.

A polarizing plate is generally a method of dyeing a PVA-based polymer film after uniaxial stretching using iodine or a dichroic dye, a method of dyeing a PVA-based polymer film after monoaxially stretching and performing a fixation treatment with a boron compound, the In any method, a polarizing film is manufactured by the method of performing a dyeing | staining process simultaneously with dyeing, etc., and bonding protective films, such as a cellulose triacetate film and a cellulose acetate butyrate cellulose film, to one or both surfaces of the polarizing film obtained by it. Are prepared.

In recent years, with the expansion of the use of a liquid crystal display device and the like, in addition to the enhancement of the display quality, further reductions in costs and further improvement in handling are required. In terms of cost reduction, it is possible to improve the production speed at the time of manufacturing the polarizing film, to prevent breakage (break) when stretching the PVA polymer film, to reduce the breakage loss and to improve the yield. It is necessary to prevent the interruption of the stretching operation or the stretching or dyeing operation due to the breakage.

Moreover, as one of the productivity improvement at the time of manufacturing a polarizing film, shortening of the drying time at the time of manufacturing a polarizing film is calculated | required, In this point, as a raw film for polarizing films, conventionally thickness is 75 PVA-based polymer films having a thickness of about μm have been generally used, but a thinner PVA-based polymer film having a thickness of more than 70 μm has recently been demanded.

However, the thinner the PVA-based polymer film, there is a problem that breakage is more likely to occur when the film is stretched at a high speed and at a high magnification. In this respect, the film can be stretched at a high speed and at a high magnification without causing breakage even if thin. There is a demand for a PVA-based polymer film capable of producing a polarizing film having a polarization performance equivalent to or higher than that of a product with good workability, high yield, low cost, and good productivity.

Conventionally, a stock solution containing a PVA-based polymer is used for the purpose of improving the stretchability of the PVA-based polymer film, improving the uniformity at the time of stretching, improving the polarization performance and durability in a polarizing film obtained by stretching the PVA-based polymer film. In forming a film while drying, the adjustment of the film production draw (ratio of the conveyance rate of the PVA polymer film between the rolls used for the film production), the moisture content of the PVA polymer film during film production, and the like have been made.

As such a conventional technique, in order to obtain the stretched film fully molecularly oriented when (1) uniaxial stretching is carried out, the film-making operation for manufacturing a PVA-based polymer film is adopted by a film-making draw of 1 or less, (T) A method for obtaining a PVA-based polymer film capable of stretching at high magnification; (2) Patent Document 1, in particular its paragraphs [0008] to [0009], Examples, etc .; When manufacturing a PVA-type polymer film using a film making machine, the method of making [the obtained winding speed of the obtained PVA-type polymer film] / [speed of the drum located in the most upstream to which film-forming raw material is supplied] set to 0.8-1.3 (patent document) (3) In the drying process at the time of manufacturing a PVA-type polymer film using a drum film maker for the purpose of obtaining the PVA-type polymer film which can be extended | stretched with high magnification, the volatile fraction of a film is The method (patent document 3) etc. which make the speed ratio Rf / Rc of the process speed Rc and final winding speed Rf at the time of becoming 10 weight% or less to 0.9-1.1 are known.

(4) In order to obtain the PVA system film which can manufacture the wide polarizing film which has uniform optical performance also in large area, the speed of the drying roll located in the process in which the volatile matter of a PVA film becomes 10% or less ( The speed ratio (Rf / Rc) between Rc and the winding speed Rf is controlled to 0.9 to 1.1 to reduce the temperature variation of the drying step, and the tensile elongation S _{M in the} MD direction and the TD direction. Method of manufacturing PVA system film whose ratio (S _M / S _T ) of tensile elongation (S _T ) of 0.7-1.3 (Patent Document 4); (5) Wide polarization which has uniform optical performance also in large area In order to obtain the PVA system film which can manufacture a film, when the volatile content of a PVA film reaches 10-50 weight%, while peeling a PVA film from the drum located on the most upstream, the speed of the drum located in the most upstream (V1) and the ball in which the volatile matter of the PVA film became less than 10% by weight for the first time The velocity ratio (V2 / V1) of the speed (V2) of the drum which is located on the method of 1.0 to 1.3 (Patent Document 5) are known.

(6) In order to obtain a PVA-based polymer film composed of a specific skin layer / core layer / skin layer capable of uniform uniaxial stretching and providing a stretched film free of fine cracks or voids when stretched, a PVA-based polymer may be used. While heating the stock solution containing 50 to 90 mass% of volatile matter with the first drying roll, hot air is sprayed on the PVA-based polymer film surface which is not in contact with the first drying roll under predetermined conditions, and the volatile fraction is 15 to 30 mass. At the time point when it became%, the PVA-based polymer film was peeled off from the first drying roll and brought into contact with the second drying roll to be dried. At that time, the peripheral speed (S ₁ ) of the first drying roll and the peripheral speed of the second drying roll were and a method that a ratio (S ₂ / S ₁₎ of the (S _2), 1.000 ~ 1.100 (Patent Document 6) is known.

Japanese Unexamined Patent Publication No. Hei 6-136151 Japanese Unexamined Patent Publication No. 2001-315141 JP 2001-315146 A Japanese Laid-Open Patent Publication 2002-30164 Japanese Unexamined Patent Publication No. 2002-79531 Japanese Laid-Open Patent Publication 2005-324355

 `` Mineral Properties of Polymer Science One Point 10 Polymers '', First Edition, Kyoritsu Publishing Co., December 15, 2007, p.19-21

However, in Patent Documents 1 to 6 described above, measures for preventing breakage of the film when uniaxially stretching a PVA-based polymer film, particularly a thin PVA-based polymer film at high magnification, and in particular, the limit draw ratio of the film are described. It is not disclosed about the method for further improving. Moreover, in the prior arts, such as the said patent documents 1-6, when raising a extending | stretching speed, it is easy to produce a problem, such as a film breaking during the extending process, and it was difficult to extend at high speed.

An object of the present invention is that the film is not easily broken even when drawn at a high speed and at a high magnification, so that a stretched film such as a polarizing film having an optical performance equal to or higher than that of a conventional product can be produced with good yield, low cost, and good productivity. It is to provide a PVA-based polymer film that can be produced.

In particular, it is an object of the present invention to cope with a high draw speed even though thinner than a PVA-based polymer film conventionally used in the manufacture of a polarizing film, and to cope with a high draw speed, and to smoothly break at high speed and at high magnification. The PVA-based polymer film which can be uniaxially stretched and can be made into a thinner stretched film than before, further shortens the drying time when manufacturing the polarizing film, and can produce the polarizing film with better productivity. To provide.

It is also an object of the present invention to provide a method for producing a polarizing film using the PVA-based polymer film.

In order to achieve the above object, the present inventors have diligently studied to produce a PVA polymer film (ethylene modified PVA polymer film) using an ethylene modified PVA polymer containing a specific amount of ethylene units. The value obtained by averaging the birefringence in the mechanical flow direction (length direction) of the film in the thickness direction of the film and the value in which the birefringence in the width direction is averaged in the thickness direction of the film satisfy the specific relationship. When the value obtained by averaging the birefringence in the width direction of the film in the thickness direction is set to a specific numerical range, breakage of the film does not occur easily even at a high speed and at a high magnification, such as a polarizing film having excellent optical performance such as polarization performance. What can be produced with good productivity at high yield and low cost without interrupting the stretching operation It was his wife.

In particular, the value obtained by averaging the birefringence in the mechanical flow direction of the ethylene-modified PVA-based polymer film in the thickness direction of the film and the value in which the birefringence in the width direction is averaged in the thickness direction of the film satisfies a specific relationship, and also in the width direction. In the ethylene-modified PVA-based polymer film described above, in which a value obtained by averaging the birefringence in the thickness direction of the film is in a specific range, the thickness of the film is thinner than the thickness of the PVA-based polymer film generally used in the manufacture of polarizing films. Even if the thickness is about 10 to 65 µm, the film can be smoothly uniaxially stretched at high speed and at high magnification without causing breakage, thereby further thinning the film in manufacturing the polarizing film, and drying time in manufacturing the polarizing film. The present invention was found to be further shortened, and further studies were repeated based on such knowledge.

That is, the present invention,

[1] an ethylene-modified PAV-based polymer film containing an ethylene-modified PVA polymer having a content ratio of ethylene units of 1 to 4 mol% and satisfying the following formulas (I) and (II);

Δn (MD) _Ave -0.1 × 10 ^-3 ≤ Δn (TD) _Ave ≤ Δn (MD) _Ave + 0.25 × 10 ^-3 (I)

Δn (TD) _Ave ≤ 2.5 × 10 ^-3 (II)

[Wherein, Δn (MD) _Ave represents a value obtained by averaging the birefringence in the machine flow direction of the ethylene-modified PVA-based polymer film in the thickness direction of the film, and Δn (TD) _Ave is the ethylene-modified PVA-based polymer film Represents a value obtained by averaging the birefringence in the width direction in the thickness direction of the film.]

[2] the ethylene-modified PVA-based polymer film of the above-mentioned [1], which satisfies the following formula (III);

1.3 × 10 ⁻³ ≤ Δn (MD) _Ave ≤ 2.0 × 10 ^-3 (III)

[3] the ethylene-modified PVA-based polymer film of the above [1] or [2], having a thickness in the range of 10 to 65 µm;

[4] Dyeing and uniaxial stretching using the ethylene-modified PVA polymer film in any one of said [1]-[3], The manufacturing method of the polarizing film;

[5] The method according to the above [4], having a step of uniaxially stretching at a stretching rate of 300% / min or more based on the length of the ethylene-modified PVA-based polymer film before uniaxial stretching;

.

When the ethylene-modified PVA-based polymer film of the present invention produces a stretched film, even if it is uniaxially stretched at high speed and at high magnification, the breakage of the film does not occur easily, and thus, stretching of a polarizing film having excellent optical performance such as polarization performance is performed. The film can be produced with good productivity at high yield and low cost without interrupting the stretching operation.

In particular, the ethylene-modified PVA-based polymer film of the present invention does not cause breakage even if the thickness of the film is about 10 to 65 µm, which is thinner than the thickness of the PVA-based polymer film that has been generally used to manufacture polarizing films and the like. Therefore, it is possible to smoothly uniaxially stretch at high speed and at high magnification, thereby making it possible to further reduce the thickness of the stretched film when manufacturing the stretched film and to further shorten the drying time when manufacturing the polarizing film. Productivity can be improved.

In addition, PVA-based polymer films having a length of more than 1000 m have also recently been used as disc films for polarizing films. Since the ethylene-modified PVA-based polymer films of the present invention have a high limit of draw ratio, they are much higher than conventional ones. It can extend | stretch and can make it the amount of acquisition of the polarizing film from an ethylene modified PVA system polymer film more than before.

And by employ | adopting the manufacturing method of the polarizing film of this invention, a polarizing film excellent in polarization performance can be manufactured with favorable productivity with high yield and low cost, without interrupting an extending | stretching operation.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows the sample collection method at the time of measuring (DELTA) n (MD) _Ave of an ethylene modified PVA system polymer film.
It is a schematic diagram which shows the sample collection method at the time of measuring (DELTA) n (TD) _Ave of an ethylene modified PVA system polymer film.

Hereinafter, the present invention will be described in detail.

In general, in a transparent film produced by using a transparent polymer such as a PVA-based polymer, an atomic group constituting the polymer by aligning the polymer chain in a flow direction (machine flow direction: longitudinal direction) according to plastic deformation or deformation caused by shear stress. The direction of polarization becomes macroscopically constant, whereby birefringence peculiar to the polymer occurs (Non Patent Literature 1).

The birefringence [Δn (MD)] in the machine flow direction in the PVA polymer film is obtained from the following formula [i], and the birefringence [Δn (TD)] in the width direction is obtained from the following formula [ii]. .

Δn (MD) = nMD-nz [i]

Δn (TD) = nTD-nz [ii]

[Wherein nMD denotes a refractive index in the machine flow direction (length direction) of the film, nTD denotes a refractive index in the width direction of the film, and nz denotes a refractive index in the thickness direction of the film]

As described in Non-Patent Document 1, in a film produced using a transparent polymer such as a PVA-based polymer, the polymer chain forming the film is easily oriented in the machine flow direction (length direction), and the aforementioned patent document In the PVA-based polymer film including the PVA-based polymer film described in 1 to 6, generally, "birefringence in the machine flow direction [Δn (MD)]>" birefringence in the width direction [Δn (TD)] " In other words, the birefringence [Δn (MD)] in the machine flow direction tends to be larger than the birefringence [Δn (TD)] in the width direction.

In contrast, the ethylene-modified PVA-based polymer film of the present invention is different from the conventional PVA-based polymer film in that the following formulas (I) and (II) are satisfied.

Δn (MD) _Ave -0.1 × 10 ^-3 ≤ Δn (TD) _Ave ≤ Δn (MD) _Ave + 0.25 × 10 ^-3 (I)

Δn (TD) _Ave ≤ 2.5 × 10 ^-3 (II)

[Wherein, Δn (MD) _Ave represents a value obtained by averaging the birefringence in the machine flow direction of the ethylene-modified PVA-based polymer film in the thickness direction of the film, and Δn (TD) _Ave is the ethylene-modified PVA-based polymer film Represents a value obtained by averaging the birefringence in the width direction in the thickness direction of the film.]

That is, as shown by said Formula (I), in the ethylene modified PVA system polymer film of this invention, the machine flow direction of the ethylene modified PVA system polymer film (line direction at the time of continuous film formation of an ethylene modified PVA system polymer film) "Δn (MD) _Ave " which is the value which averaged the birefringence of the following "length direction (MD)" in the thickness direction of the said film is the width direction (length direction and the ethylene modified PVA system polymer film). Orthogonal direction) [hereinafter may be referred to as "width direction (TD)" below, equal to or smaller than "Δn (TD) _Ave " which is a value obtained by averaging the birefringence in the thickness direction of the film, or "Δn Even if (TD) _Ave "is exceeded, the quantity is insignificant.

In addition, the ethylene-modified PVA-based polymer film of the present invention also has a feature of satisfying the above formula (II) together with the above formula (I).

When the ethylene-modified PVA-based polymer film of the present invention satisfies the above formulas (I) and (II), even when the film thickness is thinner than before, it has a high limit draw ratio, thereby producing stretched films such as polarizing films. Even when uniaxially stretching at high magnification, the breakage of the film does not occur easily, and the thinned stretched film having excellent optical performance such as polarization performance is not produced without causing interruption of the stretching operation due to breakage of the film. It can be prepared by.

When it deviates from said Formula (I), the limit draw ratio of an ethylene modified PVA system polymer film will become low, and breakage of a film will occur easily when uniaxially stretched by high magnification, and breakage arises especially especially when thickness of a film is thin.

The ethylene-modified PVA-based polymer film of the present invention preferably satisfies the following formula (I '), more preferably satisfies the following formula (I' '), and satisfies the following formula (I' ''). More preferred.

Δn (MD) _Ave -0.05 × 10 ^-3 ≤ Δn (TD) _Ave ≤ Δn (MD) _Ave + 0.23 × 10 ^-3 (I ')

Δn (MD) _Ave ≤ Δn (TD) _Ave ≤ Δn (MD) _Ave + 0.2 × 10 ^-3 (I '')

Δn (MD) _Ave + 0.05 × 10 ^-3 ≤ Δn (TD) _Ave ≤ Δn (MD) _Ave + 0.18 × 10 ^-3 (I ''')

When the Δn (TD) _Ave of the ethylene-modified PVA-based polymer film exceeds 2.5 × 10 ⁻³ , the limiting draw ratio of the ethylene-modified PVA-based polymer film is lowered, resulting in ethylene-modified modification. It is difficult to stretch the PVA-based polymer film at high magnification in the longitudinal direction (MD), and it is difficult to obtain a stretched film having excellent optical performance.

In order to make Δn (TD) _Ave excessively small, it is necessary to allow dry shrinkage in the width direction at the time of production of the ethylene-modified PVA-based polymer film, so that the effective width yield of the ethylene-modified PVA-based polymer film tends to decrease. ethylene-modified PVA-based polymer film of the present invention Δn (TD) _Ave is ^{1.5 × 10 -3 ~ 2.2 × 10} - 3 , and preferably in the range ^{of, 1.6 × 10 -3 ~ 2.0 ×} 10 - in the range of ³ It is more preferable.

It is preferable that the ethylene modified PVA system polymer film of this invention further satisfy | fills following formula (III) in addition to said Formula (I) and (II).

1.3 × 10 ⁻³ ≤ Δn (MD) _Ave ≤ 2.0 × 10 ^-3 (III)

When Δn (MD) _Ave of the ethylene-modified PVA-based polymer film is 2.0 × 10 ⁻³ or less, the limit draw ratio of the ethylene-modified PVA-based polymer film is further increased, and the ethylene-modified PVA-based polymer film is moved in the longitudinal direction (MD). It is easy to extend | stretch to high magnification, and the stretched film excellent in optical performance is obtained more easily. On the other hand, in order to make Δn (MD) _Ave of the ethylene-modified PVA-based polymer film less than 1.3 × 10 ⁻³ , it is necessary to greatly reduce the peripheral speed ratio of the dry roll. There exists a tendency for loosening to occur easily in a polymer film.

In the range of ^{3-ethylene-modified} PVA-based polymer film of the present invention Δn (MD) _Ave is ^{1.4 × 10 -3 ~ 1.95 × 10} - more preferably in the range of ^{3 and, 1.5 × 10 -3 ~ 1.9 ×} 10 More preferably.

In addition, in the ethylene-modified PVA polymer film, there are many variations in the values of Δn (MD) _Ave and / or Δn (TD) _Ave in the width direction (TD) of the film, and in particular, at both ends in the width direction, Δn ( MD) _{Ave tends} to increase, but at least the formulas (I) and (II) in the center of the width direction (TD) of the ethylene-modified PVA-based polymer film are preferably satisfied of formulas (I) to (III), and ethylene Formulas (I) and (II) are preferably in the whole region of 80% or more of the width direction (TD) centered on the center of the width direction (TD) of the modified PVA-based polymer film, preferably formulas (I) to (III) It is preferable to satisfy). Both ends of the width direction (TD) of the ethylene-modified PVA-based polymer film that do not satisfy the formulas (I) and (II) are cut off and removed (trimmed) before stretching the ethylene-modified PVA-based polymer film in the longitudinal direction (MD). can do.

"Δn (MD) _Ave " of the ethylene-modified PVA-based polymer film [value obtained by averaging the birefringence in the longitudinal direction (MD) of the ethylene-modified PVA-based polymer film in the thickness direction of the film] and "Δn (TD) _Ave " [ A value obtained by averaging the birefringence in the width direction (TD) of the ethylene-modified PVA polymer film in the thickness direction of the film] can be measured by the following method.

《1》 Measurement of Δn (MD) _Ave :

(Here, the measuring method of (DELTA) n (MD) _Ave in the width direction (TD) center part of an ethylene modified PVA system polymer film is illustrated.

(i) MD * TD = 2mmx from the center part in the width direction (TD) of a film, as shown to Fig.1 (a) at arbitrary positions of the longitudinal direction (MD) of an ethylene modified PVA system polymer film. Three pieces of 10 mm in size are cut out, and the pieces are sandwiched by a PET film having a thickness of 100 µm, and the pieces are sandwiched again between wooden frames to be mounted on a microtome apparatus.

(ii) Next, the three pieces collected above are sliced at intervals of 10 μm in parallel with the longitudinal direction (MD) of the three pieces, as shown in FIG. 1 (b) (PET film and wooden frame not shown). Ten slice pieces for observation (MD * TD = 2mm * 10micrometer) shown to 1 (c) are manufactured. Among the slice pieces, five slice pieces having smooth slice surfaces and no slice thickness variation are selected, and each slice piece is placed on a slide glass and the slice thickness is measured by a microscope (manufactured by Keyence Co., Ltd.). In addition, observation is performed by the eyepiece 10 times and the objective 20 times (total 200 times).

(iii) Subsequently, the slice piece is turned down as shown in Fig. 1 (d) so that the slice face can be observed, and the slice face is faced up and placed on a slide glass and sealed with cover glass and silicone oil (refractive index 1.04), and two-dimensional photoelasticity. The retardation of five slice pieces is measured using evaluation system "PA-micro" (made by Photonic Latiss Corporation).

(iv) In the state where the retardation distribution of each slice piece is displayed on the measurement screen of "PA-micro", a line α perpendicular to the original film surface is drawn to cross the slice piece, and a line analysis is performed on the line segment α. Retardation distribution data of a film thickness direction are acquired. In addition, observation is performed by the eyepiece 10 times and the objective 20 times (total 200 times). Moreover, in order to suppress the error by the position which the line segment (alpha) passes on a slice piece, the average value of retardation is employ | adopted to make line width 300 pixels.

(v) The birefringence Δn (MD) distribution in the film thickness direction is obtained by dividing the value of the retardation distribution in the film thickness direction obtained by the microscope with the thickness, and the birefringence Δn (MD) distribution in the film thickness direction. The average value of is adopted. The average value of birefringence (DELTA) n (MD) distribution of each film thickness direction calculated | required about five slice pieces is averaged again, and it is set as "(DELTA) n (MD) _Ave. "

<< 2 >> Determination of Δn (TD) _Ave :

(Here, the measuring method of (DELTA) n (TD) _Ave in the width direction (TD) center part of an ethylene modified PVA system polymer film is illustrated.)

(i) MD * TD = 10mm * 2 from the center part in the width direction (TD) of a film, as shown to Fig.2 (a) at arbitrary positions of the longitudinal direction (MD) of an ethylene modified PVA system polymer film. The three pieces of mm size are cut out, the two pieces are sandwiched by a PET film having a thickness of 100 µm, and the pieces are sandwiched again between wooden frames to be mounted on the microtome apparatus.

(ii) Next, the three pieces collected above are sliced at intervals of 10 μm in parallel with the width direction TD of the three pieces as shown in FIG. 2 (b) (PET film and wooden frame are not shown), and FIG. Ten slice pieces for observation (MDxTD = 10micrometer * 2mm) shown to 2 (c) are manufactured. Five slice pieces with smooth slice surfaces and no slice thickness variation are selected from the slice pieces, and each is placed on a slide glass to measure the slice thickness with a microscope (manufactured by Keyence Co., Ltd.). In addition, observation is performed by the eyepiece 10 times and the objective 20 times (total 200 times).

(iii) Subsequently, slice slices are turned up as shown in Fig. 2 (d) so that the slice faces can be observed, and the slice faces upwards and placed on a slide glass and sealed with cover glass and silicone oil (refractive index 1.04), and two-dimensional photoelasticity. The retardation of five slice pieces is measured using evaluation system "PA-micro" (made by Photonic Latiss Corporation).

(iv) In the state where the retardation distribution of each slice piece is displayed on the measurement screen of "PA-micro", a line β perpendicular to the original film surface is drawn to cross the slice piece, and a line analysis is performed on the line segment β. Retardation distribution data of a film thickness direction are acquired. In addition, observation is performed by the eyepiece 10 times and the objective 20 times (total 200 times). Moreover, in order to suppress the error by the position where the line segment (beta) passes on a slice piece, the average value of retardation is employ | adopted as 300 pixel line width.

(v) The birefringence Δn (TD) distribution in the film thickness direction is determined by dividing the value of the retardation distribution in the film thickness direction obtained by the microscope with the thickness, and the birefringence Δn (TD) distribution in the film thickness direction. The average value of is adopted. The average value of birefringence (DELTA) n (TD) distribution of each film thickness direction calculated | required about five slice pieces is averaged again, and it is set as "(DELTA) n (TD) _Ave. "

The thickness of the ethylene-modified PVA-based polymer film of the present invention can be in the range of 5 to 150 µm, but in the case of using as a master for a polarizing film, the thickness is preferably 10 to 65 µm. Since the ethylene-modified PVA-based polymer film of the present invention has a high limit draw ratio and can cope with a high draw rate, the PVA-based polymer having a thickness of about 75 μm, which is often used as a raw material for a polarizing film, has been used. When the thickness is 10 to 65 占 퐉, which is thinner than that of the film, the film can be stretched at high speed and at high magnification without causing breakage of the film. In addition, the thickness of the film after extending | stretching can be made much thinner than before, by extending | stretching the ethylene modified PVA-type polymer film which is 10-65 micrometers in thickness at high magnification smoothly, and can manufacture with favorable productivity smoothly. The drying time at the time of manufacturing can be shortened, and the manufacturing speed of a polarizing film can be improved. From the viewpoint as described above, the thickness of the ethylene-modified PVA-based polymer film is more preferably 60 µm or less, further preferably 50 µm or less. In addition, when uniaxial stretching is performed at a higher temperature using a general PVA polymer film, the PVA polymer is dissolved in a bath used for stretching, or the film strength after water swelling is extremely lowered, so stretching is difficult. Although it may become a case, according to the ethylene modified PVA system polymer film of this invention, since the melt | dissolution to the said bath and the extreme fall of film strength can be suppressed, thickness can be made thinner. In this respect, the effect of the present invention is more marked when the thickness of the ethylene-modified PVA-based polymer film is less than 30 µm. If the thickness of the ethylene-modified PVA-based polymer film is too thick, it becomes difficult to dry quickly when producing the polarizing film.

On the other hand, when the thickness of an ethylene-modified PVA-based polymer film is too thin, breakage of the film easily occurs during uniaxial stretching for producing a polarizing film. From this viewpoint, the thickness of the ethylene-modified PVA polymer film is more preferably 15 µm or more, still more preferably 18 µm or more, and particularly preferably 20 µm or more.

Although the width of the ethylene-modified PVA-based polymer film of the present invention is not particularly limited, in recent years, since liquid crystal televisions and monitors are large screens, the width of the ethylene-modified PVA-based polymer film is preferably 2 m or more, and preferably 3 m or more in order to be effectively used for them. It is more preferable, and it is still more preferable that it is 4 m or more. Moreover, when manufacturing a polarizing plate with a realistic producer, since uniform uniaxial stretching may become difficult when the width | variety of a film is too large, it is preferable that the width of an ethylene modified PVA system polymer film is 8 m or less.

It is preferable that the swelling degree of the ethylene modified PVA system polymer film of this invention is 180 to 250%, It is more preferable that it is 185 to 240%, It is further more preferable that it is 190 to 230%. If the mass swelling degree of the ethylene-modified PVA-based polymer film is too low, it may not be easily stretched, and it may be difficult to produce a stretched film having excellent optical performance. On the other hand, if the mass swelling degree is too high, the process passability at the time of stretching is high. It may deteriorate or a highly durable polarizing film may not be obtained.

The mass swelling degree herein means a percentage of the value obtained by dividing the mass when the ethylene-modified PVA-based polymer film is immersed in 30 ° C. distilled water for 30 minutes by the mass after drying at 105 ° C. for 16 hours after the immersion. As can be measured by the method described in the following Examples.

Examples of the ethylene-modified PVA-based polymer contained in the ethylene-modified PVA-based polymer film of the present invention include ethylene-modified PVA and ethylene-modified PVA obtained by saponifying an ethylene-modified vinyl ester-based polymer obtained by copolymerizing ethylene and vinyl ester. Ethylene-modified PVA-based polymers prepared by graft copolymerization of comonomers in the main chain, ethylene-modified PVA-based polymers prepared by saponifying ethylene-modified vinyl ester polymers copolymerized with ethylene, vinyl esters, and other comonomers other than ethylene and comonomers other than ethylene So-called polyvinyl acetal resins obtained by crosslinking a part of the hydroxyl groups of an ethylene-modified PVA polymer not modified with ethylene or a ethylene-modified PVA-based polymer modified with a comonomer other than ethylene with formalin, butylaldehyde and benzaldehyde, etc. .

In the case where the ethylene-modified PVA-based polymer forming the ethylene-modified PVA-based polymer film of the present invention is an ethylene-modified PVA-based polymer modified with comonomers other than ethylene, the copolymers other than ethylene in the ethylene-modified PVA-based polymer It is preferable that it is 15 mol% or less, and, as for the modification amount, it is more preferable that it is 5 mol% or less.

As said vinyl ester used for manufacture of an ethylene modified PVA system polymer, For example, vinyl formate, vinyl acetate, a vinyl propionate, a vinyl butyrate, a vinyl valerate, a vinyl pivalate, a vinyl laurate, a vinyl stearate, benzoic acid, for example. Vinyl, vinyl basartate, and the like. These vinyl esters can be used alone or in combination. Among these vinyl esters, vinyl acetate is preferred from the viewpoint of production cost.

Moreover, as said comonomer (comonomers other than ethylene), For example, C3-C30 olefins (alpha-olefin etc.), such as propylene, 1-butene, isobutene; Acrylic acid or a salt thereof; Acrylic esters, such as methyl acrylate, ethyl acrylate, n-propyl acrylate, i-propyl acrylate, n-butyl acrylate, i-butyl acrylate, t-butyl acrylate, 2-ethylhexyl acrylate, dodecyl acrylate, and octadecyl acrylate ( For example, C1-C18 alkyl ester of acrylic acid; Methacrylic acid or its salt; Methyl methacrylate, ethyl methacrylate, n-propyl methacrylate, i-propyl methacrylic acid, n-methacrylate Methacrylic acid esters, such as butyl, i-butyl methacrylate, t-butyl methacrylate, 2-ethylhexyl methacrylate, dodecyl methacrylate, and octadecyl methacrylate (for example, of methacrylic acid C1-C18 alkyl ester); Acrylamide, N-methyl acrylamide, N-ethyl acrylamide, N, N- dimethyl acrylamide, diacetone acrylamide, acrylamide propanesulfonic acid or its salt, acrylamide propyl dimethylamine, orAcrylamide derivatives, such as a salt and N-methylol acrylamide or its derivatives; methacrylamide, N-methylmethacrylamide, N-ethyl methacrylamide, methacrylamide propanesulfonic acid or its salt, methacrylamide propyl dimethylamine Or methacrylamide derivatives such as salts thereof, N-methylol methacrylamide or derivatives thereof; N-vinylamides such as N-vinylformamide, N-vinylacetamide, and N-vinylpyrrolidone; methylvinyl ether Vinyl ethers such as ethyl vinyl ether, n-propyl vinyl ether, i-propyl vinyl ether, n-butyl vinyl ether, i-butyl vinyl ether, t-butyl vinyl ether, dodecyl vinyl ether and stearyl vinyl ether; Nitriles such as acrylonitrile and methacrylonitrile; vinyl halides such as vinyl chloride, vinylidene chloride, vinyl fluoride and vinylidene fluoride; allyl compounds such as allyl acetate and allyl chloride; Derivatives such as unsaturated dicarboxylic acids such as maleic acid and itaconic acid, salts thereof or esters thereof; vinylsilyl compounds such as vinyltrimethoxysilane; isopropenyl acetate; unsaturated sulfonic acid or derivatives thereof, and the like. Among these, an alpha olefin is preferable.

The content rate of the ethylene unit of the ethylene modified PVA system polymer which the ethylene modified PVA system polymer film of this invention contains is in the range of 1-4 mol%, It is preferable to exist in the range of 1.5-3.5 mol%. When the content rate of the ethylene unit is 1 mol% or more, it becomes possible to cope with a high stretching speed and breakage of the film does not occur well even when uniaxially stretching at a high speed and at a high magnification, thereby resulting in a polarizing film having excellent optical performance such as polarization performance. The stretched film can be produced with good productivity at high yield and low cost without interrupting the stretching operation. On the other hand, when the content rate of the ethylene unit is 4 mol% or less, the water solubility of the ethylene-modified PVA-based polymer can be maintained at a high level, and the productivity is increased when the ethylene-modified PVA-based polymer film is produced from a film-forming stock solution containing water. While improving, the dyeability of the ethylene-modified PVA polymer film obtained and the stability of the iodine complex which is a polarizing element can be improved, and the hue of the polarizing film obtained can prevent a blue group-green group from becoming.

The average degree of polymerization of the ethylene-modified PVA-based polymer forming the ethylene-modified PVA-based polymer film of the present invention is preferably 1000 or more, more preferably 1500 or more, even more preferably 2000 or more in terms of polarization performance and durability of the resulting polarizing film. desirable. On the other hand, the upper limit of the average degree of polymerization of the ethylene-modified PVA-based polymer is preferably 8000 or less, particularly preferably 6,000 or less, in view of the ease of production of the homogeneous ethylene-modified PVA-based polymer film, the stretchability, and the like.

Here, the "average degree of polymerization" of the ethylene-modified PVA-based polymer in the present specification refers to the average degree of polymerization measured according to JIS K6726-1994, and after re-saponifying and purifying the ethylene-modified PVA-based polymer in water at 30 ° C. It is calculated | required from the measured ultimate viscosity.

The saponification degree of the ethylene-modified PVA-based polymer contained in the ethylene-modified PVA-based polymer film of the present invention is preferably 95.0 mol% or more, more preferably 98.0 mol% or more, in terms of polarization performance and durability of the resulting polarizing film, 99.0 mol% or more is more preferable, and 99.3 mol% or more is the most preferable. On the other hand, in order to obtain an ethylene-modified PVA-based polymer having a saponification degree of more than 99.999 mol%, it is necessary to react with a strong saponification catalyst for a long time, so that the manufacturing cost is easily increased and problems such as coloring due to side reactions are easily caused. The saponification degree of the ethylene-modified PVA-based polymer is preferably 99.999 mol% or less.

Here, the "saponification degree" of the ethylene-modified PVA-based polymer in the present specification refers to the total moles of the structural units (typically vinyl ester units) and vinyl alcohol units that can be converted into vinyl alcohol units by saponification. The ratio (mol%) which the mole number of a vinyl alcohol unit occupies says. The saponification degree of an ethylene modified PVA system polymer can be measured according to description of JISK6726-1994.

The ethylene-modified PVA-based polymer film of the present invention may contain only the above-described ethylene-modified PVA-based polymer as the PVA-based polymer, but may contain other PVA-based polymers other than that together with the ethylene-modified PVA-based polymer. It is preferable that the content rate of the said ethylene modified PVA system polymer in the ethylene modified PVA system polymer film of this invention is 50 mass% or more, It is more preferable that it is 80 mass% or more, It is further more preferable that it is 90 mass% or more.

Although the manufacturing method of the ethylene modified PVA system polymer film of this invention is not specifically limited, You may manufacture by any method as long as it is a method which can manufacture the ethylene modified PVA system polymer film which satisfy | fills said Formula (I) and (II), Ethylene-modified PVA-based polymer film of the present invention,

(a) A membrane-forming stock solution containing an ethylene-modified PVA-based polymer on a first dry roll of the membrane-forming apparatus, using a membrane-forming apparatus including a plurality of drying rolls in which the rotation axes are parallel to each other. After discharging to a portion and partially drying, drying with a drying roll subsequent thereto to form a film;

(b) The ratio (S _T / S ₁ ) of the circumferential speed S _T of the dry roll when the volatile fraction of the ethylene-modified PVA polymer film became 13 mass% with respect to the circumferential speed S ₁ of the first drying roll. 0.990 to 1.050;

(c) an ethylene-modified PVA-based a ratio (S _L / S _T) of the polymer film-volatile content ratio of a peripheral speed (S _L), the final dry roll to the main speed (S _T) of the drying roll when it is 13% by mass 0.960 To 0.980;

to the (d) ratio (S _L / S ₁₎ of claim 1, the peripheral speed (S _L) of the final drying of the peripheral speed of the roll (S ₁₎ of the drying roll with 0.970 ~ 1.010;

By the manufacturing method which consists of these, it can manufacture continuously and smoothly with high productivity.

The manufacturing method of said ethylene modified PVA system polymer film is demonstrated more concretely below.

The film-forming stock solution containing an ethylene-modified PVA-based polymer may be prepared by mixing the ethylene-modified PVA-based polymer with a liquid medium to form a solution, or by melting an ethylene-modified PVA-based polymer pellet or the like containing a liquid medium into a melt. Can be.

Melting of an ethylene-modified PVA-based polymer into a liquid medium, melting of the ethylene-modified PVA-based polymer pellets containing a liquid medium and the like can be carried out using a stirring mixer, a melt extruder or the like.

As a liquid medium used at that time, water, dimethyl sulfoxide, dimethylformamide, dimethylacetamide, N-methylpyrrolidone, ethylenediamine, diethylenetriamine, etc. are mentioned, for example, These liquid media Can be used individually by 1 type or in combination of 2 or more type. Of these, water, dimethylsulfoxide, or a mixture of both is preferably used, and water is more preferably used.

Addition of a plasticizer to the membrane-forming stock solution in terms of promoting dissolution and melting of the ethylene-modified PVA-based polymer in the liquid medium, improvement of process passability during film production, and improvement of the stretchability of the resulting ethylene-modified PVA-based polymer film. desirable.

As a plasticizer, polyhydric alcohol is used preferably, For example, ethylene glycol, glycerin, diglycerol, propylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol, trimethylol propane, etc. are mentioned, These plasticizers are 1 A species can be used individually or in combination of 2 or more types. Among these, 1 type, or 2 or more types of glycerin, diglycerol, and ethylene glycol are used preferably from the point which is excellent in the effect of extending | stretching property.

As for the addition amount of a plasticizer, 0-30 mass parts is preferable with respect to 100 mass parts of ethylene modified PVA system polymers, 3-25 mass parts is more preferable, 5-20 mass parts is especially preferable. When the addition amount of a plasticizer exceeds 30 mass parts with respect to 100 mass parts of ethylene modified PVA system polymers, the ethylene modified PVA system polymer film obtained may become soft too much and handleability may fall.

It is preferable to add surfactant to a film-forming stock solution from a viewpoint of the peelability improvement from the dry roll at the time of manufacturing an ethylene modified PVA system polymer film, and the handleability of the ethylene modified PVA system polymer film obtained. The kind of the surfactant is not particularly limited, but an anionic surfactant or a nonionic surfactant is preferably used.

As the anionic surfactant, for example, carboxylic acid type such as potassium laurate, sulfate ester type such as octyl sulfate, and sulfonic acid type anionic surfactant such as dodecylbenzenesulfonate are preferable.

Moreover, as a nonionic surfactant, For example, Alkyl ether type, such as polyoxyethylene oleyl ether, Alkylphenyl ether type, such as polyoxyethylene octyl phenyl ether, Alkyl ester type, such as polyoxyethylene laurate, Alkylamine types, such as polyoxyethylene lauryl amino ether, Alkylamide types, such as polyoxyethylene lauric acid amide, Polypropylene glycol ether types, such as polyoxyethylene polyoxypropylene ether, Alkanolamide, such as oleic acid diethanamide Nonionic surfactants of allylphenyl ether type, such as a type and a polyoxyalkylene allyl phenyl ether, are preferable. These surfactant can be used individually by 1 type or in combination of 2 or more type.

As for the addition amount of surfactant, 0.01-1 mass part is preferable with respect to 100 mass parts of ethylene modified PVA system polymers, 0.02-0.5 mass part is more preferable, 0.05-0.3 mass part is especially preferable. When the amount is less than 0.01 part by mass, the film forming property and the peelability may not be improved. On the other hand, when the amount is greater than 1 part by mass, the surfactant may be eluted to the film surface, causing blocking, and the handling may be deteriorated. have.

The film-forming stock solution contains various additives such as stabilizers (for example, antioxidants, ultraviolet absorbers, heat stabilizers, etc.), compatibilizers, and blocking agents in a range that does not impair the properties of the ethylene-modified PVA-based polymer film of the present invention. It may contain an inhibitor, a flame retardant, an antistatic agent, a lubricant, a dispersant, a fluidizing agent, an antibacterial agent and the like. These additives can be used individually by 1 type or in combination of 2 or more type.

60-75 mass% is preferable, and, as for the volatile matter fraction of the film-forming stock solution used for manufacture of an ethylene modified PVA system polymer film, 65-70 mass% is more preferable. If the volatilization fraction of the membrane-forming stock solution is less than 60 mass%, the viscosity of the membrane-forming stock solution is high, and in addition to difficulty in filtration and defoaming, membrane production itself may be difficult. On the other hand, when the volatile fraction of a film-forming stock solution is larger than 75 mass%, a viscosity may become low too much and the uniformity of the thickness of an ethylene modified PVA system polymer film may be impaired.

Here, the "volatile fraction of the film-forming undiluted | stock solution" referred to in this specification means the volatile fraction calculated | required by following formula [iii].

Volatilization fraction (mass%) of film-forming stock solution = w (Wa-Wb) / Wa} × 100 [iii]

[Wherein, Wa represents the mass (g) of the membrane-forming stock solution, and Wb represents the mass (g) after drying the membrane-forming stock solution of Wa (g) for 16 hours in a 105 ° C electrothermal dryer.]

In the film production apparatus provided with a plurality of drying rolls in which the rotation axes are parallel to each other, used for producing the ethylene-modified PVA-based polymer film, the number of the drying rolls is preferably three or more, more preferably four or more, 5 It is more preferable that it is-30 individuals.

It is preferable that the some dry roll is formed with metals, such as nickel, chromium, copper, iron, stainless steel, for example, In particular, the surface of a roll does not corrode well and is formed with the metal material which has a mirror glossiness, It is more preferable that there is. Moreover, in order to improve the durability of a drying roll, it is more preferable to use the drying roll which plated the nickel layer, the chromium layer, the nickel / chromium alloy layer, etc. combining single layer or two or more layers.

It is preferable that it is 65 degreeC or more, and, as for the roll surface temperature of each dry roll in several drying rolls, it is more preferable that it is 75 degreeC or more. Moreover, it is preferable that the roll surface temperature of each dry roll is 100 degreeC or more, More preferably, it is 100-120 degreeC about the roll surface temperature of the dry roll which can be used as a heat processing roll in a final process or a process near it, It is preferable that roll surface temperature of other dry rolls is 100 degrees C or less.

The film production apparatus used by the said manufacturing method may have a hot air type hot air drying apparatus, a heat processing apparatus, a humidity control apparatus, etc. after a some drying roll as needed.

In discharging the membrane-forming stock solution containing the ethylene-modified PVA-based polymer onto the membrane on the first drying roll of the membrane-forming apparatus, for example, a T-type slit die, a hopper plate, an I-die, a lip coater die, or the like. Using the already known film discharge device (film casting device), a film production stock solution containing an ethylene-modified PVA-based polymer is discharged (flexible) onto the first drying roll as a film.

The liquid containing the ethylene-modified PVA-based polymer discharged in a film form on the first drying roll is dried on the first drying roll, and the volatile fraction of the ethylene-modified PVA-based polymer film is preferably 17 to 30% by mass, more preferably. It peels from a 1st dry roll at the time of becoming 17-29 mass%, More preferably, 18-28 mass%.

If the volatilization fraction of the ethylene-modified PVA-based polymer film at the time of peeling from the first drying roll is less than 17 mass%, the value of Δn (MD) _Ave relative to Δn (TD) _Ave becomes large and does not satisfy formula (I). On the other hand, when the volatilization fraction of the ethylene-modified PVA polymer film at the time of peeling from a 1st dry roll exceeds 30 mass%, peeling from a 1st dry roll becomes difficult, and in some cases, it breaks and a nonuniformity arises. It tends to be easy to do.

Here, the "volatile fraction of an ethylene-modified PVA-type polymer film or an ethylene-modified PVA-type polymer film" in this specification means the volatile fraction calculated | required by following formula [iv].

A (mass%) = ｛(Wc-Wd) / Wc} × 100 [iv]

[Wherein, A is the volatile fraction (mass%) of the ethylene-modified PVA-based polymer film or the ethylene-modified PVA-based polymer film, and Wc is the mass of the sample taken from the ethylene-modified PVA-based polymer film or the ethylene-modified PVA-based polymer film (g ), Wd represents the mass (g) when the sample Wc (g) is placed in a vacuum drier having a temperature of 50 ° C. and a pressure of 0.1 Pa or less and dried for 4 hours.]

In an ethylene-modified PVA-based polymer film or an ethylene-modified PVA-based polymer film formed from a membrane-forming stock solution prepared using a polyhydric alcohol (plasticizer) such as an ethylene-modified PVA-based polymer or glycerin, a surfactant, and water, the temperature described above is 50 ° C. When dried under the condition of 4 hours under a pressure of 0.1 kPa or less, mainly water is volatilized, and most of the other components except water are not volatilized and remain in the ethylene-modified PVA-based polymer film or the ethylene-modified PVA-based polymer film. The volatile fraction of the modified PVA-based polymer film or the ethylene-modified PVA-based polymer film can be obtained by measuring the amount of water (water content) contained in the ethylene-modified PVA-based polymer film or the ethylene-modified PVA-based polymer film.

At the time of drying in a 1st dry roll, it is preferable that the roll surface temperature of a 1st dry roll is 80-120 degreeC from a viewpoint of uniform drying property, a drying rate, etc., It is more preferable that it is 85-105 degreeC, It is more preferable that it is 93-99 degreeC. When the surface temperature of a 1st dry roll exceeds 120 degreeC, a film will become easy to foam, On the other hand, below 80 degreeC, drying on a 1st dry roll becomes inadequate and it becomes a cause of peeling defect.

A first peripheral speed (S ₁₎ of the drying rolls and to uniform drying characteristics, drying speed, and an ethylene-modified PVA-based point 8 ~ 25 m / min in the productivity of the polymer film is preferable, more preferably 11 ~ 23 m / min It is more preferable that it is 14-22 m / min. If the circumferential speed S ₁ of a 1st dry roll is less than 8 m / min, productivity will fall, and birefringence will become large easily, and it is unpreferable. On the other hand, when the circumferential speed S _{1 of} a 1st dry roll exceeds 25 m / min, drying on a 1st dry roll will become inadequate easily, and it is unpreferable.

Partial drying on the first drying roll of the film-forming stock solution containing the ethylene-modified PVA-based polymer discharged in the form of a film may be performed only by heat from the first drying roll, but is heated to the first drying roll and simultaneously with the first drying roll. Hot air is sprayed on the membrane surface which is not in contact (hereinafter may be referred to as the "first dry roll non-contact surface"), and heat is applied from both sides of the ethylene-modified PVA-based polymer membrane to perform drying and uniform drying rate. It is preferable at such a point.

In spraying hot air on the non-contacting surface of the first dry roll of the ethylene-modified PVA-based polymer film on the first drying roll, hot air having a wind speed of 1 to 10 m / sec is sprayed on the entire region of the first dry roll non-contacting surface. It is preferable to spray hot air with a wind speed of 2 to 8 m / sec, and more preferably to spray hot wind with a wind speed of 3 to 8 m / sec.

When the wind speed of the hot air sprayed on the non-contacting surface of the first drying roll is too small, it becomes difficult to obtain an ethylene-modified PVA-based polymer film having a high limit draw ratio, which is the object of the present invention, and at the time of drying on the first drying roll. Condensation, such as water vapor, arises, and the water droplets are dripped on an ethylene-modified PVA-type polymer film, and the defect in the ethylene-modified PVA-based polymer film finally obtained easily arises. On the other hand, if the wind speed of the hot air sprayed on the non-contacting surface of the first drying roll is too large, an ethylene-modified PVA-based polymer film having a high limit draw ratio, which is the object of the present invention, is difficult to be obtained, and the ethylene-modified PVA-based finally obtained Thickness deviation arises in a polymer film, and troubles, such as generation | occurrence | production of dyeing nonuniformity, arise easily by it.

It is preferable that it is 50-150 degreeC from the point of drying efficiency, the uniformity of drying, etc., and, as for the temperature of the hot air sprayed on the 1st dry roll non-contact surface of an ethylene modified PVA system polymer film, it is more preferable that it is 70-120 degreeC, 80 It is more preferable that it is-95 degreeC. Moreover, it is preferable that the dew point temperature of the hot air sprayed on the 1st dry roll non-contact surface of an ethylene modified PVA system polymer film is 10-15 degreeC. When the temperature of the hot air sprayed on the non-contact surface of the 1st dry roll of an ethylene-modified PVA system membrane is too low, drying efficiency, uniform drying property, etc. will fall easily, and when too high, foaming will arise easily.

The method for injecting hot air into the first dry roll non-contacting surface of the ethylene-modified PVA-based polymer film is not particularly limited, and the hot air having uniform wind speed and uniform temperature is preferably applied to the first dry roll non-contacting surface of the PVA-based polymer film, preferably Any method that can uniformly spray the whole can be employed, and among them, a nozzle method, a rectifying plate method or a combination thereof is preferably employed. The direction of spraying hot air to the first dry roll non-contacting surface of the ethylene-modified PVA-based polymer film may be a direction opposite to the first dry roll non-contacting surface, and is almost in accordance with the circumferential shape of the first dry roll non-contacting surface of the ethylene-modified PVA-based polymer membrane. Direction (direction substantially along the circumference of the roll surface of a 1st dry roll) may be sufficient, or a direction other than that may be sufficient.

In addition, at the time of drying of the ethylene-modified PVA-based polymer film on the first drying roll, it is preferable to exhaust the volatile matter generated from the ethylene-modified PVA-based polymer film by drying and hot air after the injection. Although the method of exhaustion is not specifically limited, It is preferable to employ | adopt the exhaust method which does not produce the wind speed variation and temperature deviation of the hot wind which injects to the 1st dry roll non-contact surface of an ethylene modified PVA system polymer film.

On the first drying roll, the ethylene-modified PVA-based polymer film preferably dried up to a volatile fraction of 17 to 30% by mass is peeled from the first drying roll, and this time, the first dry roll non-contact surface of the ethylene-modified PVA-based polymer film is second to the second. It is preferable to dry with a 2nd dry roll facing a dry roll.

The first non-(S ₂ / S ₁₎ of the peripheral speed (S ₂₎ of the second drying rolls to a peripheral speed (S ₁₎ of the drying roll is preferably in the range of 1.005 ~ 1.090, more preferably 1.010 ~ 1.080. When the ratio (S ₂ / S ₁ ) is less than 1.005, the peeling point of the ethylene-modified PVA-based polymer film from the first drying roll tends to be uneven, and the birefringence variation in the width direction becomes large and cannot be used as an optical film master. There is a case. Further, if the non-(S ₂ / S ₁₎ is more than 1.090 it is difficult to obtain according to the present invention has a high limit draw ratio of ethylene-modified PVA-based polymer film.

At the time of drying with a 2nd drying roll, it is preferable that the roll surface temperature of a 2nd drying roll is 65-100 degreeC, and, as for a uniform drying property, a drying rate, etc., it is more preferable that it is 65-98 degreeC, It is more preferable that it is 75-96 degreeC.

The ethylene-modified PVA polymer film dried with the second drying roll is peeled from the second drying roll, and the third drying roll, the fourth drying roll, the fifth drying roll,... It is made to dry sequentially by several drying rolls, such as these.

In that case, the above-described manufacturing method, the non-(S _T of the first peripheral speed (S _T) of the drying roll at the time of the peripheral speed (S ₁₎ of the drying roll, an ethylene-modified PVA-based polymer film volatile content ratio is 13 mass% / S ₁ ) is 0.990 to 1.050, and drying is performed while adjusting the tension applied to the ethylene-modified PVA polymer film. Here, "a dry roll when the volatile fraction of an ethylene-modified PVA-type polymer film became 13 mass%" means the said dry roll, when the volatile fraction of an ethylene-modified PVA-based polymer film became 13 mass% on a dry roll, When the volatilization fraction becomes 13 mass% between two drying rolls, it means the drying roll located behind one of the said two drying rolls. By setting the ratio (S _T / S ₁ ) in the above-described range, troubles such as loosening and sticking of the film are not generated in the drying step until the volatilization fraction of the ethylene-modified PVA-based polymer film becomes 13 mass%. Value [Δn (MD) _Ave ] obtained by averaging the birefringence in the longitudinal direction (MD) in the thickness direction of the film, and a value obtained by averaging the birefringence in the thickness direction of the film (Δn (TD) _Ave in the film direction. ] The ethylene-modified PVA-based polymer film of the present invention satisfying the above formulas (I) and (II), and also the formula (III) can be produced smoothly.

Wherein a ratio (S _T / S ₁₎ for producing the ethylene-modified PVA-based polymer film is preferably 1.000 ~ 1.045.

In the above production method, the ethylene-modified PVA-based polymer film having a volatile fraction of 13% by mass is dried again with a subsequent drying roll to prepare an ethylene-modified PVA-based polymer film. At that time, the ratio of the peripheral speed (S _L), the final dry roll to the main speed (S _T) of the drying roll at the time the above-described manufacturing method, an ethylene-modified PVA-based polymer film volatile content ratio is 13 mass% (S _L / to conduct drying while the S _T) in the range of 0.960 ~ 0.980. By making ratio (S _L / S _T ) into the above-mentioned range, in the drying process until obtaining a final ethylene-modified PVA-type polymer film, length does not generate | occur | produce trouble, such as loosening of a film and sticking. The value [Δn (MD) _Ave ] obtained by averaging the birefringence in the direction MD in the thickness direction of the film and the value [Δn (TD) _Ave ] obtained by averaging the birefringence in the thickness direction of the film in the direction [Δn (MD) _Ave ] Ethylene-modified PVA-type polymer film of this invention which satisfy | fills Formula (I) and (II), and also said Formula (III) can be manufactured smoothly.

Wherein a ratio (S _L / S _T) for producing the ethylene-modified PVA-based polymer film is preferably 0.963 ~ 0.976.

In producing the ethylene-modified PVA-based polymer film by the method described above, the value obtained by averaging the birefringence in the longitudinal direction (MD) of the ethylene-modified PVA-based polymer film in the thickness direction of the film [Δn (MD) _Ave ] And the value [Δn (TD) _Ave ] obtained by averaging the birefringence in the width direction TD in the thickness direction of the film is the ratio S between the peripheral speed S ₁ of the first drying roll and the peripheral speed S _L of the final drying roll. _L / S ₁ ) Fluctuates accordingly. , The end of the above formula (Ⅰ) and (Ⅱ), and further has a peripheral speed (S ₁₎ of the first drying roll to the formula (Ⅲ) smoothly producing the ethylene-modified PVA-based polymer film of the present invention satisfying the necessary to the ratio (S _L / S ₁₎ of the peripheral speed of the drying roll (S _L) in the range of 0.970 ~ 1.010, and it is preferable in the range of 0.972 ~ 1.008, is more preferably in the range of 0.975 ~ 1.006 Do. Thereby, the ethylene-modified PVA-based polymer film satisfying the above formulas (I) and (II) and further the above formula (III) can be produced smoothly while suppressing the occurrence of wrinkles and loosening.

In the above production method, the final drying roll, or the final drying roll close to the last and the final drying roll may be used as a heat treatment roll by increasing the surface temperature thereof. When using a dry roll as a heat processing roll, 90-140 degreeC is preferable and, as for roll surface temperature, 100-130 degreeC is more preferable.

Moreover, you may install a heat processing apparatus separately from a dry roll.

Although there is no restriction | limiting in particular in the heating direction at the time of drying an ethylene modified PVA system membrane in the process from a 1st dry roll to a final dry roll, In the point which can dry an ethylene modified PVA system polymer film more uniformly, an ethylene modified PVA system It is preferable to dry so that the surface and the back surface in any part of a polymer film may alternately contact each dry roll from a 1st dry roll to a final dry roll.

The ethylene-modified PVA-based polymer film of the present invention can be obtained by subjecting the ethylene-modified PVA-based polymer film subjected to the drying treatment to a heat treatment, a humidity control treatment, or the like as necessary, and finally winding the roll in a predetermined length.

It is preferable to exist in the range of 1-5 mass%, and, as for the volatile fraction of the ethylene modified PVA system polymer film finally obtained by said series of processes, it is more preferable to exist in the range of 2-4 mass%.

In order to manufacture a polarizing film from the ethylene-modified PVA-type polymer film of this invention, what is necessary is just to dye and uniaxially stretch using the ethylene-modified PVA-type polymer film of this invention, For example, the ethylene-modified PVA-type polymer film of this invention What is necessary is just to perform dyeing, uniaxial stretching, a fixed process, a drying process, and heat processing further as needed. The order of dyeing and uniaxial stretching is not particularly limited and may be a dyeing process before the uniaxial stretching process, a dyeing process simultaneously with the uniaxial stretching process, or a dyeing process after the uniaxial stretching process . The uniaxial stretching, dyeing, and the like may be repeated a plurality of times. Particularly, if the monoaxial stretching is divided into two or more stages, uniform stretching can be easily performed, which is preferable.

Examples of the dye used for dyeing the ethylene-modified PVA polymer film include iodine or a dichroic organic dye (for example, Direct Black 17, 19, 154; Direct Brown 44, 106, 195, 210, 223; Direct Red 2, 23, 28, 31, 37, 39, 79, 81, 240, 242, 247; Direct Blue 1, 15, 22, 78, 90, 98, 151, 168, 202, 236, 249, 270; Direct Violet 9, 12, 51, 98; Direct Green 1, 85; Direct Yellow 8, 12, 44, 86, 87; dichroic dyes such as Direct Orange 26, 39, 106, and 107); These dyes may be used singly or in combination of two or more. Although dyeing can be normally performed by immersing an ethylene modified PVA type polymer film in the solution containing the said dye, the processing conditions and a processing method are not specifically limited.

Although the uniaxial stretching which extends an ethylene modified PVA system polymer film in the longitudinal direction (MD) may be performed by either a wet stretching method or a dry heat stretching method, the wet stretching method is preferable from a viewpoint of the performance and quality stability of the polarizing film obtained. Do. As the wet stretching method, a method of stretching an ethylene-modified PVA-based polymer film in an aqueous solution containing various components such as pure water, an additive or an aqueous medium, or an aqueous dispersion in which various components are dispersed may be mentioned. As a specific example of the uniaxial stretching method, the method of uniaxial stretching in the warm water containing boric acid, the method of uniaxial stretching in the solution containing the said dye, or a fixed process bath mentioned later, etc. are mentioned.

Although the extending | stretching temperature at the time of uniaxial stretching by a wet stretching method is not specifically limited, For example, although the temperature within the range of 30-90 degreeC and 40-70 degreeC can be employ | adopted, without breaking, It is preferable to employ | adopt the temperature within the range of 55-67 degreeC from the point which can uniaxially stretch at high speed more smoothly, It is more preferable to employ | adopt the temperature within the range of 57-65 degreeC, The range of 59-64 degreeC It is more preferable to employ the internal temperature. In particular, when dividing uniaxial stretching into two or more stages, it is especially preferable to employ | adopt the said temperature in the stage (at the last stage of a uniaxial stretching process) which a draw ratio becomes the largest.

The stretching speed at the time of uniaxial stretching is not specifically limited, For example, based on the length of the ethylene modified PVA system polymer film before uniaxial stretching, it can be 30% / min or more and 100% / min or more, According to the ethylene-modified PVA-based polymer film of the present invention, breakage of the film does not occur well even when uniaxially stretching at a high speed and at a high magnification, thereby stretching a stretched film such as a polarizing film having excellent optical performance such as polarization performance. It has a process of uniaxially stretching at a stretching speed of 300% / min or more based on the length of the ethylene-modified PVA-based polymer film before uniaxial stretching, in that it can be produced with good productivity at high yield and low cost without interruption. It is preferable, and it is more preferable to have the process of uniaxially stretching at the extending | stretching speed of 500% / min or more, and to uniaxially stretching at the stretching speed of 700% / min or more. It is more preferably a step. In addition, when the stretching speed is too fast, there is a tendency to cause problems such as breakage and uneven stretching during stretching, and the stretching rate is 2000% / min based on the length of the ethylene-modified PVA-based polymer film before uniaxial stretching. It is preferable not to exceed, it is more preferable not to exceed 1600% / min, it is still more preferable not to exceed 1300% / min, and it is especially preferable not to exceed 1000% / min.

It is preferable to extend | stretch as much as possible before the film is cut | disconnected from the point of polarization performance, and the draw ratio of a uniaxial stretching process (when the uniaxial stretching is carried out in multiple stages), and it is preferable that it is 4 times or more specifically, It is more preferable that it is 5 times or more, and it is further more preferable that it is 5.5 times or more. The upper limit of the draw ratio is not particularly limited as long as the film is not broken, but is preferably 8.0 times or less in order to perform uniform drawing.

It is preferable that the thickness of the film (polarizing film) after extending | stretching is 1-35 micrometers, especially 5-30 micrometers, However, when using the ethylene modified PVA system polymer film whose thickness is less than 30 micrometers as mentioned above, the film after polarizing (polarizing film) Film) can be 15 micrometers or less.

In the production of the polarizing film, fixing treatment is often carried out in order to strengthen the adsorption of the dye on the uniaxially stretched film. As a fixed treatment, a method of immersing a film in a treatment bath to which boric acid and / or a boron compound is added is generally widely adopted. In that case, you may add an iodine compound in a process bath as needed.

It is preferable to carry out the drying process (heat processing) of the film which performed the uniaxial stretching process or the uniaxial stretching process and the fixed process subsequently. It is preferable that the temperature of a drying process (heat processing) is 30-150 degreeC, especially 50-140 degreeC. If the temperature of the drying treatment (heat treatment) is too low, the dimensional stability of the resulting polarizing film tends to decrease, while if too high, the decrease in polarization performance accompanying decomposition of the dye tends to occur.

The protective film which is optically transparent and has mechanical strength is bonded together on both surfaces or single side | surface of the polarizing film obtained as mentioned above, and it can be set as a polarizing plate. As a protective film in that case, a cellulose triacetate (TAC) film, an acetic acid butyric-acid cellulose (CAB) film, an acryl-type film, a polyester film, etc. are used. As the adhesive for bonding the protective film, a PVA adhesive, a urethane adhesive, or the like is generally used, and among them, a PVA adhesive is preferably used.

The polarizing plate obtained as described above can be used as a component of a liquid crystal display device after being coated with a pressure-sensitive adhesive such as acrylic or the like and then adhered to a glass substrate. When bonding a polarizing plate to a glass substrate, you may bond together a retardation film, a viewing angle improvement film, a brightness improving film, etc. simultaneously.

Example

Although an Example demonstrates this invention concretely below, this invention is not limited at all by the following example.

In the following Examples, Reference Examples and Comparative Examples, the volatile fraction of the membrane-forming stock solution, the volatile fraction (water content) of the ethylene-modified PVA-based polymer film or the ethylene-modified PVA-based polymer film, the physical properties of the ethylene-modified PVA-based polymer film, And the optical performance of the polarizing film was measured by the following method.

(1) Volatilization fraction of film production stock:

According to the method mentioned above, it calculated | required by the said Formula [iii].

(2) Volatile fraction (water content) of an ethylene-modified PVA-based polymer film or an ethylene-modified PVA-based polymer film:

According to the above method, it calculated | required by said Formula [iv].

In addition, the measurement of the volatile fraction (water content) of an ethylene modified PVA system polymer film or an ethylene modified PVA system polymer film is collect | collected from the width direction (TD) center part of the ethylene modified PVA system polymer film or ethylene modified PVA system polymer film taken out from the drying roll. One sample was used.

(3) Δn (MD) _Ave of the ethylene-modified PVA polymer film:

(DELTA) n (MD) _Ave in the width direction (TD) center part of an ethylene modified PVA system polymer film was calculated | required by the method mentioned above in the item of "Measurement method of << 1 >> (DELTA) n (MD) _Ave ", and this is an ethylene modified PVA system. It was set as (DELTA) n (MD) _Ave of a polymer film.

(4) Δn (TD) _Ave of the ethylene-modified PVA polymer film:

(DELTA) n (TD) _Ave in the width direction (TD) center part of an ethylene modified PVA system polymer film was calculated | required by the method mentioned above in the item of "Measurement method of << 2 >> (DELTA) n (TD) _Ave ", and this is an ethylene modified PVA system. It was set as (DELTA) n (TD) _Ave of a polymer film.

(5) Mass swelling degree of ethylene-modified PVA-based polymer film:

The ethylene-modified PVA-based polymer film was cut to 1.5 g, immersed in 1000 g of 30 ° C. distilled water for 30 minutes, and after immersion for 30 minutes, the ethylene-modified PVA-based polymer film was taken out, and the surface water was sucked with a filter paper. Mass (W _e ) was measured. Subsequently, after drying the ethylene modified PVA system polymer film for 16 hours in the 105 degreeC dryer, the mass ( _Wf ) was measured. From the obtained masses (W _e and W _f ), the mass swelling degree of the ethylene-modified PVA polymer film was determined by the following formula [v].

Mass Swelling (%) = (W _e / W _f ) × 100 [v]

(6) Limit draw ratio of ethylene-modified PVA-based polymer film ：

From the width direction (TD) center part of the ethylene modified PVA system polymer film before extending | stretching obtained by the following example, the reference example, or the comparative example, the test piece of length direction (MD) x width direction (TD) = 10 cm x 5 cm was taken out, Both ends of the longitudinal direction of the said test piece are fixed to the extending | stretching jig so that the size of a extending | stretching part may become length direction (MD) x width direction (TD) = 5 cm x 5 cm, and it is immersed for 38 second in 30 degreeC water. During uniaxial stretching (first stage stretching) in the longitudinal direction (MD) at 2.2 times the original length at a stretching speed of 12 cm / min (240% / min), and then 0.03 mass% of iodine and potassium iodide of 3 mass% Uniaxially stretched in the longitudinal direction (MD) to 3.3 times the original length at a stretching rate of 12 cm / min (240% / min) while immersing in an aqueous solution of iodine / potassium iodide at a temperature of 30 ° C. for 30 seconds. Second stage), and then 3 mass% of boric acid and While immersing in an aqueous solution of boric acid / potassium iodide at a temperature of 30 ° C. containing potassium dihydride at a concentration of 3% by mass for about 20 seconds in the longitudinal direction at a stretching speed of 12 cm / min (240% / min) to 3.6 times its original length (MD) uniaxially stretched (third stage stretched), and then immersed in an aqueous solution of boric acid / potassium iodide at a predetermined temperature containing 4% by mass of boric acid and about 5% by mass of potassium iodide at a predetermined stretching rate. The uniaxial stretching (fourth step stretching) was performed in the longitudinal direction (MD) until the test piece broke, and the draw ratio (ratio of the length at the break to the original length) when the test piece was broken was read.

Said extending | stretching test was performed 5 times about the same ethylene modified PVA system polymer film, and the average value was taken and it was set as the limit draw ratio (times) of an ethylene modified PVA system polymer film.

(7) Optical performance of polarizing film ：

(i) Transmittance

From the width direction center part of the polarizing film obtained by the following example, the reference example, or the comparative example, two square samples of 1.5 cm x 1.5 cm were taken in parallel in the orientation direction of a polarizing film, and about each, the spectroscopy by Hitachi Ltd. In accordance with JIS Z8722 (Measurement Method of Object Color) using a photometer V-7100 (integrated sphere included), the visibility of the C light source and the visible light region in the 2-degree field of view was corrected, and one polarizing film sample was The transmittance of light when tilted at 45 degrees with respect to the stretch direction and the transmittance of light when tilted at −45 degrees were measured, and their average value (Y ₁ ) was obtained.

For the other one sheet of the polarizing film sample, by measuring the transmittance of light in the case in the same manner as the light transmittance of Fig 45 when tilted and inclined -45 degrees, it was determined their mean value (Y _2).

By averaging the Y ₁ and Y ₂ obtained in the above it was set to the transmittance of the polarizing film (Y) (%).

(ii) polarization degree:

The two sheets of polarizer film samples taken from the (i), wherein the light transmittance in case that the alignment direction is parallel to it such that overlap (Y ∥), and the light transmittance (Y⊥) in the case where the alignment direction are superposed so as to be perpendicular It measured by the method similar to the measuring method of transmittance | permeability, and calculated polarization degree (V) (%) from the following formula [vi].

Degree of polarization (V) (%) = { (Y ∥- Y⊥) / (Y ∥ + Y⊥)} 1/2 × 100 [vi]

(iii) Polarization degree in 44.25% transmittance:

As described in the following Examples, Reference Examples, and Comparative Examples, in each Example, Reference Example, or Comparative Example, five sheets prepared by changing the immersion time in an aqueous solution of iodine / potassium iodide at the time of the second stage stretching were prepared. For each polarizing film, the transmittance (Y) and the polarization degree (V) were obtained by the above-described method, and for each Example, Reference Example or Comparative Example, the transmittance (Y) was used as the horizontal axis and the polarization degree (V) as the vertical axis. Points were plotted on a graph to obtain an approximation curve, and the value of polarization degree (V) when the transmittance (Y) was 44.25% was obtained from the approximation curve.

&Quot; Example 1 &

(1) Preparation of ethylene-modified PVA polymer film ：

100 parts by mass of ethylene-modified PVA-based polymer (2.0 mol% of ethylene units, 99.9 mol% of saponification degree, polymerization degree 2400) obtained by saponifying ethylene-modified polyvinyl acetate obtained by copolymerizing ethylene and vinyl acetate, 12 parts by mass of glycerin Ur di ethanol amide 0.1 parts by mass of volatile matter and water comprising drying rate of the first roll of film production raw liquid from a T-die of 66 mass% (surface temperature 93 ℃, a peripheral speed (S ₁₎ 16.7 m / min), and dried on a first drying roll until a moisture content of 18% by mass was sprayed at a rate of 5 m / sec with a hot air of 90 deg. C on the entire first non-contact surface of the first drying roll. Next, it peels from a 1st drying roll and performs drying after a 2nd drying roll at roll surface temperature of about 85 degreeC so that the surface and back surface in arbitrary parts of an ethylene modified PVA system polymer film may contact each drying roll alternately. Finally, after heat-processing with the final drying roll (heat processing roll) of surface temperature of 108 degreeC, it wound up and obtained the ethylene modified PVA system polymer film (thickness 60micrometer, width 3m, volatile fraction 3 mass%). In this Example 1, the dry roll when the volatile fraction became 13 mass% was a 7th dry roll.

In this Example 1, (S) ratio (S) of the circumferential speed S _T of the drying roll (seventh dry roll) when the volatile fraction became 13 mass% with respect to the circumferential speed S ₁ of the first drying roll (α). _T / S ₁ ) as 1.000; (β) of the peripheral speed S _L of the final drying roll with respect to the peripheral speed S _T of the drying roll (seventh drying roll) when the volatile fraction became 13 mass%. Let ratio (S _L / S _T ) be 0.974; (γ) Ratio (S ₂ / S ₁ ) of the peripheral speed S ₂ of the second drying roll to the peripheral speed S _{1 of} the first drying roll is 1.030. (Δ) The circumferential speed (S _{T +1} ) of the next drying roll (eighth dry roll) with respect to the circumferential speed S _T of the drying roll (seventh dry roll) when the volatile fraction became 13 mass%. Let ratio (S _T / S _{T +1} ) be 0.998; (ε) Ratio of circumferential speed S _L of the final dry roll to circumferential speed S ₁ of the first drying roll (S _L / S ₁ ) Was 0.975, to prepare an ethylene-modified PVA polymer film.

Δn (MD) _Ave , Δn (TD) _Ave , mass swelling degree and limit draw ratio of the obtained ethylene-modified PVA-based polymer film (The temperature of the boric acid / potassium iodide solution of the fourth stage stretching is 63 ° C., and the stretching rate is 48 cm / min.) 960% / min) was measured by the above-mentioned method, and it was as showing in following Table 1.

(2) Preparation of Polarizing Film:

(i) The test piece of length direction (MD) x width direction (TD) = 10 cm x 5 cm was taken from the width direction (TD) center part of the ethylene modified PVA system polymer film obtained by said (1), and the length of the said test piece Both ends of the direction are fixed to the stretching jig so that the size of the stretched portion becomes the longitudinal direction (MD) x width direction (TD) = 5 cm x 5 cm, and 12 cm / while immersed in water at a temperature of 30 ° C. for 38 seconds. After uniaxial stretching (stage 1st stage) in the longitudinal direction (MD) at 2.2 times the original length at the stretching rate of minutes (240% / min), the iodine is contained at a concentration of 0.03% by mass and potassium iodide at a concentration of 3% by mass. While immersing in an aqueous solution of iodine / potassium iodide at a temperature of 30 ° C. for 60 seconds, uniaxial stretching in the longitudinal direction (MD) up to 3.3 times the original length at a stretching speed of 12 cm / min (240% / min) (second stage stretching) Then, the concentration of 3% by mass of boric acid and 3% by mass of potassium iodide While immersing in an aqueous solution of boric acid / potassium iodide at a temperature of 30 ° C. for about 20 seconds, uniaxially stretching in the longitudinal direction (MD) to 3.6 times the original length at a stretching speed of 12 cm / min (240% / min) (3 Drawing), and then a stretching rate of 48 cm / min (960% / min) while immersing in an aqueous boric acid / potassium iodide solution at a temperature of 63 ° C. containing 4% by mass of boric acid and about 5% by mass of potassium iodide. Potassium iodide containing potassium iodide at a concentration of 3% by mass after uniaxial stretching (fourth stage stretching) in the longitudinal direction (MD) to the stretching ratio immediately before the limit stretching ratio of the ethylene-modified PVA-based polymer film measured above It was immersed in aqueous solution for 10 second, the iodine ion impregnation process was performed, and it dried for 4 minutes with the dryer of 60 degreeC after that, and the polarizing film (thickness about 21 micrometers) was manufactured.

The transmittance | permeability (Y) and polarization degree (V) of the polarizing film obtained by this were calculated | required by the above-mentioned method, and the point was plotted on the graph which makes transverse axis | shaft transmittance (Y) and vertical axis | shaft the polarization degree (V).

(ii) In the above (i), except for changing the immersion time in the iodine / potassium iodide aqueous solution at a temperature of 30 ° C at the time of the second stage stretching from 60 seconds to 75 seconds, 90 seconds, 105 seconds or 120 seconds, the above-mentioned (i) ), Four kinds of polarizing films (thickness about 21 micrometers) in which the transmittance | permeability differs were manufactured.

The transmittance | permeability (Y) and polarization degree (V) of each polarizing film obtained by this were calculated | required by the above-mentioned method, respectively, and the point was plotted on the graph of said (i).

(iii) An approximate curve of five points plotted on the graph in (i) and (ii) is plotted on the graph, and the value of polarization degree (V) when the transmittance (Y) is 44.25% from the approximation curve is obtained. As a result, it was 99.98 as shown in Table 1 below.

&Quot; Example 2 &quot;

(1) In Example 1, the film production conditions at the time of producing the ethylene-modified PVA-based polymer film are changed as shown in Table 1 below, and the discharge amount when the film is discharged onto the first dry roll as a film is changed. In the same manner as in (1) of Example 1, an ethylene-modified PVA-based polymer film having a thickness of 25 µm was prepared.

Δn (MD) _Ave , Δn (TD) _Ave , mass swelling degree and limit draw ratio of the ethylene-modified PVA polymer film thus obtained (64 ° C. at a temperature of the boric acid / potassium iodide solution of the fourth stage drawing, stretching rate 48 cm / Min (960% / min) was measured by the above-mentioned method, and it was as showing in following Table 1.

(2) Using the test piece of the longitudinal direction (MD) x width direction (TD) = 10 cm x 5 cm taken from the width direction (TD) center part of the ethylene modified PVA system polymer film obtained by said (1), 4 On the other hand, the temperature of boric acid / potassium iodide aqueous solution of extending | stretching is changed from 63 degreeC to 64 degreeC, the same operation as (2) of Example 1 is performed, five types of polarizing films are produced, and the transmittance | permeability (Y of each polarizing film ) And the degree of polarization (V), and plot the point on a graph with the transmissivity (Y) and the vertical axis as the polarization degree (V), and plot an approximation curve of five points plotted on the graph, It was as showing in following Table 1 when the value of the polarization degree (V) when the transmittance | permeability (Y) is 44.25% was calculated | required from the said approximation curve.

<< Examples 3-5 >>

(1) In Example 1, the film-forming conditions at the time of manufacturing an ethylene modified PVA-type polymer film were changed as shown in following Table 1, and it carried out similarly to (1) of Example 1, and was 60 micrometers in thickness. A modified PVA-based polymer film was prepared.

Δn (MD) _Ave , Δn (TD) _Ave , mass swelling degree and limit draw ratio of each of the ethylene-modified PVA polymer films obtained thereby (decreased the temperature of the boric acid / potassium iodide aqueous solution of the fourth stage stretching at 63 ° C., and the stretching rate was 48 Cm / min (it was set to 960% / min) by the method mentioned above, and it was as showing in following Table 1.

(2) It carries out using the test piece of the longitudinal direction (MD) x width direction (TD) = 10 cm x 5 cm taken from the width direction (TD) center part of each ethylene modified PVA system polymer film obtained by said (1). The same operation as in (2) of Example 1 was carried out to produce five kinds of polarizing films for each Example, and the transmittance (Y) and the degree of polarization (V) of each polarizing film were obtained, and the horizontal axis was measured for transmittance (Y) and Plot the point on a graph with the vertical axis as the polarization degree (V), and draw an approximate curve of five points plotted on the graph on the graph, and the polarization degree when the transmittance (Y) is 44.25% from the approximation curve ( It was as having shown in following Table 1 when the value of V) was calculated | required.

"Reference Example 1"

(1) In Example 1, the ethylene-modified PVA-based polymer was replaced with unmodified PVA (which was obtained by saponifying polyvinyl acetate. Saponification degree 99.9 mol%, polymerization degree 2400) was changed to Example 1 (1). In the same manner as)), a PVA film having a thickness of 60 μm was prepared.

Δn (MD) _Ave , Δn (TD) _Ave , mass swelling ratio and limit draw ratio of the PVA film thus obtained (60 ° C. at the temperature of the boric acid / potassium iodide solution of the fourth stage drawing, stretching rate 48 cm / min (960) % / Min) was measured by the method described above (measured by considering the PVA film as an ethylene-modified PVA-based polymer film), and the results were as shown in Table 1 below.

(2) Boric acid of the 4th stage extending | stretching using the test piece of the longitudinal direction (MD) x width direction (TD) = 10 cm x 5 cm taken from the width direction (TD) center part of the PVA film obtained by said (1). The temperature of the aqueous solution of potassium iodide was changed from 63 ° C. to 60 ° C., and the same operation as in (2) of Example 1 was carried out to prepare five kinds of polarizing films, and the transmittance (Y) and the polarization degree of each polarizing film, respectively. Obtain (V), plot the point on a graph with the transmittance (Y) on the horizontal axis and the degree of polarization (V) on the horizontal axis, and plot the approximate curve of the five points plotted on the graph on the graph to obtain from the approximation curve. It was as showing in following Table 1 when the value of the polarization degree (V) when the transmittance | permeability (Y) was 44.25% was calculated | required.

<< reference example 2 >>

(1) Regarding the PVA film obtained in (1) of Reference Example 1, the temperature of the boric acid / potassium iodide aqueous solution of the fourth stage stretching was 63 ° C, and the stretching speed was 48 cm / min (960% / min), The limit draw ratio was measured by the method (assuming that the PVA film is regarded as an ethylene-modified PVA-based polymer film) and the results are as shown in Table 1 below.

(2) Moreover, it carried out using the test piece of the longitudinal direction (MD) x width direction (TD) = 10 cm x 5 cm which was collected from the width direction (TD) center part of the PVA film obtained by (1) of the reference example 1. The same operation as in (2) of Example 1 was carried out to produce five kinds of polarizing films, and the transmittance (Y) and the polarization degree (V) of each polarizing film were obtained, and the horizontal axis was the transmittance (Y) and the vertical axis was the polarization degree. Plot the point on a graph of (V), draw an approximate curve of the five points plotted on the graph on the graph, and the value of the degree of polarization (V) when the transmittance (Y) is 44.25% from the approximation curve. As a result, it was as showing in following Table 1.

<< Comparative Examples 1-7 >>

(1) In Example 1, the type of ethylene-modified PVA-based polymer to be used and the film production conditions when producing the ethylene-modified PVA-based polymer film are changed as shown in Table 2 below, and Example 1 (1) In the same manner as in)), an ethylene-modified PVA-based polymer film having a thickness of 60 μm was prepared.

Δn (MD) _Ave , Δn (TD) _Ave , mass swelling degree and limit draw ratio of each of the ethylene-modified PVA polymer films obtained thereby (decreased the temperature of the boric acid / potassium iodide aqueous solution of the fourth stage stretching at 63 ° C., and the stretching rate was 48 Cm / min (it was set to 960% / min) by the method mentioned above, and it was as showing in following Table 2.

(2) It carries out using the test piece of the longitudinal direction (MD) x width direction (TD) = 10 cm x 5 cm taken from the width direction (TD) center part of each ethylene modified PVA system polymer film obtained by said (1). The same operation as in (2) of Example 1 was carried out to produce five kinds of polarizing films for each comparative example, the transmittance (Y) and the degree of polarization (V) of each polarizing film were obtained, and the horizontal axis was measured for the transmittance (Y) and Plot the point on a graph with the vertical axis as the polarization degree (V), and plot an approximation curve of five points plotted on the graph on the graph, and the polarization degree when the transmittance (Y) is 44.25% from the approximation curve. It was as having shown in following Table 2 when the value of (V) was calculated | required.

As shown in Table 1 and Table 2, the ethylene-modified PVA-based polymer films of Examples 1 to 5 contain an ethylene-modified PVA-based polymer containing a specific amount of ethylene units, and Δn (MD) _Ave [ethylene-modified; The value obtained by averaging the birefringence in the longitudinal direction (MD) of the PVA-based polymer film in the thickness direction of the film] and the Δn (TD) _Ave [the birefringence in the width direction (TD) of the ethylene-modified PVA-based polymer film in the thickness direction of the film Averaging by the Formula 1) The formulas (I) and (II) satisfy the formulas (I) and (II), and thus have a high limit draw ratio of 6.76 to 6.92 even when stretched at a high speed, and further, the ethylene-modified PVA system of Examples 1 to 5 The polarizing film obtained from the polymer film has the outstanding polarization performance equivalent to or more than the conventional polarizing film.

In particular, in Example 2, although the thickness of the ethylene-modified PVA-based polymer film is 25 µm thinner, even when stretched at high speed in the same manner as in the other examples, high limit draw ratio and excellent polarization performance are achieved.

In contrast, the ethylene-modified PVA-based polymer films of Comparative Examples 1 to 3 did not satisfy Formula (I), and the ethylene-modified PVA-based polymer films of Comparative Examples 4 and 5 did not satisfy Formula (II), and Comparative Examples Since the ethylene-modified PVA-based polymer films of 6 and 7 do not contain an ethylene-modified PVA-based polymer containing a specific amount of ethylene units, the limit draw ratios are both higher than those of the ethylene-modified PVA-based polymer films of Examples 1 to 5. It is low and the polarizing film obtained by the comparative example 7 has a blue color compared with the polarizing film of Examples 1-5.

In addition, since the PVA films of Reference Examples 1 and 2 did not contain an ethylene-modified PVA-based polymer containing a specific amount of ethylene units, the limit draw ratio in the case of stretching at high speed was reduced, and thus the polarization performance of the polarizing film obtained. Is also lowered.

When manufacturing a polarizing film from a PVA-type polymer film, in order to avoid the rupture of the film at the time of extending | stretching, although uniaxial stretching is performed by extending | stretching ratio somewhat lower than a limit draw ratio, the ethylene modified PVA-type polymer of Examples 1-5 When the limit draw ratios of the films are all high at 6.76 or higher, the ethylene-modified PVA-based polymer films of Examples 1 to 5 perform uniaxial stretching at a draw ratio of 6 times or higher when a polarizing film is produced under the conditions of the examples. Even if it carries out uniaxial stretching at 6.5 times or more high draw ratio, it can extend | stretch smoothly, without breaking | breaking a film.

On the other hand, when manufacturing the polarizing film on the conditions of the said comparative example, the ethylene modified PVA-type polymer film of Comparative Examples 1-7 is worrisome in the fracture | rupture surface of a film to uniaxially stretch by 6 or more draw ratios.

Moreover, in the raw film for polarizing films, although the length of one roll may be 1000 m or more, for example, in the PVA system polymer film of 1000 m in full length, the limit draw ratio raises by 0.1 point (0.1 times). The thing becomes 100 m (1000 m * 0.1 times = 100 m) of the length of the stretched film obtained by carrying out uniaxial stretching, and more polarizing films are obtained from the raw film of the same length.

In regard to Examples 1 to 5, the ethylene-modified PVA-based polymer film of Examples 1 to 5 has a limit draw ratio of 0.13 to 0.90 points (times) in comparison with the ethylene-modified PVA-based polymer film of Comparative Examples 1 to 7. If the length of the ethylene-modified PVA-based polymer film is 1000 m, for example, the length of the polarizing film is PVA in Comparative Examples 1 to 7, More polarizing films can be obtained by lengthening 130-900 m compared with the case where a film is used.

Claims (5)

An ethylene-modified polyvinyl alcohol-based polymer film containing an ethylene-modified polyvinyl alcohol-based polymer having an ethylene unit content of 1 to 4 mol% and satisfying the following formulas (I) and (II).
Δn (MD) _Ave -0.1 × 10 ^-3 ≤ Δn (TD) _Ave ≤ Δn (MD) _Ave + 0.25 × 10 ^-3 (I)
Δn (TD) _Ave ≤ 2.5 × 10 ^-3 (II)
[Wherein, Δn (MD) _Ave represents a value obtained by averaging the birefringence in the mechanical flow direction of the ethylene-modified polyvinyl alcohol polymer film in the thickness direction of the film, and Δn (TD) _Ave is an ethylene-modified polyvinyl alcohol Shows the value obtained by averaging the birefringence in the width direction of the polymer film in the thickness direction of the film.] The method of claim 1,
Ethylene-modified polyvinyl alcohol polymer film which satisfy | fills following formula (III).
1.3 × 10 ⁻³ ≤ Δn (MD) _Ave ≤ 2.0 × 10 ^-3 (III) 3. The method according to claim 1 or 2,
Ethylene-modified polyvinyl alcohol-type polymer film whose thickness is in the range of 10-65 micrometers. It dyes and uniaxially stretches using the ethylene modified polyvinyl alcohol-type polymer film of any one of Claims 1-3, The manufacturing method of the polarizing film characterized by the above-mentioned. 5. The method of claim 4,
The manufacturing method which has the process of uniaxially stretching at the extending | stretching speed of 300% / min or more based on the length of the ethylene modified polyvinyl alcohol-type polymer film before uniaxial stretching.

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