KR20150136591A - Process for producing polarizing film - Google Patents

Abstract

In the case where the swelling treatment is carried out by a plurality of swelling treatment tanks, the swelling ratio in the film width direction in the first swelling treatment tank is 90% or less of the saturated swelling rate in the treatment temperature and composition, And the absolute value of the difference in expansion ratio in the film width direction in the subsequent second swelling treatment tank is adjusted to be within two points. When the swelling treatment is carried out by one swelling treatment tank, the swelling rate in the film width direction in the swelling treatment tank is 90% or less of the saturated swelling rate in the treatment temperature and the composition, and the swelling rate in the swelling treatment tank and the subsequent staining The respective treatment temperatures and the time for passing through the treatment bath are adjusted so that the absolute value of the difference in expansion ratio in the film width direction in the treatment bath is within two points.

Description

PROCESS FOR PRODUCING POLARIZING FILM [0002]

The present invention relates to a method for producing a polarizing film for use in a liquid crystal display device.

Conventionally, a polarizing film having a dichroic dye adsorbed on a polyvinyl alcohol resin film has been used. That is, an iodine-based polarizing film using iodine as a dichroic dye or a dye-based polarizing film using a dichroic dye as a dichroic dye are known. These polarizing films are usually polarized plates obtained by bonding a protective film such as triacetylcellulose through an adhesive composed of an aqueous solution of a polyvinyl alcohol resin to at least one side, preferably both sides thereof, of a liquid crystal television, a monitor for a personal computer, And is used in a liquid crystal display device such as a cellular phone.

The polarizing film is produced by subjecting a polyvinyl alcohol-based resin film to swelling treatment, dyeing treatment, stretching treatment, boric acid treatment (crosslinking treatment) and washing treatment, and finally drying. This stretching treatment is usually performed by using a pair of nip rolls and changing the rotating circumferential speed of these nip rolls.

In recent years, in the market, there is a tendency to demand a high display quality in addition to the enlargement and thinning of a liquid crystal display device, and accordingly, a widening or thinning of a polarizing film is required, and excellent optical characteristics And a method for producing a polarizing film capable of achieving high performance such as in-plane uniformity. In order to produce a large polarizing film, it is necessary to uniformly uniaxially stretch a wide original film. However, in the case of using a wide original film, it is difficult to uniformly swell or uniaxially stretch as compared with the conventional original film, so that the light absorption axis of the obtained polarizing film is not aligned in a certain direction, The performance tends to deteriorate. In addition, there is a tendency that the thickness of the film becomes uneven and the uniformity in the film surface of the optical performance such as transmittance is deteriorated. The image display apparatus to which such a polarizing film is applied has a problem that display unevenness occurs and the image quality deteriorates. Thus, a method for producing a polarizing film having a requirement for the polarizing film as described above and having excellent productivity has been developed.

For example, in Japanese Patent No. 4229932 (Patent Document 1), a plurality of swelling treatment tanks are provided, and the bath temperature of the swelling treatment tank located at the front end side of the swelling treatment tanks is used as the bath temperature of the swelling tank A polarizing film can be produced in a short period of time with a high-quality polarizing film in which color unevenness is suppressed. According to this method, since the swelling amount of the resin film reaches saturation in a short time, the film is hardly swollen in the subsequent dyeing treatment, and the color unevenness of the polarizing film caused thereby is suppressed. On the other hand, as in Patent Document 1, if the bath temperature in the swelling treatment tank located at the front is raised, the film swells rapidly due to the high treatment temperature, and the thickness of the film becomes uneven. Depending on the temperature of the following swelling treatment bath There is a problem that the film is further swollen and the film is wrinkled to deteriorate the appearance.

Disclosure of the Invention Problems to be Solved by the Invention A problem to be solved by the present invention is to provide a polarizing film excellent in productivity and capable of suppressing unevenness in the thickness of the film and occurrence of wrinkles in each processing performed on the original film made of a polyvinyl alcohol- And a method for producing the film.

According to the present invention, there is provided a method for producing a polarizing film by performing a swelling treatment, a dyeing treatment, a boric acid treatment, and a cleaning treatment on an original film made of a polyvinyl alcohol-based resin in this order, And the swelling treatment is carried out by passing through a plurality of swelling treatment tanks including at least a first swelling treatment tank and a second swelling treatment tank which are arranged in order from the side where the original film enters, Wherein the expansion ratio of the film in the width direction is 90% or less of the saturation expansion ratio when the film is immersed in the treatment liquid of the same temperature and composition, the expansion ratio in the width direction of the film in the first swelling treatment tank, The processing temperature of the first swelling treatment tank and the treatment temperature of the second swelling treatment tank are adjusted so that the absolute value of the difference when the expansion ratio in the width direction of the film in the tank is expressed as a percentage, There is provided a method of manufacturing a polarizing film that adjusts a time to pass through a bath.

In this method, the treatment temperature of the first swelling treatment tank is 35 to 45 캜, and the treatment temperature of the second swelling treatment tank is lower than the treatment temperature of the first swelling treatment tank and is preferably 25 to 35 캜. In these methods, it is preferable to adjust the treatment temperature of the first swelling treatment tank and the time passing through the treatment tank so that the expansion ratio of the film in the widthwise direction in the first swelling treatment tank is 15 to 25%.

 According to the present invention, there is also provided a method for producing a polarizing film by performing a swelling treatment, a dyeing treatment, a boric acid treatment, and a cleaning treatment on an original film made of a polyvinyl alcohol-based resin in this order, 10 to 60 占 퐉 and the swelling treatment is carried out by passing through one swelling treatment tank and the swelling ratio of the film in the width direction in the swelling treatment tank is not more than the saturated swelling ratio And the absolute value of the difference when the expansion ratio of the film in the width direction in the swelling treatment tank and the expansion ratio in the width direction of the film in the dyeing treatment tank are respectively expressed as a percentage is within 2 points, Wherein the treatment temperature of the treatment tank and the dyeing treatment tank and the time of passing through the treatment tank are adjusted.

In this method, the treatment temperature of the swelling treatment tank is 35 to 45 占 폚, and the treatment temperature of the dyeing treatment tank is lower than the treatment temperature in swelling treatment, and is preferably 25 to 35 占 폚. Also in these methods, it is preferable to adjust the treatment temperature of the swelling treatment tank and the time passing through the treatment tank so that the expansion ratio in the width direction of the polyvinyl alcohol-based resin film is 15 to 25%.

According to the polarizing film producing method of the present invention, it is possible to suppress the unevenness of the swelling of the film in each treatment performed in the production of the polarizing film, in particular, in the swelling treatment, and suppress the occurrence of wrinkles or breakage of the film It is possible to efficiently obtain a polarizing film having excellent appearance.

In the present invention, a polarizing film is produced by subjecting an original film made of a polyvinyl alcohol-based resin to a swelling treatment, a dyeing treatment, a boric acid treatment, and a cleaning treatment in this order. Further, the polarizing film obtained by carrying out the drying treatment after the washing treatment is suppressed from wrinkles and the like, and is suitably used for the polarizing plate. Hereinafter, the present invention will be described in detail.

[Production method of polarizing film]

Specifically, the polarizing film is adsorbed and oriented on a polyvinyl alcohol-based resin film. The polyvinyl alcohol-based resin to be a raw material is usually obtained by saponifying a polyvinyl acetate-based resin. The saponification degree is usually 85 mol% or more, preferably 90 mol% or more, and more preferably 99 mol% or more. Examples of the polyvinyl acetate-based resin include polyvinyl acetate, which is a homopolymer of vinyl acetate, as well as copolymers of vinyl acetate and other monomers copolymerizable therewith. Examples of other monomers copolymerizable with vinyl acetate include unsaturated carboxylic acids, olefins, unsaturated sulfonic acids, and vinyl ethers. The polymerization degree of the polyvinyl alcohol-based resin is usually about 1000 to 10000, preferably about 1500 to 5000.

These polyvinyl alcohol resins may be modified. For example, polyvinyl formal modified with aldehydes, polyvinyl acetal, polyvinyl butyral and the like may be used. An unoriented film (original film) of a polyvinyl alcohol based resin film having a thickness of about 10 to 60 占 퐉, preferably about 12 to 55 占 퐉 is used as a material for polarizing film production. It is industrially practical that the width of the film is 1500 to 6000 mm. The thickness of the polarizing film obtained by treating the original film in the order of the swelling treatment, the dyeing treatment, the boric acid treatment (crosslinking treatment) and the washing treatment, and finally drying is about 5 to 25 탆.

The polarizing film is produced by subjecting the original film made of a polyvinyl alcohol-based resin to the swelling treatment, the dyeing treatment, the boric acid treatment, and the washing treatment in that order as described above. During the treatment with boric acid, Uniaxial stretching of the film is performed beforehand. The uniaxial stretching may be a wet stretching or a dry stretching. In the case of performing the swelling treatment before the boric acid treatment and the swelling treatment before the boric acid treatment, or when the dyeing treatment is performed, the wet stretching is performed. This uniaxial stretching may be performed in one step or in two or more steps, but is preferably performed in a plurality of steps. On the other hand, in the uniaxial stretching of the present invention, a known stretching method can be employed. Examples of the stretching method include inter-roll stretching in which stretching is carried out with a main speed difference between two nip rolls for transporting the film, thermal roll stretching as described in Japanese Patent No. 2731813, and tenter stretching.

(Swelling treatment)

In the swelling treatment, the polyvinyl alcohol-based resin film swells in the width direction and wrinkles tend to occur in the film. Therefore, it is preferable to use an expander roll (wider roll), a spiral roll, a crown roll, It is preferable to transport the film while removing the wrinkles of the film. For example, in a swelling treatment tank having a high film expansion rate, such as a first swelling treatment tank in the case of performing the swelling treatment described below in a plurality of treatment tanks and a swelling treatment tank in the case of performing the swelling treatment in one treatment tank, Is effective.

Further, for the purpose of stabilizing the transport of the film in the bath, an EPC device (Edge position control device) for controlling the water flow in the swelling treatment tank by an underwater shower or detecting the film end to prevent meandering It is also useful to use it in combination.

In the swelling process, since the film swells and expands even in the transport direction of the film, when the film is not actively stretched, the speed of the transport roll such as the nip roll or the guide roll is adjusted It is desirable to take measures to When the original film is subjected to the swelling treatment, the dyeing treatment and the boric acid treatment in this order, uniaxial stretching may be performed in the swelling treatment. In this case, the stretching magnification is preferably about 1.2 to 3 times, Is 1.3 to 2.5 times.

The swelling treatment bath may contain, in addition to pure water, boric acid (Japanese Unexamined Patent Publication No. 10-153709), chloride (Japanese Unexamined Patent Publication No. 06-281816), inorganic salt, inorganic acid, % May be used.

In one embodiment of the present invention, the swelling treatment is carried out using a plurality of swelling treatment tanks. In this case, the swelling treatment is carried out by passing through a plurality of swelling treatment tanks including at least a first swelling treatment tank and a second swelling treatment tank arranged in order from the side where the original film enters. The treatment temperature in the first swell treatment tank and the second swell treatment tank and the passage time of the film are appropriately adjusted so that the expansion ratio in the width direction of the film in each treatment tank is within a predetermined range.

Here, the expansion rate in the width direction of the film will be described. The expansion ratio of the film in the width direction refers to the expansion amount in the width direction of the polyvinyl alcohol type resin film produced by the swelling treatment as a percentage. Specifically, a long original film made of a polyvinyl alcohol-based resin is first cut into a piece having a size of 50 mm in the longitudinal direction x 50 mm in the width direction, and the film is subjected to swelling treatment Swelling treatment is carried out under the same treatment conditions. (The width in the width direction after the swelling process - the length in the width direction before the swelling process) of the film piece before and after the swelling process is divided by the length (50 mm) in the width direction at the time of cutting and is expressed as a percentage Is the expansion rate.

Therefore, the expansion ratio of the film in the widthwise direction in the first swelling treatment tank in the present invention is such that the swelling ratio when the swelling treatment is performed under the same treatment conditions as those in the first swelling treatment tank Point. The expansion ratio is the same as that of the first swelling treatment bath in a state in which tension is not applied to the film segment for the same time as the film passes through the first swelling treatment tank in the production apparatus , And further immersed in an aqueous solution set at the same temperature, and the amount of change in the width direction of the film fragments generated at that time is divided by the length (50 mm) in the width direction at the time of cutting, and is expressed as a percentage.

Likewise, the expansion ratio of the film in the widthwise direction in the second swelling treatment tank in the present invention refers to the film swollen with the swelling treatment under the same treatment condition as the above-mentioned first swelling treatment tank, And the expansion rate when the swelling treatment is carried out under the same treatment conditions as those of the swelling treatment. The expansion rate is obtained by dividing the film piece subjected to the swelling treatment corresponding to the treatment in the first swelling treatment tank by the same amount of time as the time during which the film passes through the second swelling treatment tank in the production apparatus, The amount of change from the length in the transverse direction of the film piece at the time of cutting after immersion in an aqueous solution having the same composition as that of the second swelling treatment bath and set at the same temperature (in the width direction after the second swelling treatment (Length in the width direction at the time of cutting) is divided by the length (50 mm) in the width direction at the time of cutting, and is expressed as a percentage.

The term "saturation expansion ratio" in the present invention refers to a film fraction having an expansion ratio of 50 mm in the longitudinal direction × 50 mm in the width direction, which is the expansion ratio obtained under the same conditions as the calculation of the expansion ratio in the swelling treatment tank except for the immersion time, And the rate of expansion when it is immersed in the treatment bath for 10 minutes. The saturation expansion ratio is a value obtained by dividing the change amount in the width direction of the film piece (length in the width direction after immersion-length in the width direction before immersion) generated when the film piece is immersed in the treatment bath in a state in which no tension is applied for 10 minutes And the length in the width direction (50 mm), which is expressed as a percentage. When the saturated swelling rate in the first swelling treatment tank is to be obtained, the treatment bath used here is an aqueous solution having the same composition and the same temperature as the first swelling treatment bath.

In an embodiment in which the swelling treatment is carried out by a plurality of steps, the expansion ratio of the film in the width direction in the first swelling treatment tank is the saturated expansion ratio To be 90% or less of the total amount of the solution. By setting the saturation expansion ratio to 90% or less, it is not necessary to use a huge manufacturing apparatus and the swelling treatment can be efficiently performed even when the film feeding speed is increased. In addition, the expansion ratio of the film in the width direction in the first swelling treatment tank is preferably 70% or more. When the expansion ratio is smaller than 70%, it is difficult to uniformly swell the inside of the film surface in the swelling treatment, and color unevenness and wrinkles are likely to occur.

When the expansion ratio of the film in the widthwise direction in the first swelling treatment tank is too small and the expansion ratio in the width direction of the film in the second swelling treatment tank is large, the film swells swiftly in the second swelling treatment tank There is a case that the expansion ratio varies in the end portion and the central portion of the film. As a result, when the above-mentioned widening apparatus is used in the treatment tank, wrinkles may occur due to the variation in the expansion ratio. On the other hand, when the expansion ratio of the film in the width direction in the first swelling treatment tank is excessively large, wrinkles may occur because the film can not be sufficiently widened by the widening apparatus used in the treatment tank. Therefore, the absolute value of the difference when the widthwise expansion ratio of the film in the first swelling treatment tank and the expansion ratio in the width direction of the film in the second swelling treatment tank are expressed as percentages is made to be 2 points or less, It is important to adjust the respective treatment temperatures of the first swell treatment tank and the second swell treatment tank and the time passing through the treatment tank.

In this manner, in the first swelling treatment tank and the second swelling treatment tank, the absolute value of the difference when expressed in percentage in the width direction of the film in each of the first swelling treatment tank and the second swelling treatment tank By regulating the treatment temperature and the time passing through the treatment tank, it is possible to suppress the shortage of treatment in the first swelling treatment tank and suppress the undesirable rapid swelling in the second swelling treatment tank. Further, by combining the processing temperatures of the first swelling treatment tank and the second swelling treatment tank with the passage time of the treatment tank, it is possible to suppress the film thickness from becoming uneven at the time of swelling. Therefore, Can be suppressed, and a polarizing film having good optical characteristics and good appearance can be produced.

When the swelling treatment is carried out using a plurality of swelling treatment tanks, it is preferable that the treatment temperature of the first swelling treatment tank is higher than the treatment temperature of the second swelling treatment tank, and from the viewpoint of shortening the swelling treatment time, Lt; 0 > C. The temperature of the second swelling bath is preferably 25 to 35 占 폚. It is also preferable to adjust the treatment temperature of the first swelling treatment tank and the time passing through the treatment tank so that the expansion ratio in the width direction of the film in the first swelling treatment tank is 15 to 25%.

The time for the film to pass through the first swelling treatment bath is 10 to 60 seconds, preferably 15 to 50 seconds. On the other hand, the time for the film to pass through the second swelling treatment tank is 10 to 60 seconds, preferably 15 to 50 seconds.

As another embodiment of the present invention, there is a form in which the swelling treatment is performed by only one swelling treatment tank. In this embodiment, the original film is taken out of the swelling treatment tank, and then returned to the dyeing treatment tank. In this case, the treatment temperature in the swelling treatment tank and the dyeing treatment tank, and the passage time of the film are suitably adjusted so that the expansion ratio in the width direction of the film in each treatment tank is within a predetermined range. Specifically, although described in detail in the following dyeing process, the expansion ratio of the film in the width direction in the swelling treatment tank is 90% or less of the saturated expansion coefficient when immersed in the treatment liquid of the same temperature and composition, Of the film in the width direction and the expansion ratio in the width direction of the film in the dyeing treatment tank are respectively expressed by percentage, the absolute value of the difference is within 2 points. The processing temperature of the swelling treatment tank and the dyeing treatment tank, And the time required for the passage of time.

(Dyeing treatment)

The dyeing treatment is carried out for the purpose of adsorbing a dichroic dye to a polyvinyl alcohol-based resin film. As the dichroic dye, iodine or a water-soluble dichroic dye can be used. The processing conditions are determined within a range that can achieve these purposes and within a range that does not cause problems such as dissolution and devitrification of the polyvinyl alcohol based resin film.

In the case of using iodine as the dichroic dye, an aqueous solution having a concentration of iodine / potassium iodide / water of about 0.003 to 0.2 / about 0.1 to 10/100 at a concentration can be used for the treatment bath (dyeing treatment bath). Instead of potassium iodide, other iodides such as zinc iodide may be used, or potassium iodide and other iodides may be used in combination. Further, compounds other than iodide such as boric acid, zinc chloride, cobalt chloride, etc. may be coexistent. When boric acid is added to the treatment bath, it is distinguished from the boric acid treatment described below in that it contains iodine. If it contains about 0.003 part by weight or more of iodine with respect to 100 parts by weight of water, it can be regarded as a dyeing treatment bath. The temperature of the treatment bath when immersing the film is about 10 to 45 캜, preferably 25 to 35 캜. The immersion time of the film is about 30 to 600 seconds, preferably 30 to 300 seconds.

When a water-soluble dichroic dye is used as the dichroic dye, an aqueous solution having a dichroic dye / water concentration of about 0.001 to 0.1 / 100 in terms of the concentration by weight can be used for the treatment bath. The treatment bath may contain a dyeing assistant or the like, and examples thereof include inorganic salts such as sodium sulfate and surfactants. The dichroic dye may be used singly or two or more kinds of dichroic dyes may be used in combination. The temperature of the treatment bath when immersing the film is about 20 to 80 캜, preferably 25 to 70 캜, and the immersion time of the film is about 30 to 600 seconds, preferably 30 to 300 seconds.

The stretching treatment in the case of stretching the film in the dyeing treatment is carried out by a method such as providing a pair of nip rolls with a peripheral speed difference. The stretching magnification of the totalization up to the dyeing treatment is usually 1.6 to 4.5 times, preferably about 1.8 to 4 times. If the total stretching magnification ratio up to the dyeing treatment is less than 1.6 times, the frequency of breakage of the film increases, and the yield tends to deteriorate.

Also in the dyeing treatment, it is preferable to carry the film while spreading the wrinkles of the film by using a known widening apparatus such as an expander roll, a spiral roll, a crown roll, and a bent bar in the same manner as the swelling treatment.

In the present invention, in the case where the swelling treatment is carried out by only one swelling treatment tank, the swelling treatment tank and the dyeing treatment tank are so arranged that the expansion ratio in the width direction of the film in the swelling treatment tank and the dyeing treatment tank is within a predetermined range. And the time for the film to pass through are appropriately adjusted.

The expansion ratio of the film in the width direction can be obtained in the same manner as the expansion rate in the width direction of the film in the first swelling treatment tank and the film fragments obtained by cutting the original film as described above are subjected to the same treatment conditions And the amount of change in the width direction of the film fragments generated at this time and the length in the width direction at the time of cutting can be calculated. On the other hand, the saturation expansion coefficient in the swelling treatment tank can also be obtained by the same method as the saturation expansion coefficient in the first swelling treatment tank.

The expansion ratio in the width direction of the film in the dyeing treatment tank is the expansion ratio when the film piece subjected to the swelling treatment under the same processing conditions as the swelling treatment tank is subjected to the treatment under the same treatment conditions as the dyeing treatment tank, Can be obtained in the same manner as the expansion rate in the swelling treatment tank. More specifically, the film piece subjected to the swelling treatment under the same processing conditions as the swelling treatment bath is subjected to the same time as the time when the film passes through the dyeing treatment tank, in the same manner as in the dyeing treatment bath (Length in the width direction after the dyeing treatment - length in the width direction at the time of cutting) from the length in the width direction of the film piece at the time of cutting after immersion in the aqueous solution set at the temperature And it is expressed as a percentage.

In the present invention, in the embodiment wherein the swelling treatment is performed with only one swelling treatment tank, the expansion ratio of the film in the width direction in the swelling treatment tank is preferably 90% or less of the saturated expansion coefficient when immersed in the treatment liquid of the same temperature and composition, Or less of the total amount of water to be treated. By setting the saturation expansion rate to 90% or less, it is not necessary to use a huge apparatus and the swelling process can be efficiently performed even when the film feeding speed is increased. The swelling ratio in the width direction of the film in the swelling treatment tank is preferably 70% or more. When the expansion ratio is smaller than 70%, it is difficult to uniformly swell the inside of the film surface in the swelling treatment, and color unevenness and wrinkles are likely to occur.

Further, when the expansion ratio of the film in the width direction in the swelling treatment tank is too small and the expansion ratio in the width direction of the film in the dyeing treatment tank is large, the film swells swiftly in the dyeing treatment tank, There is a case where a variation in the expansion ratio occurs. As a result, when the above-mentioned widening apparatus is used in the treatment tank, wrinkles may occur due to the variation in the expansion ratio. On the other hand, when the expansion ratio of the film in the width direction in the swelling treatment tank is excessively large, the film can not be sufficiently widened by the widening apparatus used in the treatment tank, and wrinkles may be generated. Therefore, the swelling treatment tank and the swelling treatment tank are set so that the absolute value of the difference when the expansion ratio in the width direction of the film in the swelling treatment tank and the expansion ratio in the width direction of the film in the dye- It is important to adjust the treatment temperature of each of the dyeing treatment tanks and the time of passing through the treatment tanks.

The present invention relates to a swelling treatment tank and a dyeing treatment tank treatment such that the difference in the expansion ratio in the width direction of the film in the swelling treatment tank and the expansion rate in the width direction of the film in the dyeing treatment tank are respectively in the above- By adjusting the time and the time passing through the treatment tank, it is possible to suppress the shortage of treatment in the swelling treatment tank and suppress the undesirable rapid swelling in the dyeing treatment tank. Further, by combining the treatment temperature of the swelling treatment tank and the dyeing treatment tank with the passage time of the treatment tank, it is possible to suppress the film thickness from becoming uneven at the time of swelling, so that the occurrence of wrinkles caused by this can be suppressed, A polarizing film having good optical characteristics and good appearance can be produced.

At this time, from the viewpoint of shortening the time of the swelling treatment, it is preferable that the temperature is as high as possible within a range where the film does not dissolve, and the treatment temperature of the swelling treatment tank is preferably 35 to 45 deg. The temperature of the dyeing bath is preferably 25 to 35 ° C. It is also preferable to adjust the treatment temperature of the swelling treatment tank and the time passing through the treatment tank so that the swelling ratio in the width direction of the film in the swelling treatment tank is 15 to 25%.

(Boric acid treatment)

The boric acid treatment is carried out for the purpose of water resistance and color adjustment (preventing the blue or red color of the film) by crosslinking. In the treatment bath, an aqueous solution containing about 1 to 10 parts by weight of boric acid per 100 parts by weight of water is used. In the case where the dichroic dye used in the dyeing treatment is iodine, iodide in addition to boric acid is added in an amount of 1 To 30 parts by weight. Examples of the iodide include potassium iodide, sodium iodide and zinc iodide. Further, compounds other than iodide such as zinc chloride, cobalt chloride, zirconium chloride, sodium thiosulfate, potassium sulfite, sodium sulfate and the like may be coexistent. On the other hand, there is a case where the boric acid treatment for water resistance is referred to as a name such as a cross-linking treatment, a water-resistant treatment, an immobilization treatment and the like. The boric acid treatment for color adjustment is called a complementary treatment, May be referred to.

This boric acid treatment is carried out by appropriately adjusting the concentration of boric acid and iodide and the temperature of the treatment bath, depending on the purpose. The boric acid treatment for water resistance and the boric acid treatment for color adjustment are not particularly discriminated but are carried out under the following conditions.

The swelling treatment, the dyeing treatment and the boric acid treatment are carried out in this order on the original film made of a polyvinyl alcohol-based resin. In the case where the purpose of the boric acid treatment is water-resistance by cross-linking, And an aqueous solution of boric acid / iodide / water = 3 to 10/1 to 20/100. If necessary, a crosslinking agent such as glyoxal and glutaraldehyde may be used instead of boric acid, or boric acid and a crosslinking agent may be used in combination. The immersion time of the film is generally about 10 to 600 seconds, preferably 20 to 300 seconds, more preferably 20 to 200 seconds, Seconds. When the pre-stretched polyvinyl alcohol based resin film is subjected to the dyeing treatment and the boric acid treatment in this order, the temperature of the boric acid treatment bath is usually about 50 to 85 ° C, preferably 55 to 80 ° C .

After the boric acid treatment for moisture resistance, the boric acid treatment for color adjustment may be performed. For example, when the dichroic dye is iodine, the treatment bath may be an aqueous solution having a concentration of boric acid / iodide / water = 1 to 5/3 to 30/100 by weight. The temperature of the treatment bath is usually about 10 to 45 占 폚, and the immersion time of the film is usually about 10 to 300 seconds, preferably 10 to 100 seconds.

These boric acid treatments may be carried out a plurality of times such as a boric acid treatment for water resistance and a boric acid treatment for color adjustment. In this case, the composition and temperature of the aqueous solution of each boric acid treatment tank to be used may be the same or different in the above-mentioned range. The boric acid treatment for water resistance and the boric acid treatment for color adjustment may be carried out in a plurality of steps, respectively.

(Cleaning treatment)

The cleaning treatment is carried out after the boric acid treatment for the purpose of removing the excess boric acid or iodine adhered to the polyvinyl alcohol resin film. This cleaning treatment is carried out, for example, by immersing a polarizing film subjected to a boric acid treatment for water resistance and / or color tone adjustment in water, spraying water with a shower or the like, or both in combination. The temperature of water in the washing treatment is usually about 2 to 40 캜, and the treating time is preferably about 5 to 120 seconds.

(Dry treatment)

After the cleaning treatment, the polarizing film can be produced by drying the polyvinyl alcohol-based resin film. The drying treatment is carried out in a drying furnace at a temperature of about 40 to 100 DEG C for about 60 to 600 seconds.

The final integral stretch magnification of the polarizing film thus produced is usually about 4.5 to 7 times, preferably about 5 to 6.5 times.

(Other processing)

The processing other than the above may be added for other purposes. Examples of treatments which can be added include immersion treatment (iodide treatment) in an iodide aqueous solution containing no boric acid, which is carried out after boric acid treatment, immersion treatment in an aqueous solution containing zinc chloride or the like without containing boric acid Zinc treatment).

[Polarizing plate production method]

The polarizing plate as a lamination layer of the polarizing film and the protective film is formed by bonding a protective film to at least one surface of the polarizing film thus produced by using an adhesive. As the protective film, for example, an acrylic resin film such as an acetylcellulose resin film such as triacetyl cellulose, a cycloolefin resin film, a cycloolefin copolymer resin film, a polyethylene terephthalate, a polyester resin film such as polyethylene naphthalate or polybutylene terephthalate , Polycarbonate resin films, acrylic resin films such as polymethyl methacrylate, and non-cyclic olefin resin films such as polypropylene and polyethylene.

In order to improve the adhesiveness between the adhesive and the polarizing film and / or the protective film, it is preferable that the bonding surfaces of the polarizing film and / or the protective film are subjected to a corona treatment, a plasma treatment, a flame treatment, an ultraviolet treatment, a primer treatment, It is also possible to carry out surface treatment such as solvent treatment by application of a solvent and drying.

On the other hand, instead of these protective films, a stretched film of a thermoplastic resin or an optical compensation film in which a liquid crystal compound is aligned with a thermoplastic resin may be bonded to the polarizing film through an adhesive. A known film can be suitably used as the stretched film of the thermoplastic resin or the optical compensation film obtained by orienting the liquid crystal compound in the thermoplastic resin.

The adhesive used for bonding the polarizing film and the protective film or the like is not particularly limited as long as it can bond the polarizing film and the protective film or the like, but it is selected to satisfy the sufficient adhesive force and transparency. In these respects, an ultraviolet curable adhesive is preferably used for bonding the polarizing film and the protective film or the like. For bonding the polarizing film and the acetylcellulose-based resin film, besides the ultraviolet-curing resin described above, an aqueous adhesive, for example, an aqueous solution of a polyvinyl alcohol-based resin and an aqueous solution or a urethane emulsion- have.

The ultraviolet curable adhesive may be a mixture of an acrylic compound and a photo radical polymerization initiator, a mixture of an epoxy compound and a cationic photopolymerization initiator, and the like. In addition, a cationic polymerizable epoxy compound and a radical polymerizable acrylic compound may be used in combination, and a photocationic polymerization initiator and a photo radical polymerization initiator may be used together as an initiator.

In the case of using an ultraviolet curable adhesive, the film is laminated and then irradiated with ultraviolet rays to cure the adhesive. The light source of ultraviolet rays is not particularly limited, but it is preferable that the light source has a light emission distribution at a wavelength of 400 nm or less. Specific examples thereof include low pressure mercury lamps, medium pressure mercury lamps, high pressure mercury lamps, ultra high pressure mercury lamps, chemical lamps, A metal halide lamp or the like is preferably used.

The light irradiation intensity for curing the ultraviolet curable adhesive is appropriately determined depending on the composition of the adhesive and is not particularly limited, but it is preferable that the irradiation intensity in the wavelength range effective for activating the polymerization initiator is 0.1 to 6000 mW / cm 2 . By appropriately selecting the irradiation intensity in this range, the reaction time is not excessively long, and the yellowing of the adhesive due to the heat radiated from the light source and the heat generation at the time of curing of the adhesive, and deterioration of the polarizing film can be suppressed. The light irradiation time is also not particularly limited as long as it is selected in accordance with the adhesive to be cured, but it is preferable that the integrated light amount as a product of the irradiation intensity and the irradiation time is set to 10 to 10,000 mJ / cm 2.

By properly selecting the accumulated light quantity in this range, a sufficient amount of active species originating from the polymerization initiator can be sufficiently generated to surely advance the curing reaction and to shorten the irradiation time, so that good productivity can be maintained. When the ultraviolet curable adhesive is cured by irradiation of ultraviolet rays in a laminated film including a polarizing film and a protective film, various functions of the polarizing plate, such as polarizing degree, transmittance and color, and transparency of the protective film, It is preferable to perform the curing under a condition that the temperature is not lowered.

When an aqueous adhesive is used, for example, an adhesive may be uniformly applied to the surface of the film or introduced between two films, the two films may be superimposed via the coating layer, Method can be adopted. After drying, it may be cured at a room temperature or a slightly higher temperature, for example, at a temperature of about 20 to 45 占 폚.

The thickness of the above-mentioned adhesive layer is appropriately selected from the range of about 0.001 to 5 占 퐉 by the kind of the adhesive and the combination of the two films to be bonded. The thickness thereof is preferably 0.01 탆 or more, and more preferably 2 탆 or less.

Example

Hereinafter, the present invention will be described in detail with reference to Examples, but the present invention is not limited by these Examples. In the following examples, the expansion ratio in the width direction of the polyvinyl alcohol film was measured by the following method.

<Measurement of Expansion Rate>

The expansion rate of the film was calculated from the amount of change in the width direction of the film before and after immersion in the swelling treatment tank or the dyeing treatment tank. First, a long polyvinyl alcohol film (original film) used in each of Examples and Comparative Examples described below was cut to a size of 50 mm in the longitudinal direction x 50 mm in the width direction to obtain a film segment. Next, this film piece was immersed in the treatment liquid at the same temperature as the actual treatment, and for the same time as the film passed through the treatment tank, to the treatment liquid having the same composition as the treatment bath for measuring the expansion rate. This immersion was performed in a state in which tension was not applied to the film. Thereafter, the film piece was taken out from the treatment liquid, and the length of the film piece in the width direction (length after processing - length at the time of cutting: 50 mm) in the film piece before and after the treatment in the width direction at the time of cutting was obtained, Expressed as a percentage. The length of the processed film piece was measured by using a commercially available digital nog- zus ("Coolant Digimatic Nogis CD-15PSX", manufactured by Mitsutoyo Corporation) and measuring the size of the film piece immediately after it was taken out from the water bath.

[Example 1]

(Trade name: KurarupoPhaval Film VF-PE # 6000, manufactured by Kuraray Co., Ltd., degree of polymerization: 2400, degree of saponification: 99.9 mol% or more) having a thickness of 60 탆 was prepared, and as a swelling treatment, 37 Lt; 0 &gt; C of pure water was immersed in the first swelling treatment tank for 40 seconds while keeping the tension so that the film would not sag. Thereafter, the film was immersed in a second swelling treatment tank containing pure water at 30 DEG C for 20 seconds. At this time, in the first swelling treatment tank, the film was transported using an expander roll. Next, as a dyeing treatment, uniaxial stretching was performed up to 2.2 times while immersing in a dyeing treatment bath containing iodine and potassium iodide in an aqueous solution at 30 DEG C for 60 seconds, and potassium iodide / boric acid / water in a weight ratio of 12 / 4.4 / 100 The uniaxial stretching was carried out by dipping in a boric acid treating bath containing an aqueous solution at 55 캜 to carry out water hydration treatment until the total draw ratio from the disc was 5.5 times. Subsequently, the substrate was immersed in a bath containing an aqueous solution of boric acid at 40 占 폚, immersed in a cleaning bath containing pure water at 12 占 폚, and then dried at 70 占 폚 for 3 minutes in a drying furnace to prepare a polarizing film. No wrinkles were observed in the swelling treatment, and no breakage of the film was observed.

(A) the saturation expansion coefficient in the first swelling treatment tank

The polyvinyl alcohol film "Kurarupoval film VF-PE # 6000" used in Example 1 was cut into a size of 50 mm in the long direction and 50 mm in the width direction, and this was cut into a water tank containing pure water at 37 ° C (the first swelling treatment tank Equivalent) for 10 minutes as the saturation expansion ratio. After immersion, the length of the film piece in the width direction was 62.70 mm. From the amount of change in length due to immersion relative to the length in the width direction before immersion, the saturation expansion ratio in the first swelling treatment tank was 25.4%.

(B) Expansion ratio of the film in the width direction in the first swelling treatment tank

The same swollen film piece as that in the above (A) was separately prepared, and the swollen rate when immersed in a water bath containing 37 ° C pure water for 40 seconds as in the case of the first swollen treatment tank of Example 1 was defined as the first swollen This was taken as the expansion ratio in the treatment tank. After immersing, the length of the film piece in the width direction was 61.00 mm. From the amount of change in length in the first swelling treatment tank with respect to the length in the width direction before immersion, the expansion ratio in the width direction of the film in the first swelling treatment tank was 22.0%. This expansion ratio was 86.6% with respect to the saturated expansion ratio of the above (A). In Table 1 below, the expansion rate of the first swelling treatment tank is shown in the column of "expansion rate 1", and the expansion rate of the first swelling treatment tank in relation to the saturated expansion rate is shown in the column of "expansion rate 1 / saturation expansion rate".

(C) Expansion ratio of the film in the width direction in the second swelling treatment tank

In order to perform the same treatment as that of the second swelling treatment tank, the film piece subjected to the same treatment as the first swelling treatment tank in (B) was immersed in a water bath containing pure water at 30 DEG C for 20 seconds. After immersion, the length of the film piece in the width direction was 60.60 mm. From the amount of change in length in the second swelling treatment tank to the length in the transverse direction of the film piece at the time of cutting, the expansion ratio of the film in the width direction in the second swelling treatment tank was 21.2%. The difference between the expansion ratio in the width direction of the film in the first swelling treatment tank of (B) was -0.8 points. In Table 1 below, the expansion rate of the second swelling treatment tank is shown in the column of &quot; expansion rate 2 &quot;, and the difference in expansion rate in the first swelling treatment tank and the second swelling treatment tank is shown in the column of & .

[Example 2]

(Trade name: "Kurarupoval film VF-PE # 5000 ", manufactured by Kuraray Co., Ltd., degree of polymerization: 2400, degree of saponification: 99.9 mol% or more) having a thickness of 50 m was used as the original film, A polarizing film was produced in the same manner as in Example 1 except that the swelling treatment in the swelling treatment tank was immersed in pure water at 35 캜 for 30 seconds. No wrinkles were observed in the swelling treatment, and no breakage of the film was observed.

(A) the saturation expansion coefficient in the first swelling treatment tank

The same procedure was followed as in Example 1 (A) except that the film piece was cut from the polyvinyl alcohol film "Kurarupoval film VF-PE # 5000" used in Example 2 and the temperature of pure water in the water bath was changed to 35 ° C The saturation expansion ratio in the first swelling treatment tank was obtained. After immersion, the length of the film piece in the width direction was 62.10 mm. From the amount of change in length due to immersion relative to the length in the width direction before immersion, the saturation expansion ratio in the first swelling treatment tank was 24.2%.

(B) Expansion ratio of the film in the width direction in the first swelling treatment tank

The same piece as that of the film piece cut in Example 2 (A) was separately prepared and immersed in a water bath containing pure water at 35 캜 for 30 seconds in the same manner as the treatment in the first swelling treatment tank of Example 2 to prepare a first swelling treatment tank Was obtained. After immersion, the length of the film piece in the width direction was 60.45 mm. The coefficient of expansion of the film in the width direction in the first swelling treatment tank was 20.9% as determined in the same manner as in Example 1 (B). The expansion ratio was 86.4% with respect to the saturated expansion ratio of the above (A).

(C) Expansion ratio of the film in the width direction in the second swelling treatment tank

In order to perform the same treatment as that of the second swelling treatment tank, the film piece subjected to the same treatment as the first swelling treatment tank in (B) was immersed in a water bath containing pure water at 30 DEG C for 20 seconds. After immersion, the length of the film piece in the width direction was 60.50 mm. The expansion ratio of the film in the width direction in the second swelling treatment tank was 21.0% as determined in the same manner as in Example 1 (C). The difference between the expansion ratio in the width direction of the film in the first swelling treatment tank of (B) was +0.1 points.

[Example 3]

(Trade name: "Kurarupofal film VF-PE # 6000 ", trade name, manufactured by Kuraray Co., Ltd., degree of polymerization: 2400, degree of saponification: 99.9 mol% or more) having a thickness of 60 탆 was used as the original film, Was immersed in a swelling treatment tank containing pure water at 37 DEG C for 40 seconds while keeping the tension so that the film would not sag. At this time, in the swelling treatment tank, the film was transported using an expander roll. Next, uniaxial stretching was carried out up to 2.2 times while immersing for 60 seconds in a dyeing treatment bath containing iodine and potassium iodide aqueous solution containing an aqueous solution at 30 DEG C, and 55% of potassium iodide / boric acid / water in a weight ratio of 12 / 4.4 / 100 Deg.] C, and uniaxial stretching was carried out until the total drawing ratio from the disc was 5.5 times. Subsequently, the substrate was immersed in a bath containing an aqueous solution of boric acid at 40 占 폚, immersed in a cleaning bath containing pure water at 12 占 폚, and dried at 70 占 폚 for 3 minutes in a drying furnace to prepare a polarizing film. Wrinkles were not observed in the swelling treatment and dyeing treatment, and no breakage of the film was observed.

(A) Saturation expansion rate in the swelling treatment tank

The saturation expansion coefficient in the swelling treatment tank was obtained in the same manner as in Example 1 (A) except that the film piece was cut from the polyvinyl alcohol film "Kurarapoval film VF-PE # 6000" used in Example 3. After immersion, the length of the film piece in the width direction was 62.70 mm. From the amount of change in length due to immersion relative to the length in the width direction before immersion, the saturation expansion ratio in the swelling treatment tank was 25.4%.

(B) Expansion ratio of the film in the width direction in the swelling treatment tank

The same piece as that of the piece of the film cut in the above (A) was separately prepared, and it was immersed in a water bath containing pure water at 37 DEG C for 40 seconds in the same manner as the treatment in the swelling treatment tank of Example 3 to obtain an expansion ratio in the swelling treatment tank . After immersing, the length of the film piece in the width direction was 61.00 mm. The swelling rate in the width direction of the film in the swelling treatment tank was determined to be 22.0% in the same manner as in Example 1 (B). This expansion ratio was 86.6% with respect to the saturated expansion ratio of the above (A). In Table 1 below, the swelling rate of the swelling tank is indicated by the column of &quot; expansion rate 1 &quot;, and the swelling rate of the swelling treatment tank by the saturated expansion rate is shown by the column of &quot; expansion rate 1 / saturation expansion rate &quot;.

(C) Expansion ratio of the film in the width direction in the dyeing treatment tank

In order to perform the same treatment as that of the dyeing treatment tank, the film piece subjected to the same treatment as the swelling treatment tank in (B) above was added to a water bath containing the same aqueous solution having the same composition as the dyeing treatment bath and at the same temperature Lt; / RTI &gt; After immersion, the length of the film piece in the width direction was 60.85 mm. From the amount of change in length in the dyeing treatment tank to the length in the width direction of the film piece at the time of cutting, the expansion ratio in the width direction of the film in the dyeing treatment tank was 21.7%. Further, the difference between the expansion rate in the width direction of the film in the swelling treatment tank of (B) was -0.3 points. In the following Table 1, the expansion rate of the dyeing treatment tank is shown in the column of "expansion rate 2", and the difference in the expansion rate in the swelling treatment tank and dyeing treatment tank is shown in the column of "expansion rate difference".

[Comparative Example 1]

A polarizing film was produced in the same manner as in Example 1 except that the immersion time of the film in the first swelling treatment tank was changed to 10 seconds. Wrinkles were generated in the first swelling treatment tank and the second swelling treatment tank, and the film was frequently cut at the time of stretching. Further, when the appearance of the resulting polarizing film was confirmed, wrinkles were seen.

(A) the saturation expansion coefficient in the first swelling treatment tank

The saturation expansion ratio in the first swelling treatment tank was obtained in the same manner as in Example 1 (A). The length of the film piece in the width direction after immersion was 62.70 mm and the saturation expansion rate was 25.4%.

(B) Expansion ratio of the film in the width direction in the first swelling treatment tank

The swelling ratio in the first swelling treatment tank was determined in the same manner as in Example 1 (B) except that the immersion time was changed to 10 seconds. After immersing, the length of the film piece in the width direction was 55.35 mm, and the coefficient of expansion was 10.7%. This expansion ratio was 42.1% with respect to the saturated expansion ratio of the above (A).

(C) Expansion ratio of the film in the width direction in the second swelling treatment tank

The same treatment as in Example 1 (C) was carried out except that the used film piece was changed to the same treatment as the first swelling treatment tank in (B) above. After immersion, the length of the film piece in the width direction was 58.20 mm, and the expansion ratio of the film in the width direction in the second swelling treatment tank was 16.4%. The difference between the expansion rate in the width direction of the film in the first swelling treatment tank of (B) was +5.7 points.

[Comparative Example 2]

A polarizing film was produced in the same manner as in Example 2 except that the immersion time of the film in the first swelling treatment tank was changed to 10 seconds. Further, wrinkles were generated in the first swelling treatment tank and the second swelling treatment tank, and the film was severed at the time of stretching. When the appearance of the resulting polarizing film was confirmed, wrinkles were seen.

(A) the saturation expansion coefficient in the first swelling treatment tank

The saturation expansion ratio in the first swelling treatment tank was determined in the same manner as in Example 2 (A). The length of the film piece in the width direction after immersion was 62.10 mm and the saturation expansion rate was 24.2%.

(B) Expansion ratio of the film in the width direction in the first swelling treatment tank

The swelling ratio in the first swelling treatment tank was determined in the same manner as in Example 2 (B) except that the immersion time was changed to 10 seconds. After immersion, the length of the film piece in the width direction was 56.60 mm, and the expansion ratio was 13.2%. This expansion ratio was 54.5% with respect to the saturated expansion ratio of the above (A).

(C) Expansion ratio of the film in the width direction in the second swelling treatment tank

The same treatment as in Example 1 (C) was carried out except that the used film piece was changed to the same treatment as the first swelling treatment tank in (B) above. After immersion, the length of the film piece in the width direction was 59.05 mm, and the expansion ratio in the width direction of the film in the second swelling treatment tank was 18.1%. Furthermore, the difference between the expansion rate in the width direction of the film in the first swelling treatment tank of (B) was + 4.9 points.

[Comparative Example 3]

A polarizing film was produced in the same manner as in Example 2 except that the immersion time of the film in the first swelling treatment bath was changed to 100 seconds. Wrinkles were not observed in the first swelling treatment tank and the second swelling treatment tank.

(A) the saturation expansion coefficient in the first swelling treatment tank

The saturation expansion ratio in the first swelling treatment tank was determined in the same manner as in Example 2 (A). The length of the film piece in the width direction after immersion was 62.10 mm and the saturation expansion rate was 24.2%.

(B) Expansion ratio of the film in the width direction in the first swelling treatment tank

The swelling ratio in the first swelling treatment tank was determined in the same manner as in Example 2 (B) except that the immersion time was changed to 100 seconds. After immersing, the length of the film piece in the width direction was 61.70 mm, and the expansion ratio was 23.4%. The expansion ratio was 96.7% with respect to the saturated expansion ratio of the above (A).

(C) Expansion ratio of the film in the width direction in the second swelling treatment tank

The same treatment as in Example 1 (C) was carried out except that the used film piece was changed to the same treatment as the first swelling treatment tank in (B) above. After immersion, the length of the film piece in the width direction was 61.75 mm, and the expansion ratio in the width direction of the film in the second swelling treatment tank was 23.5%. The difference between the expansion rate in the width direction of the film in the first swelling treatment tank of (B) was +0.1 points.

[Comparative Example 4]

A polarizing film was produced in the same manner as in Example 2 except that the treatment temperature in the first swelling treatment tank was changed to 50 캜. Wrinkles were generated in the first swelling treatment tank and the second swelling treatment tank, and the film was often cut at the time of stretching, so that a polarizing film could not be produced.

(A) the saturation expansion coefficient in the first swelling treatment tank

The saturation expansion ratio in the first swelling treatment tank was obtained in the same manner as in Example 2 (A) except that the pure water temperature was changed to 50 캜. The length of the film piece in the width direction after immersion was 73.10 mm and the saturation expansion rate was 46.2%.

(B) Expansion ratio of the film in the width direction in the first swelling treatment tank

The swelling ratio in the first swelling treatment tank was determined in the same manner as in Example 2 (B) except that the pure water temperature was changed to 50 캜. After immersion, the length of the film piece in the width direction was 69.30 mm, and the expansion ratio was 38.6%. This expansion ratio was 83.5% with respect to the saturated expansion ratio of the above (A).

(C) Expansion ratio of the film in the width direction in the second swelling treatment tank

The same treatment as in Example 1 (C) was carried out except that the used film piece was changed to the same treatment as the first swelling treatment tank in (B) above. After immersion, the length of the film piece in the width direction was 67.00 mm, and the expansion ratio in the width direction of the film in the second swelling treatment tank was 34.0%. The difference between the expansion rate in the width direction of the film in the first swelling treatment tank of (B) was -4.6 points.

[Comparative Example 5]

A polarizing film was produced in the same manner as in Example 2 except that the treatment temperature in the first swelling treatment tank was changed to 20 캜. Wrinkles were generated in the first swelling treatment tank and the second swelling treatment tank, and the film was frequently cut at the time of stretching. When the appearance of the resulting polarizing film was confirmed, wrinkles were seen.

(A) the saturation expansion coefficient in the first swelling treatment tank

The saturation expansion ratio in the first swelling treatment tank was obtained in the same manner as in Example 2 (A) except that the pure water temperature was changed to 20 캜. The length of the film piece in the width direction after immersion was 59.15 mm and the saturation expansion rate was 18.3%.

(B) Expansion ratio of the film in the width direction in the first swelling treatment tank

The expansion rate in the first swelling treatment tank was determined in the same manner as in Example 2 (B) except that the pure water temperature was changed to 20 占 폚. After immersing, the length of the film piece in the width direction was 54.45 mm, and the coefficient of expansion was 8.9%. The expansion ratio was 48.6% with respect to the saturated expansion ratio of (A).

(C) Expansion ratio of the film in the width direction in the second swelling treatment tank

The same treatment as in Example 1 (C) was carried out except that the used film piece was changed to the same treatment as the first swelling treatment tank in (B) above. After immersion, the length of the film piece in the width direction was 58.05 mm, and the expansion ratio of the film in the width direction in the second swelling treatment tank was 16.1%. The difference between the expansion rate in the width direction of the film in the first swelling treatment tank of (B) was +7.2 points.

The results are shown in Table 1. From Table 1, it can be seen that Example 1 which satisfies all the requirements of the present invention and Comparative Example 1 which uses the same original film as that of Example 1 but does not satisfy the requirements of the present invention are compared, As a result of the sufficient swelling of the film in the treatment tank, wrinkles due to the difference in expansion ratio in the subsequent second swelling treatment tank during production were not generated, and wrinkles were not observed in the obtained polarizing film and appearance was good, 1, since the treatment time was short, it was not sufficiently swollen. As a result, wrinkles and film breakage occurred during production, and wrinkles were also observed in the obtained polarizing film. Further, in Example 2 using the original film of the thin film than in Example 1, and Comparative Examples 2, 4 and 5 in which the same original film is used but the original film is not used, in Example 2, Wrinkles and film breakage did not occur, and a polarizing film having good appearance was able to be produced. In any comparative example, wrinkles and film breakage occurred during production, wrinkles were seen in the obtained polarizing film, It was found that a polarizing film could not be obtained.

Comparative Example 3 was able to produce a polarizing film having good appearance without causing wrinkles or breaks of the film during production, but the processing time in the first swelling treatment tank was long and the production efficiency was lower than in Example 2.

Example 3, which is another embodiment of the present invention, in which the swelling treatment is carried out by only one swelling treatment tank, satisfies all the requirements of the present invention. As a result of sufficient swelling of the film in the swelling treatment tank, Wrinkles caused by the difference in the expansion ratio in the dyeing treatment did not occur and wrinkles were not observed in the obtained polarizing film and the appearance was good.

According to the polarizing film producing method of the present invention, it is possible to suppress the unevenness of the swelling of the film in each treatment, especially the swelling treatment, when the polarizing film is produced, and to suppress the occurrence of wrinkles and breakage of the film It is possible to efficiently obtain a polarizing film having excellent appearance.

Claims (6)

A method for producing a polarizing film by performing a swelling treatment, a dyeing treatment, a boric acid treatment, and a cleaning treatment on a raw film made of a polyvinyl alcohol-based resin in this order,
The thickness of the original film is 10 to 60 탆,
Wherein the swelling treatment is carried out by passing a plurality of swelling treatment tanks including at least a first swelling treatment tank and a second swelling treatment tank which are arranged in order from the side where the original film enters,
The expansion ratio in the width direction of the film in the first swelling treatment tank is 90% or less of the saturated expansion coefficient when the film is immersed in the treatment liquid of the same temperature and composition,
The first swelling treatment is performed so that the absolute value of the difference when the expansion ratio in the width direction of the film in the first swelling treatment tank and the expansion ratio in the width direction of the film in the second swelling treatment tank are respectively expressed as a percentage, Wherein the treatment temperature of the treatment tank and the second swelling treatment tank are adjusted so that the treatment bath and the second swelling treatment tank pass through the treatment tank. The method for producing a polarizing film according to claim 1, wherein the treatment temperature of the first swelling treatment tank is 35 to 45 占 폚, the treatment temperature of the second swelling treatment tank is lower than the treatment temperature of the first swelling treatment, . The polarizing film according to any one of claims 1 to 5, wherein the polarizing film is a polarizing film for adjusting the processing temperature of the first swelling treatment bath and the passage time of the treatment bath so that the expansion ratio in the width direction of the film in the first swelling treatment bath is 15 to 25% &Lt; / RTI &gt; A method for producing a polarizing film by performing a swelling treatment, a dyeing treatment, a boric acid treatment, and a cleaning treatment on an original film made of a polyvinyl alcohol-based resin in this order,
The thickness of the original film is 10 to 60 탆,
Wherein the swelling treatment is carried out by passing through one swelling treatment tank,
The expansion ratio of the film in the width direction in the swelling treatment tank is 90% or less of the saturated expansion coefficient when the film is immersed in the treatment liquid of the same temperature and composition,
The expansion rate of the film in the width direction in the swelling treatment tank and the expansion rate in the width direction of the film in the dyeing treatment tank are respectively expressed as percentages, And adjusting the treatment temperature and the time passing through the treatment tank. The method for producing a polarizing film according to claim 4, wherein the processing temperature of the swelling treatment tank is 35 to 45 占 폚, the treatment temperature of the dyeing treatment tank is lower than the treatment temperature of swelling treatment, and the temperature is 25 to 35 占 폚. The method of manufacturing a polarizing film according to claim 4 or 5, wherein the processing temperature of the swelling treatment tank and the time passing through the treatment tank are adjusted so that the swelling rate in the width direction of the film in the swelling treatment tank is 15 to 25%.