KR101610954B1 - Method for drying coating film - Google Patents

Abstract

assignment

Provided is a drying method of a coating film capable of preventing defects of a coating film from occurring due to condensation of a solvent on the surface of a cylinder and adhesion of the condensed solvent to a coating film as water droplets in a drying method of a coating film.

Solution

The solvent in the coating film of the flexible film 12 is heated by the heater 19 from the backside of the flexible film 12 while the flexible film 12 coated with the coating film is applied to the surface, The solvent vaporized by the cooling plate 20 disposed at a position separated from the flexible film 12 by a predetermined distance is agglomerated and the agglomerated solvent is supplied to the tube 21 ).

Flexible film, coating film, heater, cooling plate

Description

METHOD FOR DRYING COATING FILM [0002]

The present invention relates to a drying method of a coated film, and more particularly to a drying method of a coated film for drying a long and wide coating film surface formed by applying various liquid compositions to a running flexible film.

With regard to the drying method for drying the long and wide coating film surface formed by applying various liquid compositions to the running flexible film, the uncoated side is supported by a roller, and air is sprayed from the air nozzle onto the coated surface side, There is a non-contact type air-floating drying method in which air is blown from an air nozzle onto both a coated surface and a non-coated surface, and the support is floated, that is, the support is dried without being contacted with a roller or the like.

Generally, in a method of spraying these winds (hereinafter, referred to as a ventilation drying method), a conditioned air is sprayed onto a coated surface to evaporate the solvent contained in the coated surface and dry it. However, since the air is blown directly to the coated surface or through the perforated plate or the rectifying plate, the coated surface is disturbed by the wind, so that the thickness of the applied layer becomes uneven and deviations occur, The rate of evaporation of the solvent on the coated surface becomes uneven due to the presence of the surface of the coating film, so that the surface of the skin becomes like a tangerine skin, resulting in a problem that a uniform coated layer can not be obtained.

In particular, in the case where an organic solvent is contained in the coating liquid, such deviation occurs remarkably. This is because the organic solvent is sufficiently contained in the coating film at the initial stage of drying and if evaporation distribution of the organic solvent occurs at this stage, the temperature distribution and the surface tension distribution are generated on the coating film surface, , So-called marangoni convection flows. The occurrence of such a deviation becomes a serious coating defect.

When the liquid crystal is contained in the coating film, not only the above-described drying deviation but also the deviation of the alignment of the liquid crystal on the coating film surface due to the blowing air is caused.

Thus, Patent Document 1 discloses a method in which a solvent in a coating liquid is evaporated, recovered, and dried without blowing wind. In this method, the solvent is condensed by a method of heating the uncoated surface in the drying apparatus to promote evaporation of the solvent from the coated surface and dew condensation on the condensation plate provided on the coated surface side, and the solvent is recovered from the tube to dry the coated film to be.

[Patent Document 1] JP-A-2003-170101

However, in the method of drying a coated film in which the container is disclosed in Patent Document 1, the concentration of the solvent gas in the vicinity of the container increases with the improvement of the drying capability, and the solvent in the coated film sometimes becomes condensed on the surface of the container. Then, this condensed solvent becomes a droplet, which adheres to the coating film, resulting in a problem that the coating film becomes defective.

SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances, and it is an object of the present invention to provide a method of manufacturing a flexible film, which comprises a heater for heating and vaporizing a solvent in a coating film coated with a coating liquid, There is provided a drying method of a coating film for drying a coating film by using a cooling plate arranged substantially in parallel and a drying apparatus comprising a cylinder for cooling a cooling plate and recovering a solvent condensed on the cooling plate, It is another object of the present invention to provide a drying method of a coating film capable of preventing defects of a coating film from occurring due to adhesion of the condensed solvent to a coating film as droplets.

In order to achieve the above object, the present invention provides a method for manufacturing a flexible film, comprising the steps of: heating a solvent in a coated film of the flexible film from a back side of the flexible film by a heater while running a flexible film coated with a coating film on the surface, A step of aggregating a solvent vaporized by a cooling plate disposed at a position spaced apart from the flexible film by a predetermined distance on the surface side of the flexible film and recovering the coagulated solvent in a tube maintained at a predetermined temperature .

According to the present invention, a solvent in a coated film of the flexible film is heated from a backside of the flexible film by a heater while traveling on a flexible film coated with a coating film on the surface, and the surface of the flexible film A step of condensing the solvent vaporized by the cooling plate disposed at a position spaced apart from the flexible film by a predetermined distance and collecting the coagulated solvent in a container maintained at a predetermined temperature, It is possible to prevent water droplets of the solvent from adhering to the coating film, thereby making it possible to prevent the coating film from becoming defective. The predetermined temperature varies depending on the kind of the solvent contained in the coating liquid, the temperature of the heater and the cooling plate, and is in the range of 20 ° C to 50 ° C.

Furthermore, the drying method according to the present invention is characterized in that the flexible film is caused to run perpendicularly to the paper surface.

When the flexible film is formed so as to run in a direction perpendicular to the paper surface, a barrel cover (not shown) for preventing the condensed solvent from splashing onto the coating film is formed at a portion of the barrel facing the flexible film. It is preferable that the second electrode is formed.

In the case where a tub cover is formed on a portion of the tub facing the flexible film, it is preferable that the tub cover is integral with the tub. By integrally passing through the cylinder cover, not only the cylinder but also the cylinder cover can be maintained at a predetermined temperature, so that the condensed solvent becomes water droplets and adheres to the coating film, thereby making it possible to prevent the coating film from being defective.

According to the present invention, it is possible to provide a coating film drying method capable of preventing defects of a coating film from occurring due to condensation of the solvent on the surface of the cylinder and the condensed solvent becoming water droplets and adhering to the coating film

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The present invention is described below with reference to the preferred embodiments. However, the present invention can be modified in many ways without departing from the scope of the present invention, and other embodiments other than the present embodiment can be used. Accordingly, all modifications within the scope of the present invention are included in the claims. In the present specification, the numerical range indicated by using " ~ " means a range including numerical values described before and after " ~ ".

Fig. 1 is a conceptual diagram showing an example of a coating / drying line 10 equipped with a drying apparatus to which a drying method of a coating film of the present invention is applied.

As shown in the figure, the coating and drying line 10 mainly comprises a delivery device (not shown) for delivering the flexible film 12 wound in the form of a roll, an application device (not shown) for applying the application liquid to the flexible film 12 A drying device 18 for condensing and recovering the solvent in the coating liquid of the coating film formed on the flexible film 12 and a winding device (not shown) for winding the product produced by coating and drying , And a plurality of guide rollers (15, 15) forming a conveyance path on which the flexible film (12) travels. Further, a ventilation and drying unit (not shown) for drying the coating film is formed downstream of the drying unit 18 as necessary.

As the flexible film 12, a resin film such as polyethylene, PET (polyethylene terephthalate), or TAC (triacetate), paper, metal foil, or the like can be used.

The application means 16 may be of various types. For example, a slot die coater, a wire bar coater, a roll coater, a gravure coater, a slide hopper coating method, a curtain coating method, or the like can be used. 1, the application unit 16 may have a configuration in which the application surface is lower in the horizontal direction, or may be in the upper side in the horizontal direction. Alternatively, it may be configured to be inclined with respect to the horizontal direction.

Dust removing equipment 70 may be provided at the front stage of the application unit 16 or the surface of the flexible film 12 may be subjected to pretreatment or the like as shown in Fig. In an optical film or the like requiring high quality with little dust or the like, a high-quality coating and a dried film can be obtained by employing them at the same time.

2 is a schematic diagram showing a schematic configuration of an apparatus for producing an optical compensation sheet on which a drying apparatus 18 to which a drying method of a coating film of the present invention is applied is mounted.

The production line of the optical compensation sheet is carried out, for example, by the following process.

1) a feeding step (14) of the flexible film (12);

2) a step (52) of forming a resin layer for forming an alignment film for applying and drying a coating liquid containing a resin for forming an alignment film on the surface of the flexible film;

3) a rubbing step (54) for forming an alignment film on the flexible film by rubbing the surface of the resin layer on a flexible film having a resin layer for forming an alignment film formed on its surface;

4) a step (16) of applying a liquid crystal discotic compound for applying a coating liquid containing a liquid crystalline discotic compound onto an alignment film;

5) a drying step (18) for drying the coated film to evaporate the solvent in the coated film;

6) a liquid crystal layer forming step (58) of heating the coated film to a discotic nematic phase forming temperature to form a liquid crystal layer of discotic nematic phase;

7) When the liquid crystal layer is solidified (that is, solidified by quenching after formation of a liquid crystal layer, or when a liquid crystal discotic compound having a crosslinkable functional group is used, the liquid crystal layer is crosslinked by light irradiation ) Step (60);

8) a winding step (24) for winding the flexible film on which the alignment film and the liquid crystal layer are formed.

Reference numeral 50 denotes a drying zone, 64 denotes a test apparatus, 66 denotes a protective film, and 68 denotes a laminate group.

1, the drying apparatus 18 includes a heater 19 for heating and vaporizing a solvent in a coating film coated with a coating liquid on a running flexible film 12, A cooling plate 20 formed substantially parallel to the flexible film with a predetermined distance therebetween and a cylinder 21 cooled by the cooling plate 20 to recover the solvent condensed on the cooling plate. As a result, when the solvent in the coating liquid of the coating film is volatilized, the volatilized solvent is condensed in the cooling plate 20 and recovered in the cylinder 21.

Examples of the solvent of the coating liquid include aromatic hydrocarbon such as toluene, xylene and styrene, chlorinated aromatic hydrocarbon such as chlorobenzene and ortho-dichlorobenzene, methane derivative such as monochloromethane, ethane such as monochlorethane, Alcohols such as methanol, isopropyl alcohol and isobutyl alcohol; esters such as methyl acetate and ethyl acetate; ethers such as ethyl ether and 1,4-dioxane; ketones such as acetone , Ketones such as methyl ethyl ketone, glycol ethers such as ethylene glycol monomethyl ether, alicyclic hydrocarbon such as cyclohexane, aliphatic hydrocarbon such as normal hexane, and mixture of aliphatic or aromatic hydrocarbons.

The material used for the surface for condensing the solvent of the cooling plate 20 is not particularly limited, such as a metal, a plastic or a wood, but when an organic solvent is contained in the coating liquid, a material resistant to the organic solvent It is preferable to use a coating on the surface, or to coat the surface.

In the drying device 18, the means for recovering the condensed solvent in the cooling plate 20 may be formed by forming grooves on the condensation surface of the cooling plate 20 and using a solvent force (capillary force) . The direction of the groove may be the running direction of the flexible film 12, or the direction perpendicular to the direction.

It is preferable that the drying device 18 is disposed as close as possible to the application means 16 in order to prevent the drying film from drifting due to the occurrence of natural convection immediately after application of the application liquid. More specifically, it is preferable that the inlet of the drying apparatus 18 is arranged so as to be located within 5 m from the application means 16, and the position of the inlet of the drying apparatus 18 is within 2 m from the application means 16 And it is most preferable that the inlet of the drying device 18 is arranged so as to be located within 0.7 m from the application means 16. [

For the same reason, the running speed of the flexible film 12 is preferably such that the flexible film 12 reaches the drying device 18 within 30 seconds after application by the application means 16, It is more preferable that the speed at which the film 12 reaches the drying apparatus 18 within 20 seconds after application by the application means 16 is preferable.

The greater the application amount of the coating liquid and the coating film thickness, the more easily the inside of the coating film is likely to flow, so that the deviation easily occurs. If the thickness of the coating film is 0.001 mm to 0.08 mm,

If the running speed of the flexible film 12 is excessively large, the boundary layer near the coating film is disturbed by the accompanying wind, adversely affecting the coating film. Therefore, the running speed of the flexible film 12 is preferably set at 1 m / min to 100 m / min, and more preferably set at 5 m / min to 80 m / min.

In the drying apparatus 18 to which the drying method of the present invention is applied, a heater 19 is disposed on the opposite side of the coated film to heat the flexible film 12 to vaporize the solvent in the coated film. As the heater, not only a plate shape as shown in Fig. 1 but also a heating roll capable of heating can be arranged and heated. In addition, it may be heated by using an infrared heater, microwave heating means or the like.

In order to promote the condensation of the solvent vaporized from the coating liquid, a cooling plate 20 is disposed on the coating film side of the flexible film 12 and cooled.

The temperature of the heater 19 and the cooling plate 20 is preferably controlled. In particular, the cooling plate 20 needs to be provided with a facility for controlling the temperature, and for cooling the cooling plate 20. Cooling may be performed using a water-cooled heat exchanger system using a refrigerant or the like, an air-cooling system using wind, a system using electricity, or a system using a Peltier element, for example.

Here, it is preferable that the temperature of the heater 19 is maintained at 70 to 130 占 폚, and the temperature of the cooling plate 20 is preferably maintained at 8 to 10 占 폚.

As shown in Fig. 1, a cylinder 21 for recovering a condensed solvent is formed below the cooling plate 20, and the solvent is recovered through the cylinder 21. As shown in Fig. When the cylinder 21 is formed in this manner, the condensed solvent can be easily recovered. That is, since the surface of the cylinder 21 is provided between the flexible film 12 and the cooling plate 20, the condensed solvent can be easily recovered.

The position where the cylinder 21 is formed is formed on the lower side of the cooling plate 20. Thus, it is preferable that the cylinder 21 is formed at a position where it can be recovered by the flow of the solvent. Further, as shown in the drawing, the drying device 18 to which the drying method of the coating film of the present invention is applied is provided in the vertical direction so that the flexible film 12 runs perpendicular to the paper surface. Therefore, .

However, in the drying apparatus constructed as described above, the concentration of the solvent gas in the vicinity of the cylinder 21 rises along with the improvement of the drying ability, and the solvent in the coating film may condense on the surface of the cylinder. Then, this condensed solvent becomes water droplets and adheres to the coating film, resulting in a problem that the coating film becomes defective.

Therefore, in the present invention, the solvent in the coating film of the flexible film (12) is moved from the back side of the flexible film (12) by the heater (19) while the flexible film (12) The solvent vaporized by the cooling plate 20 disposed at a position spaced apart from the flexible film 12 by a predetermined distance is agglomerated on the surface side of the flexible film 12 and the agglomerated solvent is agitated at a predetermined temperature And recovering the recovered product in the cylinder (21) maintained at a constant temperature.

According to the present invention, the solvent in the coated film of the flexible film is heated from the back side of the flexible film by a heater while traveling on the surface of the flexible film coated with the coated film, And a step of coagulating the solvent vaporized by the cooling plate disposed at a position separated from the film by a predetermined distance and collecting the coagulated solvent in a container maintained at a predetermined temperature, Can be prevented from being adhered. Therefore, it is possible to prevent water droplets of the solvent from adhering to the coating film due to condensation on the surface of the cylinder, resulting in defects of the coating film. Here, the predetermined temperature varies depending on the type of the solvent contained in the coating liquid (coating film), the temperature of the heater and the cooling plate, and is 20 ° C to 50 ° C.

Further, the predetermined temperature of the cylinder indicates the surface temperature of the portion of the cylinder 21 that is strictly between the flexible film 12 and the cooling plate 20. As will be described later, when the cylinder cover 21a is formed in the cylinder 21, the surface temperature of the cylinder cover is indicated.

3 is an enlarged view of the vicinity of the cylinder 21 of the drying apparatus 18. As shown in Fig. In the cylinder 21, the warm water 22 is circulated so that a predetermined temperature can be maintained. The cylinder 21 is fixed to the cooling plate 20 by a fixing member 23. It is necessary to fix the cylinder 21 to the cooling plate 20 or the like in order to keep the cylinder 21 at a predetermined temperature. Alternatively, the fixing member 23 may be fixed to the cylinder 21, It is preferable to interpose a heat insulating material therebetween.

1 and 2, when the flexible film 12 is formed so as to run in a substantially vertical direction with respect to the paper surface, as shown in Fig. 3, It is preferable that a cover 21a for preventing the solvent 17 condensed in the cooling plate 20 from splashing onto the coating film of the flexible film 12 is formed.

When the cover 21a for preventing the solvent condensed on the cooling plate 20 from splashing onto the coating film is formed at the portion facing the flexible film of the container, as shown in Fig. 3, It is preferable that the cover 21a is integral with the cylinder 21. [ By integrally passing through the cylinder cover, not only the cylinder but also the cylinder cover can be maintained at a predetermined temperature, thereby preventing condensation of the solvent on the cylinder cover and causing the condensed solvent to adhere to the coating film as water droplets, .

The distance (distance) between the surface of the coating film and the surface of the cylinder 21 of the drying apparatus 18 needs to be adjusted to a proper distance after considering the drying speed of the desired coating film. If the distance is shortened, the drying speed is accelerated, while it is easily affected by the set distance accuracy. On the other hand, when the distance is increased, not only the drying speed is greatly reduced but also natural convection due to heat occurs, thereby causing a drying deviation. The distance between the surface of the coating film and the surface of the cylinder 21 of the drying device 18 is preferably 1 mm to 200 mm, more preferably 1.5 mm to 100 mm.

Examples of the air-blowing drying means used in the prior art include a roller conveying dryer system in which a non-coated side is supported by a roll and air is blown from an air nozzle onto the side of the coated side to dry the same, A non-contact type air-floating dryer system in which air is blown from an air nozzle and a support body is floated, that is, a support body is dried without being contacted with a roll or the like, or a non-contact type drying system. A drying method such as a chord-winding type drying method may be used. In any of the ventilation drying means, the drying air is supplied to the surface of the coating film to dry the coating film.

In addition, a common member is used for the delivery device, the guide roller 15, the winding device, etc. used in the coating and drying line 10 equipped with the drying device to which the drying method of the present invention is applied, The description is omitted.

According to the drying method of the coating film of the present invention described in detail above, it is possible to provide a method of drying a flexible film to be driven, which comprises a heater for heating and vaporizing a solvent in a coating film on which a coating liquid is applied, A drying method of a coating film for drying a coating film by using a cooling plate arranged substantially in parallel with a distance and a drying apparatus comprising a cylinder for cooling a cooling plate and recovering a solvent condensed on the cooling plate, It is possible to provide a method for drying a coating film which can prevent condensation on the surface of the coating film, and that the condensed solvent becomes water droplets and adheres to the coating film to prevent defects of the coating film.

In addition, the drying method of the coating film of the present invention can achieve the same effect when applied to a solid solution such as a polymer or a particle dissolved or dispersed in a coating liquid. On the other hand, in a system including particles or the like, the occurrence of a drying deviation significantly affects the dispersion distribution of particles in the coating film. Therefore, it is desirable to use this system for this system.

The shape of the cooling plate 20 of the drying device 18 is not necessarily the shapes shown in Figs. 1 and 3, and for example, as shown in Fig. 4, 20a may be formed. By forming the bent portion 20a in the cooling plate 20 in this manner, water droplets of the solvent condensed on the cooling plate 20 are preferably guided into the cylinder 21. [

Example

An experiment was conducted with an apparatus for producing an optical compensatory sheet equipped with a drying apparatus 18 to which the drying method of the coating film of the present invention shown in Fig. 2 was applied.

The production method of the optical compensation sheet was continuously carried out from the step of feeding the elongated flexible film to the step of winding the obtained optical compensation sheet. (MP-203, manufactured by Kuraray Co., Ltd.) was applied to one side of a long film of flexible film of triacetyl cellulose (thickness: 100 m, width: 500 mm, manufactured by Fujifilm, ) And 5% by weight of a solution of POVAR (registered trademark)) was applied and dried at 90 DEG C for 4 minutes to form a resin layer for forming an alignment film having a film thickness of 2.0 mu m. The transporting speed of the film was 50 m / min.

(Nx-ny) x d = 16 nm when the refractive index of the triacetylcellulose film in the film plane is nx, ny, the refractive index in the thickness direction is nz, and the thickness of the film is d, (nx-ny) / 2-nz} x d 75 nm. Further, at the time of forming the orientation film-forming resin layer, a coating and drying line equipped with the drying device 18 of FIG. 3 was used.

Subsequently, the resulting film having the orientation film-forming resin layer was continuously conveyed at a rate of 50 m / min, and the surface of the resin layer was rubbed to form an orientation film. The rubbing treatment was carried out at a rotation speed of the rubbing roller at 300 rpm, and the orientation film thus obtained was subjected to vibration suppression.

Next, the coating liquid for the liquid crystal layer was applied from the slot die such that the coating speed was 50 m / min and the coating amount was 6.5 cc / m ² while the film having the obtained alignment film was conveyed at a speed of 50 m / To form a liquid crystal layer (coating film), and then passed through a drying device 18 and a hot air drying device. The hot air drying apparatus was adjusted to 130 ° C. After 3 seconds from the application, it entered the drying device 18 and entered the hot air drying device after 3 seconds. The hot air dryer passed in about 3 minutes.

The coating liquid for a liquid crystal layer used was prepared by adding a photopolymerization initiator (trade name: Irgacure 907, manufactured by Nippon Chiba Kogei Co., Ltd., Japan) to a mixture of the following discotic compounds TE- ) Was added in an amount of 1% by mass, and the mixture was dissolved in 40% by weight of methyl ethyl ketone.

[Chemical Formula 1]

The wet film thickness t of the liquid crystal layer was 6.5 占 퐉 and the interval D between the web 12 and the tip end of the slot die 18 was 65 占 퐉. The value of t / D was 0.1.

Subsequently, while the alignment film and the film coated with the liquid crystal layer were continuously conveyed at 50 m / min, the surface of the liquid crystal layer was irradiated with ultraviolet rays using an ultraviolet lamp. That is, the film having passed through the heating zone was irradiated with ultraviolet light having an illuminance of 600 mW for 4 seconds by using an ultraviolet irradiation device (ultraviolet lamp: output 160 W / cm, light emission length 1.6 m) to crosslink the liquid crystal layer.

Here, an experiment was conducted on the effect of keeping the tub 21 warm in the drying device 18 of the coating film of Fig. The temperature of the heater 19 was set to 120 deg. C, and the temperature of the cooling plate 20 was set to 10 deg.

In the first to tenth embodiments, the cylinder 21 was kept warm while the cylinder 21 was not kept warm in the first and second comparative examples. The cylinder 21 was kept at the temperature shown in Table 1 below. In Comparative Example 1, the temperature of the cylinder surface is shown.

In addition to the sixth embodiment, the cylinder cover 21a is formed in the cylinder 21. [ The cylinder cover 21a used in the passage-integrated type in Examples 1 to 5, 9, and Comparative Example 1, and the passage cover separated in Example 7, Example 8, and Example 10 were used. For the tube cover 21a formed, the temperature of the tube cover surface was measured and described in Table 1.

Evaluation was made on the condensation state of the solvent, the surface shape of the coated film, and the odor around the drying device with respect to the cylinder 21 (barrel cover 21a) at this time, and the results are shown in Table 1. From this evaluation result, comprehensive evaluation was carried out in four steps of? To?, And it is shown in Table 1.

Preservation of barrel Barrel temperature
(° C) Cover type Cover cover temperature
(° C) Condensation Surface shape The smell around the device evaluation Example 1 has exist 37 Integral type 32 none OK OK ◎ Example 2 has exist 27 Integral type 22 Faintly frosty OK OK ○ Example 3 has exist 25 Integral type 20 But the liquid does not swell. OK OK △ Example 4 has exist 45 Integral type 38 none OK Has a little smell ○ Example 5 has exist 60 Integral type 55 none There is a slight deviation
Allowed within Has a little smell △ Example 6 has exist 35 none - none Liquid scattering from cold plate Has a little smell ○ Example 7 has exist 30 Detachable type 22 Faintly frosty OK OK ○ Example 8 has exist 40 Detachable type 32 none OK Has a little smell ○ Example 9 has exist 23 Integral type 18 has exist
The droplet grows. There is a little condensation liquid scattering OK △ Example 10 has exist 26 Detachable type 18 has exist
The droplet grows. There is a little condensation liquid scattering OK △ Comparative Example 1 none 20 Integral type 18 has exist
The droplet grows, and the droplet that is grown contacts. There is a slight condensation liquid scattering,
The grown droplet contact portion becomes a process failure OK ×

From the above results, it can be seen that the overall evaluation is good when the cylinder 21 is kept warm. In addition, it is preferable to form the cylinder cover in the cylinder, and it is preferable that the cylinder cover is integrally formed. Further, in the case where the cylinder cover is not formed, it is preferable to heat the cylinder so that the temperature of the cylinder surface and the temperature of the cylinder cover surface when the cylinder cover is formed in the cylinder are in the range of 20 ° C to 50 ° C Able to know.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing an example of a coating / drying line equipped with a drying apparatus to which a drying method of a coating film of the present invention is applied; Fig.

2 shows a production line of an optical compensation sheet;

3 is an enlarged view of a vicinity of a drum of a drying apparatus to which a drying method of a coating film of the present invention is applied;

4 is a view showing another embodiment of a drying apparatus to which the method of drying a coating film of the present invention is applied.

[Description of Drawings]

10 ... Coating / drying line

12 ... Flexible film

14 ... Delivery device (delivery process)

15 ... Guide roller

16 ... Application means (application step)

17 ... Solvent (water droplets)

18 ... Drying apparatus (drying step)

19 ... heater

20 ... Cooling plate

20a ... Bent portion

21 ... barrel

21a ... Barrel cover

22 ... Insulation

23 ... Fixed member

24 ... Winding device (winding process)

Claims (5)

The solvent in the coated film of the flexible film is heated from the back side of the flexible film by a heater while traveling on the surface of the flexible film coated with the applied film, A solvent evaporated by a cooling plate disposed at a position separated from the flexible film by a predetermined distance is agglomerated on the surface side of the flexible film, And collecting the coagulated solvent in a column maintained at a predetermined temperature by keeping warm water circulating, Wherein a tub cover is integrally formed at a portion facing the flexible film of the cylinder. The solvent in the coated film of the flexible film is heated from the back side of the flexible film by a heater while traveling on the surface of the flexible film coated with the applied film, A solvent evaporated by a cooling plate disposed at a position separated from the flexible film by a predetermined distance is agglomerated on the surface side of the flexible film, And recovering the coagulated solvent in a column maintained at a predetermined temperature, Wherein a tub cover is integrally formed at a portion of the barrel facing the flexible film, Wherein the tub cover is formed to a position higher than a lower end of the cooling plate. The solvent in the coated film of the flexible film is heated from the back side of the flexible film by a heater while traveling on the surface of the flexible film coated with the applied film, A solvent evaporated by a cooling plate disposed at a position separated from the flexible film by a predetermined distance is agglomerated on the surface side of the flexible film, And recovering the coagulated solvent in a column maintained at a predetermined temperature, Wherein a tub cover is integrally formed at a portion of the barrel facing the flexible film, And a bending portion for guiding the coagulated solvent to the barrel is formed at a lower end of the cooling plate. 4. The method according to any one of claims 1 to 3, Wherein the predetermined temperature is 20 to 50 占 폚. 4. The method according to any one of claims 1 to 3, And the flexible film is caused to run perpendicularly to the paper surface.

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