JP2007075683A - Coating film formation apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a coating film formation apparatus capable of easily manufacturing an optical film such as a brightness enhancement film with a wide reflection band area and a visual field angle enlargement film. <P>SOLUTION: The coating film formation apparatus for forming the coating film on a surface of a support is provided with a paying-out device for continuously paying out the support; a first coating head for coating the support paid out from the paying-out device with a composition for coating film formation to provide the coating film; a selection UV-ray irradiation device for irradiating the coating film provided on the support by the first coating head with a first UV ray selected with a wavelength range and/or an output; a heating means for heating the coating film irradiated with the first UV ray by the selection UV-ray irradiation device; and a UV-ray curing irradiation device for irradiating the coating film heated by the heating means with second UV ray to cure the coating film. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a coating film forming apparatus, and more particularly to a coating film forming apparatus used for manufacturing various optical films and the like.

  In the production of various laminated film products such as optical films, a film as a support is continuously supplied into the production line, and a liquid such as a resin solution is applied to the film by means such as a coating head, and dried. Forming a cured coating film by curing is generally performed, and coating film forming apparatuses for performing such processes are also widely known.

  As an example of the optical film manufactured in such an embodiment, there are a brightness enhancement film and a viewing angle widening film. In these films, for example, a monomer that can be oriented in a state such as a cholesteric liquid crystal phase is applied to the surface of the support, and this monomer is oriented and polymerized by irradiation with ultraviolet rays or the like to obtain an oriented state. It is manufactured by forming a fixed polymer coating layer (cholesteric liquid crystal layer).

  However, a laminated film in which only one layer of cholesteric liquid crystal layer is formed by such a method cannot reflect in the entire visible light region because of the narrow selective reflection wavelength range of about 50 nm. Insufficient to use. Therefore, in order to obtain a film capable of reflecting in the entire visible light region, at least seven cholesteric liquid crystal layers having different pitches, that is, different selected wavelength regions are laminated (see Patent Document 1). Therefore, the present situation is that it takes a lot of time to form such a multi-layered coating film.

Japanese Patent Laid-Open No. 06-324333

  The objective of this invention is providing the coating-film formation apparatus which can manufacture easily optical films, such as a brightness improvement film with a wide reflection zone, and a viewing angle expansion film.

  As a result of intensive studies to solve the above-mentioned problems, the inventors of the present invention have, as a coating film forming apparatus, a device for selectively irradiating ultraviolet rays having a specific wavelength range and / or output prior to normal ultraviolet irradiation, and the selection. The present invention was completed by finding that an optical film having a wide reflection band can be obtained even with a small number of layers by further providing a heating means for heating the coating film after performing typical ultraviolet irradiation.

That is, according to the present invention,
[1] A coating film forming apparatus for forming a coating film on the surface of a support, comprising a feeding device for continuously feeding the support, and a coating film formed on the support fed from the feeding device A first coating head on which a composition is applied and a coating film is provided, and a wavelength range and / or output is selected for a coating film provided on a support by the first coating head. A selective ultraviolet irradiation device that irradiates the ultraviolet rays, a heating means that heats the coating film irradiated with the first ultraviolet rays by the selective ultraviolet irradiation device, and a second coating for the coating film heated by the heating means. A coating film forming apparatus comprising: a curing ultraviolet irradiation device that cures the coating film by irradiating ultraviolet rays;
[2] The coating film forming apparatus according to [1], wherein the first ultraviolet ray is an ultraviolet ray having a wavelength width of 80 nm or less;
[3] The coating film forming apparatus according to [1] or [2], wherein the first ultraviolet ray has a maximum intensity in a wavelength range of 320 nm or more and less than 400 nm;
[4] The coating film forming apparatus according to [1] or [2], wherein the first ultraviolet ray exhibits a maximum intensity in a wavelength range of 280 nm or more and less than 320 nm;
[5] The coating film forming apparatus according to any one of [1] to [4], wherein the coating film forming composition is applied onto the support from the first coating head. A coating film forming apparatus, further comprising means for imparting a property of orienting molecules in the coating film forming composition on the surface of the support fed from the feeding apparatus;
[6] The coating film forming apparatus according to any one of [1] to [5], wherein the coating film forming composition includes a first solvent, and the selective ultraviolet irradiation apparatus And drier for drying the first solvent in the coating film applied on the support from the first coating head before irradiating the coating film with the first ultraviolet ray. Coating film forming apparatus;
[7] The coating film forming apparatus according to any one of [1] to [6], further including means for storing a support on which a coating film cured by the curing ultraviolet irradiation apparatus is formed. [8] The coating film forming apparatus according to any one of [1] to [7], wherein the heating means is heated before the coating film is heated. The coating film further comprising a second coating head for applying a second solvent that swells the coating film to the coating film irradiated with the first ultraviolet ray from the selective ultraviolet irradiation device. Forming device;
Is provided.

The coating film forming apparatus of the present invention is the first ultraviolet ray in which the wavelength range and / or output is selected with respect to the configuration of [1], particularly, the coating film provided on the support by the coating head. And a heating means for heating the coating film irradiated with the first ultraviolet ray by the selective ultraviolet irradiation apparatus, the reflection band of the coating film can be expanded, A wide optical film can be easily produced. More specifically, by irradiating the coating film applied by the coating head with specific ultraviolet rays using the selective ultraviolet irradiation device, the surface side of the coating film (on the side of the coating film opposite to the support) Polymerization with a gradient of the degree of polymerization from a portion close to the surface side) to a portion far from the surface can be carried out. Furthermore, a gradient such as molecular orientation can be generated by heating the coating film with a heating means. Furthermore, it is fixed by irradiation of ultraviolet rays from the cured ultraviolet irradiation device, and can provide a coating film having a wide reflection band in the visible region, etc., and thus useful as an optical film such as a brightness enhancement film and a viewing angle widening film A laminated film can be produced.
The coating film forming apparatus of the present invention can further enhance the reflection band of the coating film by arbitrarily including the configuration [2].
The coating film forming apparatus of the present invention can further appropriately improve the reflection band according to the characteristics of the coating film by arbitrarily including the configuration of [3] or [4].
The coating film forming apparatus of the present invention can appropriately align molecules in the coating film and improve optical characteristics by arbitrarily including the configuration of [5].
The coating film forming apparatus of the present invention optionally includes the above-mentioned configuration [6], whereby the coating film is dried prior to the irradiation with the selective ultraviolet rays, and the molecular orientation can be more effectively generated.
The coating film forming apparatus of the present invention can arbitrarily store the support and can smoothly perform the coating film forming operation by arbitrarily including the configuration of [7].
The coating film formation apparatus of this invention can extend the reflection zone of a coating film more favorably by arbitrarily including the configuration of [8].

  The coating film forming apparatus of the present invention is a coating film forming apparatus for forming a coating film on the surface of a support, and a feeding device that continuously feeds the support, and a support that is fed from the feeding device A first coating head on which a coating film-forming composition is applied to form a coating film, and a wavelength range and / or output for the coating film provided on the support by the first coating head. A selective ultraviolet irradiating device for irradiating the selected first ultraviolet ray, a heating means for heating the coating film irradiated with the first ultraviolet ray by the selective ultraviolet irradiating device, and a coating film heated by the heating means. On the other hand, a curing ultraviolet irradiation device that irradiates the second ultraviolet ray to cure the coating film is provided.

  The curing device, the first coating head, and the curing ultraviolet irradiation device that irradiates the second ultraviolet rays are not particularly limited, and known devices can be used. The second ultraviolet ray irradiated from the curing ultraviolet ray irradiating device can be a normal ultraviolet ray that hardens the coating film more uniformly by a wider wavelength range and / or higher output than the first ultraviolet ray described later.

  In the coating film forming apparatus of the present invention, the cured ultraviolet irradiation device may be configured to irradiate ultraviolet rays from the surface side of the support on which the coating film is formed, or on the opposite side of the surface on which the coating film is formed. May be configured to irradiate ultraviolet rays from both sides, and may be configured to irradiate ultraviolet rays from both sides.

  In the coating film forming apparatus of the present invention, the composition for forming a coating film applied by the first coating head includes a solvent and a polymerizable single polymer dissolved in the solvent and exhibiting liquid crystallinity. A solution containing the monomer (hereinafter, the solvent of the composition for forming a coating film is referred to as “first solvent”) can be used. Specific examples of liquid crystal properties that can be exhibited by the monomer include a cholesteric liquid crystal phase. As such a monomer, various organic type polymerizable liquid crystal substances can be used. The solvent is not particularly limited, and a solvent containing an organic and / or inorganic substance can be used. In particular, a solvent that can volatilize without hindering the orientation of the monomer is preferably used. it can.

  The coating film forming composition can be prepared such that the monomer can be cured by irradiation with ultraviolet rays. Specifically, a monomer that can be cured by ultraviolet irradiation and / or a polymerization initiator that can cure the monomer by ultraviolet irradiation can be used. In the present specification, unless otherwise specified, for the sake of convenience, from the coating film after the coating film-forming composition is applied onto the support, to the coating film cured through the final curing process. Is simply referred to as “coating film”.

  Although it does not specifically limit as a support body which forms a coating film on it with the coating-film formation apparatus of this invention, The resin film normally used in order to form various optical laminated films can be used. In particular, those capable of imparting the property of orienting molecules such as monomers in the coating film-forming composition by rubbing means described later can be preferably used. Although the shape of a support body is not specifically limited, It can be set as the shape of the continuous strip | belt-shaped film. The support may be a single-layer resin film or a laminated film in which another layer is formed on the resin film before being used for coating film formation by the coating film forming apparatus of the present invention. Specific examples of the other layer include an alignment film for making the alignment by rubbing treatment more effective. The alignment film can be formed by, for example, applying an alignment film forming material on a support, drying, and curing.

  The selective ultraviolet irradiation apparatus used in the present invention is an apparatus capable of performing the irradiation of the first ultraviolet ray, that is, the ultraviolet ray having a selected wavelength range and / or output when the coating film is irradiated with ultraviolet rays. Specifically, the first ultraviolet ray may be an ultraviolet ray irradiated in a specific narrow wavelength range narrower than the second ultraviolet ray, or an ultraviolet ray irradiated with an appropriate weak output. Specifically, the wavelength range of the ultraviolet rays in a specific narrow wavelength range can be within 80 nm. More specifically, as an example of the width of the wavelength, the wavelength range can be a range of 320 nm to less than 400 nm, and as another example, the wavelength range can be a range of 280 nm to less than 320 nm. . By such first ultraviolet irradiation, a gradient can be generated in the degree of ultraviolet irradiation in the thickness direction of the coating film.

  In addition, the wavelength range of the first ultraviolet ray can be set according to the ultraviolet absorption property of the coating film forming composition. For example, it can be set to selectively irradiate ultraviolet rays having a wavelength width of 80 nm or less, centered on the wavelength at which the polymerization initiator contained in the coating film-forming composition exhibits maximum absorption. The output of the selective ultraviolet irradiation device can be made variable so as to obtain an optimum output for selective ultraviolet irradiation, whereby polymerization with a gradient of the degree of polymerization is performed in a portion close to and far from the surface of the coating film. be able to.

  Such a selective first ultraviolet irradiation device specifically includes, for example, a light source that emits ultraviolet light in a specific narrow wavelength range, or a specific light path from the light source to the irradiated object. It is possible to configure by providing a band-pass filter that transmits ultraviolet light having a wavelength of. Moreover, the irradiation amount of ultraviolet rays can be adjusted by making the voltage of the light source variable or providing a filter having pores in the optical path from the light source to the irradiated object. As the light source of the first ultraviolet irradiation device, a mercury lamp, a metal halide lamp, or the like can be used.

  In the coating film forming apparatus of the present invention, the selective ultraviolet irradiation device may be configured to irradiate ultraviolet rays from the surface side of the support on which the coating film is formed, and on the opposite side of the surface on which the coating film is formed. May be configured to irradiate ultraviolet rays from both sides, and may be configured to irradiate ultraviolet rays from both sides. By irradiating ultraviolet rays from either the surface side where the coating film is formed or from the opposite side of the support, a gradient in which the degree of polymerization decreases from a portion close to the surface of the coating film to a portion far from the surface, or A gradient in which the degree of polymerization increases from a portion close to the surface of the coating film to a portion far from the surface can be formed.

  The heating means used in the coating film forming apparatus of the present invention can be constituted by a heating zone device, a heating roll or the like, and is particularly preferably a heating zone device. The said heating zone apparatus can be used as the apparatus which encloses a part of conveyance path | route of a support body, and maintains the temperature in it in the fixed temperature suitable for hardening of the composition for film formation.

  The coating film forming apparatus of the present invention is preferably fed out of the feeding device before applying the coating film forming composition onto the support from the first coating head, in addition to the above-described configuration. A means for imparting the property of orienting molecules in the coating film-forming composition on the surface of the support is provided. The molecule in the composition for forming a coating film specifically refers to a monomer capable of exhibiting liquid crystal properties such as the cholesteric liquid crystal phase described above. As means for imparting such properties to the support, specifically, means for performing rubbing such as a rubbing roll can be used. Further, the rubbing means may be configured such that the alignment film is provided on the support by in-line coating and drying, and the alignment film is rubbed. Further, when an alignment film is already provided on the support, the alignment film may be rubbed.

  The coating film forming apparatus of the present invention is preferably applied to the support from the first coating head before irradiating the coating film with the first ultraviolet ray by the selective ultraviolet irradiation apparatus in addition to the above-described configuration. A drier for drying the first solvent in the coated film. The dryer can be a device that encloses a part of the conveyance path of the support and maintains the temperature therein at a constant temperature suitable for drying the solvent. By drying the solvent with the dryer, it is possible to achieve better alignment of molecules such as the monomer.

  The coating film forming apparatus of the present invention preferably has, in addition to the above configuration, the coating film irradiated with the first ultraviolet rays from the selective ultraviolet irradiation apparatus before heating the coating film with the heating unit. A second coating head for applying a second solvent that swells the coating film is further provided. A second solvent that swells the coating film with the second coating head (hereinafter sometimes referred to as “swelling liquid”) is applied to the coating film on which the degree of polymerization is formed by the selective ultraviolet irradiation device. By coating, the coating film absorbs the swelling liquid, and a film having an increased volume and weight is formed without changing its essence. Thereby, the gradient of molecules in the coating film (gradient in the pitch of liquid crystal substance molecules) can be further increased. The swelling liquid is not particularly limited as long as it is a liquid that can achieve swelling, and can be appropriately selected according to the composition of the composition for forming a coating film, but may be a liquid containing a basic compound. it can.

Hereinafter, the present invention will be described more specifically with reference to the drawings.
FIG. 1 is a schematic diagram showing an example of the configuration and operation of the coating film forming apparatus of the present invention. The apparatus shown in FIG. 1 is an apparatus for forming a coating film on a support 2, and includes a feeding device 1, a rubbing roll 3, a first coating head 4, a dryer 5, a selective ultraviolet irradiation device 6, and a heating zone 7. The curing ultraviolet irradiation device 8 and the winding device 9 as the support housing means are provided in this order. In the example of the apparatus shown in FIG. 1, the selective ultraviolet irradiation device 6 is configured to irradiate ultraviolet rays from the surface side of the coating film, and the cured ultraviolet irradiation device 8 irradiates ultraviolet rays from the back surface side of the coating film. It is configured as follows.

  Prior to the formation of the coating film by the coating film forming apparatus of the present invention, the support 2 is provided with a coating film by the apparatus of the present invention after an alignment film is previously provided on the resin film as the base material. The alignment film may be formed using another apparatus for that purpose, or the apparatus of the present invention may be used. That is, the support is fed from the feeding device 1 and the alignment film forming liquid is applied using the coating head 4 or another coating head, and the dryer 5 and the curing ultraviolet irradiation device 8 are used as necessary. A roll of the support on which the alignment film has been formed in advance is prepared by drying and curing and winding with the winding device 9, and this is further used for forming a coating film by the coating film forming apparatus of the present invention described below. be able to.

Subsequently, an operation of forming a coating film by the coating film forming apparatus of the present invention will be described.
The surface of the support 2 fed from the feeding device 1 and having an alignment film is rubbed with a rubbing roll 3. In the apparatus shown in FIG. 1, the rubbing treatment is preferably performed by rotating the rubbing roll 3 so as to rotate in a direction opposite to the traveling direction of the support 2 (that is, rotate in the direction of arrow A2 in FIG. 1). Let me go. However, the aspect of the rubbing treatment is not limited to this, and the rubbing treatment in an arbitrary direction with respect to the traveling direction of the support 2 may be performed as necessary.

  Subsequently, the coating film forming composition is discharged and applied from the coating head 4 onto the surface of the support 2 having the alignment film subjected to the rubbing treatment, thereby forming a coating film. The coating film-forming composition is preferably applied on the surface of the alignment film that has been subjected to the rubbing treatment, whereby the molecules in the coating film-forming composition can be aligned in a desired direction. In the example of the present embodiment, as the coating film forming composition, a solution containing a polymerizable monomer compound showing a cholesteric liquid crystal phase, a polymerization initiator, and a solvent is used.

  The coating film applied on the support 2 is dried by the dryer 5 and then subjected to the first ultraviolet irradiation by the selective ultraviolet irradiation device 6. Irradiation by the selective ultraviolet irradiation device 6 can be adjusted as appropriate according to the composition for coating film formation, properties desired for the product, and the like, but as described above, the wavelength width is preferably within 80 nm. Specifically, the wavelength is within a range of, for example, 320 nm or more and less than 400 nm, 280 nm or more and less than 320 nm, or a wavelength width of about 80 nm centered on the wavelength at which the polymerization initiator contained in the coating film forming composition exhibits maximum absorption. In such a narrow wavelength range, ultraviolet irradiation can be performed. Moreover, the output of the selective ultraviolet irradiation device 6 can be appropriately adjusted according to the coating film forming composition, the properties desired for the product, and the like. In the example of this embodiment, the selective ultraviolet irradiation device 6 irradiates ultraviolet rays from the surface side of the coating film, but can also irradiate from the back side or both sides. Thus, by irradiating a coating film with selective ultraviolet rays, the polymerization degree of the monomer compound in the coating film forming composition can be changed with respect to the depth direction of the coating film. Specifically, the polymerization of the monomer compound proceeds on the surface side of the coating film, but the polymerization of the monomer compound does not proceed so much on the back side of the coating film, so the polymerization is performed in the depth direction of the coating film. A gradient occurs in degrees.

  The characteristics such as the irradiation wavelength range and output of the selective ultraviolet irradiation device 6 can be adjusted so that the optical characteristics and the like of the manufactured product are optimized. Specifically, for example, a means (not shown) for measuring the transmittance spectrum of the laminate to be manufactured is provided between the cured ultraviolet irradiation device 8 and the winding device 9, thereby reflecting the reflection band of the product. Can be adjusted so that the output of the selective ultraviolet irradiation device 6 can be adjusted or the irradiation wavelength range can be changed. The irradiation wavelength range can be changed by replacing a filter provided in the optical path from the light source of the selective ultraviolet irradiation device 6 to the irradiated object.

  The support 2 having the coating film subjected to selective ultraviolet irradiation by the selective ultraviolet irradiation device 6 is subsequently passed through the heating zone 7 and heated. By being subjected to the heating, the partially and partially polymerized monomer compound in the coating film-forming composition is likely to change as it swells as the part having a lower degree of polymerization. A gradient will occur. The heating temperature in the heating zone 7 can be made variable. Further, the heating time can be adjusted by the length of the heating zone 7 along the conveying path of the support, the line speed, and the like, and a gradient of a desired orientation can be obtained by these adjustments.

  The support that has been heated by the heating zone 7 is subsequently irradiated with the second ultraviolet ray by the curing ultraviolet ray irradiation device 8. Irradiation of ultraviolet rays by the curing ultraviolet irradiation device 8 can be performed with a wavelength range and output sufficient to cure the entire coating film. In the example of the present embodiment, the curing ultraviolet irradiation device 8 irradiates ultraviolet rays from the back side of the coating film, but can also irradiate from the front side or both sides. The laminated film obtained by curing the coating film with the curing ultraviolet irradiation device 8 can be wound up by the winding device 9.

FIG. 4 is a schematic diagram showing another example of the configuration and operation of the coating film forming apparatus of the present invention.
The apparatus shown in FIG. 4 is different from the apparatus shown in FIG. 1 in that a second coating head 10 is provided between the selective ultraviolet irradiation device 6 and the heating zone 7. When the swelling liquid (second solvent) is applied to the coating film by the second coating head 10, the coating film absorbs the swelling liquid, and the pitch of the cholesteric liquid crystal substance molecules increases. In addition, the rate of increase is considered to be higher on the back surface side of the coating film having a low polymerization degree than on the coating film surface side having a high polymerization degree. By such an operation, it is possible to further increase the pitch of the liquid crystalline substance molecules, further expand the reflection band, or shift the reflection band to the long wavelength side.

  The coating film forming apparatus of the present invention includes not only those specifically described above but also those belonging to the scope of the claims of the present application and their equivalents. For example, in the apparatus specifically described above, an apparatus for providing only one layer of a liquid crystal compound coating film has been described. On the production line, for example, a configuration from a first coating head to a curing ultraviolet irradiation apparatus Can be provided as another apparatus, in which two or more coating films of liquid crystalline compounds are provided on one or both sides of the support. When providing the coating film of a liquid crystalline compound of two or more layers, structures, such as a non-contact-type inversion apparatus, can also be provided as needed. In addition to the usual die type, the coating head can have any configuration that can apply a liquid to the surface of the support, such as a wire bar or a brush. When providing a coating film of two or more layers of liquid crystalline compounds, a coating film of the same type of material can be provided, or a coating film of a different material can be provided. Although the apparatus becomes complicated by providing a plurality of coating films, at least one of them is formed in a process including ultraviolet irradiation by a selective ultraviolet irradiation apparatus, so that fewer layers than those of the prior art are formed. It is possible to obtain an optical film or the like having a more effective reflection band expansion in number.

  Moreover, the coating-film formation apparatus of this invention can contain arbitrary components as needed in addition to said each component. Specifically, for example, an apparatus for applying a corona discharge treatment to the support can be provided in front of the coating head 4 in order to improve the coating property of the coating film forming composition. Further, for example, a static eliminating device or a dust removing device for removing static electricity and dust generated by the rubbing treatment from the support can be provided between the rubbing means 3 and the coating head 4. Further, a laminating device for removing the protective film from the support can be provided between the feeding device 1 and the rubbing roll 3. Further, a laminating device for mounting a protective film on the surface side of the coating film can be provided between the curing ultraviolet device 8 and the winding device 9.

  Hereinafter, the present invention will be described in more detail with reference to Examples and Comparative Examples, but the present invention is not limited thereto.

Example 1
A coating film forming apparatus of the present invention shown in FIG. 1 having an E-type die as a coating head and a 100 μm-thick cycloolefin polymer film (Zeonor Film, Nippon Zeon Co., Ltd.) )), Poval (PVA) is used as a coating liquid for forming an alignment film, and a composition containing a cholesteric liquid crystal compound (hereinafter referred to as “variety A”) as a coating film forming composition containing a liquid crystal compound. Using the product, an alignment film was formed on the support according to the following first step, and further a cured coating film of a liquid crystalline compound was formed according to the following second step.

(First step: formation of alignment film)
While running the support from the feeding device 1 at a running speed of 10 m / min, the coating liquid for forming an alignment film was discharged from the first coating head 4 and applied. Then, it dried with the dryer 5, and wound up with the winding device 9, and obtained the roll of the support body which has an oriented film.

(2nd process: Formation of the cured coating film of a liquid crystalline compound)
The support having the alignment film obtained in the first step was used as the support 2 and mounted on the feeding device 1 again. The support 2 was sent out at a running speed of 10 m / min from the feeding device 1 so that the surface having the alignment film became the surface to be coated, and the rubbing process was performed on the alignment film on the support 2 by the rubbing device 3. Further, on the surface subjected to the rubbing treatment, the coating film-forming composition containing the kind A was laminated and applied from the first coating head 4, and dried and oriented by the dryer 5.

Furthermore, the coating of dried-oriented varieties A, from the surface side, the ultraviolet 0.2 mW / cm ² was irradiated for one second by the selection ultraviolet irradiation device 6. At this time, a 313 nm band pass filter was used. The light transmission region in the 313 nm band pass filter is 299 to 345 nm, and the bandwidth is 46 nm. Thereafter, the heating zone 7 was heated and dried at 100 ° C. for 1 minute.

Then, using the curing ultraviolet irradiation device 8, the coating film of the product type A is cured by irradiating ultraviolet rays at 150 mJ / cm ² from the back surface (the surface opposite to the surface on which the coating film is provided), The film was wound by the winder 9 to obtain a laminated film in which an orientation film and a cured film of type A were formed on the cycloolefin polymer film.

  The transmittance spectrum of the obtained laminated film was measured with a measuring instrument: MCPD-3000 manufactured by Otsuka Electronics Co., Ltd., and a microscope used: Eclipse E-600POL manufactured by Nikon Corporation. A measurement result is shown with a broken line in the graph of FIG.

(Comparative Example 1)
A laminated film was obtained in the same manner as in Example 1 except that ultraviolet irradiation from the selective ultraviolet irradiation device 6 was not performed, and the transmittance spectrum was measured. The measurement results are indicated by broken lines in the graph of FIG.

  As shown by the broken line in FIG. 3, the reflection bandwidth was 60 nm from 520 nm to 580 nm in the result of Comparative Example 1, whereas the reflection bandwidth was 500 nm in the result of Example 1 as shown by the broken line in FIG. It can be confirmed that the bandwidth is increased to 140 nm of ˜640 nm. From these, by providing the selective ultraviolet irradiation device 6, extension of the reflection band in the visible region of the coating film of the type A is realized, and a laminated film that can be usefully used as an optical film such as a brightness enhancement film is manufactured. I understand.

(Example 2)
The use of another cholesteric liquid crystal compound (hereinafter referred to as “product B”) in place of product A, UV irradiation from selective UV irradiation device 6 is 30 mw / cm ² UV-A (320 to 390 nm) UV In the same manner as in Example 1, except that the heating time in the heating zone was set to 2 minutes, and the ultraviolet irradiation by the curing ultraviolet irradiation device 8 was irradiated at 70 mJ / cm ² from the surface side of the support. The alignment film and the cured coating film of the liquid crystalline compound were formed on the support to obtain a laminated film, and the transmittance spectrum was measured. The measurement results are indicated by solid lines in the graph of FIG.

(Comparative Example 2)
A laminated film was obtained in the same manner as in Example 2 except that the ultraviolet irradiation from the selective ultraviolet irradiation device 6 was not performed, and the transmittance spectrum was measured. The measurement results are indicated by solid lines in the graph of FIG.

  As shown by the solid line in FIG. 3, the reflection bandwidth in the result of Comparative Example 2 was 75 nm from 500 nm to 575 nm, whereas in the result of Example 2 as shown by the solid line in FIG. 2, the reflection bandwidth was 420 nm. It can be confirmed that the bandwidth is increased to 200 nm of ˜620 nm. From these, by providing the selective ultraviolet irradiation device 6, the extension of the reflection band in the visible region of the coating film of type B is realized, and a laminated film that can be usefully used as an optical film such as a brightness enhancement film is manufactured. I understand.

(Example 3)
As a coating film forming apparatus, a device further provided with the second coating head 10 shown in FIG. 4 was used, and a swelling treatment for applying a swelling liquid (variety A liquid crystalline compound, bisphenol type epoxy acrylate, etc.) was performed. Were operated in the same manner as in Example 1 to obtain a laminated film. In the obtained laminated film, it was confirmed that the reflection band in the visible range of the coating film of type A was further expanded.

FIG. 1 is a schematic diagram showing an example of the configuration and operation of the coating film forming apparatus of the present invention. FIG. 2 is a graph showing the measurement results of the transmittance spectrum of the laminated film in Example 1 (type A) and Example 2 (type B) of the present application. FIG. 3 is a graph showing the measurement results of the transmittance spectrum of the laminated film in Comparative Example 1 (type A) and Comparative Example 2 (type B). FIG. 4 is a schematic diagram showing another example of the configuration and operation of the coating film forming apparatus of the present invention.

Explanation of symbols

1: Feeding device 2: Support 3: Rubbing roll (means for imparting the property of orienting molecules)
4: First coating head 5: Dryer 6: Selective UV irradiation device 7: Heating zone (heating means)
8: Curing ultraviolet irradiation device 9: Winding device (storage means)
10: Second coating head A2: Rubbing roll rotation direction

Claims (8)

A coating film forming apparatus for forming a coating film on the surface of a support,
A feeding device for continuously feeding out the support;
A first coating head for applying a coating film-forming composition on a support fed from the feeding device and providing a coating film;
A selective ultraviolet irradiation device for irradiating a first ultraviolet ray having a selected wavelength range and / or output to the coating film provided on the support by the first coating head;
Heating means for heating the coating film irradiated with the first ultraviolet rays by the selective ultraviolet irradiation device;
A curing ultraviolet irradiation device that cures the coating film by irradiating the coating film heated by the heating means with a second ultraviolet ray;
A coating film forming apparatus comprising: The coating film forming apparatus according to claim 1,
The coating film forming apparatus, wherein the first ultraviolet ray is an ultraviolet ray having a wavelength width of 80 nm or less. The coating film forming apparatus according to claim 1 or 2,
The coating film forming apparatus, wherein the first ultraviolet ray exhibits a maximum intensity in a wavelength range of 320 nm or more and less than 400 nm. The coating film forming apparatus according to claim 1 or 2,
The coating film forming apparatus, wherein the first ultraviolet ray exhibits a maximum intensity in a wavelength range of 280 nm or more and less than 320 nm. It is a coating-film formation apparatus of any one of Claims 1-4,
Before coating the coating film forming composition on the support from the first coating head, the molecules in the coating film forming composition are oriented on the surface of the support fed from the feeding device. A coating film forming apparatus, further comprising means for imparting a property to be caused. It is a coating-film formation apparatus of any one of Claims 1-5,
The coating film forming composition contains a first solvent,
A dryer for drying the first solvent in the coating film applied on the support from the first coating head before irradiating the coating film with the first ultraviolet ray by the selective ultraviolet irradiation device; A coating film forming apparatus comprising the coating film forming apparatus. It is a coating-film formation apparatus of any one of Claims 1-6,
A coating film forming apparatus, further comprising means for storing a support on which a coating film cured by the curing ultraviolet irradiation apparatus is formed. It is a coating-film formation apparatus of any one of Claims 1-7,
Before heating the coating film by the heating means, a second coating for applying a second solvent for swelling the coating film to the coating film irradiated with the first ultraviolet ray from the selective ultraviolet irradiation device. A coating film forming apparatus, further comprising a working head.

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