Technical Field

The present disclosure relates to a method for manufacturing a laminated film and more specifically relates to a method for manufacturing a graphics laminated film including a UV ink layer.

Summary

According to the method for manufacturing the laminated film of the present disclosure, it is possible to make a laminated film with excellent interlayer adhesion.

The method for manufacturing the laminated film of the present disclosure is related to a laminated film including a transparent film layer, a UV ink layer, and an adhesive layer. The laminated film may further include a carrier film and/or a release liner. Preferably, the laminated film is approximately 50 to approximately 150 μιη thick.

In one embodiment, the method for manufacturing the laminated film includes a first UV curing step and second UV curing step . The first UV curing step includes disposing the UV ink layer on the transparent film layer and partially curing the UV ink layer by performing a first UV irradiation with an irradiance less than 0.5 J/cm ² . Preferably, the disposing of the UV ink layer on the transparent film layer includes printing the UV ink on the transparent film layer by inkj et printing .

The second UV curing step includes disposing the adhesive layer on a surface of the UV ink layer opposite the transparent film layer and further curing the UV ink layer by performing a second UV irradiation with an irradiance of 0.5 J/cm2 to 1 .5 J/cm ² . Advantageously, the second UV irradiation is performed within 1 hour after performing the first UV irradiation.

Preferably, the adhesive layer is transparent with respect to light having a wavelength of 200-800 nm and the second UV irradiation is carried out through the adhesive layer.

Preferably, the adhesive layer is a removable pressure sensitive adhesive layer.

In another embodiment, the laminated film is shown by the cross sectional view in Fig. 1 , and includes the layers in the order of transparent layer 102, UV ink layer 104, and adhesive layer 106. In the embodiment of Fig . 1 , the laminated film also includes carrier film 108 disposed above transparent film layer 102 , and release liner 1 10 disposed below adhesive layer 106. The above summary of the present disclosure is not intended to describe each disclosed embodiment or every implementation of the present disclosure. The description that follows more particularly exemplifies illustrative embodiments. In several places throughout the application, guidance is provided through lists of examples, which examples can be used in various combinations . In each instance, the recited list serves only as a

representative group and should not be interpreted as an exclusive list.

Brief Description of the Drawings

The disclosure may be more completely understood in consideration of the following detailed description of various embodiments of the disclosure in connection with the accompanying drawings .

Fig. 1 is a cross sectional view of the laminated film with B SPC structure. Fig. 2 is a schematic view showing the laminated film manufacturing device used in the method for manufacturing the laminated film according to the embodiment of the present disclosure. Detailed Description

The detailed description below illustrates representative embodiments of the present invention with examples . However, the present invention is not limited to these embodiments.

Various products with a graphics laminated film fixed on a lighting unit of an internally illuminated signboard are commercially available and are used for advertising, signs, and trade name displays . These products, which are commonly called internally illuminated signboards, are used by turning on the light of the lighting unit so as to provide an internally illuminated signboard. The graphics laminated film may be removed by being detached from the lighting unit of the internally illuminated signboard after use . At the time of detaching the graphics laminated film, it is preferable that remnants of the film do not remain on the lighting unit of the internally illuminated signboard.

The present disclosure relates to a graphics laminated film with BSPC (Back Side Printable Clear) structure which includes a receptor layer to accept the printing ink such as UV ink forming a printed layer. Preferably, the receptor layer is a transparent film. In aspects where the receptor layer is a transparent film, the receptor layer may also be referred to as a transparent film layer. Disposed on the receptor layer is an adhesive layer. The receptor layer may have a laminated film top layer disposed on the printed layer in order to protect the printed layer. It has a simple structure as compared to a conventional graphics laminated film and a low production cost. In addition, the graphics laminated film with BSPC structure requires fewer organic substances and a lower combustion heat due to a simple laminated structure . Therefore, the environmental impact for disposal after usage is low without damaging the incombustibility of the structure on which the laminated structure is applied. The graphics laminated film with B SPC structure provides an improved product for signboard applications. According to the present disclosure, "(meth) acrylic" is an "acrylic or methacrylic. "

According to the present disclosure, the amount of UV radiation is the product of the irradiation time (seconds) and the irradiation strength (W/cm ² ) on the irradiation surface irradiated from the light source . For example, wavelengths of 320 nm - 390 nm are measured in a UV-A condition using the UV Power Puck II (EIT Co . , Ltd.) .

According to the present disclosure, the layer and material comprising the laminated film is "transparent," meaning the layers and material should have transmittance more than 70%, preferably more than 80% and more preferably more than 90% with respect to light having a wavelength of 200-800 nm. The transmittance is measured according to JISK 7105 plastic optical property test method 5.5 "Measurement method A of light transmittance and reflectance of the entire light. " For example, it is measured by using spectrophotometric colorimeter CM-3700d (Konica Minolta Co . , Ltd.) .

Japanese published unexamined application No . 2009-282471 , which is incorporated by reference in its entirety, describes " [t]he graphics structure containing a receptor layer, a printing layer created by printing on the receptor layer and an acrylic white adhesive layer wherein the acrylic white adhesive layer contains the carboxyl group containing (meth) acrylic polymer, white pigments of 8 to 150 mass portion with respect to the 1 00 mass portion of carboxyl group containing a (meth) acrylic polymer. "

The obj ect of the present disclosure provides a method for manufacturing a graphics laminated film with BSPC structure with excellent interlayer adhesion. The method for manufacturing a laminated film includes a first UV curing step and a second UV curing step . The laminated film includes, in order, a transparent film layer, a printed layer including UV ink, and an adhesive layer. The first UV curing step includes disposing the UV ink layer on the transparent film layer and partially curing the UV ink layer by performing a UV irradiation according to the present disclosure. The second UV curing step includes disposing the adhesive layer on the surface of the UV ink layer opposite to the transparent film layer and further curing the UV ink layer by performing the UV irradiation according to the present disclosure .

The transparent film layer of the graphics laminated film includes a resin composition commonly used as a receptor for various types of printings . The resin composition may be, for example, a thermoplastic resin selected according to the ink used and the method for printing the ink. The resin composition of the transparent film layer may contain acrylic resin, acrylic urethane, polyurethane, polyester, polyvinyl acetate, polyvinyl chloride, and polystyrene etc. The transparent film layer can be formed by applying the resin composition on a carrier film having a desired thickness and drying or curing it as per necessity.

The thickness of the transparent film layer has no specific limit but it may be more than approximately 1 μιη or 5 μιη and less than approximately 100 μιη or 50 μιη. The thickness of the transparent film layer can be selected according to the application of the laminated film and the method for printing the ink. The transparent film layer may optionally have a primer layer to increase the adhesiveness of the UV ink layer on the surface on which the UV ink layer is printed. To increase the printing performance of the UV ink layer, surface treatments such as plasma treatment, corona treatment, frame treatment, electron irradiation treatment, rough surface treatment, or ozone treatment may be performed on the surface of the transparent film layer.

The laminated film may optionally include a carrier film on the surface of the transparent film layer opposite the UV ink layer. The carrier film protects the transparent film layer surface by increasing the handling performance by supporting the transparent film layer during the

manufacturing of the laminated film. In such embodiments, the laminated film is manufactured by using the laminated body of the transparent film layer and the carrier film. The carrier film is removed at the time of using the laminated film. The carrier film may include, for example, a polyester such as polyethylene terephthalate (PET), a polylefin such as polyvinyl chloride (PVC), polyethylene (PE), or polypropylene (PP), an acrylic polymer, a urethane polymer, or a fluorinated polymer. The carrier film can be formed by applying a composition containing any of the above polymers on the transparent film layer and drying or curing it.

The thickness of the carrier film can be selected according to the

manufacturing conditions and usage conditions of the laminated film. For example, the thickness may be more than approximately 5 μιη or 10 μιη or less than approximately 500 μιη or 300 μιη. The carrier film may be transparent or opaque . If the carrier film is transparent, UV irradiation can be carried out on a UV ink layer through the carrier film and the transparent film layer. The carrier film may have a blocking inhibition treatment layer, for example, back surface treatment layer containing the micro globules and non-adhesive resin on the surface opposite to the transparent film layer. The printed layer of the graphics laminated film is formed by printing an ink on a receptor layer using various methods such as inkj et printing, screen-printing, or electrostatic printing. Preferably the ink is a UV ink. In aspects where the ink is a UV ink, the printed layer may also be referred to as a UV ink layer. UV ink has curability and can be cured by UV irradiation . The b asic material receives less calorific value at the time of curing . Due to this, it is specifically used to print to plastic film which is easily affected by heat . In addition, UV ink is generally solventless and since solvent is not discharged into the environment at the time of curing, it is suitable for printing films with low solvent resistance . In addition, it can also reduce the environmental impact . However, solventless UV ink is thick compared to a conventional solvent ink with a low leveling ability. Therefore , the printed layer tends to be thick. When p erforming fine printing using inkj et printing, insufficient leveling causes the printed layer to become uneven. Therefore , an adhesive layer gets accumulated on the printing layer and good adhesion cannot be achieved between the printing layer and adhesive layer in the graphics laminated film with B SPC structure . As described previously, this may give rise to the problem of film remnants remaining on the lighting unit o f an internally illuminated signboard at the time of removing the graphics laminated film from the lighting unit of the internally illuminated signboard.

The UV ink layer is formed by printing the UV ink on the transparent film layer using inkj et printing, screen printing, electrostatic printing , etc . , and curing by UV irradiation. The UV ink layer may be continuous or discontinuous . In the case o f a UV ink layer, printing can be performed in such a way that the characters , patterns , images and marks are displayed. The UV ink layer may be unicolor or multicolor.

The thickness of the UV ink layer has no specific limit but it may b e for example , more than approximately 1 μιη or 2 μιη and less than approximately 1 0 μιη or 5 μιη. The thickness of the UV ink layer changes according to the rheo logy properties (for example the viscosity) of ink, metho d and conditions for printing of ink. The thickness of the ink layer may be adjusted according to the application of the laminated film. The UV ink includes a polymerized monomer or oligomer, a light cured initiator, and a color material . As per necessity it may also contain a dispersing agent and/or a detergent. It can be classified into two types according to the polymerized monomer or the oligomer and the light cured initiator to be used: a radical polymerization type, and a cation

polymerization type . The radical polymerization type UV ink commonly includes an acrylate monomer or oligomer, and a light cured initiator such as benzophenone or phenylphosphine oxide . The cation polymerization type UV ink commonly includes an epoxy monomer and a light cured initiator such as an onium salt (for example, a diallyliodonium salt or a

triallylsulfonium salt) . The UV ink is solventless but useful for the aspects of low environmental impact and cost. To further increase the interlayer adhesion between UV ink layer and adhesive layer, a radical polymerization UV ink is preferred when an adhesive or a pressure sensitive polymer included in the adhesive layer is acrylic, and a cation polymerization type UV ink is preferred when an adhesive or pressure sensitive polymer included in the adhesive layer is urethane or ester.

The adhesive layer includes an adhesive or pressure sensitive polymer such as acrylic, urethane, polyester, or silicon. The adhesive or the pressure sensitive agent may further include a white pigment such as zinc carbonate, zinc oxide, zinc sulfide, or titanium oxide (titanium dioxide) to provide a covering to the laminated film and to reduce the difference in color density in UV ink layers. However, as described below, if an adhesive or a pressure sensitive agent is transparent, it may further increase the interlayer adhesion between the adhesive layer and the UV ink layer by performing a UV irradiation through the adhesive layer. The adhesive layer may be a removable pressure sensitive layer according to the application of the laminated film. Advantageously, in aspects where the adhesive layer is a removable pressure sensitive layer, the graphics laminated film can be easily removed from the adherend after usage.

In some embodiments, including the acrylic adhesive or pressure sensitive agent in the adhesive layer is advantageous. The acrylic adhesive or pressure sensitive agent may include an unreacted acrylic group . When a radical polymerization type UV ink is used, an unreacted acrylic group can form a chemical bond between the UV ink layer and the adhesive layer by reacting with a reactive group present in the UV ink and increasing the interlayer adhesion between the UV ink layer and the adhesive layer. When a cation polymerization type UV ink including an adhesive or pressure sensitive agent of urethane or polyester is used, hydroxyl groups or carboxyl groups in the adhesive or pressure sensitive agent may react with an epoxy group present in the UV ink increasing the interlayer adhesion between the UV ink layer and adhesive layer in the same manner.

As described in Japanese published unexamined application No .

2009-035602 , which is incorporated by reference in its entirety, in certain embodiments, an adhesive layer can be formed using an acrylic pressure sensitive agent by including carboxyl group containing (meth) acrylic adhesive polymer with a weight-average molecular weight less than 800,000 and a glass transition temperature - 1 00°C to -30° C , and an amino group containing (meth) acrylic non-adhesive polymer with an average molecular weight 30,000 to 100,000 and a glass transition temperature 20°C to 90°C , amino group containing (meth) acrylic adhesive polymer in the amount of more than 1 mass portion and less than 20 mass portion with respect to 100 mass portion of carboxyl group containing (meth) acrylic adhesive polymer and further including cross linking agents such as bisamido cross linking agent, aziridine cross linking agent, carbodiimide cross linking agent, epoxy cross linking agent and isocyanate cross linking agent to react with the carboxyl group and/or amino group as per necessity.

There is no specific limit for the thickness of the adhesive layer. For example, the thickness may be more than approximately 5 μιη or 10 μιη and less than approximately 100 μιη or 50 μπι. When UV irradiation is to be performed through the transparent adhesive layer, advantageously the adhesive layer is as thin as possible to obtain the necessary adhesive strength according to the application and it is advantageous from the aspect of further increasing the interlayer adhesion between the UV ink layer and the adhesive layer by successfully curing the UV ink. In such embodiments, the thickness of the adhesive layer may be less than approximately 50 μιη or 30 μιη. The average roughness (Ra) of the surface of the adhesive layer may be approximately more than 0. 1 μιη with regular or irregular bumpy shape so that repositioning is possible during pasting of the laminated film. A bumpy surface can be formed on the adhesive layer by holding a tool having a bumpy shape on the surface of the adhesive layer and copying the bumpy shape of the tool on the surface of the adhesive layer. A bumpy surface can also be formed on the adhesive layer by providing an irregularity to the surface of the release liner and laminating the release liner on the adhesive layer.

For example, when the images and patterns formed on the UV ink layer, which is partially cured by the UV irradiation, are accurate, an adhesive sheet containing the adhesive or pressure sensitive adhesive is laminated on the UV ink layer and the adhesive layer can be disposed on the UV ink layer without damaging these images and patterns. At the time of laminating the adhesive sheet on the UV ink layer, the adhesive sheet may conform sufficiently to the shape of the surface of the UV ink layer by applying pressure and warmth. The thickness of the adhesive sheet is practically equivalent to the thickness of the adhesive layer. For example it may be more than approximately 5 μιη or 10 μιη and less than approximately 100 μιη or 50 μιη.

The laminated film may optionally further include a release liner to protect the adhesive layer. The release liner is removed at the time of using the laminated film. The release liner may include items commonly used in the field of adhesive tape . For example, a film containing a polymer such as polyethylene, polypropylene, polyester, or acetylcellulose, or a laminated paper coated by these polymers may be used. The release liner may be released by, for example, silicon treatment of the surface contacting the adhesive layer. As described above, regarding the surface of the adhesive layer, a bumpy shape may similarly be given to the surface of the release liner. If the adhesive layer and the release liner are transparent, UV irradiation can be carried out on the UV ink layer through the release liner and the adhesive layer.

The laminated film may optionally further include other additional layers such as, for example, a support layer and/or a reflection layer.

The thickness of the laminated film containing a carrier film and a release liner may be more than approximately 10 μιη or 20 μιη and less than approximately 1 mm or 500 μιη. In one embodiment of the present disclosure, the laminated film comprises an adhesive layer, a UV ink layer and a transparent layer with a thickness more than approximately 50 μιη and less than approximately 150 μιη. A thin laminated film with such simple laminated structure uses fewer organic substances with less combustion heat. Therefore, the environmental impact for disposal after usage is low without damaging the incombustibility of the structure on which the laminated film is applied.

The method for manufacturing the laminated film of the present disclosure includes a first and a second UV curing step . The first UV curing step includes disposing a UV ink layer on a transparent film layer and partially curing the UV ink layer by performing a first UV irradiation with an irradiance less than 0.5 J/cm ² . The second UV curing step includes disposing an adhesive layer on the surface of the UV ink layer opposite the transparent film layer and further curing the UV ink layer by performing a second UV irradiation with the irradiance of 0.5 J/cm ² to 1 .5 J/cm ² and performing the second UV irradiation within 1 hour after the first UV irradiation in the first UV curing step .

Fig. 2 shows a schematic view of the laminated film manufacturing device 10 used in the method for manufacturing the laminated film by an embodiment of the present disclosure. An example of a method for manufacturing a laminated film of the present disclosure is described by referring to Fig. 2. Fig. 2 describes a method for manufacturing a continuous laminated film by using a roll to roll method. However, the method for manufacturing the laminated film of the present disclosure can be executed by using a batch method following a sheet fed treatment.

The laminated body 120 of transparent film layer 102 and carrier film 1 08 is supplied in the winded roll 12. In the first UV curing step, UV ink layer 104 is disposed on transparent film layer 102 by printing the UV ink using inkj et printing, screen printing, or electrostatic printing, and UV ink layer 104 is partially cured by performing a first UV irradiation with a UV irradiance of less than 0.5 J/cm ² . The lower limit value of the irradiance of the UV irradiance may vary according to the thickness of UV ink layer but commonly it is approximately 0. 1 J/cm ² . UV irradiance may vary according to the line speed and output of UV light source. For example it may be less than approximately 0. 1 J/cm ² to 0.5 J/cm ² and approximately 0. 1 5 J/cm ² to 0.48 J/cm ² or approximately 0.2 J/cm ² to 0.45 J/cm ² . In Fig. 2 , inkj et printing of UV ink and partial curing of UV ink layer 104 is performed by using the inkj et printing device 16 with the UV irradiation device provided internally. Though not restricted by any theory, the area physically contacted with the adhesive layer may be reduced further as the UV ink layer does not cure beyond the mark due to partial curing of the UV ink layer and/or chemical bonds can be formed by allowing a polymerization group, such as acrylate group, and epoxy group remaining in the UV ink layer to react with a reactive base included in the adhesive layer by performing the UV irradiation described in the second UV curing step . As a result, the interlayer adhesion between the adhesive layer and the UV ink layer can be increased.

The method for manufacturing the laminated film of the present disclosure is well suited for an embodiment which includes printing of UV ink on the transparent film layer by using the inkj et printing. The method for manufacturing the laminated film of the present disclosure is well suited for the roll-to-roll printing method.

Then, according to the second UV curing step, adhesive layer 106 is disposed on UV ink layer 104 on the surface of UV ink layer 104 opposite transparent film layer 102 and is further cured by a second UV irradiation. Again, UV irradiance may vary according to the line speed and output of the UV light source. For example it may be approximately 0.5 J/cm ² to 1 .5

J/cm ² , and approximately 0.5 J/cm ² to 1 .3 J/cm ² or approximately 0.5 J/cm ² to 1 .2 J/cm ² . The adhesive layer can be formed by applying an adhesive or a pressure sensitive agent on the UV ink layer by using a knife coater, a bar coater, or a cross linking agent as necessary after drying. The coating amount of the adhesive or pressure sensitive agent is approximately 0. 1 g/m ² to 30 g/m ² or approximately 2 g/m ² to 10 g/m ² . With the above range, sufficient adhesive strength can be assured and drying or curing defects can be avoided. In another embodiment, adhesive layer 106 is disposed on UV ink layer 104 by placing and laminating an adhesive sheet on UV ink layer 104. In this embodiment, though the images and patterns formed on the UV ink layer are accurate, the adhesive layer can be easily provided on the UV ink layer without damaging these images and patterns . In Fig. 2, adhesive sheet 130 with release liner 1 10 (not illustrated in the figure) is rolled up and supplied from roll 1 8 and adhesive sheet 130 is fixed and laminated on UV ink layer 104 so that it comes in contact with UV ink layer 1 04 by using the roll form laminator 20 provided with a heating mechanism as necessary. At the time of laminating the adhesive sheet 130 on UV ink layer 1 04, the adhesive sheet 130 may be conformed sufficiently to the shape of the surface of UV ink layer 104 by applying pressure and warmth.

After that, UV irradiation is performed on UV ink layer 1 04 by using UV irradiation device 22. The laminated sheet obtained in such a way is rolled up by using winding roll 14 and the roll shape product can be obtained.

As the UV light source of the UV irradiation device, low pressure mercury lamp, high pressure mercury lamp, very high pressure mercury lamp , halogen lamp, excimer lamp, laser light source (light source such as helium-cadmium laser or excimer laser), or UV-LED can be used.

When the laminated film is manufactured by using a roll to roll method, the line speed (supply speed of transparent film layer) is approximately 0.01 m/minute to 4 m/minute and approximately 0.05 m/minute to 2 m/minute or approximately 0.08 m/minute to 1 m/minute .

It is advantageous to perform the second UV irradiation curing step immediately after the first UV irradiation for example within 1 hour, preferably within 10 minutes and more preferably within 1 minute as it is possible to increase the interlayer adhesion between the UV ink layer and the adhesive layer. UV irradiation in the first UV curing step is commonly performed through the UV ink layer but it can b e p erformed through the transparent film layer. When a carrier film is used, it is possib le to p erform the UV irradiation through the transparent carrier film and the transparent film layer when the carrier film is transparent. It is preferable to perform the UV irradiation from both surfaces of the UV ink layer by using the transparent carrier film as per necessity to p artially cure the thick UV ink layer uniformly.

UV irradiation in the second UV curing step is advantageous to perform through the transparent adhesive layer by providing transparent adhesive layer on the UV ink layer as it further increases the interlayer adhesion between the adhesive layer and the UV ink layer. UV irradiation can also be performed through the transparent film layer or through the transparent carrier film and the transparent film layer. It is advantageous to perform UV irradiation from both surfaces of the UV ink layer through both of transparent film layer and transparent adhesive layer to cure thick UV ink layer comp letely and uniformly.

UV irradiation in the first and second UV curing step can be p erformed under inert atmosphere such as nitrogen and argon to reduce polymerization inhibition due to oxygen in the air when the UV ink is o f radical

polymerization type . In addition, when UV ink is o f cation polymerization type , it is better to adjust the temperature inside the manufacturing device or operation environment to avoid curing defects due to moisture in the air. To increase the printing performance of the UV ink layer, it is advantageous to perform surface treatments such as plasma treatment, corona treatment, frame treatment, electron irradiation treatment, or rough surface treatment on the surface of the transparent film layer in-situ before disposing the UV ink layer.

The laminated film obtained by the method for manufacturing the laminated film of the present disclosure can be used by adhering to indoor and outdoor vehicles, large buildings (walls, columns etc .), traffic signals, packaging material, or sign boards. In addition, the laminated film can be used as internally illuminated graphics or internally and externally illuminated graphics by fixing it on the internally illuminated sign board surface .

Example 1

The present disclosure is illustrated by example with the following basic embodiment of the present disclosure; however, the scope of this disclosure is not construed to be limited by the scope of this example .

The raw material or the product used for manufacturing the laminated film is as follows :

Transparent film layer and carrier film: acrylic film (transparent film layer) used in Scotchcal (registered trade name) film IJ5384/polyester film (carrier film) laminated body (Sumitomo 3M Limited) . UV ink: 3M (registered trade name) UV2800 ink (Sumitomo 3M Limited), ink density 300% (yellow 66%, magenta 66%>, cyan 66%> and black 1 00%) Adhesive layer: Acrylic transparent pressure sensitive adhesive sheet (obj ect wherein the adhesive composition described in embodiment 1 of the Japanese published unexamined patent application No . 2009-035602 is formed like a sheet on the polyethylene covering release paper) Release liner: Transparent polyester film with a thickness of 50 μιη and one side covered with silicon. The laminated film was manufactured by the following procedure :

UV 2800 ink was printed on a square with size 250 mm x 250 mm by using VUTEkQ S2000 (EFI Co . , Ltd.) as the UV inkj et printer on the surface of the acrylic film of the laminated body of acrylic film/polyester film and at the same time UV irradiation was performed. Then, acrylic transparent pressure sensitive adhesive sheet was laminated on the partially cured UV 2800 ink by using a hand roller. Polyethylene covering release paper was removed from the laminated body obtained and a transparent polyester film (release liner) was pasted on the surface of the acrylic transparent pressure sensitive adhesive so that the silicon covering surface comes in contact with the transparent pressure sensitive adhesive . After that, the excluding comp arison examp les 1 to 4 , UV was irradiated in UV 2800 ink through the transparent polyester film and an acrylic transparent pressure sensitive adhesive below it. The cross sectional view of the laminated film obtained is as shown in Fig . 1 .

The relation between setting of Q S2000 irradiance and the UV irradiance (wavelength 320 nm to 390 nm, UVA) is shown in Fig . 1 .

Table 1 UVA irradiance

Interlayer adhesion of the laminated film obtained was evaluated by T-peel test, the procedure o f which is shown b elow . The carrier film was removed from the laminated film and the white color PVC film (S/C 3650PR, Sumitomo 3 M Limited) was pasted on the transparent film layer as a support medium which provides stiffness to the laminated film. The laminated film was cut into a strip with a length 1 50 mm x width 25 mm. Then, release liner was removed, stripe was folded in such a way that two short sides of the strip gets overlapp ed and come face to face with the adhesive layer, adhesive layers were fixed by using hand ro ller, aging was performed for 30 minutes in an oven at 650° C and furthermore aging was performed for 1 0 minutes at a room temperature . Two overlapping short sides of the obtained material were hold tightly with right and left hand and an interlayer adhesion of transparent film layer/UV ink layer/adhesive layer was confirmed visually after quickly dragging the two short sides by 1 80° C . When released between the two tightly attached adhesive layers, the splitting of the laminated film was considered to be 0% . When the transparent film layer and the UV ink layer and/or the UV ink layer and the adhesive layer are separated, the area generated by these splitting was represented by percentage.

The evaluation result obtained by T-peel test after manufacturing the laminated film under such UV irradiation conditions is shown in Table 2.

Table 2 T-peel test result with UV irradiation conditions

Refer en ce N um erals

10 Laminated film manufacturing device

12 Winded roll

14 Winding roll

16 Inkj et printing device

1 8 Adhesive sheet winded roll

20 Laminator

22 UV irradiation device

100 Laminated film

102 Transparent film layer

104 UV ink layer

106 Adhesive layer

108 Carrier film

1 10 Release liner

120 Laminated body of transparent film layer/carrier film

130 Adhesive sheet