KR102035927B1 - A thin film for smart phone and a method thereof - Google Patents

Abstract

A method of manufacturing a thin film film for a smartphone, comprising: applying a UV resin to a UV mold having a desired pattern imprinted thereon, placing a release film, and pressing the release film with a roller to form a UV molding layer having a patterned surface; First preliminarily curing the patterned surface of the UV molding layer with a UV lamp at a light quantity of 250 to 350 mJ / cm 2, and removing the UV mold after completion of the preliminary curing, forming a printing layer on the preliminarily cured UV molding layer, After applying the UV layer to the printed layer again, the second step of temporarily curing the upper surface of the UV layer with a UV lamp of about 500 mJ / ㎠ light, by removing the release film to adhere the flat surface of the UV molding layer to the object And arranging a protective film on the UV layer on the opposite side and laminating using a roller, removing the protective film, and simultaneously curing the UV molding layer and the UV layer at a light amount of 700 to 1000 mJ / cm 2.Prevent the film includes the step of completely adhered to the object. In this way, the thin film thickness can be made thinner.

Description

A thin film for smart phone and a method of manufacturing the same

The present invention relates to a protective film which protects a touch screen made of glass or transparent material in various electronic products such as a smartphone, and is printed with a trademark, a manufacturer's name, or other wording on a portion other than the touch screen portion, particularly for a smartphone. A thin film and a method for producing the same.

In the case of conventional glass printing, a label, a manufacturer's name, or other text is printed on a glass on a shatter proof film. That is, UV pattern molding, vapor deposition, and printing on the anti-scattering film are used to realize the decoration, and then laminated with glass to achieve both the decoration effect and the anti-scattering effect.

However, since the scattering prevention film includes an OCA (Optically Clear Adhesive) and a PET film and includes a printing ink layer therein, the thickness of the film is increased.

In another way, the printing method is thermal transfer printing in order to reduce the thickness of the film. In thermal transfer printing, the ink itself is directly adhered to the film, so it is necessary to use a thermal ink ink sheet. The price of this dedicated ink paper is more than twice that of conventional ink. In addition, there is a tear when removing the release film, which is not suitable for high-quality products such as mobile phone windows.

As such a type, the invention of Patent Registration No. 10-0515291 (the date of registration September 8, 2005) is "multifunctional thermal transfer paper with UV curable coating layer and its manufacturing method" in the form of transparent or matte polyester or polypropylene. , A base film made of polyvinyl chloride or coated with a matting agent on the three kinds of films, a release agent layer mainly composed of an acrylic resin formed on the base film, a polyester acrylate resin formed on the release agent layer, and a urethane acrylate A primer layer mainly composed of an acryl resin and a vinyl resin formed on the coating layer of the UV-curable coating solution of the resin resin, the coating layer, or a nitrocellulose resin or polyvinyl butyral resin of SS-type or RS-type. ; A print layer formed on the primer layer; And it discloses a multifunctional thermal transfer paper formed with a UV curable coating layer consisting of an adhesive layer formed on the printing layer and a method of manufacturing the same. The thermal transfer paper of the present invention has excellent abrasion resistance, chemical resistance, solvent resistance, light resistance, and crush resistance, is easy to manufacture, and can be retransmitted, thereby reducing product cost and easily diversifying design presentation.

And as a manufacturing method patent registration No. 10-1485963 (registration date January 19, 2015) is applied to the film on which the image is printed UV adhesive and transfer the pattern using UV curing to expand the transferable material, work speed It relates to a transfer method using UV curing to improve the step, by forming an image printing layer on the UV transfer film formed primer layer by a pretreatment step to combine the image printing layer in the primer layer; Applying a UV adhesive on the UV transfer film having the image print layer formed thereon; Bonding the UV transfer film coated with the UV adhesive to the transfer target layer to be transferred; And a step of performing curing using a UV curing apparatus to transfer the image print layer to the transfer target layer, and separating the transfer target layer from which the UV transfer film and the image print layer are transferred. The effect of this patent is to apply a UV adhesive to the printed film and transfer the pattern using UV curing to enlarge the transferable material, simplify the process and improve the working speed. In addition, it is possible to minimize maintenance costs by using an inkjet printer and ink as an image transfer method using UV curing, to enable transfer to uneven surfaces, and to mass production. In this patent, a transfer film printed with a pre-made image is used, which is expensive.

In addition, in the name of the invention of Patent No. 10-1459078 (Registration Date October 31, 2014), "Thinking method for thin film labeling having UV pattern", the thickness of the double-sided tape is removed by removing the double-sided tape from the existing label. It provides a thin film attachment method of a label label having a UV pattern that can be saved, (A) has a UV pattern layer formed by the pattern transfer by coating the UV resin, the protective film layer and the release film on the UV pattern layer Forming a layer sequentially, and having a trademark label on which a metal deposition layer, a printing layer, and an adhesive layer are sequentially formed under the UV pattern layer; (B) seating and placing the object of the product to be attached a label label on the lower supporter of the hot press machine consisting of the upper press mold and the lower supporter; (C) placing the label label provided in step (A) on the upper surface of the object, placing the adhesive layer of the label label on the surface of the object so that the release film layer faces the upper press mold; (D) by moving the upper press mold of the hot press in the downward direction and hot pressing to automatically apply a label label to the surface of the object through heat fusion of the adhesive layer, but only the protective film layer by the heat of the upper press mold Heat-shrinkable to facilitate separation from the UV pattern layer; (E) hot-pressing the trademark label to separate the heat-shrinkable protective film layer by peeling off the release film layer in the state of automated attachment to the object side, thereby thinning the trademark label; It includes.

In this patent, the adhesive layer is attached to the object by thermocompression instead of double-sided tape, and a heat shrink protection film is provided between the release film and the UV pattern layer to facilitate removal of the release film. However, this patent forms a UV pattern layer and an adhesive layer separately, so that the thickness of the film bonded to the final object is thick and the manufacturing process is complicated.

In addition, the name of the invention of the registration number 10-1467444 (registration date November 25, 2014) is "manufacturing method of the camera glass including UV pattern" in the release film is provided with a print layer, UV pattern layer, Forming a layer structure by sequentially forming a deposition layer and an adhesive layer; Removing a portion of the layer structure corresponding to the center window of the glass by cutting to form an empty space at the bottom of the center window of the glass; A third step of bonding the outer adhesive layer of the layer structure to the camera glass to transfer the layer structure to the glass; Removing a release film from the layer structure to complete a camera glass structure in which a shape by the pattern layer is expressed; It includes. The layer structure may further include a UV coating layer provided between the release film and the printing layer and between the deposition layer and the adhesive layer. For the bonding of the layer structure, the thickness of the camera glass can be reduced as much as possible by using a transfer or double transfer method, and the quality of the pattern and the shape expression is sufficiently ensured, and the productivity of the camera glass is excellent.

However, in this patent, the UV pattern layer and the adhesive layer are formed separately, so that the thickness of the film bonded to the final object is thick.

Patent Registration No. 10-0515291 (Registration date September 8, 2005) Patent Registration No. 10-1485963 (Registration date January 19, 2015) Patent Registration No. 10-1459078 (Registration date October 31, 2014) Patent registration number 10-1467444 (Registration date November 25, 2014)

An object of the present invention is to provide a thin film film and a manufacturing method for a smartphone capable of simultaneously forming a pattern and adhesion with one UV molding layer and / or a UV layer. In other words, it is to provide a thin film for smartphones and a manufacturing method that does not use an adhesive layer.

Another object of the present invention is to provide a thin film for smartphones and a manufacturing method for reducing the thickness of the thin film adhered to the final object of about 40um or more.

Still another object of the present invention is to provide a thin film for a smartphone and a manufacturing method for providing a film having excellent high quality and reliability by setting specific curing conditions and present curing conditions of the UV molding layer and the UV layer.

Another object of the present invention is to further provide an adhesive component to the UV material in order to maintain the adhesion of the UV molding layer and the UV layer.

Another object of the present invention is to provide a thin film film and a manufacturing method for a smart phone that can be manufactured in large quantities in the form of a UV molding layer in rolls to enable cost reduction in mass production.

In order to achieve the above-described problem, in the method for manufacturing a thin film film for a smartphone of the present invention, after the UV resin is applied to the UV mold in which the desired pattern is imprinted on the top, the release film is placed and the release film is pressed with a roller to form the pattern surface. Forming a plurality of UV molding layers, first preliminarily curing the patterned surface of the UV molding layer with a UV lamp at a light quantity of 250 to 350 mJ / cm 2, and removing the UV mold after completion of preliminary curing, the preliminary UV curing Forming a printing layer on the molding layer, applying the UV layer to the printing layer again, and secondarily curing the upper surface of the UV layer with a UV lamp at a light amount of about 500 mJ / cm 2, and removing the release film. Sticking the flat surface of the UV molding layer to the object and arranging a protective film on the UV layer on the opposite side and laminating using a roller; removing the protective film and simultaneously applying the UV molding layer and the UV layer to 700 And curing the thin film to an object in an amount of 1000 mJ / cm 2, thereby completely bonding the thin film to the object.

As a modification of the step of forming the UV molding layer, applying a UV resin on the release film, and passing through the pattern roll to form a UV molding layer having a patterned surface.

In a preferred embodiment, the method further includes forming a deposition layer on the temporarily cured UV molding layer before forming the printed layer.

In a preferred embodiment, the cured coating type UV resin further includes a pressure-sensitive adhesive component.

In order to achieve the above object, the smartphone thin film of the present invention comprises a UV molding layer, a printing layer and a UV layer exposed to the outside as a thin film produced by the above-described manufacturing method to the object.

In a preferred embodiment, the total thickness of the malleable thin film is 40 μm or less.

In a preferred embodiment, further comprising a deposition layer between the UV molding layer and the printed layer.

1 illustrates one step of the present invention.
2 shows two steps of the invention.
3 illustrates three steps of the present invention.
4 shows four steps of the invention.
5 shows five steps of the present invention.
6 illustrates six steps of the present invention.
Figure 7 shows a perspective view of another embodiment of applying a UV molding layer using a pattern roll.

Matters relating to the operational effects, including the technical configuration for solving the above problems of the thin film for smartphones and the manufacturing method according to the present invention will be clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention. .

In addition, in describing the present invention, if it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. That is, essential components in the thin film film and manufacturing method for a smart phone of the present invention, components not related to the feature configuration of the present invention will be omitted. In the case of structural symmetry, only one side will be described. The other structure will apply equally.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention.

1 to 6 are cross-sectional views sequentially showing a method for manufacturing a thin film for a smartphone of the present invention.

First, referring to FIG. 1, after the UV resin is applied to a UV mold (not shown) in which a desired pattern is imprinted on the top, a release film 1 is disposed and the release film is pressed with a roller to form a UV molding layer having a pattern surface. (2) shows the step of forming. Preferably, since the UV resin is hardenable and the adhesive force is weakened when the curing is performed, a small amount of the adhesive component may be added for this purpose.

The adhesive component may include a rubber and a polyacrylic acid ester which is a pressure-sensitive adhesive component.

Referring to FIG. 2, a step of preliminarily curing the pattern surface of the UV molding layer 2 shown in FIG. 1 to 250 to 350 mJ / cm 2 light amount with a UV lamp and removing the UV mold after preliminary curing is illustrated. Temporarily hardening only the pattern surface of the UV molding layer 2 with a UV lamp The pattern surface is not distorted when the printing layer is formed thereon. On the opposite side of the patterned surface of the UV molding layer 2, it is still not cured and thus has adhesiveness, so that the release film 1 can be bonded later.

Quantity of light Less than 100mj 200mj, 250-350mj More than 400mj Temporary hardening Surface hardness 1H 2H 3H 3H Pattern collapses during printing Occur Occur none none Adhesive  Poor (uncured) Good Good Strong adhesion (reduced peeling) Light transmittance 88% 89% 89% 90%

As described in Table 1 above, when the amount of UV irradiation light is less than 100 mJ / cm 2, hardening does not occur in the pattern surface of the UV resin, so that a pattern layer is formed and the hardness is too low. At 200 mJ / cm <2> of ultraviolet irradiation light quantity, hardening is not enough and a pattern collapses at the time of printing, and surface hardness is weak. And hardening is not performed at the opposite side of a pattern surface, and the adhesive force of the release film 1 and the UV molding layer 20 is favorable. However, because the pattern surface is weak, the pattern collapses and the surface hardness is also weak.

When the amount of UV irradiation light is 250-350mJ / cm 2, curing is performed to some extent on the patterned surface so that the surface hardness is sufficient as 3H, the pattern is also maintained during printing, and the release film 1 and the UV molding on the opposite side of the patterned surface. Adhesion with layer 20 is also good.

However, when 400 mJ / cm <2> of ultraviolet-ray irradiation light amount hardens | cures too much, strong adhesion of the release peeler 1 and the UV molding layer 2 will be carried out. In this case, the release film 1 and the UV molding layer 2 should be separated in a later step, but the peeling force is weak, so that the release film 1 is difficult to separate from the UV molding layer 2.

In a preferred embodiment, as shown in FIG. 7, the UV resin is uniformly coated on the release film 1, and the coated portion passes through the pattern roll 11 to form a pattern to form the UV molding layer 2. Forming, curing with a UV lamp can be carried out through the guide roll 10 described above. In this case, mass production is possible compared to using a UV mold. Therefore, mass production has a great effect on cost reduction.

Referring to Fig. 3, the steps of forming the deposition layer 3 on the temporarily cured UV molding layer and the printing layer 4 thereon are shown.

The deposition layer 3 is placed between the print layer 4 and the UV molding layer 2, and the deposition can be carried out by conventionally known methods such as physical vapor deposition (PVD) and chemical vapor deposition (CVD). The vapor deposition layer 3 is for giving a metal texture to a film and giving a decoration effect. Various materials may be used for the deposition metal, for example, gold, silver, chromium, nickel, copper, and the like. The thickness of the deposited layer is very thin in nm (1/1000000000 10 ^ -9) (millionths) m.

The print layer 4 may be printed with letters or graphics, such as the type of smartphone, the manufacturer's logo, the display of the use key, advertising, etc. can be printed. As a method of forming a printed layer, a well-known method can be used, for example, gravure printing, flexographic printing, screen printing, etc. are mentioned. The thickness of a printed layer is 0.5-10 micrometers normally.

The UV molding layer 2, the deposition layer 3, and the printing layer 4 described above are laminated as tightly as one member.

Next, referring to FIG. 4, the UV layer adhering to the printing layer 4 is coated on the printing layer 4 for the purpose of protecting the printing layer, and the secondary temporary curing at a light amount of about 500 mJ / cm 2 is carried out with a UV lamp. Shows the steps to do this.

Main hardening Quantity of light 400 mJ 500mj 700mj Surface hardness 4H 6H 6H Light transmittance 90% 90% 90% Adhesive to the print layer Weak (uncured) Good Good (fully cured)

The above-described UV layer 5 is a layer which is directly exposed to the outside after adhering to the object 20, the surface hardness should be higher than 6H. And it should be strongly adhered to the printing layer 4. In addition, when the protective film 6 for the UV layer 6 is attached to the UV layer (5) to be adhered and pressed by a roller, the roller work can be smoothed only if the protective film (6) and the UV layer (5) are kept in an adhesive state. have. As described in Table 2 above, when the amount of UV irradiation light is less than 400 mJ / cm 2, curing of the UV resin does not occur, resulting in insufficient adhesiveness and low hardness. The desired hardness of 500 mJ / cm 2 is 6H, and the adhesion between the print layer 4 and the UV layer 5 is also good. And since the upper surface of the UV layer hardly hardens completely, the adhesive force is maintained to some extent. In the case of 700 mJ / cm 2, if the adhesion and hardness of the printing layer 4 and the UV layer 5 are good, the upper surface of the UV layer may be completely cured and lose adhesive force, which may make it difficult to carry out subsequent roller work. .

Next, referring to FIG. 5, the release film 1 is separated from the UV molding layer 2 and the UV molding layer 2 is seated on the object 20 and further protected on the hardened UV layer 5. The film 6 is covered and pressed using a roller. The UV molding layer 2 and the object 20 are firmly adhered to each other by a pressing force. At this time, since the protective film 6 is adhered to the UV layer 5, the protective film 6 is not pushed out by the roller during the roller work. In addition, when the UV molding layer 2 includes a pressure-sensitive adhesive component, the adhesion between the UV molding layer 2 and the object 20 can be enhanced. If this adhesion is weak, additional adhesive may be applied.

Finally, referring to FIG. 6, the whole film is pressure-bonded using a roller and the protective film 6 for UV layers is removed. In addition, UV curing is further performed by using a UV lamp from about the side to completely cure the UV molding layer and the UV layer. More specifically, the step of completely curing the UV molding layer (2) and the UV layer (5) at the same time 700 to 1000 mJ / cm 2 light amount to completely adhere the thin film to the object. In the case of below 700 mJ / cm 2, sufficient curing is not achieved. In the case of 1000 mJ / cm 2, the UV adhesive force is strong, and the object 20 in contact with the UV layer, the bonding print layer 4, and the UV molding layer 2 is not separated even after a long time. And the hardness of UV can be raised more. If it is 1000 mJ / cm 2 or more, no additional effect is generated.

The final thin film F of the present invention adhered to the object 20 comprises a UV molding layer 2, optionally a deposition layer 3, a printing layer 4 and a UV layer 5. These layers are firmly laminated into one and are not separated. The object 20 includes a transparent material such as glass and acrylic.

In a preferred embodiment, the light source used in the curing step is any one of mercury UV lamps, metal halide lamps, gallium UV lamps and LED UV lamps. In the present invention, the LED UV lamp is preferably used due to the advantages described below.

UV LED Curing Machine Advantages ( UVSMT  Excerpt from homepage)

Advantages The details Thermal deformation zero No heat radiation, no film thermal deformation Ultra high intensity UV radiation Ultra high intensity UV radiation of 4000mW / ㎠ improves quality and productivity Compound Wavelength UV LEDs Foreign UV LED curing machines such as Japan and the US have only a single wavelength such as 365nm or 385nm.
SMT's UV LED Curing Machine is the world's only UV-LED curing machine
Any resin will cure immediately. Significant improvement in bubble generation Since little heat is generated, most of the bubble problems are solved. Significant improvement in quality such as transmittance and diffusion The absence of heat greatly improves the optical quality of the product, which generates almost no heat, which solves most bubble problems. Yellowing prevention The yellowing problem is dramatically improved by the absence of yellowing short wavelength UV. Immediate ON / OFF 100% light immediately after ON, no waiting time Improved adhesion UV strength is 10-100 times stronger, which greatly improves adhesion Curing Machine Width 5mm-World's Smallest World's smallest width: 5 mm wide at the curing machine, no UV diffusion. No need to install duct for cooling the lamp Since there is no heat, there is no need to install a duct to extract the lamp cooling air, and there is no need for cooling clean air cleaned with hepafil used in the clean room. Save 95% on energy costs Energy costs: up to 95% savings Environmental Friendly-No Ozone, No Mercury, No co ₂ No ozone, no mercury, no co ₂ so environmentally friendly Infinitely variable power Very easy to fine-tune in 20% to 120% in 1% increments

The present invention also features a thin film produced by the method described above, wherein the thin film (F) of the present invention is exposed to the UV molding layer (2), the print layer (4) and the outside which are adhered to the object 20 UV layer 5 to be included.

In a preferred embodiment, the thickness of the thin film film (F) of the present invention is composed of a UV molding layer (2), 9-10 μm, a print layer (4), 15-20 μm and a UV layer (5), 9-10 μm. . That is, the total thickness of the thin film F is 24-40 micrometers. The overall thickness of the thin film (F) of the present invention is 40㎛ or less, it can be made thinner about 50% or less than the existing scattering film method (consisting of 75㎛ film, 20㎛ printed layer). And the printing layer 4 is protected by the UV layer 5 with high hardness, and is excellent in reliability. In addition, since the adhesive layer is not applied separately, the work process is simple.

In a preferred embodiment, further comprising a deposition layer between the UV molding layer and the printed layer.

While specific embodiments of the present invention have been described above by way of example, these are for illustrative purposes only and are not intended to limit the protection scope of the present invention. It will be apparent to those skilled in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention.

1: release film
2: UV molding layer
3: deposition layer
4: printing layer
5: UV layer
6: protective film
10: guide roll
11: Pattern roll
20: object
F: thin film

Claims (8)

As a thin film manufacturing method for smartphones,
Applying a UV resin to a UV mold having a desired pattern imprinted thereon, placing a release film and pressing the release film with a roller to form a UV molding layer having a patterned surface,
Firstly curing the patterned surface of the UV molding layer with a UV lamp at 250 to 350 mJ / cm 2 light quantity, and removing the UV mold after completion of the temporary curing.
Forming a printing layer on the temporarily cured UV molding layer,
Applying the UV layer to the printed layer again and then temporarily curing the upper surface of the UV layer with a UV lamp at a light quantity of 500 mJ / cm 2,
Removing the release film and adhering the flat surface of the UV molding layer to the object and laminating the protective film on the UV layer on the opposite side, and laminating using a roller;
Removing the protective film and subjecting the UV molding layer and the UV layer simultaneously to 700 to 1000 mJ / cm 2 light quantity to completely adhere the thin film to the object. The method of claim 1,
Forming the UV molding layer comprises applying a UV resin onto a release film and forming a UV molding layer having a patterned surface while passing through the pattern roll. The method of claim 1,
Prior to forming the printed layer, further comprising forming a deposition layer on the provisionally cured UV molding layer. The method of claim 1,
The cured coating type UV resin further comprises a pressure-sensitive adhesive component. A thin film made of any one of claims 1 to 4, comprising a UV molding layer adhered to an object, a printing layer and a UV layer exposed to the outside. The method of claim 5,
The thin film of which the total thickness of the malleable thin film is 40 micrometers or less. The method of claim 5,
The thin film further comprises a deposition layer between the UV molding layer and the printed layer. The method of claim 1,
The UV lamp is an LED lamp.

Images