WO2007066410A1

WO2007066410A1 - Insulating transfer film with excellent metallic luster, process for producing the same, and molded article made with the same

Info

Publication number: WO2007066410A1
Application number: PCT/JP2005/022657
Authority: WO
Inventors: Seiichi Umekage; Yukiyoshi Soma
Original assignee: Reiko Co., Ltd.
Priority date: 2005-12-09
Filing date: 2005-12-09
Publication date: 2007-06-14
Also published as: JPWO2007066410A1; JP3955084B2

Abstract

A transfer film produced by forming a release layer and a protective layer on a plastic film, pattern-wise applying a water-soluble coating layer to the protective layer, subsequently successively forming a thin insulating metal film and a thin metal oxide film, forming a water-resistant resin layer on the thin metal oxide film, thereafter washing the resultant multilayer structure with water to remove the water-soluble coating layer and the thin insulating metal film, thin metal oxide film, and water-resistant resin layer superposed on the water-soluble coating layer while leaving those parts of the thin insulating metal film, thin metal oxide film, and water-resistant resin layer under which the water-soluble coating layer is not present, and then forming an adhesive layer. This transfer film has exceedingly high quality and does not suffer scratches or the peeling of the thin insulating metal film. It is excellent in appearance and durability and enables the transfer of a design having an excellent metallic luster.

Description

Specification

Insulating transfer film with excellent metallic luster, its manufacturing method, and molded products using it

Technical field

[0001] The present invention relates to a transfer film capable of stably transferring a pattern having excellent metallic luster and insulating properties with good quality, a method for manufacturing the same, and a molded article using the same. Background technology

[0002] Patent Document 1 discloses that in order to obtain a metallized film having an insulating pattern with metallic luster, a water-soluble paint layer is partially provided on a base film, and a metallized layer and a transparent metallized layer are formed on the base film. A method has been proposed in which a clear inorganic vapor deposited layer (metallic acid thin film) is laminated, washed with water, and dried. The metallized film mentioned above is used not only as a packaging material but also as a transfer foil (transfer film). However, for example, in the case of an insulating transfer foil (insulating transfer film) in which the metal vapor deposited layer is an extremely thin and discontinuous insulating metal vapor deposited layer (insulating metal thin film), the metal vapor deposited layer is simply If only a transparent inorganic vapor-deposited layer is laminated, the insulating metal vapor-deposited layer will fall off when washed with water. Also, if this insulating transfer foil is used for in-mold molding, the gate area and Cracks occur on the curved surface, making it difficult to obtain a good appearance, and the cracked areas lose their metallic luster under high temperature and high humidity conditions, resulting in poor durability.

Patent Document 1: Patent No. 3643904

Disclosure of invention

Problems that the invention seeks to solve

[0003] The present invention eliminates the drawbacks of the prior art as described above, uses an insulating metal thin film such as a tin thin film, and produces a durable insulating transfer film with unprecedented metallic luster and excellent insulation properties. The object of the present invention is to provide a method for producing the above-mentioned insulating transfer film, and at the same time, to provide a molded article using the transfer film.

Means to solve problems

[0004] In the present invention, an insulating metal thin film has a high water vapor and oxygen barrier function.ヽMetal oxide thin The above problem was solved by laminating the membrane and the water-resistant resin layer.

[0005] That is, in the present invention, a release layer and a protective layer are provided on a plastic film, a water-soluble paint is applied thereon in a pattern, a water-soluble paint layer is provided, and then an insulating metal thin layer is formed. A film and a metal oxide thin film were sequentially provided, and a water-resistant resin layer was further provided on the metal oxide thin film, and then washed with water and laminated on the water-soluble paint layer and the water-soluble paint layer. The insulating metal thin film, metal oxide thin film, and water-resistant resin layer were removed, and the insulating metal thin film, metal oxide thin film, and water-resistant resin layer remained in the areas where the water-soluble paint layer did not exist. After that, an adhesive layer is provided to produce an insulating transfer film.

[0006] The insulating transfer film of the present invention obtained in this manner has a protective layer, an insulating metal thin film, a metal oxide thin film, a water-resistant resin layer, and an adhesive layer sequentially formed on the release layer of the plastic film. An insulating metal thin film, a metal oxide thin film, and a water-resistant resin layer are laminated in the same pattern. Here, the fact that the insulating metal thin film, metal oxide thin film, and water-resistant resin layer are laminated in the same pattern means that the insulating metal thin film, metal oxide thin film, and water-resistant resin layer are the same. This refers to a metal oxide thin film laminated directly above the insulating metal thin film, and a water-resistant resin layer laminated directly above the metal oxide thin film. In addition, the protective layer, insulating metal thin film, metal oxide thin film, and water-resistant resin layer are not simply laminated. The body is stacked and stacked.

In this way, since the protective layer, the insulating metal thin film, the metal oxide thin film, and the water-resistant resin layer are laminated together, the insulating metal thin film can be easily removed during both the manufacturing process and after manufacturing. In addition, when an insulating transfer film is used for in-mold molding, it not only prevents cracks from forming on the gate and curved surfaces of the molded product, resulting in a good appearance, but also under high temperature and high humidity conditions. It is possible to obtain a high-quality insulating transfer film that has good durability and does not lose its metallic luster.

[0007] In addition, in the production method of the present invention, in order to accurately remove the water-soluble paint layer and obtain a high-quality insulating transfer film, it is necessary to remove the water-soluble paint layer while the water-soluble paint layer is present on the protective layer. Protective layers in areas where there is no water-soluble paint layer, insulating metal thin films, metal oxide thin films, and In order to do so, a) the insulating metal thin film has an island-like structure, and the thickness of the metal acid thin film is 3 to 100 nm. b) It is preferable to coat the water-resistant resin layer with a low viscosity so that the resin paint used for the water-resistant resin layer can penetrate into the protective layer. The coating method for the water-resistant resin layer is preferably a reverse coating method.

[0008] Furthermore, the thickness of the water-resistant resin layer is adjusted so that the water-soluble paint layer does not become difficult to remove (a state in which the surface irregularities of the porous water-soluble paint layer are flattened). It is preferably 1Z3 or less, particularly 2 to 20% of the thickness of the paint layer. Normally, the thickness of this water-resistant resin layer is about 0.01 μm to 0.4 μm, and it is particularly preferable to set it to 0.2 μm or less.

[0009] As the resin for forming the water-resistant resin layer, water-resistant resins that are usually used for coatings, such as ester resin, acrylic resin, salt-based resin, etc. However, when used in in-mold molding, cross-linked resins such as urethane resins, acrylic and urethane resins that are crosslinked through isocyanate bonds, etc. can be used. It is preferable to use fat.

[0010] The insulating metal thin film in the present invention refers to a metal thin film that has both metallic luster and insulating properties, and can be provided by a vapor deposition method according to conventional techniques. Usually the size of the island is ιοΑ~

The best way to provide an insulating metal thin film is to form a thin film with an island-like structure of 2 μm (lnm to 2 μm) and an island spacing of 20 A to 5000 A (2 nm to 500 nm). As the metal, a metal selected from tin, indium, lead, zinc, bismuth, titanium, chromium, iron, copper, nickel, silicon, germanium, or an alloy thereof can be used. In particular, tin or indium is preferred.

[ooii] In order to make the insulating metal thin film into the above-mentioned island-like structure, a plastic film Z mold release layer Z protective layer Z patterned water-soluble paint layer, a water-soluble paint layer of the laminate consisting of the insulating metal thin film It is preferable that the total light transmittance of the area where no light exists is 10 to 50%. Insulation here means that the dielectric breakdown voltage is 1000V or more.

[0012] The insulating transfer film of the present invention may have an undercoat layer between the plastic film and the release layer. [0013]Furthermore, in the insulating transfer film of the present invention, a colored printing layer is provided on the release layer of the plastic film, and then the protective layer is provided, thereby forming a colored printing pattern. It becomes possible to manufacture an insulating transfer film that can stably transfer designs with excellent metallic luster on the surface.

[0014] Next, the metal acid thin film laminated on the insulating metal thin film maintains the metallic luster and insulation properties of the insulating metal thin film, improves corrosion resistance, and prevents scratches on the insulating metal thin film. This is to prevent the occurrence of such problems, and it is useful to use, for example, a thin film of aluminum or silicon. The thickness of the metal oxide thin film is usually about 100 nm or less.The thickness of the silicon oxide film is preferably about 8 to 60 nm, and the thickness of the aluminum oxide film is preferably 3 to 30 nm. A sufficient effect can be obtained with a certain thickness. However, the water-resistant resin layer formed on the metal oxide thin film is laminated and integrated with the protective layer, the insulating metal thin film, and the metal oxide thin film, making it possible to manufacture a stable and high-quality insulating transfer film. For this purpose, the thickness is preferably about 3 to 10 nm. Note that if the thickness is less than 3 nm, the corrosion resistance will deteriorate, and if it exceeds lOOnm, the metal oxide thin film will be more likely to crack, especially during transfer, resulting in a decrease in corrosion resistance.

[0015] In order to form an insulating metal thin film in a pattern, in the method of the present invention, a water-soluble paint is applied on the protective layer in a pattern (negative shape of the pattern) to form a water-soluble paint layer, and then After forming an insulating metal thin film and a metal oxide thin film on the entire surface, a water-resistant resin layer is further applied, and the water-soluble paint layer is dissolved and removed by washing with water. The insulating metal thin film, metal oxide thin film, and water-resistant resin layer are removed in a pattern as the water-soluble paint layer dissolves, but in areas where the water-soluble paint layer does not exist, the water-resistant resin layer is removed. The resin in the layer penetrates to the surface of the protective layer, and the protective layer, insulating metal thin film, metal oxide thin film, and water-resistant resin layer are laminated together, so in areas where there is no water-soluble paint layer, there is no protection. layer, an insulating metal thin film, a metal oxide thin film, and a water-resistant resin layer are laminated and integrated, and the insulating metal thin film, metal oxide thin film, and water-resistant resin layer are precisely formed into the desired pattern. It remains and forms a pattern with a metallic luster.

[0016] As the plastic film in the insulating transfer film of the present invention, any of those used for ordinary transfer films can be used, and it also includes a release layer, a protective layer, an adhesive layer, and As the undercoat layer, any material similar to conventional transfer films can be applied.

[0017] As the plastic film, it is generally preferable to use a synthetic resin film, such as polyethylene terephthalate film, polypropylene film, polycarbonate film, polyethylene film, polystyrene film, polyamide film, polybutyl arylate film, etc. be able to.

[0018] Furthermore, as the release layer, it is preferable to use one or more types of resins and copolymers such as ether, ester, epoxy, acrylic, silicone, and wax resins. Furthermore, for applications requiring hard coat properties, it is preferable to form the release layer with a resin having so-called hard coat properties, such as an ultraviolet curable acrylic resin.

[0019] As the protective layer, it is preferable to use one or more types of resins and copolymers such as ether, ester, epoxy, acrylic, and urethane.As the adhesive layer, ether It is preferable to use one or more types of resins and copolymers such as resins, esters, acrylics, vinyl chloride, and vinyl acetate.

[0020] The water-soluble paint used in the water-soluble paint layer may be a paint made from a water-soluble substance such as polyvinyl alcohol, polyvinyl pyrrolidone, methyl cellulose, carboxymethyl cellulose, gelatin, or starch. Also, add some extender pigment to the water-soluble paint layer.

[0021] It is also possible to obtain an insulating molded article with a metallic luster on the surface by in-mold molding using the insulating transfer film of the present invention. In this case, an undercoat layer is added between the plastic film and the release layer in order to improve the releasability between the plastic film and the release layer and to prevent the plastic film from peeling off or tearing during transfer. By forming the undercoat layer, it is possible to stably obtain a molded article with a metallic luster and a complex shape. As the resin used for the undercoat layer, thermosetting resins such as melamine resin, aminoalkyd resin, epoxy resin, acrylic resin, silicone resin, etc. can be used. In particular, melamine-based resin and acrylic resin are preferred.

[0022] The insulating transfer film of the present invention is transferred onto a plastic substrate, and an adhesive layer, a water-resistant resin layer, a metal oxide thin film, an insulating metal thin film, a protective layer, and A mold release layer is provided in sequence, including a water-resistant resin layer, a metal oxide thin film, and an insulating gold layer. It is possible to obtain a molded article in which thin films of the same type are laminated in the same pattern.

The thus obtained molded article of the present invention has a water-resistant resin layer, a metal oxide thin film, an insulating metal thin film, and a protective layer integrated into one layer, so the insulating transfer film of the present invention can be used. When a molded product is manufactured using in-mold molding, the gate and curved surfaces of the molded product are less prone to cracking and have a good appearance, and the metallic luster does not disappear under high temperature and high humidity conditions. The result is a durable, high-quality molded product.

In addition, the mobile phone casing, which is a molded product obtained using the insulating transfer film of the present invention, not only has the same high quality as the molded product above, but also has the same high quality as the above-mentioned molded product. 5GHz band, 1.9GHz band, 2GHz band, etc.), so even if the insulating transfer film of the present invention is used in a mobile phone case that has a built-in antenna, It is possible to give metallic luster to the parts, and there is no need to adopt methods such as making the part where the antenna is built-in transparent in order to ensure radio wave transparency. .

Effect of the invention

The insulating transfer film of the present invention and the molded article of the present invention obtained using the insulating transfer film have the following effects.

As mentioned above, the insulating transfer film of the present invention has a protective layer, an insulating metal thin film, a metal oxide thin film, and a water-resistant resin layer integrated into one layer.

1) Since the insulating metal thin film has an island-like structure, it is easy to get scratches on the surface of the insulating metal thin film, but in the washing process during the manufacturing of the insulating transfer film, the insulating metal thin film does not fall off or scratches due to rubbing can be prevented. Therefore, it is possible to provide an insulating transfer film that can accurately transfer a desired pattern with metallic luster.

2) Since the adhesion between the protective layer and the insulating metal thin film is improved, the range of selection of the type of resin used for the protective layer is expanded, and restrictions on manufacturing conditions (type of coating machine, drying temperature, etc.) are reduced. has decreased.

3) Since the insulating metal thin film is less likely to corrode, there is no need to immediately perform the washing and bonding process after applying the water-resistant resin layer.It can be stored for a long period of time until the washing or bonding process, which can meet delivery deadlines. has become easier. 4) When manufacturing molded products by in-mold molding, in addition to the protective layer, insulating metal thin film, metal oxide thin film, and water-resistant resin layer being laminated together, the water-resistant resin layer is Tension and gate force generated in the insulating transfer film during in-mold molding.Since it has the effect of buffering the stress caused by the heat and pressure of the flowing resin, cracks may occur in the insulating metal thin film at the curved surface of the molded product and at the gate. Hard to occur. In particular, if the water-resistant resin layer is made of urethane-based resin or acrylic resin, which is cross-linked through isocyanate bonds, the heat resistance will be further improved, and the position of curved surfaces and gate areas will be improved. Cracks can occur in the gate, not only when it is at the edge, but also when the gate is located in the center, where higher heat resistance is required1, and the shape of the molded product and the type of plastic base material The range of choices expands.

5) When resin flows into the gate part during in-mold molding, the adhesive layer near the gate part does not dissolve or peel off, which improves the adhesion between the adhesive layer of the molded product of the present invention and the plastic base material. is good.

6) The molded product of the present invention can withstand total light transmission even in the high temperature and high humidity tests required for mobile phones and audio products, such as 65°C x 95% x 24 hours and 60°C x 80% x 96 hours. Since the corrosion rate does not exceed 60% and the insulating metal thin film does not disappear due to corrosion, it can be used in a very wide range of applications.

7) Furthermore, by providing the water-resistant resin layer, the adhesive layer will come into direct contact with the water-resistant resin layer, which is made of resin. This will expand the number of types of plastic substrates that can be transferred. As a result, the applications of insulating transfer film will expand and productivity will improve. BEST MODE FOR CARRYING OUT THE INVENTION

<Example 1> Production of insulating transfer film

A 0.5 m thick undercoat layer made of acrylic melamine resin on a 38 μm thick polyethylene terephthalate film.Z A 1 μm thick release layer made of acrylic resin. Protective layer with a thickness of 1 μm made of urethane resin Z Water-soluble paint layer with a thickness of 1 μm made of polyvinyl alcohol and extender pigment (negative pattern of desired pattern) Z Island-like structure with insulation properties A thin tin film with a thickness of 20 nm (polyethylene terephthalate in the area where there is no water-soluble paint layer) Rate film ZUndercoat layer ZRelease layer ZProtective layer ZTotal light transmittance of tin thin film: 25%)ZLaminated film by sequentially applying 5nm-thick oxidized aluminum-yum thin films with transparency I got (A).

Next, a paint consisting of vinyl chloride and vinyl acetate copolymer was coated on the thin aluminum film of the laminated film (A) using a reverse coating method to make it waterproof to a thickness of 0.1 μm. A layer of fat was provided. Afterwards, it is washed with water to remove the water-soluble paint layer and the tin thin film on the water-soluble paint layer Z. A sheet film was obtained in which a water-resistant resin layer remained. The thin tin film was completely prevented from falling off from the sheet film obtained. A 1 m thick adhesive layer made of acrylic resin was provided on the water-resistant resin layer side of the obtained sheet film, and the following layers were prepared: polyethylene terephthalate film Z undercoat layer Z release layer Z protective layer Z tin thin film Z acidic layer Aluminum thin film Water-resistant resin layer made of acetic acid copolymer

Z adhesive layer, tin thin film Z aluminum oxide thin film Z water resistant resin layer laminated in the same pattern with metallic luster, and protective layer Z tin thin film Z oxidized aluminum thin film Z water resistant An insulating transfer film of the present invention in which the resin layer was laminated and integrated was obtained.

<Example 2> Production of insulating transfer film

A paint made of acrylic and urethane resin was applied by reverse coating onto the thin aluminum film of the laminated film (A) obtained in Example 1 to give a water resistance of 0.1 μm in thickness. A resin layer was provided. After that, washing with water removes the water-soluble paint layer and the tin thin film Z aluminum oxide thin film Z water-resistant resin layer on the water-soluble paint layer, and also removes the tin thin film Z acid where the water-soluble paint layer does not exist. A sheet film was obtained in which a water-resistant resin layer remained. The thin tin film was completely prevented from falling off the sheet film obtained. A 1 m thick adhesive layer made of acrylic resin was provided on the water-resistant resin layer side of the obtained sheet film, and the adhesive layer was made of polyethylene terephthalate film, z undercoat layer, z release layer, z protective layer, z tin thin film, and z acidic layer. Tin aluminum minium thin film acrylic Water-resistant resin layer made of urethane resin Z adhesive layer, tin thin film Aluminum oxide thin film Z water-resistant resin layer laminated in the same pattern with metallic luster. An insulating transfer film of the present invention was obtained, in which the protective layers Z tin thin film Z aluminum oxide thin film Z water resistant resin layers were laminated and integrated. [0026] <Comparative Example 1> Production of insulating transfer film

The laminated film (A) obtained in Example 1 was washed with water to remove the water-soluble paint layer and the tin thin film on the water-soluble paint layer, and to remove the water-soluble paint layer. A sheet film was obtained in which the tin thin film remained in the areas where the tin thin film was not present. The resulting sheet film is coated with tin along with the aluminum oxide thin film in the areas where the water-soluble paint layer does not exist, that is, where the tin thin film should originally remain. There were some unsuitable areas where some of the thin film had fallen off. A 1 m thick adhesive layer made of acrylic resin was provided on the acid-aluminum-yum thin film side of the obtained sheet film, and then polyethylene terephthalate film z Undercoat layer Z Mold release layer Z Protective layer Z Tin thin film Z Aluminum oxide thin film z Insulation consisting of an adhesive layer, tin thin film z oxidized aluminum thin film laminated in the same pattern with metallic luster, but with unsuitable parts where the pattern has partially fallen off. A transfer film was obtained. The unsuitable parts were later cut off, resulting in a low yield of 10%.

[0027]Table 1 shows the results of comparing the suitability for washing with water between the insulating transfer film of the present invention in Example 2 and the insulating transfer film in Comparative Example 1.

[0028] [Table 1]

*1) Suitability for washing with water was visually evaluated.

Surface scratches

〇: No scratches during washing process

X: There are scratches during water-based processing.

falling off of tin

〇: No falling off during washing process

X: Falling off during washing process

[0029] As shown in Table 1, in the insulating transfer film of Comparative Example 1, oxidized aluminum was added on the tin thin film. By providing a minium thin film, we were able to prevent surface scratches during the washing process, but we were unable to prevent the tin film from falling off from the protective layer.

This is because if the metal used for the insulating metal thin film is a relatively soft metal such as tin that has weak adhesion to resin, it is necessary to strengthen the adhesion between the tin thin film and the protective layer. However, if the pattern is particularly detailed due to the water-soluble paint layer, it is necessary to increase the water pressure of the water pressure washing used in the washing process, which requires higher adhesion.

However, the insulating transfer film of Comparative Example 1 has weak adhesion between the protective layer and the tin thin film.

However, it was impossible to prevent the thin tin film from falling off from the protective layer.

Both of the insulating transfer films of the present invention in Examples 1 and 2 were of very good quality, with no scratches or falling off of the tin film. This is because the resin in the water-resistant resin layer penetrates into the protective layer, and the protective layer Z Tin Thin Film Z Aluminium-Yum Thin Film Z Water Resistant Resin Layer is laminated and integrated, resulting in the separation of the protective layer and the tin thin film. This is because the adhesion has become stronger.

<Example 3> Manufacturing of molded products

Using the insulating transfer film of the present invention in Example 1, in-mold molding was performed using transparent acrylic resin to produce a mobile phone casing.

In addition, for in-mold molding, the position of the gate for pouring the resin is determined by (1) the case where it is provided in the center of the casing (more heat resistance of the transfer film is required) and (2) the case where it is placed at the edge of the casing. Two methods were used to manufacture mobile phone casings, one for each case.

As a result, a transparent acrylic substrate, an adhesive layer, a water-resistant resin layer made of salt and acetic acid copolymer, a thin film of aluminum, a thin film of tin, a protective layer, and a release layer were sequentially formed. Laminated in the same design, the water-resistant resin layer Zoxi-aluminum thin film Z tin thin film has a metallic luster Water-resistant resin layer Zoxi-aluminum thin film Z tin thin film A mobile phone casing of the present invention in which the film Z protective layer was laminated and integrated was obtained.

The total light transmittance of the design part with metallic luster was 15%, and the dielectric breakdown voltage was 12,000V, indicating good insulation. In addition, if the gate position in (1) is in the center, no cracks will occur on the curved surface of the casing, but some cracks will occur in the gate area, and the cracked area will be heated at 65°C x 95% x 24 hours. Metallic luster slightly lost during high temperature and high humidity test at 60°CX 80% for 96 hours. (The total light transmittance of this part was 30%). When the gate position in (2) is at the edge, no cracks were observed on either the curved surface of the casing or the gate, and the product was exposed to high temperature and humidity at 65°CX 95% x 24 hours and 60°CX 80% x 96 hours. Even in tests, it was found to be practical as it maintains a beautiful metallic luster pattern without any change in appearance.

[0031] <Example 4> Production of molded product

Using the insulating transfer film of the present invention in Example 2, two types of mobile phone casings were manufactured in the same manner as in Example 3.

As a result, a transparent acrylic substrate, an adhesion layer, an acrylic layer, a water-resistant resin layer made of urethane-based resin, an aluminum thin film, a tin thin film, a protective layer, and a release layer are successively provided. Water-resistant resin layer Z aluminum oxide thin film Z tin thin film is laminated in the same pattern shape with metallic luster, and water resistant resin layer Z aluminum oxide thin film Z tin thin film Z protective layer is laminated in an integrated manner A mobile phone casing of the present invention was obtained.

The total light transmittance of the design part with metallic luster was 15%, and the dielectric breakdown voltage was 12,000V, indicating good insulation. In addition, in both cases (1) where the gate part is located at the center and (2) where the gate part is located at the edge, no cracks are observed on the curved surface of the casing or the gate part.

It has become a practical product that maintains a beautiful metallic luster pattern without any change in appearance due to high temperature and high humidity tests at 65°C x 95% x 24 hours and 60°C x 80% x 96 hours.

[0032] <Comparative Example 2> Manufacturing of molded product

Two types of mobile phone casings were manufactured using the insulating transfer film of Comparative Example 1 in the same manner as in Example 3.

As a result, a transparent acrylic base, Z adhesion layer, Z acidic aluminum-yum thin film, Z tin thin film, Z protective layer, and Z mold release layer are successively provided, and the oxidized aluminum-yum thin film Z tin thin film has a metallic luster. A mobile phone case was obtained in which the layers were stacked in the same pattern.

The total light transmittance of the design part with metallic luster was 15%, and the dielectric breakdown voltage was 12,000V, indicating good insulation. However, in both cases (1) where the gate is at the center and (2) where the gate is at the edge, cracks are found on the curved surface of the casing and the gate, and the cracks occur in the area where the cracks occur. The metallic luster disappeared (total light transmittance of the part was 65%) after high temperature and high humidity tests at 65°CX 95% x 24 hours and 60°CX 80% x 96 hours, making it no longer practical. There wasn't.

[0033] Test results of crack occurrence during in-mold molding and durability (high temperature and high humidity test) of the mobile phone casings of the present invention in Examples 3 and 4 and the mobile phone casing of Comparative Example 2. A comparison is shown in Table 2.

[0034] [Table 2]

*1) After in-mold molding, the presence or absence of cracks at the gate or curved surface of the molded product was visually evaluated.

◎ No cracks occur at all

〇 A little crack occurs

X Crack occurrence

*2) Changes in metallic luster were visually evaluated in a high temperature and humidity test.

◎ No change in metallic luster

〇 Slight loss of metallic luster

X Loss of Gloss During in-mold molding, the insulating transfer film is subject to stress due to high heat and flow velocity at the gate where the resin is poured, although the degree of insulating transfer film varies depending on the shape of the intended molded product. There is tension in the part.

Hard and brittle metal oxide thin films such as oxidized aluminum thin films usually crack when subjected to the above stress and tension, resulting in poor appearance and reduced durability.

However, in the mobile phone casings of Examples 3 and 4 obtained using the insulating transfer films of the present invention of Examples and 2, the water-resistant resin layer, the Z acid aluminum thin film, the Z tin thin film, and the Since the protective layer is integrated into a laminated layer, even the tension applied to the insulating transfer film during in-mold molding does not cause cracks on the curved surface. Furthermore, in the mobile phone casing of Example 4 in which the resin of the water-resistant resin layer is made of acrylic or urethane-based resin, the heat resistance of the water-resistant resin layer is further improved, so No cracks occurred in the gate, not only when the gate was located at the edge, but even when the gate was located at the center, where higher heat resistance is required. However, there is no water-resistant resin layer. ヽIn the mobile phone casing of Comparative Example 2 using the insulating transfer film of Comparative Example 1, cracks were observed on both the curved surface of the casing and the gate. The cracked area lost its metallic luster through high temperature and high humidity tests at 65°CX 95% x 24 hours and 60°CX 80% x 96 hours (total light transmittance of the area was 65%), making it practical. It was nothing.

Industrial applicability

The insulating transfer film of the present invention can reliably transfer designs with excellent metallic luster, insulation properties, and durability onto the surface of various plastic substrates, making it suitable for mobile phone casings and audio products. It can be widely used for housings and other applications where transfer films are traditionally used.

Claims

The scope of the claims

[1] A release layer and a protective layer are provided on a plastic film, and a water-soluble paint layer is formed by applying a water-soluble paint on top of the film in a pattern, followed by an insulating metal thin film and a metal oxide thin film. A water-resistant resin layer is further provided on the metal acid thin film, and then washed with water to form the water-soluble paint layer and the insulating metal thin film laminated on the water-soluble paint layer. , the metal oxide thin film, and the water-resistant resin layer are removed, and the insulating metal thin film, the metal oxide thin film, and the water-resistant resin layer are left in the areas where the water-soluble paint layer is not present, and then the adhesive layer is formed. A method for producing an insulating transfer film, comprising:

[2] The manufacturing method according to claim 1, wherein the protective layer is provided on top of the colored printing layer provided on the release layer.

[3] A transfer film in which a release layer, a protective layer, an insulating metal thin film, a metal oxide thin film, and an adhesive layer are sequentially provided on a plastic film, the transfer film having a release layer, a protective layer, an insulating metal thin film, a metal oxide thin film, and an adhesive layer provided between the metal oxide thin film and the adhesive layer. An insulating transfer film characterized in that a water-resistant resin layer is provided, and the insulating metal thin film, metal oxide thin film, and water-resistant resin layer are laminated in the same pattern.

[4] The insulating transfer film according to claim 3, wherein the metal oxide thin film is an oxide aluminum thin film or an oxide silicon thin film.

[5] The metal oxide thin film is an oxide aluminum thin film with a thickness of 3 to 30 nm, and the insulating metal thin film has an island size of 10 A to 2 /z m and an island spacing of 20 A to 5000 A. 5. The insulating transfer film according to claim 3 or 4, which has an island-like structure.

[6] The insulating transfer film according to claim 1, wherein the insulating metal thin film is a tin thin film or an indium thin film.

[7] The insulating transfer film according to any one of claims 3 to 6, wherein the water-resistant resin layer is made of urethane resin or acrylic resin.

[8] Claim 3, wherein the protective layer is provided on top of the colored printing layer provided on the release layer.

~7, The insulating transfer film according to any one of item 1.

[9] The insulating transfer film according to any one of claims 3 to 7 is transferred onto a plastic base material, and an adhesive layer, a water-resistant resin layer, a metal oxide thin film, and an insulating film are formed on the plastic base material. metal thin A molded article characterized in that a film, a protective layer, and a mold release layer are sequentially provided, and the water-resistant resin layer, metal oxide thin film, and insulating metal thin film are laminated in the same pattern.

[10] The insulating transfer film according to claim 8 is transferred onto a plastic substrate, and an adhesive layer, a water-resistant resin layer, a metal oxide thin film, an insulating metal thin film, a protective layer, A molded article characterized in that a colored printing layer and a mold release layer are sequentially provided, and the water-resistant resin layer, metal oxide thin film, and insulating metal thin film are laminated in the same pattern.

[11] The molded product according to claim 9 or 10, wherein the molded product is a casing for a mobile phone.