JP3187000U - Plateless transfer film - Google Patents

Abstract

Provided is a plateless transfer film in which adhesion between a transfer film and an electronic device does not become uneven or fall off even when transferred to an electronic device having a non-flat surface or a right angle portion. .
A plateless transfer film of the present invention includes a base material and a transfer layer located on the base material. The transfer layer 12 is located on the base material 10 and is used to selectively separate the base material 10 and the transfer layer 12. The transfer layer 12 is located on the release layer 121, and full-color graphics, characters, A design layer 125 having a sign or a number; a white ink layer 127 located on the design layer 125; and an adhesive layer 129 located on the white ink layer 127 and providing an adhesive force to the plateless transfer film 1. Selected figure] Figure 1

Description

  The present invention relates to a transfer technique, and more particularly to a plateless transfer technique capable of transferring a design to a casing of an electronic device.

  Transfer techniques include water transfer, thermal transfer, and friction transfer. The design to be transferred is produced by general printing and digital printing. Transfer is divided into plate transfer and plateless transfer. Thermal transfer is widely applied on various articles and imparts aesthetics or originality to the article.

  In thermal transfer, a design on a transfer film is transferred onto an article to be transferred by coating the transfer film on the article to be transferred, and transfer is performed with high quality on a small area or plane. be able to. However, when transferring to a non-flat place such as an uneven surface or a right-angled part, bubbles may enter between the transfer film and the article to be transferred, resulting in uneven adhesion or dropping off.

JP-A-7-290686

  An object of the present invention is to provide a plateless transfer film in which adhesion between a transfer film and an electronic device does not become uneven or drop off even when transferred to an electronic device having a non-flat surface or a right angle portion. Is to provide.

  In order to solve the above-described problems, the plateless transfer film of the present invention includes a base material and a transfer layer located on the base material. The transfer layer is located on the base material, a release layer used for selectively separating the base material and the transfer layer, and a design located on the release layer and having full-color graphics, letters, symbols, or numbers. A white ink layer located on the design layer, and an adhesive layer located on the white ink layer and providing an adhesive force to the plateless transfer film

  The substrate is a plastic film or paper.

  The design layer is formed by an ink jet printer or a laser printer.

  The release layer is a hot-melt release agent, a thermosetting release agent, or a semi-curable release agent.

  The adhesive layer is a thermal transfer adhesive.

  The plateless transfer film further includes a transparent protective layer located between the release layer and the design layer.

  The release layer is a transparent solvent resistant ink, a transparent acrylic adhesive, or a transparent hot melt adhesive.

  The present invention transfers a plateless transfer film onto an electronic device main body by heating at a low temperature and applying pressure by blowing air. Can be transferred. According to the present invention, it is possible to solve the problem that air bubbles enter between the transfer film and the electronic device main body in the prior art and the transfer film falls off when used for a long time.

It is sectional drawing which shows one Embodiment of the plateless transfer film of this invention. It is a perspective view which shows one Embodiment of the plateless transfer film of this invention. 1 is a perspective view illustrating an electronic device having a full color design according to an embodiment of the present invention. It is sectional drawing which shows one Embodiment of the plateless transfer apparatus of this invention. It is a flowchart which shows the step which manufactures the plateless transfer film of this invention. 3 is a flowchart illustrating steps of manufacturing an electronic device having a full color design according to an embodiment of the present invention.

  DESCRIPTION OF EMBODIMENTS Embodiments showing the objects, features, and effects of the present invention will be described in detail with reference to the drawings.

  In the present invention, a plateless transfer is performed on an electronic device main body with a roller, and a plateless transfer film is uniformly and flatly transferred onto the electronic device main body to manufacture an article having a full color design.

  In the following description, when explaining a predetermined layer located on another layer or explaining a relative position, in order to explain the embodiment shown in the drawing, when the coordinates of the drawing are rotated, What is depicted as being located above another layer is located below the other layer, and there may be other layers between the two layers.

  Please refer to FIG. FIG. 1 is a cross-sectional view showing an embodiment of the plateless transfer film of the present invention. As shown in FIG. 1, the plateless transfer film 1 includes a substrate 10 and a transfer layer 12. The transfer layer 12 includes a release layer 121, a transparent protective layer 123, a design layer 125, a white ink layer 127, and an adhesive layer 129.

  The transfer layer 12 is located on the substrate 10. The release layer 121 in the transfer layer 12 is located on the substrate 10. The transparent protective layer 123 is located on the release layer 121. The design layer 125 is located on the transparent protective layer 123. The white ink layer 127 is located on the design layer 125. The adhesive layer 129 is located on the white ink layer 127.

The base material 10 is a soft sheet material such as a plastic film or paper. When the substrate 10 is a plastic film, it is difficult for pigments such as ink to adhere to the substrate 10, and thus it is necessary to add a release layer 121. The release layer 121 is a hot-melt release agent, a thermosetting release agent, or a semi-curable release agent, and prevents the design layer 125 and the substrate 10 from being separated. That is, the release layer 121 can be a film release agent. The transparent protective layer 123 is a transparent solvent-resistant ink, a transparent acrylic adhesive, a transparent hot melt adhesive, or the like, and has a heat resistance and a property of being hardly dissolved.
Further, the transparent protective layer 123 protects the design layer 125 by making it easy to print the design layer 125 from a printer, preventing the chemical solvent from eroding, and preventing damage due to scratches. The design layer 125 is a color ink layer (ink is a solvent ink of a type that does not pollute the environment) ejected from a laser printer or an ink jet printer, and one or more of figures, characters, symbols, and numbers A design including a combination of
The design layer 125 may be a design completed by applying four types of complexion paints four times and drying them. The four face colors are four primary colors of yellow, red, blue and black. The coating step is performed by a coating machine, and the drying step is performed by a blower or an oven. The white ink layer 127 is one type of white paint. The adhesive layer 129 is a thermal transfer adhesive for printing.

Please refer to FIG. FIG. 2 is a perspective view showing an embodiment of the plateless transfer film of the present invention. As shown in FIG. 2, the plateless transfer film 1 is a single sheet or a single roll of flexible sheet material. The substrate 10 has 250 mesh (the unit of the mesh is book / inch). In one embodiment, the plateless transfer film 1 is manufactured by first forming the release layer 121 on the substrate 10 by coating with a coating machine or printing with a printer. Next, the design layer 125 is formed on the release layer 121 by coating with a coating machine or printing with a printer. Alternatively, first, the transparent protective layer 123 is applied, and then the design layer 125 is printed. The release layer 121 has a high mesh (at least 400 or higher mesh), and the ink or paint of the design layer 125 does not easily pass through and can be uniformly colored.
Next, a white ink layer 127 is applied or printed on the design layer 125. The white ink layer 127 has 300 mesh and is used to supplement white pigment that cannot be printed by the printer and to increase the contrast of the design layer 125. Finally, the adhesive layer 129 is formed on the white ink layer 127 by coating with a coating machine or printing with a printer. The adhesive layer 129 is in a molten state at an appropriate temperature. The adhesive layer 129 has an optimum viscosity when it is about 75 to 120 degrees, and has a low viscosity at room temperature. Therefore, when the plateless transfer film 1 is heated, it has adhesiveness, and at room temperature, it has a roller shape. Can be stored.

Please refer to FIG. FIG. 3 is a perspective view illustrating an electronic apparatus having a full color design according to an embodiment of the present invention. The electronic device 2 having a full-color design includes an electronic device body 20 and a transfer layer 12. The design layer 125 of the transfer layer 12 includes a design designed according to a customer's request. The transferred object is a casing of a replaceable notebook type personal computer, and can give the original appearance of the notebook type personal computer and the effect of preventing counterfeiting. In order to smoothly transfer the plateless transfer film 1 to the electronic device main body 20, the material of the adhesive layer 129 needs to match the material of the electronic device main body 20 and match the material of the surface of the electronic device main body 20.
The material of the adhesive layer 129 is polyester, epoxy resin, or a composition thereof, and the material of the electronic device body 20 is metal or plastic. Since the adhesive layer 129 has suitable adhesiveness under a predetermined temperature, the adhesive layer 129 can be brought into close contact with the surface of the electronic device body 20. At this time, since the melting point of the electronic device main body 20 has not been reached, the electronic device main body 20 is not damaged. In one embodiment, since the adhesive layer 129 has a low melting point of about 75 to 100 degrees, it can be transferred by heating at a low temperature. For this reason, it is possible to prevent the electronic device main body 20 from being melted and deformed or damaged.
Moreover, since the peeling layer 121 is in a liquid state when cooled to about 40 degrees, the transfer layer 12 can be uniformly peeled from the substrate 10. The transfer layer 12 may or may not include the transparent protective layer 123. When the transfer layer 12 does not include the transparent protective layer 123, the substrate 10 and the transfer layer 12 are peeled off, and then a solvent-resistant transparent ink is applied onto the design layer 125 to form the transparent protective layer 123. It can be prevented from being damaged or scratched by a chemical solvent. Further, in another embodiment, the transfer layer 12 does not include the adhesive layer 129, and the material of the electronic device body 20 itself or the paint on the surface becomes viscous by receiving heat, and adheres the design layer 125. be able to.

Please refer to FIG. FIG. 4 is a cross-sectional view showing an embodiment of the plateless transfer apparatus of the present invention.
As shown in FIG. 4, the plateless transfer device 3 includes a plateless transfer film 1 and a transfer machine 30. The transfer machine 30 includes a roller 33, a fixed base 31, and a transmission unit 35. The fixed base 31 is used for fixing the electronic device main body 20. The roller 33 can be moved up and down according to the outer shape of the electronic device main body 20. In one embodiment, by using a plurality of rollers 33 having the same or different radii, the plateless transfer film 1 can be uniformly pressure-bonded to the electronic device main body 20. The transmission unit 35 is used for flatly spreading the plateless transfer film 1 on the electronic device main body 20. The transmission unit 35 is a rotating shaft or a roller. Before the plateless transfer film 1 is coated on the electronic device main body 20, the plateless transfer film 1 is heated to a predetermined temperature (for example, about 75 to 100 degrees) by a heating unit (not shown). Make 1 viscous.
The heating unit can use light energy such as a laser as a heat source. When the plateless transfer film 1 is positioned on the surface of the electronic device main body 20 to be transferred, the roller 33 applies pressure to the plateless transfer film 1 so that the plateless transfer film 1 is evenly and uniformly placed on the electronic device main body 20. Transfer without bubbles. In one embodiment, the transfer machine 30 further includes an air intake (not shown). The air intake unit evacuates the environment in the transfer machine 30 so that air bubbles do not enter between the plateless transfer film 1 and the electronic device main body 20. In one embodiment, the roller 33 has a heating source (not shown). The temperature of the heating source is about 75 to 100 degrees, and when the roller 33 and the plateless transfer film 1 are in contact with each other, the plateless transfer film 1 is heated and the plateless transfer film 1 and the electronic device main body 20 are moved. Adhere to each other.
In other embodiments, the transfer machine 30 further includes a high temperature exhaust (not shown). After the roller 33 presses the plateless transfer film, the plateless transfer film 1 is coated with the silicon rubber layer 331, and the high pressure exhaust part blows against the silicon rubber layer 331, thereby applying pressure to the plateless transfer film 1. In contrast, pressure is applied indirectly. Thereby, when the surface of the electronic device main body 20 is not flat or has a right angle portion, the silicon rubber layer 331 makes the pressure on the plateless transfer film 1 more uniform, and the plateless transfer film 1 is transferred to the electronic device main body 20. To improve the transfer quality.

Please refer to FIG. FIG. 5 is a flowchart showing the steps for producing the plateless transfer film of the present invention. As shown in FIG. 5, first, a plastic film or paper is prepared as the base material 10, and a release agent is applied onto the base material 10 by an applicator to form a release layer 121 (S501). After the release layer 121 is dried, a transparent solvent-resistant ink is applied on the release layer 121 to form a transparent protective layer 123 (S503). A full color design is printed on the transparent protective layer 123 using a laser printer or an ink jet printer to form the design layer 125 (S505).
In one embodiment, the design layer 125 may be formed by repeating printing several times with a printer. After the design layer 125 is dried, white ink is printed on the design layer 125 to form a white ink layer 127 (S507). After the white ink layer 127 as the lower layer on the design layer 125 is dried, a thermal transfer adhesive is applied on the white ink layer 127 to form an adhesive layer 129 (S509).

Please refer to FIG. FIG. 6 is a flowchart illustrating steps for manufacturing an electronic device having a full color design according to an embodiment of the present invention. As shown in FIG. 6, first, the plateless transfer film 1 is prepared, and the plateless transfer film is flatly coated on the electronic device main body 20 by the transmission unit 35 of the transfer machine 30. (S601). The plateless transfer film 1 is heated using a heat source such as a laser light source (S603). Here, the heating temperature is 75 degrees to 100 degrees. The plateless transfer film 1 is pressed using the roller 33 (S605).
In one embodiment, the roller 33 has a heating source and presses the plateless transfer film 1 and simultaneously heats the plateless transfer film 1. In one embodiment, the transfer machine 30 may include a plurality of rollers 33. Next, a high-temperature gas of about 75 to 100 degrees is sprayed on the plateless transfer film 1 to apply pressure (S607). In one embodiment, a uniform pressure is indirectly applied to the plateless transfer film 1 by coating the plateless transfer film 1 with a silicon rubber layer 331 and blowing high temperature gas onto the silicon rubber layer 331 to apply pressure. .

  As can be seen from the above, the present invention transfers the plateless transfer film onto the electronic device body by heating at a low temperature and applying pressure by blowing air, and is not flat. The design can be transferred on the surface or at a right angle. Thereby, it is possible to solve the problem that the transfer film tends to drop off when used for a long time due to air bubbles entering between the transfer film and the electronic device main body in the prior art.

  The above description and drawings show embodiments of the present invention and do not limit the present invention. Those skilled in the art can make various modifications based on the above description, and any modifications made to the technology of the present invention based on the gist of the present invention are included in the scope of the utility model registration request of the present invention. .

DESCRIPTION OF SYMBOLS 1 Plateless transfer film 10 Base material 12 Transfer layer 121 Peeling layer 123 Transparent protective layer 125 Design layer 127 White ink layer 129 Adhesive layer 2 Electronic device having a full color design 20 Electronic device main body 3 Plateless transfer device 30 Transfer machine 31 Fixed base 33 Roller 35 Transmitter 331 Silicon rubber layer

Claims (7)

A plateless transfer film comprising a substrate and a transfer layer located on the substrate,
The transfer layer is
A release layer located on the substrate and used to selectively separate the substrate and the transfer layer, and a design located on the release layer and having full-color graphics, letters, symbols or numbers A plateless transfer film comprising: a layer; a white ink layer positioned on the design layer; and an adhesive layer positioned on the white ink layer and imparting an adhesive force to the plateless transfer film.   The plateless transfer film according to claim 1, wherein the substrate is a plastic film or paper.   The plateless transfer film according to claim 1, wherein the design layer is formed by an ink jet printer or a laser printer.   The plateless transfer film according to claim 1, wherein the release layer is a hot-melt release agent, a thermosetting release agent, or a semi-curable release agent.   The plateless transfer film according to claim 1, wherein the adhesive layer is a thermal transfer adhesive.   The plateless transfer film according to claim 1, further comprising a transparent protective layer positioned between the release layer and the design layer.   The plateless transfer film according to claim 6, wherein the release layer is a transparent solvent-resistant ink, a transparent acrylic adhesive, or a transparent hot melt adhesive.

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