KR20200017796A - Watch Band with reflective micro structure - Google Patents

Abstract

The present invention relates to a watch band prepared by coating metal on a film such that both sides of the watch band looks like metal. The present invention relates to a watch band which shows a printing effect, a light reflection effect, and a metal effect on both sides thereof. Also, a film structure of the present invention can be used as a decoration film.

Description

Watch band with reflective micro structure

The present invention relates to a structure and a manufacturing method in the watch band of a traditional watch or smart watch.

In particular, as a watch band for coating metal on plastic film, it has a three-dimensional structure with better metal reflection effect as compared to a watch band manufactured by processing a metal directly.

Moreover, the decoration film by the structure of this invention is applied to accessories.

Typically, watchbands are made from metal, fabric, or molded urethane.

Of these, metal watchbands manufactured by processing metals are recognized as the most expensive and high quality products.

Metal watchband uses a lot of materials such as stainless steel, and stainless steel is hard to process due to its high hardness.

In addition, since the metal watch band manufactured by processing is heavy, there are many inconveniences during actual use.

However, metal watchbands are still used a lot because they are the most luxurious watchbands.

Watch bands using these metals are expensive and difficult to manufacture, so they are often coated with metal.

However, the film-coated structure cannot be used as a luxury watchband product because it is difficult to produce reflectivity as the processed metal.

The problem to be solved by the present invention is to have a metal reflective effect of the watch band difficult to come out by coating a metal thin film on the film material, but the metal directly processed,

In addition, the watch band manufactured by metal processing is to enable the watch band manufactured by coating a metal thin film to have a three-dimensional structure as long as it can make a three-dimensional structure.

In addition, in order to manufacture a colorful design of the watch band, it is possible to form a reflective structure of printing, microstructure and metal thin film together.

In this structure, it is possible to produce a metal effect on both sides.

In order to achieve the above object of the present invention, the present invention forms a microstructure having a size of several micrometers to several hundred micrometers using an ultraviolet curable resin on a moldable film, coating a metal thin film on the microstructure, and (Silicone) Molding using rubber.

Urethane films are used a lot as the film which can be molded, and various film materials such as PET, PE, and PC films can be used.

It demonstrates as an urethane film which is easy to shape | mold as description of this invention, The use of another film is also possible.

In general, the film is transparent, and the film used in the present invention also uses a transparent film so that the reflective surface of the metal can be seen.

In the present invention, in addition to using a transparent film, the metal is coated with a transparent silicone (Silicone) on the back.

Molding from transparent silicone allows the metal surface to be visible from the back, creating a metal effect on both sides of the watchband.

Urethane films are typically used with a film thickness between 10 and 500 micrometers.

The urethane film is used a lot because it is excellent in drawing force and thus silicone molding is possible.

Reflective microstructure is formed on the urethane film with an ultraviolet curable resin.

The reflective microstructure refers to a structure capable of reflecting light, such as a prism structure, and when the metal is coated on the reflective structure, the reflective effect of the metal is outstanding.

In the method of forming a microstructure by using an ultraviolet curable resin on the urethane film, a UV curable resin is applied to a disc on which the microstructure is formed, and then pressed onto a urethane film, and then cured with ultraviolet rays to form a microstructure on the urethane film. It is.

Ultraviolet curing resin also uses more urethane than acrylic to increase the stretching force.

After the microstructure is formed, a metal thin film is coated on the surface where the microstructure is formed.

The type of metal is gold. All metals including silver, aluminum, chromium, titanium and copper may be used, and metal oxides including TiO2, SiO2, Nb2O5, copper oxide, etc. may be coated, and the metal oxide thin film and the metal thin film may be sequentially It can also be coated with.

The thickness of the metal thin film is generally about 10 to several micrometers thick coating.

Coating method of the metal thin film is a method such as E-Beam Evaporation, Thermal Evaporation, Sputtering or other vacuum thin film deposition method.

The reason why the microstructure is formed on the urethane film and then the metal thin film is coated is because the reflective effect of light by the metal thin film can be variously changed by forming the microstructure.

The reflection of light, such as the prism effect, including the hologram effect, can produce a different effect than a planar metal reflective structure with a mirror effect.

The microstructure is formed on the urethane film, the metal thin film is coated, and then molded with silicone rubber.

The surface on which the microstructure of the urethane film is formed becomes the adhesion surface with silicon, and the opposite surface of the urethane film becomes the outer surface of the urethane film.

When the silicone rubber is attached to the urethane film for molding, the silicone rubber is easy to mold, and thus the shape is easy.

The thickness of the silicone rubber layer is formed to a thickness between 0,1 mm and 10 mm, and the molding depth is formed from several tens of micrometers to several millimeters deep.

The thickness can be arbitrarily changed according to the design.

The reason for forming is to produce the effect of the watch band with metal processing.

In general, metal watchbands are in the form of chains, and each metal part is machined in an elliptical form.

Similarly, silicone is attached to the urethane film to perform molding.

The molding method is to apply the silicone in the liquid state or the solid state before curing to urethane film, and then press the mold to mold.

When molding, the temperature is generally raised to 100 to 250 degrees, and in this state, the silicon is cured while being molded according to the shape of the mold.

In order to make a watch band in the structure of the present invention, one side is made of a urethane film coated with a micro structure and a metal thin film, and the other side may be used in a state in which the silicone is bonded to the urethane film and molded, and the urethane film on both sides There is also a method of forming and molding silicone rubber between urethanes.

In this structure, a microstructure and a metal thin film may be formed on both the urethane film that is the outer surface of the watch band and the urethane film that is the inner surface of the watch band, or when the watch band is worn on the wrist, It is also possible to form a microstructure and a metal thin film.

As the structure of the present invention, the urethane film may have an effect of overlapping the effects of the printed image or the printing pattern, the microstructure, and the metal thin film.

The image or pattern is printed on the urethane film first, and the microstructure is formed by UV-curing resin, and the metal thin film structure on the microstructure can have a metal effect and a printing effect on the urethane film structure used as decoration.

In particular, in the structure according to the present invention in the microstructure formed on the print layer, the partially formed without forming the print layer on the front surface to be a transparent portion, and when viewed from the outside is coated on the microstructure and microstructure By making the metal layer appear, the microstructure effect such as printing effect and prism and the metal effect can be shown together.

As another application of this patent, the printed layer is partially formed on the urethane film to form a transparent portion which is not printed, and the microstructure is partially formed, and the structure having the microstructured portion and the planar portion is mixed. It can be formed, the metal layer is applied as a whole so that the metal reflection effect, such as the part with and without the print, the part with and without the microstructure is different.

The metal layer may also be a single metal layer, or two or more metal layers may be partially formed in a plane to produce an effect by the metal color.

In addition, as a structure of the present invention, the reinforcing sheet or the reinforcing metal sheet may be inserted into the silicon layer.

Since the watchband must have sufficient tensile strength, additional sheets or metal chains can be formed in the silicon layer to improve the tensile strength.

As the material of the reinforcing sheet, a polymer film such as PET film or PC film may be used, but various materials having flexibility may be used, such as fabric cloth material.

The metal as a reinforcement can be chained to increase the durability to tensile strength while allowing the wrist strap to be flexible.

By forming reinforcements, you can drill holes in urethane and silicone watchbands.

Because the wristband is worn on the wrist, there are side effects such as sweating.

Therefore, the more holes are drilled, the better the breathability and the increased fit.

However, the urethane and silicone structure of a simple structure alone, if you make a lot of holes weaken the tensile force. Therefore, by using a reinforcing sheet or a metal reinforcing material it is possible to increase the tensile strength in the structure of the present invention.

Advantages of the structure of bonding the urethane film formed with the microstructure of the present invention to a silicone rubber material and forming the urethane film have the effect of reflecting light in different directions by matching the alignment area of the microstructure with the forming area. I can make it.

In order to manufacture such a structure, the original plate for fabricating the microstructure is formed by dividing a microstructure such as a prism structure into a certain area by a photolithography method to have a different light reflection direction for each section. The mold of the structure to form a microstructure on the urethane film, it can be molded in accordance with the molding structure to match the direction of light reflection.

Partial printing on the urethane film of the present invention, forming a microstructure in part or as a whole, and the structure and material that reflects by coating the metal is not only a watch band, but also a bag material such as a handbag, cloth material, etc. It can be used variously as a film material.

By forming a three-dimensional structure by forming a urethane film with a metal thin film coated structure on the surface of the microstructure and the microstructure according to the present invention by forming a watch band and the reflection effect of the metal compared to the watch band processed conventional metal In addition, the design effect as a watch band can be enhanced by the three-dimensional structure.

The tensile strength is improved by forming a reinforcing sheet or reinforcing material in the silicon layer.

In addition, by varying the light reflection effect of the microstructure according to the structure to be molded can produce a variety of effects as a watch band.

In addition, the decoration film of the present invention can be used in various materials such as a bag material such as a handbag, a cloth material or the like, or a film material to be attached to a wall surface.

1 shows a general watch band.
Figure 2 shows a plan view and a side view of the structure of the metal coating layer on both sides of the present invention.
3 shows various structures molded from silicon.
4 is a cross-sectional view of a structure in which a metal oxide layer is formed on both sides of a metal in a structure in which both surfaces of the present invention show a metal coating layer.
FIG. 5 shows a cross-sectional view of a structure in which a fine film is formed on a transparent film, a metal is coated on a surface formed with micro bends, and a transparent silicon (Silicone) is formed on the metal coated surface. have.
6 shows a process of forming a structure according to the present invention in cross section.
7 shows, as an example, a plan view of a film in which a microstructure having a different orientation of the prism structure is formed in a pattern.
8 shows a structure molded according to a pattern of fine bending.
FIG. 9 shows, as a cross-sectional view, a structure in which a transparent bend is formed on a printed layer after printing on a transparent film as a structure of the present invention.
Fig. 10 shows a structure in which the printing is partially or printed on both sides of the prism structure.
Fig. 11 shows a sample structure for printing in the structure of the present invention.
FIG. 12 shows a structure of the decorative film of the present invention, in which a printing layer is formed on a transparent film, a fine bending layer is formed, a metal is coated on the fine bending layer, and a protective layer is formed to protect the metal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or limited by the embodiments.

For reference, in the present description, the same numbers refer to substantially the same elements, and may be described by quoting the contents described in other drawings under the above rules, and the descriptions repeated or deemed obvious to those skilled in the art may be omitted.

1 shows the shape of the watch band 101.

Existing timepieces are made of metal, fabric, or urethane.

In the present invention, the watch band is to show the metal texture on both sides.

To do this, a metal is coated on one side of the film, and a transparent film is applied to the metal-coated side. Molding is made of transparent silicone.

Figure 2 shows a plan view and a side view of the structure of the metal coating layer on both sides of the present invention.

In (a), the watch band 101 of the plan view is shown, and the coated metal 202 is visible.

(b) is a cross-sectional view of the watch band of the present invention structure, in which the metal 202 is coated on the inner surface of the transparent film 201, and is a structure attached to the metal by means of transparent silicon 203.

The transparent film is a urethane film, or means a transparent film through which light such as PET, PC, PE film, and polyimide film passes, and uses a transparent urethane film.

The urethane film has high moldability and is suitable as a raw material of the present invention.

Urethane film or PET film is usually used with a film thickness of 10 micrometers to 500 micrometers.

A metal thin film is coated on one side of the transparent film.

By inner side is meant that the coated metal is not exposed on the back side of the film.

The type of metal is gold. All metals including silver, aluminum, chromium, titanium and copper may be used, and metal oxides including TiO2, SiO2, Nb2O5, copper oxide, etc. may be coated, and the metal oxide thin film and the metal thin film may be sequentially It can also be coated with.

The thickness of the metal thin film is generally about 10 to several micrometers thick coating.

Coating method of the metal thin film is a method such as E-Beam Evaporation, Thermal Evaporation, Sputtering or other vacuum thin film deposition method.

In order to increase the adhesion of the metal may be a primer coating on the surface of the metal coating the film.

To attach silicon to metal by molding with silicon is to apply silicon (Silicone) that is cured between 100-250 degrees and apply it to the metal as it is cured by raising the temperature with a mold. to be.

In the present invention, the transparent silicon is used so that the metal can be seen from the silicon side.

Besides the method of attaching transparent silicone by molding, there is also a method of attaching a transparent film such as a urethane film or PET film to the coated metal with an adhesive.

3 shows various structures molded from silicon.

Since the silicon molding is performed by applying pressure at a high temperature of 100 degrees or more, the film is molded in the shape of the mold, and the silicone is cured in the shape of the mold.

In (a), an example of the watch band 101 is shown in plan view.

(b) is sectional drawing in the width direction of a watch band, the film 201 and the coated metal 202 are planar, and the silicon 203 shows that the base was formed in the curved surface.

(c) is a cross-sectional view of the watch band in the width direction, in which the film 201 and the coated metal 202 are formed into a curved curved structure, and the bottom surface of the silicon 203 is molded into a curved surface.

(d) is a cross-sectional view in the width direction of the watch band, in which the film 201 and the coated metal 202 are formed in a curved curved structure, and the bottom surface of the silicon 203 is molded in a plane.

(e) is a cross-sectional view in the width direction of the watch band, the film 201 and the coated metal 202 is a structure formed in a curved structure with a flat and curved edge only, the bottom surface of the silicon 203 is molded in a plane Indicates that

In this way, it is possible to manufacture a variety of plane and curved structure by silicon molding.

Even in a structure in which a film is attached instead of silicon, molding is possible by applying pressure to a mold while raising the temperature, and a urethane film has particularly high moldability.

In the structure of the present invention, the metal oxide may be coated in a single layer or multiple layers on both sides of the metal surface to be coated.

Metal oxides are generally coated with a thickness of several nanometers to several tens of nanometers.

When metal oxides such as SiO 2, TiO 2, and Al 2 O 3 are coated in a single layer or multiple layers, various colors are reflected according to reflectance.

4 is a cross-sectional view of a structure in which a metal oxide layer is formed on both sides of a metal in a structure in which both surfaces of the present invention show a metal coating layer.

As a cross-sectional view of the watch band of the present invention, the metal 202 is coated on the inner surface of the transparent film 201, and the first transparent film 201 before the metal coating in the structure attached to the metal by molding with a transparent silicon (203). ) To form a metal oxide layer 401 coated with a metal oxide in a single layer or a multi-layer, and then coating the metal 202, and then coating the metal oxide layer 402 in a single layer or a multi-layer, and Next, the silicon 203 is attached by molding.

As such a structure, various colors of reflective characteristics of the metal oxide layer may be exhibited on the metal texture.

Figure 5 shows a cross-sectional view of the structure of the present invention, forming fine bends on the transparent film, coating the metal on the surface formed with fine bends, and forming by attaching transparent silicone (Silicone) to the metal-coated side have.

As shown in the figure, the inner surface of the transparent film 201 forms a transparent fine bend 501, a metal 202 is coated on the fine bend, and is a structure attached to the metal by molding with transparent silicon 203. .

The formation of the fine bend forms a microstructure of the size of several micrometers to several hundred micrometers using an ultraviolet curable resin on a transparent film, coating a metal thin film on the microstructure, and molding it by using a silicone (Silicone) rubber will be.

The microstructure may have a triangular structure such as a prism structure or various structures such as an elliptical structure.

As the film of the present invention, a urethane film is often used as a film that can be molded, and various film materials such as PET, PE, PC film, and polyimide film can be used.

By coating the metal with fine bends, metal texture can be enhanced due to the reflection of light at various angles.

In addition, by molding with transparent silicone, the metal surface can be seen from the back side, thereby producing a metal effect on both sides of the watch band.

In the present invention, the fine bend forms a reflective microstructure with an ultraviolet curable resin.

The reflective microstructure refers to a structure capable of reflecting light, such as a prism structure, and when the metal is coated on the reflective structure, the reflective effect of the metal is outstanding.

In the structure of the present invention, the reflection by the metal formed in the fine bend is also seen through the film, and also through the transparent silicon so that the watch band can exhibit the metal texture on both sides.

6 shows a process of forming a structure according to the present invention in cross section.

(a) shows a transparent film 201 in the order of tens of micrometers to several hundred micrometers to several millimeters of thickness such as urethane film.

(b) shows that microscopic bending was formed of an ultraviolet curable resin.

In the method of forming a microstructure using a UV curable resin on a transparent film, a UV curable resin is applied to a disc on which a microstructure is formed, and then pressed onto a urethane film, and then cured with ultraviolet rays to form a microstructure on the urethane film. It is.

Ultraviolet curing resin also uses more urethane than acrylic to increase the stretching force.

Fine bends can be manufactured in sizes and heights ranging from hundreds of nanometers to several micrometers or tens of micrometers.

In (c), a microstructure is formed, and then a metal thin film is coated on the surface where the microstructure is formed.

The type of metal is gold. All metals including silver, aluminum, chromium, titanium and copper may be used, and metal oxides including TiO2, SiO2, Nb2O5, copper oxide, etc. may be coated, and the metal oxide thin film and the metal thin film may be sequentially It can also be coated with.

Metal thin films are generally coated with thicknesses ranging from tens of nanometers to several micrometers.

Coating method of the metal thin film is a method such as E-Beam Evaporation, Thermal Evaporation, Sputtering or other vacuum thin film deposition method.

The reason for forming the microstructure on the transparent film and then coating the metal thin film is that by forming the microstructure, the reflection effect of light by the metal thin film can be variously changed.

The reflection of light, such as the prism effect, including the hologram effect, can produce a different effect than a planar metal reflective structure with a mirror effect.

Single or multi-layered metal oxides may be coated on both sides of the metal.

In (d), a microstructure is formed on a transparent film, a metal thin film is coated, and then molded with silicone rubber.

The surface on which the microstructure of the urethane film is formed becomes the adhesion surface with silicon, and the opposite surface of the urethane film becomes the outer surface of the urethane film.

When the silicone rubber is attached to the urethane film for molding, the silicone rubber is easy to mold, and thus the shape is easy.

The thickness of the silicone rubber layer is formed to a thickness between 0,1mm and 10mm, and the molding depth is formed from several tens of micrometers to several millimeters deep.

The thickness can be arbitrarily changed according to the design.

The reason for forming is to produce the effect of the watch band with metal processing.

In general, metal watchbands are in the form of chains, and each metal part is machined in an elliptical form.

Similarly, silicone is attached to the urethane film to perform molding.

The molding method is to apply the silicone in the liquid state or the solid state before curing to urethane film, and then press the mold to mold.

When molding, the temperature is generally raised to 100 to 250 degrees, and in this state, the silicon is cured while being molded according to the shape of the mold.

In order to make a watch band in the structure of the present invention, one side is made of a urethane film coated with a micro structure and a metal thin film, and the other side may be used in a state in which the silicone is bonded to the urethane film and molded, and the urethane film on both sides There is also a method of forming and molding silicone rubber between urethanes.

In this structure, a microstructure and a metal thin film may be formed on both the urethane film that is the outer surface of the watch band and the urethane film that is the inner surface of the watch band, or when the watch band is worn on the wrist, It is also possible to form a microstructure and a metal thin film.

With the above manufacturing process, it is possible to manufacture a metal-textured watch band in which light is reflected in various directions in which metals are seen from both sides.

The micro-bending structure and the metal-coated structure shown in both sides of the present invention can form a variety of micro-bending structure as a pattern to form the film.

7 shows, as an example, a plan view of a film in which a microstructure having a different orientation of the prism structure is formed in a pattern.

(a) shows that the fine bending pattern 701 is formed in various directions on the transparent film 201 as a plan view.

In such a structure, since light is reflected in different directions in each pattern, a pattern effect according to the reflection direction of light can be produced.

(b) shows that the prism structure 501 is formed as an example of micro-bending, and by producing the prism structure differently in the patterns of each micro-bending, the pattern effect of changing the reflection direction of light can be produced.

Another feature of the present invention is to increase the effect of the pattern reflecting the light of the fine bend by making a three-dimensional structure that protrudes or enters each of the fine bend pattern portion in a pattern structure with a different direction of fine bend.

8 shows a structure molded according to a pattern of fine bending.

(a) shows a plan view, in which fine bending patterns 701 are formed in various directions on the transparent film 201.

(b) is a cross-sectional view, in which a fine bend 501 is formed in the transparent film 201, the metal 202 is coated, and the transparent silicon 203 is formed. It shows that the three-dimensional structure is formed by molding the pattern 701 of the fine bending.

In the structure of the present invention by forming a transparent silicon in the metal-coated structure there is an advantage that can be made a variety of three-dimensional structure.

Another structure of the present invention is to print on one surface of the transparent film, to form a fine bend with an ultraviolet curable resin on the printed surface, to coat the metal on it, and to form a silicon.

When manufactured in such a structure, it is possible to produce a watch band with a printing effect, a fine bending effect and a metal reflection effect.

FIG. 9 shows the structure of the present invention, in which a transparent film is printed on a transparent film and then a transparent bend is formed on the printed layer as a cross-sectional view.

As shown in the figure, the inner surface of the transparent film 201 is printed to form a printed layer 901, to form a transparent fine bend 501 on the printed layer, the metal 202 is coated on the fine bend, It is a structure attached by molding with transparent silicon 203 to a metal.

The printed layer is a part that is completely opaque, semitransparent, or unprinted to form a part that transmits and reflects light partially, such as a part that is completely transparent, so that the light can be reflected from the metal layer formed on the fine bend layer.

The printing layer may be partially formed on the outer side of the transparent film to increase the printing effect.

Fig. 10 shows a structure in which the printing is partially or printed on both sides of the prism structure.

In (a), a print layer 901 is formed by printing on the inner side of the transparent film 201, and a transparent portion 1001 which is not printed is also partially formed, and a transparent fine bend 501 is formed on the print layer. It is formed, and the metal 202 is coated on the fine bend, it is a structure attached to the metal by a transparent silicon 203 by molding.

As such a structure, light transmits through the printing layer, so that the metal effect can be mixed with the printing effect.

In (b), a print layer 901 is formed by printing on the inner side of the transparent film 201, and a transparent portion 1001 which is not printed is also partially formed, and a transparent fine bend 501 is formed on the print layer. The metal 202 is coated on the fine bend, and the printed layer 1002 partially printed on the metal surface is formed, and the structure is attached to the metal and the print layer by molding with transparent silicon 203.

In this structure, the light transmits through the printing layer, and the metal effect can be mixed with the printing effect. In particular, the light reflection effect due to fine bending on both sides of the watch band and the complex effect of the metal effect and the printing effect. You can make

Fig. 11 shows a sample structure for printing in the structure of the present invention.

(a) shows that 901 printed in a pattern form on one surface of the transparent film 201 of the present invention.

In the pattern form, the printed portion and the non-printed portion are repeatedly formed, so that the printed portion has an opaque or partial transmissive effect, and the non-printed portion has a structure in which fine bending and metal surfaces are immediately visible.

Therefore, the microflex structure including the print structure and the prism and the metal reflection effect can be shown together.

(b) shows that the printed image (901) on one surface of the transparent film 201 of the present invention.

The image is partially printed, so that the printed portion has an opacity or partial transmissive effect, and the unprinted portion has a structure of fine bending and metal surface.

As such, by forming the print layer, the fine bend layer, and the metal layer on the transparent film, various effects such as metal texture and print texture can be obtained.

The transparent film structure of the present invention can be used as a general decorative film in addition to the watch band.

A general decorative film is a material for making a bag or the like, a material such as a wallpaper, an exterior material such as an air conditioner or a TV, or an interior material such as an elevator.

FIG. 12 shows a structure of a decorative film of the present invention, in which a printing layer is provided on a transparent film, a fine bending layer is formed, a metal is coated on the fine bending layer, and a protective layer is formed to protect the metal.

(a) is a plan view of the decorative film 1201 and shows a structure in which the printed layer formed on the film and the micro-bending layer and the metal layer appear as unprinted portions of the printed layer.

The printing of the printing layer has an opaque portion, a partially transparent portion where light is partially transmitted, and a transparent portion that is not printed, so that the effect of light and printing reflected from fine bending and metal can be produced.

Printing can be done in a variety of colors.

In (b), as a cross-sectional view, a printed layer 901 is formed by printing on the inner side of the transparent film 201, and a transparent portion 1001, which is not printed, is also partially formed, and a transparent fine bending on the printed layer ( 501 is formed, the metal 202 is coated on the fine bend, and a protective layer for protecting the metal is formed.

In this structure, the light transmits through the printing layer, and the metal effect can be mixed with the printing effect. In particular, the light reflection effect due to the fine bending on both sides of the watch band and the combination of the metal effect and the printing effect Can give a decorative effect.

When used as a decorative film, the back side does not need to be transparent, so it may be an opaque material or covered with a metal layer with silicon.

When used as a decorative film can be printed on the inside of the transparent film, the outside can be printed, or can be printed on both sides of the film.

The printing method may be inkjet, screen printing, gravure printing, or various printing methods such as spraying.

Decorative film according to the structure of the present invention can be used as a material of a bag, a material of home appliances, a material to be attached to the wall or an elevator material.

As described above, it has been described with reference to a preferred embodiment of the present invention, but those skilled in the art various modifications and changes to the present invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

Watch Band (101) Transparent Film (201)
Metal (202) Transparent Silicon (203)
Metal Oxide Layer 401 Metal Oxide Layer 402
Transparent Micro Bend (501) Micro Bend Pattern (701)
Printed layer 901 Unprinted transmissive portion 1001
Decorative film (1201)

Claims (15)

The printing layer is formed on one or both sides of the transparent film,
Transparent fine bending is formed on one or both sides of the transparent film,
Metal is coated on top of the fine bend,
A watch band with a protective layer on the metal-coated side.
According to claim 1,
Transparent film is a urethane film, PMMA film, PC film, polyimide film, watch band characterized in that it comprises a PET film.
10. The watchband of claim 1, wherein the print layer is a mixture of opaque and partially transparent and non-printed transparent portions.
According to claim 1,
The protective layer formed on the metal surface is a watch band characterized in that the transparent silicon (Silicone)
According to claim 1,
Transparent micro bends are watch bands characterized in that they are prismatic or hemispherical
According to claim 1,
Fine bending is formed on the printed layer,
The print layer is characterized in that it comprises an opaque portion, a partially transparent portion and a non-printing portion
According to claim 1,
The transparent protective layer formed on the metal surface is silicon (Silicone),
Watch band characterized by forming a three-dimensional structure through the molding of silicone
According to claim 1,
Watch bands characterized in that the metal oxide layer is formed on both sides of the metal formed surface
The printing layer is formed on one or both sides of the transparent film,
Transparent fine bending is formed on one or both sides of the transparent film,
Metal is coated on top of the fine bend,
Decorative film formed with a protective layer on the metal-coated surface.
10. The decorative film of claim 9, wherein the printing layer is a mixture of opaque printing, partial transparency printing, and non-printing transparent portions.
The method of claim 9,
Transparent fine bending is a decorative film characterized in that the prism shape or hemispherical shape
The method of claim 9,
Fine bending is formed on the printed layer,
The printing layer is a decorative film comprising an opaque portion, a partially transparent portion and a non-printing portion
The method of claim 9,
Watch band characterized in that to form a three-dimensional structure of the surface of the transparent film through molding
The method of claim 9,
Watch bands characterized in that the metal oxide layer is formed on both sides of the metal formed surface
The method of claim 9,
The transparent film is a urethane film, a PMMA film, a PC film, a polyimide film or a decorative film comprising a PET film

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