KR20180007634A - Cover Glass for Smartphone - Google Patents

Abstract

In the decoration of the transparent substrate on which the metal is coated, fine bending of nanometer to micrometer size is formed on one surface of the transparent substrate, fine bending is formed on the opposite side of the surface where the micro bending of the transparent substrate is formed, And a metal surface is formed on the top surface of the substrate.
Especially, it is applied to the protective glass of smart phone to display the metal texture on the front display protective glass or the camera protective glass or the protective glass on the back side of the smart phone.

Description

{Cover Glass for Smartphone}

The present invention relates to a protective glass used as a front-side display of a display or a case used as a back-side case of a smart phone used in a glass or smart phone used for interior or decoration, and a surface micro- To a structure of a glass forming a decoration including a surface treatment of a glass which becomes a coating of a metal forming a scattering structure of light reflection.

In general, a protective cover is manufactured by using a transparent substrate such as transparent plastic or glass on the front surface of a smart phone or on the back surface of a smart phone.

Such protective cover forms a decoration by a technique such as printing.

Or a metal oxide having a high refractive index and a low refractive index may be laminated so as to have a light reflecting effect.

A problem to be solved by the present invention is to provide a transparent substrate used as a protective cover on the front or rear surface of a smart phone, It is for optimization.

Especially, in the structure in which the glass is coated with the metal, it is intended to enhance the reflection effect of various kinds of metals by controlling the mirror reflection on the metal and the surface reflection on the glass.

In smart phones, glass is used to protect the front display, to be used on the back of smart phones, or to protect the camera.

The glass used for the front display protection is decorated on the border except for the display part, and the glass used on the back of the smart phone forms the decoration such as printing as a whole.

Coating the metal rather than printing is a decoration of the glass, and it can have a high-quality texture. For this purpose, it can produce various effects of reflection of light as reflection using scattering effect instead of metal reflection.

Especially, using irregular and regular patterns can be used to make light reflection effect in various forms.

In order to solve the problem of the present invention, it is necessary to form micro-bending of a size of several hundred nanometers to several micrometers in a regular shape (Regular O or Random) on one side of a glass and to form micro- And a micro-bending pattern is formed on the opposite side of the glass, and the metal coating is formed on the opposite side of the glass surface where micro-bending is formed.

Therefore, the light reflected on the metal can produce various effects of light by scattering or random reflection due to refraction on the glass surface and micro-bending on the glass opposite surface.

In particular, it forms irregular diffuse irregularities on the surface of the glass surface to randomly refract or diffuse the light, and even if it passes through the glass and reflects from the metal surface, the light is again randomly directed from the irregular glass surface The reflection of the glass surface can be reduced and the metal effect can be enhanced.

The effect of the present invention is to provide a transparent reflection substrate for use in a smart phone, in particular a display protection glass, a rear protection glass, a camera protection glass, or the like, Refraction effects can occur to minimize metal mirror reflections, especially to minimize mirror reflections on glass surfaces and to enhance various effects of light.

Figure 1 shows the back glass of a typical smartphone.
FIG. 2 is a plan view (a) and a cross-sectional view (b) of a structure in which a frame portion or the like to be free from micro-bending is masked by printing or the like in order to make the surface micro-bending structure of the protective glass according to the present invention.
FIG. 3 shows a plan view (a), a sectional view (b) and a surface enlarged view (c) of a structure in which a micro bending structure of a regular or irregular shape is formed on the surface after masking.
Fig. 4 shows the state of the surface of the protective glass from which the micro-bend is formed and then the masking is peeled off, in a plan view (a) and a sectional view (b).
5 is a plan view (a) and a cross-sectional view (b) of a structure in which a metal is coated on a surface opposite to a surface on which micro-bending is formed according to the present invention, and a sectional view (c) have.
6, there is shown a mirror surface 401 and a micro-bend 301 on the outer surface of the glass 100 as an outer surface when mounted on a smartphone, and a mirror surface 401 and a micro- There is shown a structure in which there is a print layer 601 which further forms printing next to the metal coated surface 501 in the structure of the glass coated with the metal.
Fig. 7 is a sectional view showing an example of a structure according to the present invention in which micro-bending is formed on the outer surface of the glass and micro-bending is formed on the opposite side of the glass.
FIG. 8 shows a process of fabricating the above structure.
In addition to the above structure, FIG. 9 shows a process of coating a metal with fine bending formed inside the glass.
Fig. 10 is a cross-sectional view of a film with micro-bending coated with metal on a glass having micro-bending on its outer surface.
Fig. 11 shows a plan view and a cross-sectional view of a glass and a film on which fine bending is formed.
Fig. 12 shows a structure in which a glass with fine bending and a film with fine bending are adhered to each other.
FIG. 13 shows a structure in which a micro-bend of a film is coated with a metal to form a print layer, and then a glass and a film are adhered to each other.
FIG. 14 shows a structure in which a metal is formed into a plurality of graphic shapes so that the coated structure of the metal thin film is electrically insulated, and the metal is etched between the metal shapes to electrically isolate the metal shapes from each other.
FIG. 15 is a view showing a state in which the position of the thin metal film coated on the fine bending and fine bending formed on the film faces in the glass direction.
Fig. 16 shows a structure in which fine bending is formed directly on both sides of the glass.
Fig. 17 shows a plan view (a) and a cross-sectional view (b) of a structure in which micro-bends are formed on both sides of the glass, a metal thin film is coated on the inner surface, and a printed layer is formed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments. For reference, the same numbers in this description refer to substantially the same elements, which can be explained with reference to the contents described in the other drawings under the above rules, and contents which are judged to be self-evident or repeated can be omitted.

Although the drawings of the present invention are illustrated with reference to the back glass of a smart phone, the same technology can be applied to a front glass of a smart phone, and the present invention can be applied to a glass used for a tablet or the like as well as a general glass.

In addition to glass, it can be applied to sapphire substrates or transparent plastics such as acrylic resin.

Figure 1 shows the back glass of a typical smartphone.

The back glass is an example, and the content of the present invention is applied to a front glass, a camera protective glass, and the like.

As shown in the figure, (a) is a plan view of the rear protective glass 101 formed on the back side of the smartphone, and (b) is a sectional view.

For smartphones, front and rear protective glasses are applied to most smartphones.

In the present invention, the rear side protection glass of a smart phone is described as an example, and the present invention can be applied to a front protection glass or a camera protection glass for protecting a display.

The external light 102 is reflected on the surface of the glass 103 or reflected on the transmitted surface 104.

FIG. 2 is a plan view (a) and a cross-sectional view (b) of a structure in which a frame portion or the like to be free from micro-bending is masked by printing or the like in order to make the surface micro-bending structure of the protective glass according to the present invention.

The masking portion 201 of the protective glass 101 is printed with a silicone rubber ink or the like or masked by a photoresist film or the like using a photoresist film or the like.

The portion to be masked is a portion which does not form micro-bending, and may be formed at the rim portion or may be formed into various patterns.

The portion 202 that is not masked becomes a portion where micro-bending is formed.

FIG. 3 shows a plan view (a), a sectional view (b) and a surface enlarged view (c) of a structure in which a micro bending structure of a regular or irregular shape is formed on the surface after masking.

The method of forming the micro-bending structure having a random structure is formed by sand blasting, etching using hydrofluoric acid or the like, and the micro-bending structure of the shape is formed by photoresist masking using a photoresist or the like, hydrofluoric acid etching method, or the like.

The size of the micro-bending structure may range from several tens of nanometers to several micrometers depending on the structure of the present invention.

The micro-bend 301 is formed in the unmasked portion 202 of the glass 100.

(c) shows a photograph of the fine bending 301 in which micro-bending of a random structure of several micrometer size photographed by an electron microscope is formed.

When the microscopic bending of the random structure is formed, the light is scattered by diffuse reflection or refraction occurs.

Fig. 4 shows the state of the surface of the protective glass from which the micro-bend is formed and then the masking is peeled off, in a plan view (a) and a sectional view (b).

As shown in the drawing, a portion of the surface of the protective glass 100 that is not masked is a micro-bending surface 301 having micro-bending, and a portion where the micro-bending is formed is a flat portion 401 having no micro- do.

By this masking pattern, a fine bending structure and a flat portion can be formed on the surface of the glass.

5 is a plan view (a) and a cross-sectional view (b) of a structure in which a metal is coated on a surface opposite to a surface on which micro-bending is formed according to the present invention, and a sectional view (c) have.

As shown in the figure, a metal coating 501 is formed on the opposite side of the surface where the fine bending 301 of the glass 100 is formed.

The glass surface is formed outward when mounted on a smart phone, and the metal surface is formed inward.

The types of metal that are formed on the metal surface are rhodium, platinum. Various metals such as gold, silver, chromium, titanium, and aluminum are possible.

Various coating methods such as sputtering, E-Beam evaporation, thermal evaporation, and CVD are possible.

In addition to single-layer metals, expensive rhodium, platinum, and gold can be coated with chromium in multiple layers.

In general, a thin film coating of metal can be coated with 0.1 micrometer or more to enable metal-specific colors.

However, in the case of precious metals, as the thickness increases, the price of the precious metal increases. Therefore, it is possible to reduce the price of the precious metal while maintaining the inherent color of the precious metal by coating with the multilayer.

The thickness of a metal such as rhodium, platinum, or gold is coated from 5 to 50 nanometers and then coated with a metal such as aluminum, chromium, or titanium to a thickness of about 50 to 200 nanometers. It is possible to lower the price while maintaining the reflection of the light.

It is also possible to coat multiple layers of similar colors.

Rhodium or platinum is secondarily coated with aluminum, chromium, titanium, etc. Gold can be coated with chromium or titanium after secondary coating with copper or copper alloy.

Additional coatings of the metal are possible to increase the hardness of the metal.

Since gold and silver are weak in hardness, they can be additionally coated with chromium with high hardness, protective coating with titanium, or oxides such as SiO 2, TiO 2 and Al 2 O 3.

Alternatively, a metal coating such as gold to silver may be applied, followed by an oxide coating and an additional coating. Alternatively, a multi-layered metal coating may be applied followed by an oxide coating for protection.

Thus, a first metal coating may be applied, followed immediately by an oxide coating, followed by a first metal coating followed by a second metal coating, followed by an oxide coating.

The primary metal coating may be rhodium to platinum to gold to silver, gold alloy to silver alloy, or the like.

Secondary metal coatings that are protected after the first metal coating, or that complement the metal color, can be copper, chromium to titanium, or various metals such as aluminum, and the following additional coatings are possible.

Alternatively, it is also possible to coat the metal with a metal first, followed by a metal coating with a multi-layer, followed by a metal oxide coating.

the incident light 502 incident on the fine bending surface 301 as shown in Fig. 3C is reflected by the fine bending surface 301 and diffusely reflected by the metal surface 501, which is the opposite surface of the fine bending surface, The light becomes scattered light (506) as the refraction occurs randomly on the micro-curved surface.

With such a structure, there is a diffusion effect and a hazy haze effect when external light enters the glass and is reflected.

6, there is shown a mirror surface 401 and a micro-bend 301 on the outer surface of the glass 100 as an outer surface when mounted on a smartphone, and a mirror surface 401 and a micro- There is shown a structure in which there is a print layer 601 which further forms printing next to the metal coated surface 501 in the structure of the glass coated with the metal.

In the present invention, in order to enhance the effect of the structure in which the outer surface of the glass has a certain pattern or amorphous micro-curvature and the metal is coated on the opposite side, a fine bending structure having a pattern on the opposite side of the glass is formed, Thereby enhancing the reflection effect on the metal surface due to micro-bending.

The micro-bending structure having a pattern means a structure in which the bending of a few micro-height is arranged at a constant interval or shape like a prism.

Fig. 7 is a sectional view showing an example of a structure according to the present invention in which micro-bending is formed on the outer surface of the glass and micro-bending is formed on the opposite side of the glass.

As shown in the drawing, the micro-bend 201 is formed on the outer surface of the glass 101 and the micro-bend 702 is formed on the film 701 such as PET and attached with a transparent double-sided adhesive (OCA) Structure.

The micro-bending 702 formed on the film can form micro-bending having a pattern formed at a constant interval and shape at intervals of several micrometers to several tens of micrometers at a height of several hundred nanometers to several micrometers.

FIG. 8 shows a process of fabricating the above structure.

(a) is a cross-sectional view of a transparent film 701 such as transparent PET.

(b) shows a cross-sectional view of a structure in which fine bending 702 is formed on one side of the film 701 through a molding method of a mold disc using an ultraviolet curing resin or the like on one side of the film 701.

(c) is a cross-sectional view in which a transparent double-sided adhesive film 703 is attached to the other surface of the film 701 having fine bending on one surface.

(d), a glass 101 on which fine bending 301 is formed is attached to a film 701 on which fine bending is formed using a double-sided adhesive film.

Through this manufacturing process, a transparent film is adhered to the opposite side of the glass where the micro-bend is formed on the outer surface, and the micro-bend is formed on the transparent film so that the micro-bend is formed on both sides of the glass.

In the above, the outer surface of the glass means that the outer surface of the smartphone is attached when the glass is mounted on the smartphone.

In addition to the above structure, FIG. 9 shows a process of coating a metal with fine bending formed inside the glass.

Since the fine bending formed on the inside of the glass is formed on the transparent film, the surface of the transparent film on which the micro bending is formed is coated with the metal.

(a), a metal thin film 901 is coated on a fine bend 702 formed by using an ultraviolet curable resin or the like on one side of a transparent film 701.

The types of metal that are formed on the metal surface are rhodium, platinum. Various metals such as gold, silver, chromium, titanium, and aluminum are possible.

Various coating methods such as sputtering, E-Beam evaporation, thermal evaporation, and CVD are possible.

The thickness of the metal thin film ranges from several tens of nanometers to several hundreds of nanometers, and can be coated with a single layer or multiple layers of metal.

For multilayer coating, two or more metals such as gold or chromium or titanium are coated.

(b) is generally coated with a metal, and then a printing layer 902 is formed by silk screen printing or the like for protection.

Printing color is usually black, but it is possible to print various colors such as red, yellow, and blue.

Fig. 10 is a cross-sectional view of a film with micro-bending coated with metal on a glass having micro-bending on its outer surface.

As shown in the figure, the micro-bend 301 is formed on the outer surface of the glass 101, the micro-bend 702 is formed on the inner surface of the glass 101 through the double-sided adhesive film 703, A transparent film 701 on which the layer 902 is formed is attached.

Fig. 11 shows a plan view and a cross-sectional view of a glass and a film on which fine bending is formed.

(a) and (b) are a plan view (a) and a sectional view (b) showing a structure in which micro-bending 301 is formed on one surface of the glass 101 which is an outer surface.

(c) and (d) are a plan view (c) and a sectional view (d) of a structure in which a micro-bend 702 is formed on one surface of the film 701.

In particular, the micro-bending formed on the film is represented in such a manner that a straight line is formed in the drawing, and in this form, a micro-bending form in which a line, a curve, or a regular pattern of points is repeated is possible.

In this orthopedic pattern, refraction or reflection of light occurs regularly and new light patterns can be formed.

The micro-bending pattern of the glass and the micro-bending pattern of the film can be combined to produce a new light reflection effect.

Fig. 12 shows a structure in which a glass with fine bending and a film with fine bending are adhered to each other.

(b) is a cross-sectional view in which a micro-bend 301 is formed on the outer surface of the glass 101 and a micro-bend 702 of another pattern is formed on one side of the film 701 And is bonded with a transparent double-sided adhesive film 703.

In such a structure, a micro-bending pattern of the glass and a micro-bending pattern of the film can be combined to produce a new light reflection effect.

FIG. 13 shows a structure in which a micro-bend of a film is coated with a metal to form a print layer, and then a glass and a film are adhered to each other.

(b) is a cross-sectional view in which a micro-bend 301 is formed on the outer surface of the glass 101 and a micro-bend 702 of another pattern is formed on one side of the film 701 A metal thin film 901 is coated, a print layer 902 is formed, and then a transparent double-sided adhesive film 703 is bonded.

In this structure, a micro-bending pattern of the glass and a micro-bending pattern of the film are combined to produce a new light reflection effect through the light reflected from the metal.

In the present invention, the micro-bending formed on the outer surface of the glass forms random irregular micro-bending with a large size and a high shape interval, and the micro-bending formed on the inner side of the glass is regular A regular pattern arranged at intervals is used.

With this structure, it is possible to increase the design factor of reflection effect by using diffuse reflection and regular reflection.

FIG. 14 shows a structure in which a metal is formed into a plurality of graphic shapes so that the coated structure of the metal thin film is electrically insulated, and the metal is etched between the metal shapes to electrically isolate the metal shapes from each other.

a fine bend 301 is formed on the outer surface of the glass 101 as a sectional view and a fine bend 702 of another pattern is formed on one side of the film 701, (B) shows the structure of the coated metal thin film as a plan view, and a structure in which a printed layer 902 is formed and then adhered with a transparent double-sided adhesive film 703 is formed between the metal thin film 901 A metal etching portion 1401 is formed.

The size of the metal thin film pattern can be variously formed from several micrometers to several hundred micrometers or more, and the width of the etched portion is formed with a width of several micrometers to several tens of micrometers.

The formation of the etching portion is typically performed by a photolithography method.

FIG. 15 is a view showing a state in which the position of the thin metal film coated on the fine bending and fine bending formed on the film faces in the glass direction.

(a) is a cross-sectional view of a film having fine bending before being adhered, a double-sided adhesive film and a glass.

A micro-bend 702 is formed on the surface of the film 701 facing the glass, a metal thin film 901 is coated on the micro-bend surface, and a print layer 902 is formed on the reverse surface of the film 701 to be.

The reason for this is that gold (Au) is coated by e-beam evaporation or sputtering. In general, gold is not adhered to glass or film.

Therefore, in order to improve the adhesion, it is possible to improve adhesion by coating a metal having good cohesion such as chromium or titanium and coating with gold.

Therefore, in order to coat gold or chromium or titanium with a thin film and to coat the gold with gold, the fine bend surface of the film is directed toward the glass.

(b) shows a structure in which the micro-bend 301 of the glass 101 is directed outward, a micro-bend surface 702 of the film, and a metal thin film layer 901 coated on the micro-bend surface, Is bonded by a double-sided adhesive film.

A metal which is difficult to adhere to the film by such a structure can be used for the structure of the present invention.

The structure for forming the double fine bending pattern according to the present invention can also be manufactured by forming fine bending directly on both sides of glass.

Fig. 16 shows a structure in which fine bending is formed directly on both sides of the glass.

As shown in the figure, a micro-bend 301 is formed on one side of the glass 101 and a micro-bend 1601 is formed on the other side of the glass.

In particular, a diffuse reflection pattern is formed on the outer surface of the glass by irregular micro-bending, and a regular pattern in which a certain size and shape are repeated on the inner surface of the glass can be formed.

In addition, the microscopic bend 1601 formed on the inner surface of the glass can be formed in a regular pattern, and the micro-bend can be embossed to express the light reflection effect differently.

Fig. 17 shows a plan view (a) and a cross-sectional view (b) of a structure in which micro-bends are formed on both sides of the glass, a metal thin film is coated on the inner surface, and a printed layer is formed.

A fine bend 301 is formed on the outer surface of the glass 101 and a fine bend 1601 is formed on the inner surface of the glass 101. The metal thin film 901 is coated on the fine bend surface and the printed layer 902 ).

The micro-bending formed inside the glass surface has a regularity in shape, size, and spacing to form a pattern, which can have various light reflection effects.

In the present invention, what is expressed as glass generally means reinforced glass used in a smart phone or the like.

Also included is a transparent substrate made of sapphire or transparent plastic, although it is not glass.

The glass according to the present invention is typically applied to a tempered glass attached to a mobile device including a smartphone or a tablet, and is used on the front surface of the mobile device or on the back surface of the mobile device as a cover.

When used on the front surface of a mobile device, there is no micro-bending and no metal coating on the display portion, and micro-bending is formed on the entire back surface, or a portion where micro-bending is formed and a non- .

Although the present invention has been described with reference to the preferred embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined in the following claims. It can be understood that

The rear protective glass 101 external light 102,
Reflected (103) from the surface The transmitted surface (104)
The masking portion 201 has a portion 202 that is not masked,
The fine bending 301 flat portion 401,
Metal coating (501) diffuse reflection (503)
Refraction occurs randomly (506) Printing layer (601)
The film (701) micro-bend (702)
Transparent double-sided adhesive film (703) Metal thin film (901)
The print layer 902 includes a metal etching portion 1401,
Micro-bending (1601)

Claims (9)

A fine bend is formed on one surface of the transparent substrate,
Micro-bending is formed in a transparent film including PET,
A metal is coated on the surface of the transparent film on which micro-bending is formed,
A transparent substrate adhered to a front surface or back surface of a mobile device, characterized in that a transparent substrate and a transparent film coated with a metal are adhered. The method according to claim 1,
Wherein the transparent substrate is glass, sapphire, or transparent plastic. The method according to claim 1,
Wherein the microscopic bending formed on one side of the transparent substrate is an irregular shape and the micro bending formed on the film is a regular shape in which the size, shape and interval are regularly arranged. Transparent substrate. The method according to claim 1,
The transparent substrate is attached to the front side or the back side of the display of the mobile device including the smart phone,
Wherein a surface of the transparent substrate on which fine bending is formed is attached to the outer surface of the mobile device so as to be attached to the front surface or back surface of the mobile device. The method according to claim 1,
A transparent film adhered to a transparent substrate,
A metal is coated on the surface of the transparent film on which micro-bending is formed,
The metal-coated side of the transparent film is attached in the glass direction.
Wherein the metal-coated side of the transparent film is adhered in a direction opposite to that of the glass. A fine bend is formed on one surface of the transparent substrate which is the outer surface of the mobile device,
Fine bending is formed on the other surface of the transparent substrate which is the inner surface of the mobile device,
Wherein a metal thin film is coated on the micro-bend of the inner surface of the mobile device. The method according to any one of claims 1 to 6,
Wherein the metal comprises gold, rhodium, chromium, titanium, platinum, aluminum, silver, copper or an alloy. The method according to any one of claims 1 to 6,
1. A transparent substrate comprising glass for protecting a front side and a back side of a mobile device including a smart phone,
The micro-bending that is formed on the outer surface of the transparent substrate is an irregular (formed by micro-bending of random,
Characterized in that the fine bending formed on the transparent substrate directly on the inner surface of the transparent substrate or formed on the film adhered to the transparent substrate is a pattern formed at a repeated interval with a predetermined size and shape. A transparent substrate to be attached. As a protective glass for protecting a smartphone,
A protection glass for protecting the display or a protective glass for protecting the camera or a back surface of a smart phone,
The outer surface of the protective glass is formed with a slight curvature on a part or whole surface thereof,
Micro-bending is formed directly on the protective glass on the inner surface which is the opposite side of the surface on which micro-bending of the protective glass is formed, or fine bending is formed on the film adhered to the protective glass,
And a protective glass having a structure in which a thin metal film is coated on a micro-bend formed on the inside of the protective glass,

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