KR102072591B1 - Window member for portable terminal and fabrication method for said window member - Google Patents

Abstract

The present invention provides a window member of a portable terminal, comprising: a glass member; A translucent printing layer formed on the glass member; And a metal oxide layer formed on the translucent print layer, wherein the translucent print layer discloses a window member including irregularities on a surface corresponding to the metal oxide layer. The window member configured as described above may provide a ceramic texture to the surface of the window member in a process in which light incident from the outside passes through the translucent print layer, and in the process in which light reflected from the metal oxide layer passes through the translucent print layer. do.

Description

Window member of portable terminal and manufacturing method thereof {WINDOW MEMBER FOR PORTABLE TERMINAL AND FABRICATION METHOD FOR SAID WINDOW MEMBER}

The present invention relates to a portable terminal, and more particularly, to a window member attached to a display device.

In general, a portable terminal such as a mobile communication terminal or a portable multimedia device includes a display module and a transparent window member mounted on the display module, thereby protecting the display module while transmitting a screen implemented through the display module.

A general display device only outputs a screen, and the portable terminal inputs information or performs various operations through an input device such as a separate keypad or track pad. Recently, however, various functions such as Internet access and multimedia file playback can be performed through one mobile communication terminal, and a touch screen function is mounted on the display device of the portable terminal. In other words, the screen display area is secured for internet access or multimedia functions, and the input device is implemented through a display device equipped with a touch screen function rather than a separate input device in consideration of portability. As a result, since a separate physical keypad can be removed, the portable terminal can be miniaturized while pursuing the enlargement of the display device.

As described above, the display apparatus includes a window member to protect the display module while transmitting the screen. Although most of the area of the window member is preferably transparent in order to transmit the screen, an adhesive member such as a double-sided tape or the like is disposed at least at the edge of the window member for mounting the window member to the housing of the portable terminal or the like. It is apparent that a portion of the housing or an adhesive member directly supporting the edge of the window member is also exposed to the outside through the transparent window member. The inner structure of the housing or the adhesive member is concealed by printing the edge of the window member.

FIG. 1 is a cross-sectional configuration diagram showing a window member 10 of a conventional portable terminal. In particular, FIG. 1 shows an enlarged view of an edge portion of the window member 10.

The window member 10 includes a glass member 11, which is manufactured by processing a glass member, preferably tempered glass, and layers printed on edge portions of the glass member 11. As described above, the printing layers, for hiding the adhesive member and the like, include a color layer 17 formed of a colored paint, and the surface of the color layer 17 has a black or gray-based shielding layer ( 19). The shielding layer 19 substantially conceals an adhesive member or the like interposed between the window member 10 and the housing of the portable terminal, and the color layer 17 is decorated when viewed from the outside of the window member 10. Will give an effect.

On the other hand, in order to obtain a gloss effect that can not be implemented only by the color layer 17, the metal oxide layer 15 may be formed on the window member 10. The metal oxide layer 15 is deposited between the glass member 11 and the color layer 17 by depositing a metal oxide such as titanium dioxide (TiO ₂ ), silicon dioxide (SiO ₂ ), aluminum oxide (Al ₂ O ₃ ), or the like. Is formed.

Recently, as the use of portable terminals has become commonplace, the user's taste for the design of portable terminals has gradually diversified. Therefore, efforts have been made to provide various colors or visual effects to the appearance of the portable terminal. However, the window member has a limitation in providing a visual effect other than changing the color even though the print layers are formed at the edge portion. Therefore, the metal oxide layer is used to realize a visual effect that enhances the gloss effect at the edge of the window member.

Accordingly, an aspect of the present invention is to provide a window member of a portable terminal capable of realizing various visual effects using a printing layer formed on an edge of the window member, and a method of manufacturing the same.

In addition, the present invention is to provide a window member and a manufacturing method thereof that can diversify the appearance design of the portable terminal.

Thus, the present invention in the window member of the portable terminal, the glass member; A translucent printing layer formed on the glass member; And a metal layer or a metal oxide layer formed on the translucent print layer, wherein the translucent print layer discloses a window member including irregularities on a surface corresponding to the metal layer or metal oxide layer.

The translucent printing layer is preferably formed by mixing and printing on one surface of the glass member by mixing a transparent paint and a coloring paint.

The translucent printed layer may further include an additive.

The metal oxide layer is preferably formed by mixing and depositing one or two or more of titanium dioxide (TiO ₂ ), silicon dioxide (SiO ₂ ), and aluminum oxide (Al ₂ O ₃ ).

The window member further includes a color layer formed on the metal oxide layer, and the color layer is preferably formed by printing with an achromatic or colored paint.

The window member may further include a shielding layer formed on the metal oxide layer, and the shielding layer may be formed by printing with black or gray paint.

In this case, the window member is further provided with a color layer formed between the metal oxide layer and the shielding layer, the color layer is preferably formed by printing an achromatic or colored paint.

The translucent printed layer may be formed of a plurality of printed layers having different brightness or saturation.

In this case, the terminal may further include a shielding layer formed on the metal oxide layer, and the shielding layer may be formed by printing with black or gray paint.

The terminal may further include a plurality of color layers formed between the metal oxide layer and the shielding layer, and the color layers may be formed of translucent color layers having different brightness or saturation.

In addition, the present invention provides a method for manufacturing a window member of a portable terminal, comprising: processing a glass member; And forming a translucent printing layer on the surface of the glass member, wherein the translucent printing layer is formed by mixing a transparent paint and a color paint to print and harden one surface of the glass member.

The translucent printed layer is preferably formed by further mixing an additive with the transparent paint and the color paint by printing and curing on one surface of the glass member.

The forming of the translucent printed layer may include forming a plurality of printed layers having different brightness or saturation.

The method may further comprise depositing a metal oxide on the surface of the translucent printed layer to form a metal oxide layer.

The metal oxide layer may be formed by depositing one or two or more of titanium dioxide (TiO ₂ ), silicon dioxide (SiO ₂ ), and aluminum oxide (Al ₂ O ₃ ).

The method may further include forming irregularities by processing the surface of the translucent printed layer before forming the metal oxide layer.

The unevenness of the surface of the translucent printed layer may be formed by plasma etching or an additive contained in the translucent printed layer.

The method further includes the step of forming a color layer on the surface of the metal oxide layer, the color layer may be formed by printing an achromatic or colored paint.

The method further includes forming a shielding layer on the surface of the color layer, wherein the shielding layer may be formed by printing with a black or gray paint.

The method further includes forming a plurality of the color layers on the surface of the metal oxide layer, wherein the color layers may be formed translucently with different brightness or saturation.

The method further includes forming a shielding layer on the surface of the metal oxide layer, wherein the shielding layer may be formed by printing with black or gray paint.

The window member configured as described above may provide a ceramic texture in a process in which light incident from the outside passes through the translucent print layer, and in a process in which light reflected from the metal oxide layer passes through the translucent print layer. In addition, in forming the translucent printed layer, a variety of colors can be realized by adding a coloring paint or additive, and when processing the surface of the cured translucent printed layer to form irregularities, it is also possible to imprint a pattern. Various decorations can be provided. Furthermore, in forming the translucent printed layer, when forming a plurality of printed layers having different brightness or saturation, it can have a gradation effect, it is possible to implement a variety of visual effects. Therefore, by mounting the window member according to the present invention to the portable terminal it is possible to diversify the appearance design of the portable terminal.

1 is a cross-sectional configuration view showing a window member of a conventional portable terminal;
2 is a cross-sectional view showing a window member of a portable terminal according to an embodiment of the present invention;
3 is a flowchart illustrating a method of manufacturing the window member shown in FIG. 2;
4 and 5 are cross-sectional configuration views respectively showing modified examples of the window member shown in FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

As shown in FIG. 2, the window member 20 of the portable terminal according to an exemplary embodiment of the present invention has a translucent printing layer 23 formed on one surface of the glass member 21. The metal layer or the metal oxide layer 25, the color layer 27, and the shielding layer 29 may be sequentially disposed on the translucent printing layer 23. In particular, the metal layer or the metal oxide layer 25 may be disposed on the outside. By reflecting the incident light, the visual effect of the translucent printed layer 23 is emphasized. The translucent printed layer 23 provides a ceramic texture through light incident from the outside of the window member 20 and light reflected by the metal oxide layer 25. If the unevenness 24 is formed on the surface of the translucent print layer 23, that is, the surface of the translucent print layer 23 corresponding to the metal oxide layer 25, a pattern using a lattice pattern or the like with a ceramic texture You can implement the effect.

Since the glass member 21 must transmit the screen output from the display module (not shown), the glass member 21 preferably has a transmittance of nearly 100%. Prior to the activation of multimedia services through portable terminals, window members have been relatively inexpensively manufactured using a synthetic resin made of a transparent material such as acrylic. However, the window member made of synthetic resin has a relatively low transmittance, and is vulnerable to damage such as surface scratches. Therefore, in using multimedia services such as video, the window member made of synthetic resin lowers the user's satisfaction.

In recent years, the window member of a portable terminal is produced by processing tempered glass. The glass member 21 has a high transmittance and a high surface hardness and is suitable for use as a window member of a portable terminal. Due to the nature of the glass material, there is a disadvantage in that it is vulnerable to external impacts due to falling, but this is to compensate for the weakness of the glass material by dispersing the impact using a protective film or coating treatment, or a combination structure of the housing and the window member of the portable terminal. have.

The glass member 21 is mounted and fixed to the housing of the portable terminal by an adhesive member such as a double-sided tape. In this case, the color layer 27, the shielding layer 29, and the like conceal the adhesive member between the glass member 21 and the housing, and the translucent printing layer 23 is the color layer 27 or the The ceramic texture is provided on the metal oxide layer 25.

The translucent print layer 23 is formed by mixing and coating a transparent paint and a color paint on one side of the glass member 21, preferably on the inner edge of the glass. In this case, the paint mixture for forming the translucent printing layer 23 may further contain additives such as pigment particles, such as pearl particles. In printing such a paint mixture, silkscreen printing, direct digital printing or pad printing may be used.

In addition, if the unevenness 24 is to be formed on the surface of the translucent printed layer 23, a wet or dry etching method is used. Wet etching is performed through the development and etching process using a photoresist and the like, and dry etching is performed using plasma. Through such a surface processing, the unevenness 24 may be formed on the surface of the translucent print layer 23, and a specific pattern may be formed according to the arrangement of the unevenness 24. However, in the case of the digital printing method, it is also possible to form irregularities on the surface of the translucent printing layer 23 in the printing process. In other words, when the translucent printing layer 23 is formed by a digital printing method, surface processing for forming the unevenness 24 is not necessarily required.

On the other hand, even if the unevenness 24 is not formed by the surface treatment, the color, the haze effect, and the surface roughness of the translucent printed layer 23 are changed depending on the additive of the paint forming the translucent printed layer 23. It is possible to obtain the effect of forming irregularities visually. That is, the translucent printed layer 23 may obtain various visual effects with the translucent printed layer 23 itself by using an additive and a matting agent, as well as mixing the transparent paint and the coloring paint.

The metal oxide layer 25 is formed by depositing a metal or metal oxide on the surface of the translucent printing layer 23. At this time, in order to increase the deposition affinity of the metal oxide, the translucent print layer 23 may also provide a function as a primer. The metal oxide layer 25 may be, for example, by mixing one or two or more of titanium dioxide (TiO ₂ ), silicon dioxide (SiO ₂ ), and aluminum oxide (Al ₂ O ₃ ) to the surface of the translucent printed layer 23. It is formed by vapor deposition on. As mentioned above, the metal oxide layer 25 reflects light incident to the window member 20 from the outside, thereby enhancing the gloss effect.

At least one of the color layer 27 and the shielding layer 29 is preferably formed on the metal oxide layer 25, at least the shielding layer 29. The color layer 27 is formed by printing and curing the surface of the metal oxide layer 25 with an achromatic or colored paint. In addition, the shielding layer 29 is formed by printing and curing black or gray-based paint on the surface of the metal oxide layer 25 or the surface of the color layer 27. The color layer 27 may provide a vivid color at the edge of the window member. However, it is not necessary to form the color layer 27 according to the design of the terminal on which the window member 20 is mounted. That is, if only the color of the translucent printed layer 23 can be matched to the design of the terminal, the shielding layer 29 can be directly formed on the surface of the metal oxide layer 25.

The shielding layer 29 completely blocks the transmission of light at the edge portion of the window member 20. That is, since the translucent printing layer 23 and the metal oxide layer 25 have a transmittance of a certain degree, the semi-transparent printing layer 23 and the metal oxide layer 25 do not sufficiently satisfy the purpose of hiding the adhesive member. Therefore, by forming the shielding layer 29 on the metal oxide layer 25 using a black or gray paint, the adhesive member inside the window member 20 is completely concealed.

As described above, the window member 20 on which the translucent printed layer 23 is formed may implement a ceramic texture through light incident from the outside, and also light reflected by the metal oxide layer 25. In addition, by forming the irregularities 24 on the surface of the translucent printing layer 23, it is possible to implement a variety of visual effects in the edge portion of the window member 20.

3 is a flowchart illustrating a method of manufacturing the window member 20 as described above. The method includes processing the glass member 21 (S1), and then printing the translucent printed layer (1) on one surface of the glass member 21. 23). In describing the method, reference is made to FIG. 2 together.

As mentioned above, the semi-transparent printing layer 23 is formed by mixing and printing on one surface of the glass member 21 by mixing a transparent paint and a color paint (S2). In this case, the paint mixture for forming the translucent printing layer 23 may further include an additive such as pigment particles. The translucent print layer 23 is formed by printing the coating mixture on one surface of the glass member 21 by silkscreen printing, digital printing, pad printing, or the like, and curing the same.

If necessary, the surface of the translucent printing layer 23 is processed to form the unevenness 24 (S2-1). That is, the step (S2-1) of forming the unevenness 24 is performed by wet or dry etching, which is generally performed by a dry etching process such as plasma etching. The unevenness 24 may represent a symbol using a pattern, a letter, etc. continuously arranged a predetermined figure or pattern, a carrier / manufacturer logo, and the like. In addition, if frequently used hot keys such as menu keys or call start / end keys are placed at fixed positions on the window member 20, the unevenness 24 is used to indicate the position and function of these hot keys. You can form letters and patterns. On the other hand, it has been mentioned above that the step (S2-1) of forming the irregularities 24 by processing the surface of the translucent printing layer 23 can be omitted. This means that step S2-1 is selectively performed according to the appearance design of the portable terminal on which the window member 20 is mounted. In the case of forming the translucent printed layer 23, if the digital printing method is used, the translucent printed layer 23 is formed at the same time as the additive contained in the translucent printed layer 23. Since it is possible to form the unevenness 24, a separate surface processing step (S2-1) for forming the unevenness 24 may be omitted.

The metal oxide layer 25 is formed by depositing a metal oxide on the surface of the translucent printing layer 23 (S3). In order to increase the deposition affinity of the metal oxide, the translucent print layer 23 may be used as a primer. As a metal component for forming the metal oxide layer 25, one or two or more of titanium dioxide (TiO ₂ ), silicon dioxide (SiO ₂ ), and aluminum oxide (Al ₂ O ₃ ) are preferably mixed. The metal oxide deposition is performed by disposing the glass member 21 having the translucent printed layer 23 in a deposition chamber. At this time, in depositing the metal oxide on the glass member 21, a separate primer is required to increase the deposition affinity. In a specific embodiment of the present invention, the translucent printing layer 23 is used as a primer to increase the deposition affinity of the metal oxide.

The forming of the color layer 27 (S4) is a process of printing and curing an achromatic or colored paint on the surface of the metal oxide layer 25. By forming the color layer 27, the color of the edge portion of the window member 20 is made more clear. In addition, various colors may be implemented according to the color of the achromatic or chromatic paint forming the color layer 27. However, if the color according to the design of the portable terminal on which the window member 20 is mounted based only on the color implemented through the translucent printing layer 23, the step of forming the color layer 27 may be omitted (S5). .

Forming the shielding layer 29 (S5) is a process of printing and curing a black or gray paint on the surface of the metal oxide layer 25. As mentioned above, since the color layer 27 is not necessarily formed, the shielding layer 29 may be formed directly on the surface of the metal oxide layer 25.

Through the above process, the print layers are formed at the edge portion of the window member, thereby concealing the adhesive member and the like. In addition, the translucent printed layer formed on the window member realizes a ceramic texture by using light incident from the outside, and also reflected by the metal oxide layer. If the irregularities are formed on the surface of the translucent printed layer, the decoration of various patterns is increased. Can be implemented.

4 and 5 show modified examples of the window member shown in FIG. 2, respectively. Compared with the window member of the previous embodiment, the window members shown in FIGS. 4 and 5 respectively differ in that the translucent printed layer or the color layer is composed of a plurality of layers. Therefore, for the components easily understood through the preceding embodiments, the same reference numerals are given or omitted, and the detailed description thereof may be omitted.

The window member illustrated in FIG. 4 forms a translucent printed layer between the glass member and the metal oxide layer, but illustrates the configuration in which the translucent printed layer is formed of a plurality of printed layers. The window member also includes a shielding layer, which is directly formed on the surface of the metal oxide layer. Thus, the window member is illustrated in a configuration without the color layer of the previous embodiment.

As shown in FIG. 4, the translucent printed layer of the window member is composed of a plurality of printed layers, each of which is configured with different brightness or saturation. Specifically, when the print layers constituting the translucent print layer are achromatic colors of white, black, or gray series, brightness may be differently colored. In addition, when the print layers are colored, the chroma may be further colored. Such adjustment of brightness or saturation can be adjusted by the concentration of the color inks combined with the transparent ink, and pearl particles, pigment particles and the like can be added depending on the product design.

The translucent printed layer is repeated at least twice by a method such as silk screen printing, digital printing, pad printing, or the like. At this time, by varying the paint used in each printing process, it is possible to set the brightness or saturation of the printed layers constituting the translucent printed layer differently.

The window member illustrated in FIG. 5 has a configuration in which a plurality of color layers are formed between the metal oxide layer and the shielding layer. The color layer may also be formed by printing a paint combining a transparent ink and a coloring ink. That is, the layer formed between the glass member and the metal oxide layer is referred to as a semi-transparent printing layer, and the layer formed between the metal oxide layer and the shielding layer is described as a 'color layer'. Can be formed in the same manner as the translucent printed layer.

As described above, the translucent printed layer or the color layer is composed of a plurality of translucent layers, but by varying the brightness or the saturation, various visual effects, for example, depth can be provided.

The translucent printed layer may be formed of a plurality of printed layers, or the plurality of color layers may be formed by substantially repeating the process of forming the translucent printed layer or the color layer of the previous embodiment. Therefore, a detailed description of the process of forming the translucent printed layer and the color layer shown in FIG. 4 or 5 will be omitted.

In the foregoing detailed description of the present invention, specific embodiments have been described, but it will be apparent to those skilled in the art that various modifications may be made without departing from the scope of the present invention.

20: window member 21: glass member
23: translucent printed layer 24: unevenness
25: metal oxide layer 27: color layer
29: shielding layer

Claims (21)

In the window member of the portable terminal,
Glass member;
A translucent print layer formed on the glass member by mixing a transparent paint and a color paint, the translucent print layer including a plurality of print layers having different brightness and saturation;
A metal layer or a metal oxide layer formed on the translucent printed layer;
A color layer formed on the metal layer or the metal oxide layer by mixing achromatic or chromatic paint, the color layer including a plurality of printing layers having different brightness and saturation; And
It includes a shielding layer formed on the color layer,
The translucent printed layer includes irregularities on the surface corresponding to the metal layer or the metal oxide layer,
And at least the metal layer or the metal oxide layer of the translucent printing layer, the metal layer or the metal oxide layer, the color layer, and the shielding layer partially reflects incident light.
The window member according to claim 1, wherein the translucent printing layer is formed by printing and curing on one surface of the glass member.
The window member of claim 2, wherein the translucent printed layer further comprises an additive.
The window member of claim 1, wherein the metal oxide layer is formed by mixing and depositing one or two or more of titanium dioxide (TiO ₂ ), silicon dioxide (SiO ₂ ), and aluminum oxide (Al ₂ O ₃ ). .
delete The window member according to claim 1, wherein the shielding layer is formed by printing with a black or gray paint.
delete delete delete delete In the method for producing a window member according to any one of claims 1 to 4 and 6,
Processing the glass member; And
Forming a translucent printing layer on the surface of the glass member,
The translucent printed layer is formed by mixing and printing on one surface of the glass member by mixing a transparent paint and a coloring paint.
12. The method of claim 11, wherein the translucent print layer is formed by further mixing an additive with the transparent paint and the color paint to print and cure one surface of the glass member.
The method of claim 11, wherein the forming of the translucent printed layer comprises forming a plurality of printed layers having different brightness or saturation.
The method of claim 11, wherein
And depositing a metal oxide on the surface of the translucent printed layer to form a metal oxide layer.
The method of claim 14,
The metal oxide layer is formed by mixing and depositing one or two or more of titanium dioxide (TiO ₂ ), silicon dioxide (SiO ₂ ), aluminum oxide (Al ₂ O ₃ ).
The method of claim 14,
Before forming the metal oxide layer, processing the surface of the translucent printed layer to form irregularities.
The method of claim 16, wherein the uneven surface of the translucent printed layer is formed by plasma etching or an additive contained in the translucent printed layer.
The method of claim 14,
Forming a color layer on the surface of the metal oxide layer,
The color layer is formed by printing an achromatic or colored paint.
The method of claim 18,
Forming a shielding layer on a surface of the color layer;
The shielding layer is formed by printing with black or gray paint.
The method of claim 14,
Forming a plurality of color layers on the surface of the metal oxide layer,
The color layers are characterized in that the lightness or saturation are formed translucent and different from each other.
The method of claim 14,
Forming a shielding layer on the surface of the metal oxide layer,
The shielding layer is formed by printing with black or gray paint.

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