KR20120015774A - A touch screen and its manufacturing method - Google Patents

Abstract

PURPOSE: A capacitive touch screen and a manufacturing method thereof are provided to improve the touch reliability and reaction of a touch screen by forming a touch screen on the lower side of a window. CONSTITUTION: A mirror layer(12) is formed on the upper side and the lower side of a window. A touch screen is formed on the lower side of the window. When a display is not operated, a portable terminal is used as a mirror. The mirror is formed on the edge of the lower side of the window, the exposure of the printed circuit board is prevented.

Description

Capacitive touch screen having a half-mirror layer and its manufacturing method {A touch screen and its manufacturing method}

The present invention relates to a capacitive touch screen having a half miller layer and a method of manufacturing the same. More particularly, in the touch screen, a half miller layer made of a non-conductive material is formed on one side of the upper and lower surfaces of the window. The purpose of the present invention is to form a touch screen made of an ITO layer and a printed circuit layer integrally on the lower surface of the window, thereby improving touch reliability and responsiveness of the touch screen and minimizing the thickness of the touch screen module.

In general, a touch screen is to allow an input operation when a user touches a screen displayed through a window without using a separate input device such as a keyboard.

The touch screen as described above is largely classified into a resistive film type and a capacitive type.

In the dual capacitance method, when the surface of the window is touched, the touch screen provided on the bottom of the window detects a change in capacitance value so as to sense a touch position.

The capacitive touch screen as described above has a window formed of glass or plastic of hard material, and the touch screen is attached to the rear surface of the window, so that the touch screen is attached to the bottom of the window. A bubble layer is formed between the screen and the window, and a separate assembly process is required, and the overall thickness becomes thick.

Thus, in the present invention, since the touch screen module is attached to the lower surface of the window as described above, an air bubble layer is formed between the window and the touch screen, thereby reducing touch reliability and responsiveness, and the overall thickness of the touch screen module combined with the window is thick. It is to solve the problem that the manufacturing process is complicated.

That is, in the touch screen, a semi-mirror layer made of non-conductive material is formed on one side of the upper and lower surfaces of the window, and a touch screen made of an ITO layer and a printed circuit layer are integrally formed on the lower surface of the window. will be.

Accordingly, the present invention forms a semi-mirror layer made of non-conductive material on either side of the upper and lower surfaces of the window, and integrally forms a touch screen made of an ITO layer and a printed circuit layer on the lower portion of the window, Touch reliability and responsiveness is improved, and when the display is not operated by the anti-mirror layer, it can be used as a mirror, and the overall thickness of the touch screen module is thinned and the manufacturing process is simplified to reduce productivity and production cost.

1 is a side cross-sectional view showing that a semi-miller layer is formed on an upper surface of a window according to an embodiment of the present invention.
Figure 2 is a side cross-sectional view showing that the anti-mirror layer is formed on the lower surface of the window in one embodiment according to the present invention.
Figure 3 is a side cross-sectional view showing that in one embodiment according to the present invention to form a decorative coating layer of the window and a semi-miller layer on the lower surface of the inner window of the decorative coating layer.
Figure 4 is a side cross-sectional view showing a semi-miller layer and a protective layer formed on the upper surface of the window according to an embodiment of the present invention.
Figure 5 is a process showing that the process of forming a semi-miller layer on the upper surface of the window as an embodiment of the manufacturing method according to the present invention.
Figure 6 is a process showing that the process of forming a semi-miller layer on the lower surface of the window as another embodiment of the manufacturing method according to the present invention.
Figure 7 is a process chart consisting of forming a decorative coating layer of a window as another embodiment of the manufacturing method according to the present invention and forming a semi-miller layer on the lower surface of the inner window of the decorative coating layer.
Figure 8 is a process diagram consisting of forming a semi-miller layer and a protective layer on the upper surface of the window as another embodiment of the manufacturing method according to the present invention.
9 is a process chart consisting of the process of forming the ITO layer of the touch screen only on the inside of the lower surface of the window in the manufacturing method according to the invention.
Figure 10 is a process chart consisting of the process of forming the entire ITO layer of the touch screen on the lower surface of the window in the manufacturing method according to the present invention.

Hereinafter, described in detail by the accompanying drawings as follows.

The present invention is to form a touch screen integrally on the lower surface of the window to improve the touch reliability and responsiveness and to reduce the thickness of the touch screen module.

That is, in the touch screen, the anti-mirror layer 12 made of non-conductive material such as PET and phenol resin is formed on one side of the upper and lower surfaces of the window 11, and the lower part of the window 11 is provided. The touch screen composed of the ITO layer 21 and the printed circuit layer 22 is formed integrally.

Here, the anti-mirror layer 12 is formed on the entire upper surface of the window 11, formed on the entire lower surface of the window 11, and the paint decoration part 31 is formed on the lower edge of the window 11. It can be carried out by selectively forming any one of the one formed in the center portion is formed and the coating decorative portion 31 is not formed.

 If the anti-mirror layer 12 is formed on one of the upper and lower surfaces of the window 11 as a whole, the mobile terminal to which the present invention is applied may be used as a mirror when the display is not operated, and the anti-mirror layer 12 may be used. If formed only on the bottom edge of the window, the transmittance of the display is increased to improve the sharpness of the display and to prevent the exposure of the printed circuit layer 22.

In addition, a scattering protection layer 41 is formed on either side of the bottom surface of the touch screen including the ITO layer 21 and the printed circuit layer 22 and the top surface of the window 11 to prevent scattering during breakage.

In addition, the antireflection layer 42 for minimizing light reflection by using a refractive index deviation on the upper surface of the window 11 to improve light transmittance, and applying a foreign material adhesion prevention material such as Teflon and silicon to prevent fingerprints on the window It can be carried out by forming the anti-fingerprint layer 43.

Hereinafter, the manufacturing method of the touch screen according to the present invention will be described.

The present invention is a semi-miller layer forming process 111 to apply a semi-miller material consisting of a non-conductive material such as PET and phenol resin on one side of the upper and lower surfaces of the window to form a semi-miller layer 12, Through the semi-mirror layer forming process 111, a touch screen forming process of integrally coating and forming a touch screen made of the ITO layer 21 and the printed circuit layer 22 on the anti-mirror layer 12 and the window 11 integrally. It is done.

Here, the semi-miller layer forming process 111 is formed by applying a semi-miller material made of a non-conductive material on the entire upper surface of the window 11, a semi-miller material made of a non-conductive material on the entire lower surface of the window 11 And a non-conductive material formed at a portion where the paint decoration part 31 is not formed by forming the paint decoration part 31 through the paint decoration part painting process 112 on the lower edge of the window 11. Any one of the methods made by applying a semi-miller material consisting of is made selectively.

In addition, the touch screen forming process 120 is an ITO layer forming process 121 for forming an ITO layer 21 by applying an ITO material to the bottom surface of the window 11 and then processing the edge of the ITO layer 21. A printed circuit layer forming process 122 for forming a printed circuit layer 22 on the surface, wherein the ITO layer forming process 121 is formed by coating the entire lower surface of the window, the printed circuit layer 22 of the lower surface of the window Except for the edge portion is formed, any one of the methods formed by forming can be carried out selectively.

In addition, in the practice of the present invention, a scattering protective layer for preventing scattering during breakage on any one of the lower surface of the touch screen consisting of the ITO layer 21 and the printed circuit layer 22 and the upper surface of the window 11 ( 41) and the antireflection layer 42 which minimizes light reflection by using a refractive index deviation on the upper surface of the window 11 to improve light transmittance, and an anti-fogging material such as Teflon and silicone is applied to the window. The protective layer forming process 130 for forming the anti-fingerprint layer 43, which prevents fingerprints from being buried, may be further performed.

Accordingly, the present invention forms a semi-mirror layer made of a non-conductive material on the lower surface of the window and integrally forms a touch screen made of an ITO layer and a printed circuit layer under the semi-mirror layer, thereby reducing touch reliability and responsiveness of the touch screen. This improved, semi-mirror layer can be used as a mirror when the display does not operate, and the overall thickness of the touch screen module is reduced and the manufacturing process is simplified, thereby reducing productivity and production cost.

On the other hand, by forming a paint decoration on the bottom edge of the window and forming a semi-mirror layer only in the center portion where the paint decoration is not formed, the step between the ITO layer and the printed circuit layer which are sequentially stacked is prevented.

11: Windows 12: anti-miller layer
21: ITO layer 22: printed circuit layer
31: Paint decoration part
41 scattering protective layer 42 antireflection layer 43 anti-fingerprint layer
111: anti-miller layer formation process
112: painting process
120: touch screen forming process
121: ITO layer formation process 122: Printed circuit layer formation process
130: protective layer formation process

Claims (7)

In the touch screen,
A semi-mirror layer formed of a non-conductive material is formed on one side of the upper and lower surfaces of the window, and a touch screen made of an ITO layer and a printed circuit layer is integrally formed on the bottom of the window. Capacitive touch screen having a semi-miller layer.
The method of claim 1;
The semi-mirror layer is formed on the entire upper surface of the window, formed on the entire lower surface of the window, and formed on the center of the lower surface of the window and the paint decoration portion formed on the center portion where the paint decoration portion is not formed. Capacitive touch screen having a semi-miller layer, characterized in that one selected.
The method according to claim 1 or 2,
An anti-reflective layer that forms a scattering protection layer that prevents scattering upon breakage on any one of a lower surface of the touch screen including the ITO layer and the printed circuit layer, and minimizes light reflection on the upper surface of the window. And a semi-mirror layer, wherein the anti-fingerprint layer is formed by applying an anti-fogging material to prevent adhesion of oil and foreign substances.
In the manufacturing method of the touch screen;
A semi-miller layer forming process for applying a semi-miller material made of a non-conductive material to form a semi-miller layer on the lower surface of the window, and a touch formed of an ITO layer and a printed circuit layer on the semi-miller layer through the semi-miller layer forming process. The method of manufacturing a capacitive touch screen having a semi-miller layer, characterized in that consisting of a touch screen forming process of coating the screen integrally with the window.
5. The method of claim 4,
The anti-miller layer forming process
By applying a semi-miller material made of a non-conductive material to the entire upper surface of the window,
It is made by applying a semi-mirror material made of non-conductive material to the entire lower surface of the window,
The paint decorative part is formed on the bottom edge of the window through a painting process, and the anti-mirror material made of a non-conductive material is applied to the portion where the paint decoration is not formed. A method of manufacturing a capacitive touch screen having a semi-mirror layer.
4. The method of claim 3, further comprising:
The process of forming the touch screen includes an ITO layer forming process for forming an ITO layer by applying an ITO material to a semi-miller layer, and a printed circuit layer forming process for forming a printed circuit layer on the edge of the ITO layer.
The ITO layer forming process is a half-mirror layer, characterized in that the coating is formed on the lower surface of the window as a whole, and any one of the method is formed by removing the edge of the printed circuit layer formed on the lower surface of the window selectively Method of manufacturing a capacitive touch screen.
The method of any one of claims 4 to 6;
An anti-reflective layer that forms a scattering protection layer that prevents scattering upon breakage on any one of a lower surface of the touch screen including the ITO layer and the printed circuit layer, and minimizes light reflection on the upper surface of the window. The method of manufacturing a capacitive touch screen having a semi-miller layer, characterized in that the protective layer forming process for forming a fingerprint prevention layer to prevent fingerprints on the window by applying an anti-fog foreign matter adhesion material.

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