KR20130139511A - Electrode wiring structure of touch window - Google Patents

Abstract

The present invention relates to an electrode wiring structure of a touch window and, more specifically, to an electrode wiring structure of a touch window capable of decreasing an error rate and increasing a yield rate by connecting a sensor formed on a display area and an electrode wiring of an area excluding the display area through a bridge type insulation film. [Reference numerals] (AA) Display excluding area;(BB) Display area

Description

Electrode Wiring Structure Of Touch Window {Electrode Wiring Structure Of Touch Window}

The present invention relates to an electrode wiring structure of a touch window, and more particularly, by connecting a sensing sensor formed in a display area with an electrode wiring in an area other than the display through a bridge type insulating film, it is possible to reduce a defective rate and improve a yield. It relates to an electrode wiring structure of a touch window.

The integrated touch window refers to a device in which a touch sensor is directly formed on a rear surface of the window, not a method in which a touch panel manufactured separately from the window is laminated.

The integrated touch window is widely used because a separate touch panel is not laminated so that the thickness of the device can be reduced.

The integrated touch window as described above may be configured in a two-layer method in which the X-axis sensor and the Y-axis sensor are separated into layers to form a detection sensor, and in a one-layer method in which the X-axis sensor and the Y-axis sensor are composed of a single layer. Can be.

In addition, the integrated touch window connects the signal line of the sensing sensor formed in the display area with the electrode wiring of the non-display area (BM area) formed in the edge portion.

FIG. 1 schematically illustrates a structure of a via hole method for connecting a signal line and an electrode line of a sensor of a conventional integrated touch window, and FIG. 2A is an enlarged view of an intersection area of the signal line and the electrode line of FIG. 1. 2B is a cross-sectional view taken along line (A)-(A) 'of FIG. 2A.

1 and 2, a detection sensor is formed in the display area of the rear surface of the window, and the detection sensor is connected to electrode wirings in an area other than the display through signal lines, and to separate and connect the signal lines with electrode wirings. An insulating film is formed over the entire electrode wiring region, and a via hole is formed in the insulating film of each signal line, and then the signal line and the electrode wiring are connected through the via hole.

The via-hole method as described above has the effect of reducing the number of signal lines on the non-display area (BM area), but the process is very complicated, and since wiring is formed on the insulating film, surface smoothness is lowered and sensing sensitivity is lowered.

In addition, since the via holes are patterned in a fine unit, defects and malfunctions such as short circuits are generated and reliability is inferior.

In order to solve the above problems, an object of the present invention can eliminate the via hole process by forming an island-type insulating film only on the region where the signal line and the electrode wiring of the sensing sensor intersect in the region other than the display. Therefore, the present invention provides an electrode wiring structure of a touch window that can increase process efficiency and improve surface smoothness when forming electrode wiring.

In order to achieve the above object, the electrode wiring structure of the integrated touch window according to the present invention is an electrode wiring structure of a touch window having a signal line connecting the sensor sensor formed in the display area and the electrode wiring formed in the non-display area. The electrode wiring may be formed on a partial insulating film partially formed at an intersection region where the signal line and the electrode wiring intersect with each other, and the signal wiring may be connected to the electrode wiring.

The partial insulating layer may be formed in a bridge shape such that an insulating layer is not formed on only one signal line in an intersection region of each electrode line and each signal line among the crossing regions.

In addition, the partial insulating film is blocked by an insulating film on the second to M signal lines of the area where the first electrode wiring intersects the signal lines (first to M signal lines) among the crossing regions, and only the upper part of the first signal line is an insulating film. And the second electrode wiring is blocked by the insulating film on the third to the M signal lines among the regions where the second electrode wiring intersects the signal lines (the second to the M signal lines), and only the upper part of the second signal line is exposed without the insulating film. The shape is repeatedly formed to have a shape in which only the upper portion of the M-1 signal line is exposed without an insulating layer among regions crossing the M-1 electrode wiring.

Meanwhile, the method for manufacturing an electrode wiring structure of an integrated touch window according to the present invention is a method of manufacturing an electrode wiring structure of a touch window having a signal line connecting a sensing sensor formed in a display area and an electrode wiring formed in an area other than the display. Forming a partial insulating film only in an intersection region where the signal line and the electrode wiring intersect, and forming an electrode wiring on an intersection region in which the partial insulating film is formed, wherein the partial insulating film includes one signal line in the intersection region; It is characterized in that the electrode wiring is formed to be connected to each other.

Here, the forming of the partial insulating film is formed in a bridge shape, and is formed by patterning the insulating film not to be formed only on one signal line in the intersection area of each electrode line and each signal line among the crossing areas. do.

As described above, since the electrode wiring structure of the integrated touch window and the method of manufacturing the same according to the present invention exclude the conventional via hole process, the efficiency of production can be increased through the structure design and the process simplification, and the electrode wiring is a partial insulating film. Except it is not formed on the insulating film, it is possible to secure the surface smoothness compared to the conventional via-hole method, there is an excellent effect that can eliminate the resistance increase factor due to the thickness step.

In addition, by solving the limitations of the width and spacing of the bonding pad portion caused in the touch sensor structure having a large number of signal channels, an excellent effect of eliminating the occurrence of short-circuit (open / short) is generated.

FIG. 1 schematically illustrates a structure of a via hole method for connecting a signal line and an electrode line of a sensor of a conventional integrated touch window, and FIG. 2A is an enlarged view of an intersection area of the signal line and the electrode line of FIG. 1. 2B is a cross-sectional view taken along line (A)-(A) 'of FIG. 2A.
3 is a plan view schematically illustrating a bridge-type electrode wiring structure according to a preferred embodiment of the present invention, FIG. 4A is an enlarged view of an intersection area of the signal line and the electrode wiring of FIG. 3, and FIG. 4B is FIG. 4A. (A)-(A) 'is sectional drawing.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

3 is a plan view schematically illustrating a bridge-type electrode wiring structure according to a preferred embodiment of the present invention, FIG. 4A is an enlarged view of an intersection area of the signal line and the electrode wiring of FIG. 3, and FIG. 4B is FIG. 4A. (A)-(A) 'is sectional drawing, and FIG. 5 shows the contact area | region which each signal line and electrode wiring connected in the intersection area of a signal line and electrode wiring.

3 to 5, the detection sensor 10 is formed in a one-layer manner, and the detection sensor has a single specific shape pattern without the distinction between the X-axis and Y-axis sensors, and a signal is connected from the detection sensor. Is formed.

Here, in the 1-layer method, a pattern shape of a sensing sensor may be variously formed according to a design, and when sensing a contact, coordinates of a contacted position may be extracted due to a change in capacitance formed in the sensing sensor. have.

The signal line 20 is responsible for transmitting to a signal processor (not shown) connected to the electrode wire 40. One end of the signal line 20 is connected to the sensing sensor 10 in the display area, and the other end is connected to the electrode wire 40 in the non-display area.

As shown in FIG. 3, the signal line 20 may be connected to the electrode wirings in units of columns, and a plurality of signal line columns may be connected to cross the electrode wirings. Since the number is complicated, shorting is likely to occur, and it is difficult to secure space for wiring.

According to an exemplary embodiment of the present invention, an island-type partial insulating film 30 is formed at an intersection area between the signal line 20 and the electrode wiring 40, and then the electrode wiring 40 is formed on the partial insulating film 30. The line 20 and the electrode wiring 40 are connected.

More specifically, the partial insulating film 30 is formed on the signal line 20, but when the electrode wiring 40 is formed, the partial insulating film 30 is formed so that only one signal line is connected to each electrode wiring.

For example, as shown in FIG. 4B, when one signal line column is composed of four signal lines L1 to L4 and is connected to four electrode wires E1 to E4 vertically intersecting with each signal line, the partial insulating film Is a region where only the first signal line L1 is exposed and the second electrode wiring E2 intersects the second to fourth signal lines among the regions where the first electrode wiring E1 intersects the first to fourth signal lines. Only the second signal line L2 is exposed and only the third signal line L3 is exposed to the third electrode line E3 and the third and fourth signal lines.

Since the fourth electrode wire E4 does not cross other signal lines, an insulating film is not required. When the fourth electrode wire is formed, only the fourth signal line L4 is connected.

Since the partial insulating film 30 is formed as described above, when the electrode wiring 40 is formed on the partial insulating film, the first electrode wiring E1 has the second to fourth signal lines L2 to L4 and the partial insulating film 30 is formed. The connection is cut off by) and only the first signal line L1 is connected, and the second electrode wire E2 is disconnected from the third to fourth signal lines L3 and L4 by the partial insulating layer 30. Connected only to the second signal line L2, the third electrode wire E3 is disconnected from the fourth signal line L4 by the partial insulating layer 30, and connected only to the third signal line L3, and the fourth The electrode wire E4 is connected only to the fourth signal line L4.

Therefore, the signal line and the electrode wiring can be distinguished and connected only by forming the partial insulating film as described above. As a result, the via hole process, which is a complicated process, can be removed, thereby increasing the efficiency of the process.

The partial insulating film may be formed by forming an insulating film on an electrode wiring region and then patterning the same by the photo process to a shape as described above.

In the above embodiment, the cross-sectional area has a step shape so that only one signal line is connected to each electrode line, but in addition, the partial insulating film may be formed in any shape to which only one electrode line and one signal line may be connected. It can be obvious.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

10 detection sensor 20 signal line
30 partial insulating film 40 electrode wiring

Claims (5)

In the electrode wiring structure of the touch window having a signal line connecting the sensing sensor formed in the display area and the electrode wiring formed in the non-display area,
A partial insulating film partially formed only in an intersection region where the signal line and the electrode wiring cross each other;
Electrode wiring is formed on an intersection area where the partial insulating film is formed;
An electrode wiring structure of a touch window, characterized in that one signal line and the electrode wiring is formed to be connected.
The method of claim 1,
The partial insulating film
The electrode wiring structure of the touch window, which is formed in the form of a bridge so that the insulating film is not formed only on one signal line at the intersection of each electrode wiring and each signal line among the crossing regions.
3. The method of claim 2,
The partial insulating film
The first electrode line of the intersection region is blocked by an insulating layer on the second to M signal lines among the regions where the first electrode wiring intersects the signal lines (first to M signal lines), and only the upper part of the first signal line is exposed without the insulating film;
The second electrode wire is blocked by the insulating film on the third to the M signal lines among the areas where the second electrode wiring intersects the signal lines (the second to the M signal lines), and only the upper part of the second signal line is exposed without the insulating film. The wiring structure of the touch window, wherein only the upper portion of the M-1 signal line is formed to be exposed without the insulating layer among the regions crossing the M-1 electrode wiring.
In the manufacturing method of the electrode wiring structure of the touch window having a signal line connecting the sensing sensor formed in the display area and the electrode wiring formed in the non-display area,
Forming a partial insulating film only in an intersection region where the signal line and the electrode wiring cross each other;
Forming electrode wiring on an intersection area in which the partial insulating film is formed;
And wherein the partial insulating layer is formed such that one signal line and one electrode wiring are connected to each other in the crossing area.
5. The method of claim 4,
Forming the partial insulating film
A method of manufacturing an electrode wiring structure of a touch window, which is formed in a bridge shape and is formed by patterning an insulating film on only one signal line in an intersection region of each electrode wiring and each signal line among the crossing regions.

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