KR20130109528A - Touch panel sensor - Google Patents

Abstract

PURPOSE: A touch panel sensor is provided to prepare an organic compound coating layer with a flat top surface on a glass substrate in which a transparent electrode pattern is formed, and provide an optically clear adhesive (OCA) layer on the glass substrate, thereby neatly bonding the organic compound coating layer and a reinforced glass substrate without voids. CONSTITUTION: A glass substrate (120) is disposed under a reinforced glass substrate (110), and has a transparent electrode pattern to sense a contact position. An organic compound coating layer (130) covers the transparent electrode pattern on the glass substrate and has a flat top surface. An OCA layer (140) is provided between the reinforced glass substrate and the glass substrate to bond the reinforced glass substrate and the glass substrate The organic compound coating layer includes a UV curing agent or a thermal curing agent, and is formed by being hardened after provided as a liquid form on the glass substrate.

Description

Touch Panel Sensor {TOUCH PANEL SENSOR}

The present invention relates to a touch panel sensor capable of sensing a contact position of an object such as a finger.

1 is a perspective view illustrating a conventional capacitive touch panel sensor.

1, in a conventional touch panel sensor 1, a lower insulating sheet 10 and an upper insulating sheet 20 are bonded to each other with a predetermined gap therebetween. The lower ITO electrode 30 and the upper ITO electrode 40 are vertically arranged on the opposite surfaces of the lower insulating sheet 10 and the upper insulating sheet 20, respectively.

In order to electrically connect the upper ITO electrode 40 and the terminal 52 of the flexible circuit board 50, a metal wire 48 extends from the end of the upper ITO electrode 40 to the lower portion of the upper insulating sheet 20. The lower ITO electrode 30 is also electrically connected to the circuit board 50 by a separate metal wire 38.

However, the metal wires 38 and 48 may be visually identified from the upper portion of the upper insulating sheet 20 that is shiny with metallic luster. Therefore, in order to prevent the metal wires 38 and 48 and the circuit board 50 from being visible, a non-transmissive window decoration 65 is formed on the bottom surface of the reinforcing substrate 60, and the upper substrate 60 is insulated. It is disposed on the sheet 20.

In addition, an optical adhesive layer may be interposed between the reinforcing substrate 60, the upper insulating sheet 20, and the lower insulating sheet 10 to bond adjacent substrates and sheets to each other. However, the upper ITO electrode 40 or the lower ITO electrode 30 is formed on the surfaces of the upper insulating sheet 20 and the lower insulating sheet 10 that face each other, so that the surface thereof is not smooth, and the optical adhesive layer is hardly adhered thereto. You may not. That is, since the electrodes laid on the insulating sheet actually prevent the optical adhesive layer and the sheet from intimately contacting each other, there is a possibility that the state of mutual bonding may be poor when used for a long time. Then, air may enter between the electrode and the optical adhesive layer, which may affect oxidation or corrosion of the electrode. In addition, excessive bubbles may distort an image of a flat panel display such as a liquid crystal display, a plasma display panel, and an organic light emitting diode under the touch panel sensor. have.

The present invention provides a touch panel sensor that can improve the adhesion state of the insulating substrate and the other substrate on which the transparent electrode is formed.

The present invention provides a touch panel sensor capable of protecting the transparent electrode from chemical corrosion such as physical shock or oxidation.

The present invention provides a touch panel sensor capable of minimizing image distortion of a flat panel display.

According to an exemplary embodiment of the present invention for achieving the above object of the present invention, the touch panel sensor for detecting the contact position of the object, the tempered glass substrate; A glass substrate disposed under the tempered glass substrate and having a transparent electrode pattern configured to detect a contact position of a body on an upper surface thereof; An organic coating layer provided on the glass substrate to cover the transparent electrode pattern and having a flat upper surface; And an optical adhesive layer provided between the tempered glass substrate and the glass substrate, and bonding the tempered glass substrate and the glass substrate.

In the case of the conventional touch panel sensor as shown in FIG. 1, an optical adhesive layer in the form of a film may be used to bond the substrate on which the transparent electrode formed of the same material as ITO is disposed with another substrate. Silver is not smooth, and the optical adhesive layer may not be adhered well. For this reason, air may enter between the electrode and the optical adhesive layer, so that the state of mutual bonding may be poor when used for a long time, and oxidation or corrosion of the electrode may occur. have. In addition, when bubbles are excessively interrupted, the image of the flat panel display device positioned under the touch panel sensor may be distorted.

However, in the touch panel sensor according to the present invention, by providing an organic coating layer having a flat top surface on the glass substrate on which the transparent electrode pattern is formed, and providing an optical adhesive layer thereon, the organic coating layer and the tempered glass substrate are cleanly bonded without bubbles. can do.

Furthermore, since the organic coating layer is provided in a liquid phase on the glass substrate and then cured, there is little room for air bubbles to enter between the transparent electrode pattern provided on the glass substrate and the organic coating layer, thereby preventing corrosion of the transparent electrode pattern. The transparent electrode pattern which is prevented and covered by the organic coating layer does not break easily due to easy impact, and even if it is broken, it is possible to maintain the original position by the organic coating layer, so it is a failure such as sudden stop of operation of the touch panel sensor. Can be prevented.

For reference, the organic coating layer described above may be cured through ultraviolet rays or heat after being applied in a liquid phase on a glass substrate, including an ultraviolet curing agent or a thermal curing agent.

In addition, the transparent electrode pattern according to the present invention is provided in a single layer pattern on one surface of the glass substrate, rather than the ITO electrode in the horizontal direction and the vertical direction is disposed on different substrates as in the conventional touch panel sensor shown in FIG. It is preferable.

For example, the transparent electrode pattern may include a plurality of vertical electrode patterns including a plurality of vertical node pattern portions and a vertical connection portion connecting the vertical node pattern portions in a row, and arranged in parallel in a horizontal direction; And a plurality of horizontal electrode patterns that are separated from each other and are electrically connected to each other, and include a plurality of horizontal node pattern portions disposed adjacently between the vertical node pattern portions and horizontal connecting portions respectively connected to the horizontal node pattern portions. The connection part and the horizontal connection part may be electrically connected to an external flexible circuit board. For reference, horizontal and vertical herein do not mean a specific direction, it can be understood to have a meaning that the two directions are perpendicular or approximately vertical.

The touch panel sensor according to the present invention provides an organic coating layer having a flat top surface on a glass substrate on which a transparent electrode pattern is formed, and then provides an optical adhesive layer thereon, whereby the organic coating layer and the tempered glass substrate can be bonded cleanly without bubbles. In the end, the bonding state of the glass substrate and the tempered glass substrate can be improved.

In addition, in the touch panel sensor according to the present invention, the organic coating layer is once provided in a liquid phase on the glass substrate, and hardened, so that there is little room for air bubbles to enter between the transparent electrode pattern provided on the glass substrate and the organic coating layer. Corrosion of the transparent electrode pattern may be fundamentally prevented, and image distortion of the flat panel display device disposed below by bubbles may be prevented.

In addition, in the touch panel sensor according to the present invention, the organic coating layer protects the transparent electrode pattern so that the transparent electrode pattern is not easily broken by an easy impact, and even if broken, it is possible to maintain the original position by the organic coating layer. It is possible to prevent failures such as panel sensor stoppage.

1 is a perspective view illustrating a conventional capacitive touch panel sensor.
2 is an exploded perspective view of a touch panel sensor according to an embodiment of the present invention.
3 is a cross-sectional view of a touch panel sensor according to an embodiment of the present invention.
4 is a view for explaining a process of forming an organic coating layer in the present invention.
5 is a front view of a glass substrate of a touch panel sensor according to an embodiment of the present invention.

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 and can be described with reference to the contents described in the other drawings under these rules, and the contents which are judged to be obvious to the person skilled in the art or repeated can be omitted.

The present invention relates to a touch panel sensor for detecting a contact position of a part of the body used in the touch screen.

2 is an exploded perspective view of a touch panel sensor according to an embodiment of the present invention, Figure 3 is a cross-sectional view of the touch panel sensor according to an embodiment of the present invention, Figure 4 is a process for forming an organic coating layer in the present invention 5 is a front view of a glass substrate of a touch panel sensor according to an exemplary embodiment of the present invention.

2 to 5, the touch panel sensor 100 includes a tempered glass substrate 110, a glass substrate 120, an organic coating layer 130, and an optical adhesive layer 140.

The tempered glass substrate 110 is disposed at the top of the object, such as a user's finger or a touch pen, in direct contact or access, and the transparent tempered glass substrate 110 has a non-transparent window decoration 112 along the edge thereof. ) May be arranged.

In addition, the glass substrate 120 may be provided with the same glass material as the strength is relatively lower than that of the tempered glass substrate 110, is disposed below the tempered glass substrate 110, and has a light transmitting property.

Meanwhile, tempered glass, which is a material of tempered glass substrate, is a special glass that improves mechanical strength by special heat treatment due to high heat, and its strength is 3 to 5 times higher than that of general glass, but it has a disadvantage in that manufacturing cost is high. . Therefore, it may be considered to be used as a material of the tempered glass substrate 110 disposed on the uppermost layer. However, since the glass substrate 120 is protected by the tempered glass, it is possible to use general glass having a low cost.

Basically, the transparent electrode pattern 160 is disposed on the upper surface of the insulating glass substrate 120, and the transparent electrode pattern 160 has indium tin oxide (ITO) or indium zinc oxide (IZO), It may be provided using Al-doped Tin Oxide (ATO), Al-doped Zinc Oxide (AZO), carbon nanotubes (CNT) and the like.

The two tempered glass substrates 110 and the glass substrate 120 described above may be bonded through the optical adhesive layer 140. The optical adhesive layer 140 may use an OCA (Optically Clear Adhesive) film, and by using this, both substrates may be optically excellently attached.

Here, when the optical adhesive layer 140 in the form of a film is bonded onto the glass substrate 120 having a transparent electrode pattern 160 on which the surface is not smooth, bubbles are formed between the optical adhesive layer 140 and the glass substrate 120. May remain. Specifically, bubbles may remain along the boundary between the transparent electrode pattern 160 and the glass substrate 120 shown in portion “A” of FIG. 4.

In particular, since the thickness of the transparent electrode pattern 160 decreases as the thickness of the transparent electrode pattern 160 increases, the thickness of the transparent electrode pattern 160 can increase the likelihood that bubbles remain in the “A” portion. However, in the present invention, after providing a separate organic coating layer through an inkjet, silk printing, or spray method, an optical adhesive layer may be provided on it to minimize the possibility of bubble generation.

However, the touch panel sensor 100 according to the present exemplary embodiment provides the organic coating layer 130 that provides the flat upper surface 132 on the glass substrate 120 on which the transparent electrode pattern 160 is formed, and the optical thereon. By providing the adhesive layer 140, the organic coating layer 130 and the tempered glass substrate 110 may be cleanly bonded without bubbles.

In addition, the organic coating layer 130 is once provided in a liquid phase on the glass substrate 120, and then cured to form bubbles between the transparent electrode pattern 160 and the organic coating layer 130 provided on the glass substrate 120. There is little room for this, and thus the corrosion of the transparent electrode pattern 160 may be prevented at the source, and the transparent electrode pattern 160 covered by the organic coating layer 130 may not be easily broken by an impact. Even if it is broken, since the original position can be maintained by the organic coating layer 130, it is possible to prevent a failure such as sudden stop of operation of the touch panel sensor 100.

The organic coating layer described above may be coated on a glass substrate, including an ultraviolet curing agent or a thermosetting agent, and then cured through ultraviolet rays or heat. In this embodiment, the organic coating layer 130 includes an ultraviolet curing agent, As shown in FIG. 4, the glass substrate 120 may be coated on the glass substrate 120 and then cured by ultraviolet rays.

In addition, the transparent electrode pattern 160 according to the present invention does not arrange the ITO electrodes in the horizontal direction and the vertical direction on the different substrates as in the conventional touch panel sensor illustrated in FIG. 1, and has a single layer pattern on one surface of the glass substrate. Can be provided as

In detail, the transparent electrode pattern 160 has a vertical electrode pattern 170 and a horizontal electrode pattern 180. Referring to FIG. 5, the upper surface of the glass substrate 120 has an x position at which an object is in contact with or approaches. The vertical electrode patterns 170 are arranged side by side in the horizontal direction in the drawing so as to check the coordinates. The three vertical electrode patterns 170 arranged about three may have six vertical node pattern parts 172 arranged up and down, respectively. In the drawing, the vertical node pattern unit 172 may be provided in a rhombus or quadrangle form based on one vertical line. The vertical node pattern portions 172 forming a line are electrically connected by vertical connecting portions 174 disposed therebetween, and the vertical node pattern portions 172 and the vertical connecting portions 174 are formed on the glass substrate 120. It can be provided by laying the ITO as a whole and patterning it. Of course, the number of vertical electrode patterns or the number of vertical node pattern portions constituting the vertical electrode patterns may be changed as much as possible to add or subtract a touch feeling.

In addition, the horizontal electrode pattern 180 capable of confirming the y coordinate of the position at which the object is in contact or approaching has a series of horizontal node pattern portions 182 disposed between the vertical node pattern portions 172. Each horizontal node pattern portion 182 is electrically separated from each other, each extending by the horizontal connection portion 184 to the lower end of the glass substrate 120 in the drawing. For reference, the horizontal node pattern portion or the horizontal connection portion, the aforementioned vertical node pattern portion, and the vertical connection portion may be provided at once by patterning the ITO on the glass substrate 120 as a whole. For reference, various etching liquids can be used in the patterning process for forming the electrode. The glass on which the electrode is formed is chemically stable, so the patterning process is easy, and compared to the tempered glass, the cutting, edge or surface finish is easy, and the weight is also increased. It is light and convenient in the manufacturing process.

Since the vertical connection part 174 and the horizontal connection part 184 are disposed in the touch area of the touch panel sensor, the vertical connection part 174 and the horizontal connection part 184 are preferably made of a transparent material, and the metal part such as silver paste is disposed at the edge part where the window decoration 112 is disposed. The electrode line 190 may be provided to be electrically connected to the vertical and horizontal electrode patterns, and the electrode line 190 may be connected to an external circuit such as the flexible circuit board 150. For reference, in the lower part of FIG. 5, the flexible circuit board may be bonded to each other using the anisotropic conductive film (ACF) corresponding to the electrode line 190. In this region, the organic coating layer may be uncoated.

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

100: touch panel sensor 110: tempered glass substrate
120: glass substrate 130: organic coating layer
140: optical adhesive layer 150: flexible circuit board
170: vertical electrode pattern 172: vertical node pattern portion
180: horizontal electrode pattern 182: horizontal node pattern portion
184: horizontal connection section 190: electrode wire

Claims (5)

In the touch panel sensor for detecting the contact position of the object,
Tempered glass substrate;
A glass substrate disposed under the tempered glass substrate and having a transparent electrode pattern formed on an upper surface thereof to detect a contact position of a body;
An organic coating layer provided on the glass substrate to cover the transparent electrode pattern and having a flat upper surface; And
An optical adhesive layer provided between the tempered glass substrate and the glass substrate and bonding the tempered glass substrate and the glass substrate;
Wherein the touch panel sensor comprises: The method of claim 1,
The organic coating layer is a touch panel sensor, characterized in that it comprises an ultraviolet curing agent or a thermal curing agent. The method of claim 1,
The organic coating layer is a touch panel sensor, characterized in that formed after the liquid treatment on the glass substrate, is formed by curing. The method of claim 1,
The transparent electrode pattern is a touch panel sensor, characterized in that provided in a single layer pattern. 5. The method of claim 4,
The transparent electrode pattern,
A plurality of vertical electrode patterns including a plurality of vertical node pattern portions forming a row and a vertical connection portion connecting the vertical node pattern portions in a row, and arranged side by side in a horizontal direction; And
A plurality of horizontal electrode patterns separated from each other by electrodes and including a plurality of horizontal node pattern portions disposed adjacent to each other between the vertical node pattern portions and horizontal connecting portions respectively connected to the horizontal node pattern portions;
Wherein the touch panel sensor comprises:

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