KR20110128133A - Touch sensor and the manufacturing method with combination of pet layer and tempered glass layer for a touch screen - Google Patents

Abstract

PURPOSE: A touch sensor and a manufacturing method with the combination of a pet layer and tempered glass layer for a touch screen are provided to improve the productivity of the touch screen by enforcing an ACG bonding one time. CONSTITUTION: A Y-coordinate bonding pad(230) is connected to a Y-coordinate pattern(220) and patterns the bonding pad area with a sliver link on the upper surface of a PET(Polyethylene Terephthalate) layer(210). An X-coordinate trace, an X-coordinate combination pad(140), and a FPC(Flexible Printed Circuit) bonding pad(150) are connected to a X-coordinate pattern on the upper surface of the reinforced glass layer(110) and is comprised of a CR material. The X/Y-coordinate combination pad is connected by using an ACF(Anisotropic Conductive Film)(320). The FPC combination pad is connected to a FPC(300).

Description

TOUCH SENSOR AND THE MANUFACTURING METHOD WITH COMBINATION OF PET LAYER AND TEMPERED GLASS LAYER FOR A TOUCH SCREEN}

The present invention relates to a composite touch sensor required for manufacturing a touch screen sensor and a method for manufacturing the same, and in particular, an FPC bonding pad formed on any one of a PET layer or a tempered glass layer, and an FPC connected by performing only one ACF bonding. It can greatly improve the work efficiency, significantly reduce the defect rate by reducing the alignment error generated in the ACF bonding process, and also minimize the ACF bonding area, improving design ease and greatly improving the performance of the touch sensor. The present invention relates to a touch screen PET and a tempered glass layer composite touch sensor and a method of manufacturing the same.

In general, a touch screen is an input device that does not use an input device such as a keyboard or a mouse, and detects the position of a person's hand or an object on a character or a specific location on the screen to process a specific function. It can be operated by touching the screen directly, there is an advantage such as high operation efficiency, convenience.

As described above, the touch sensor is configured to include a touch panel and a protective layer on which a circuit pattern of an ITO electrode patterned in a specific shape is formed on a substrate such as PET film or glass. The protective layer is attached on top of the touch sensor to prevent contamination from external factors on the touch panel.

An important characteristic of such a touch sensor is that ACF is connected to an electrode pad to supply power to signal lines of FPC (Flexible Print Circuit) provided on one axis of the touch panel before attaching the touch panel to the top of various displays. After bonding, selectively select the various positions on the upper side of the touch panel and analyze the equipotential and equipotential values for each position to determine whether the touch panel is suitable for detecting touch motion. Will be evaluated.

1 is a rear view of the conventional hybrid sensor 1. Referring to this, the upper surface of the tempered glass layer 10 is connected to the x coordinate pattern and the x coordinate traces to form the x coordinate bonding pad 50, and the y coordinate pattern 30 and y coordinate on the upper surface of the PET layer 20. The y-coordinate bonding pad 40 is connected to the trace.

In addition, after bonding the tempered glass layer 10 and the PET layer 20 by performing a laminating process, ACF bonding is primarily performed for the connection between the x-coordinate bonding pad 50 and the FPC 60, In order to connect the y-coordinate bond pad 40 and the FPC 60, ACF bonding is performed secondarily.

At this time, an alignment error occurs during the laminating process between the tempered glass layer 10 and the PET layer 20, and thus, the x coordinate bonding pad 50 and the FPC 60, or the y coordinate bonding pad 40 and the FPC 60. There is a problem in that the defective rate is increased due to an error due to the lamination alignment error in the ACF bonding process between the two, causing quality degradation.

In addition, the AC coordinate with the FPC 60 due to the x coordinate bonding pad 50 configured on the upper surface of the tempered glass layer 10 and the y coordinate bonding pad 40 configured on the upper surface of the PET layer 20. Due to the problem of bonding twice, there are problems in working time and production efficiency.

The present invention has been proposed to solve the above problems, the object is to change the existing composite sensor design so that there is no FPC bonding pad connected to the FPC on the PET layer upper surface, only FPC bonding pad configured on the upper surface of the tempered glass layer ACF bonding is performed only once by connecting only FPC and FPC to maximize the work efficiency through shortening of work process, and drastically reduce the alignment error between tempered glass layer and PET layer. The present invention provides a touch screen PET, a tempered glass layer composite touch sensor, and a method of manufacturing the same.

According to an aspect of the present invention,

In the complex sensor required for manufacturing the touch screen sensor,

PET layer and tempered glass layer in which Indium Tin Oxide (ITO) or Antimony Thin Oxide (ATO) is formed;

A y coordinate bonding pad formed by patterning a bonding pad region with silver ink on an upper surface of the PET layer and connected to a y coordinate pattern; And

Includes; x coordinate traces, x coordinate bonding pads and FPC bonding pads connected to the x coordinate pattern on the upper surface of the tempered glass layer and composed of Cr material,

The x coordinate bonding pad is connected to the FPC bonding pad on the upper surface of the tempered glass layer, the x coordinate bonding pad and the y coordinate bonding pad are formed at the same position on the upper surface of the PET layer and the upper surface of the tempered glass layer, and the x coordinate bonding While the pad and the y-coordinate bonding pad are connected to the ACF, the FPC bonding pad on the upper surface of the tempered glass layer is connected to the FPC.

The ITO or ATO film is characterized in that formed in substantially the same area on the PET layer and the tempered glass layer.

When the y-coordinate bonding pad is formed, a transparent conductive electrode is formed by performing a patterning process using a transparent conductive material including ITO.

In forming the x-coordinate trace, the x-coordinate bond pad, and the FPC bond pad, a material having excellent conductivity, including a transition metal, is selected and a patterning process is performed to form a pattern.

The PET layer is characterized in that the number and arrangement of the y-coordinate bonding pads connected to the y-coordinate pattern is selectively designed as needed.

The tempered glass layer is characterized in that the number and arrangement of the x-coordinate pattern, x-coordinate trace, x-coordinate bonding pad and FPC bonding pad on the upper surface is selectively designed as needed.

The PET layer is characterized by selectively designing a plurality of x-coordinate traces, x-coordinate bonding pads and FPC bonding pads on the upper surface.

The tempered glass layer is characterized by consisting of a y-coordinate pattern and a y-coordinate bonding pad on the upper surface.

The position of the x-coordinate bonding pad and the y-coordinate bonding pad may be designed at different positions as necessary.

The x-coordinate bonding pad and the y-coordinate bonding pad are ACF bonded in a process for adhesion including an ACA layer.

The FPC bonding pad may be located on an upper surface of the PET layer and is designed to be configured of a plurality of pads.

According to an aspect of the present invention,

Preparing a PET layer and a tempered glass layer in which Indium Tin Oxide (ITO) or Antimony Thin Oxide (ATO) is formed;

Patterning a bonding pad region with silver ink on an upper surface of the PET layer to form a y coordinate bonding pad and connecting the y coordinate pattern;

An x coordinate trace, an x coordinate bonding pad, and an FPC bonding pad are formed on the upper surface of the tempered glass layer, and the x coordinate pattern and the x coordinate trace are connected to an FPC bonding pad, and the x coordinate bonding pad is an FPC. Connecting with a bonding pad;

Connecting the x coordinate bonding pads and the y coordinate bonding pads formed at the same positions on the upper surface of the PET layer and the upper surface of the tempered glass layer; And

Connecting the FPC bonding pad to the FPC; forming an ITO pattern, that is, an x coordinate pattern, an x coordinate bonding pad and an FPC bonding pad, on the upper surface of the tempered glass layer, and an ITO pattern on the PET layer. Forming a y-coordinate pattern, y-coordinate bonding pad, and provides a method for manufacturing a touch screen PET and tempered glass layer composite touch sensor, characterized in that one FPC bonding pad is produced by performing an FPC and ACF bonding process. .

The tempered glass layer and the PET layer is characterized in that it is manufactured to perform a laminating process therebetween.

The PET layer is produced by performing a laminating process using a laminator equipment for adhering the OCA film on its upper surface.

The tempered glass layer has an ACA layer on the PET layer upper surface to perform the connection between the x coordinate bonding pad located on the bottom surface and the y coordinate bonding pad located on the upper surface of the PET layer. Characterized in that produced by performing the AC coordinate bonding process with the x-coordinate bonding pad is located.

The tempered glass layer is characterized by being produced by performing the ACF bonding process with the FPC by placing the ACF on the FPC bonding pad located on the upper surface.

In the touch screen PET and tempered glass layer composite touch sensor according to the present invention, the y coordinate pattern and the y coordinate bonding pad are formed on the upper surface of the PET layer, and the x coordinate pattern and the x coordinate trace on the upper surface of the tempered glass layer. Is connected to the FPC bonding pad, the x coordinate bonding pad is connected to the FPC bonding pad, and the y coordinate bonding pad on the upper surface of the PET layer is designed to be connected to the x coordinate bonding pad on the upper surface of the tempered glass layer.

Therefore, according to the present invention, there is no FPC bonding pad connected to the FPC on the upper surface of the PET layer, and only one time of ACF bonding that connects the FPC bonding pad and the FPC formed on the upper surface of the tempered glass layer is performed only once. And due to the reduction of the defective rate it is possible to greatly improve the productivity of the touch screen.

Thus, according to the present invention, the work efficiency can be maximized by shortening the ACF bonding process connecting the pad with the FPC by one time, and the effective micro pattern can be formed on the upper surface of the tempered glass layer, thereby making the pad area smaller. In addition, the ACF bonding process can be carried out even in a space where the customer's product design is narrow, and the tempered glass material is advantageous in the process for enhancing the adhesive strength, and the peel strength can be greatly increased.

In addition, according to the present invention, since the FPC bonding pad is formed only on the upper surface of the tempered glass layer, by reducing the ACF bonding process for the connection with the FPC, it is possible to drastically reduce the alignment error that may occur, thereby generating a defective rate due to electrical short. It is easy to manufacture a high quality touch panel by removing.

In particular, the present invention can be applied to a composite touch sensor using any substrate as a method for manufacturing a touch sensor.

1 is a rear view of a design drawing of a conventional hybrid touch sensor.
2 is a rear view of a PET for a touch screen and a tempered glass layer composite touch sensor according to the present invention.
3 is a sensor design diagram configured on the upper surface of the tempered glass layer provided in the touch screen PET and the tempered glass layer composite touch sensor according to the present invention.
Figure 4 is a sensor design diagram configured on the upper surface of the PET layer provided in the PET for touch screen and the tempered glass layer composite touch sensor according to the present invention.
5 is a cross-sectional view of a PET for a touch screen and a tempered glass layer composite touch sensor according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the examples, but the examples are used only for the purpose of illustration and description of the present invention, and are used to limit the scope of the present invention described in the meaning limitation or the claims. no. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from the embodiments. Therefore, the true technical protection scope of the present invention will be defined by the technical details of the claims.

First, FIG. 2 illustrates a touch screen PET and tempered glass layer composite touch sensor 100 according to the present invention.

2 to 4, the touch screen PET and tempered glass layer composite touch sensor 100 according to the present invention may include a tempered glass layer 110 in which indium tin oxide (ITO) or antimony thin oxide (ATO) is formed. The x-coordinate pattern 120, the x-coordinate bonding pad 140, the x-coordinate trace 130, and the FPC bonding pad 150 are designed on the upper surface of the ().

In addition, a y coordinate pattern 220 and a y coordinate bonding pad 230 are formed on an upper surface of the PET layer 210 having the indium tin oxide (ITO) or the antimony thin oxide (ATO) formed thereon, such a y coordinate bonding pad. As described later, 230 is adhesively connected to the x-coordinate bonding pad 140 located on the upper surface of the tempered glass layer 110.

The x coordinate pattern 120 and the x coordinate trace 130 are connected to the upper surface of the tempered glass layer 110 and connected to the FPC bonding pad 150, and the y coordinate bonding pad 230 and the upper surface of the PET layer 210. The x-coordinate bonding pad 140 is bonded to each other. More details will be described with reference to the drawings below.

3 illustrates a touch sensor design diagram configured on the upper surface of the tempered glass layer 110 provided in the touch screen PET and the tempered glass layer composite touch sensor 100 according to the present invention.

Referring to FIG. 3, after the ITO is deposited on the upper surface of the tempered glass layer 110 to form a film, the x coordinate pattern 120 is formed by a lithography process using a mask.

The x-coordinate trace 130, the x-coordinate bond pad 140, and the FPC bond pad 150 deposit Cr to form a Cr film, and then use a mask lithography process to perform the x-coordinate trace 130 and x. The coordinate bonding pad 140 and the FPC bonding pad 150 are formed.

In addition, the x coordinate pattern 120 is connected to the x coordinate trace 130, the x coordinate trace 130 is connected to the FPC bonding pad 150. In addition, the x-coordinate bonding pad 140 is connected to the FPC bonding pad 150.

Figure 4 shows the design of the touch sensor formed on the PET layer 210 upper surface of the touch screen PET and the tempered glass layer composite touch sensor 100 according to the present invention.

Referring to FIG. 4, after the ITO is deposited on the upper surface of the PET layer 210 to form a film, a y coordinate pattern 220 is formed by a silk printing process. The y coordinate bonding pad 230 forms a bonding pad pattern using silver ink, and the y coordinate pattern 220 and the y coordinate bonding pad 230 are connected to each other.

5 is a cross-sectional view after laminating the tempered glass layer 110 and PET layer 210 in the touch screen PET and tempered glass layer composite touch sensor 100 according to the present invention using a laminating device.

Referring to FIG. 5, an ITO pattern, that is, an x coordinate pattern 120, is formed on a lower surface of the tempered glass layer 110 and includes an x coordinate bonding pad 140 and an FPC bonding pad 150. An upper surface of the layer 210 is composed of an ITO pattern, that is, a y coordinate pattern 220 and a y coordinate bonding pad 230.

In addition, in order to perform a laminating process between the tempered glass layer 110 and the PET layer 210, laminating is performed using a laminator equipment for adhering the OCA film 310 on the PET layer 210.

In addition, in order to perform the connection between the x coordinate bonding pad 140 located on the lower surface of the tempered glass layer 110 and the y coordinate bonding pad 230 located on the upper surface of the PET layer 210, the ACA layer 320 may be PET. ACF bonding is performed to connect to the x-coordinate bonding pad 140 positioned on the bottom surface of the layer 210 and positioned on the bottom surface of the tempered glass layer 110.

In addition, by forming an ACF layer 330 on the FPC bonding pad 150 located on the tempered glass layer 110 for ACF bonding with the FPC 300 and performing ACF bonding with the FPC 300, a composite touch sensor ( 100) Production is complete.

The manufacturing method of the PET and tempered glass layer composite touch sensor 100 according to the present invention configured as described above is as follows.

First, the PET layer 210 and the tempered glass layer 110 in which indium tin oxide (ITO) or antimony thin oxide (ATO) are formed are prepared.

Here, the ITO or ATO film (not shown) is formed in substantially the same area on the PET layer 210 and the tempered glass layer (110).

The present invention forms an x coordinate trace 130, an x coordinate bonding pad 140, and an FPC bonding pad 150 made of Cr on the upper surface of the tempered glass layer 110.

In this case, as shown in FIG. 3, after the ITO is deposited on the upper surface of the tempered glass layer 110 to form a film, the x coordinate pattern 120 is formed by a lithography process using a mask.

The x-coordinate trace 130, the x-coordinate bond pad 140, and the FPC bond pad 150 deposit Cr to form a Cr film, and then use a mask lithography process to perform the x-coordinate trace 130 and x. The coordinate bonding pad 140 and the FPC bonding pad 150 are formed.

In addition, the x coordinate pattern 120 is connected to the x coordinate trace 130, the x coordinate trace 130 is connected to the FPC bonding pad 150. In addition, the x-coordinate bonding pad 140 is connected to the FPC bonding pad 150.

Here, in forming the x-coordinate trace 130, the x-coordinate bond pad 140, and the FPC bond pad 150, a material having excellent conductivity including a transition metal is selected, and a patterning process is performed to form a patterning process. desirable.

In addition, the tempered glass layer 110 has an x coordinate pattern 120, an x coordinate trace 130, an x coordinate bonding pad 140, and an arrangement and number of FPC bonding pads 150 on the upper surface thereof. It may be designed a number.

The tempered glass layer 110 has an x-coordinate pattern 120 and an x-coordinate trace 130, an x-coordinate bonding pad 140, and an y-coordinate pattern 220 instead of the FPC bonding pad 150 on its upper surface. It can be designed and composed of the y coordinate bonding pad 230, in this case the x coordinate pattern 120 and the x coordinate trace 130, the x coordinate bonding pad 140, and the FPC bonding pad on the PET layer 210 150 is formed.

In addition, in the present invention, the bonding pad region is patterned with silver ink on the upper surface of the PET layer 210 to form the y-coordinate bonding pad 230.

As shown in FIG. 4, after the ITO is deposited on the upper surface of the PET layer 210 to form a film, a y-coordinate pattern 220 is formed by a silk printing process. The y coordinate bonding pad 230 forms a bonding pad pattern using silver ink, and the y coordinate pattern 220 and the y coordinate bonding pad 230 are connected to each other.

In this process, when the y-coordinate bonding pad 230 is formed, a transparent conductive electrode is formed by performing a patterning process using a transparent conductive material including ITO.

In addition, the PET layer 210 may be selectively designed as many as the number and arrangement of the y-coordinate bonding pad 230 connected to the y-coordinate pattern 220 as needed.

In addition, the PET layer 210 has a y-coordinate pattern 220 and an x-coordinate pattern 120, an x-coordinate trace 130, and an x-coordinate bonding pad 140 on its upper surface instead of the y-coordinate pattern 220. In addition, a plurality of FPC bonding pads 150 may be selectively designed. In this case, the y-coordinate pattern 220 and the y-coordinate bonding pad 230 may be formed on the tempered glass layer 110.

In addition, the connection between the x coordinate bonding pad 140 located on the lower surface of the tempered glass layer 110 and the y coordinate bonding pad 230 on the upper surface of the PET layer 210 is performed.

At this time, as shown in Figure 5, between the x coordinate bonding pad 140 is located on the lower surface of the tempered glass layer 110, and the y coordinate bonding pad 230 located on the upper surface of the PET layer 210. In order to perform the connection, the ACA layer 320 is positioned on the upper surface of the PET layer 210 to perform ACF bonding with the x-coordinate bonding pad 140 located on the lower surface of the tempered glass layer 110.

In this case, the positions of the x-coordinate bonding pad 140 and the y-coordinate bonding pad 230 may be designed in different positions as necessary, and at this time, the x-coordinate bonding pad 140 and the y-coordinate bonding Pad 230 is ACF bonded in a process for adhesion including ACA layer 320.

In addition, ACF bonding with the FPC 300 is performed by forming an ACF layer 330 on the FPC bonding pad 150 located on the tempered glass layer 110 for ACF bonding with the FPC 300.

The FPC bonding pad 150 may be located on the PET layer 210 upper surface instead of the tempered glass layer 110, may be composed of a plurality of pads.

As described above, in the method for manufacturing the touch screen PET and the tempered glass layer composite touch sensor 100 according to the present invention, the ITO pattern, that is, the x coordinate pattern 120 and the x coordinate bonding, is formed on the upper surface of the tempered glass layer 110. A pad 140 and an FPC bonding pad 150 are formed, and an ITO pattern, that is, a y coordinate pattern 220 and a y coordinate bonding pad 230, is formed on the PET layer 210, and one FPC bonding pad is formed. The 150 is manufactured by performing an ACF bonding process with the FPC 300.

Therefore, in the present invention, there is no FPC bonding pad 150 connected to the FPC 300 on the PET layer 210, and only the FPC bonding pad 150 and the FPC 300 configured on the upper surface of the tempered glass layer 110 are provided. By performing only one ACF bonding process, the productivity of the touch screen can be greatly improved due to the efficient work time and the reduction of the defective rate by shortening the process.

As described above, according to the present invention, the ACF bonding process connecting the FPC 300 and the FPC bonding pad 150 may be shortened to one time to maximize work efficiency, and form an effective fine pattern on the upper surface of the tempered glass layer 110. As a result, the area of the pad can be miniaturized, the ACF bonding process can be performed even in a narrow space of the customer's product design, and the tempered glass material is advantageous to the process for enhancing the adhesive strength, thereby improving the peel strength. Can be significantly higher.

In addition, according to the present invention, since the FPC bonding pad 150 is formed only on the upper surface of the tempered glass layer 110, by reducing the ACF bonding process for the connection with the FPC 300, the alignment error that can be generated is significantly reduced. By removing the defective rate caused by the electrical short, it is easy to manufacture high-quality touch panel.

In particular, the present invention is applicable to the composite touch sensor 100 using all the substrates as a method for manufacturing the touch sensor 100.

1: Conventional composite sensor 10,110: tempered glass layer
20,210: PET layer 30: y-coordinate pattern
40: y coordinate bonding pad 50: x coordinate bonding pad
60: FPC 100: composite touch sensor of the present invention
120: x-coordinate pattern 130: x-coordinate trace
140: x coordinate bonding pad 150: FPC bonding pad
220: Y coordinate pattern 230: y coordinate bonding pad
300: FPC 310: OCA film
320: ACA layer 330: ACF layer

Claims (16)

In the complex sensor required for manufacturing the touch screen sensor,
PET layer and tempered glass layer in which Indium Tin Oxide (ITO) or Antimony Thin Oxide (ATO) is formed;
A y coordinate bonding pad formed by patterning a bonding pad region with silver ink on an upper surface of the PET layer and connected to a y coordinate pattern; And
Includes; x coordinate traces, x coordinate bonding pads and FPC bonding pads connected to the x coordinate pattern on the upper surface of the tempered glass layer and composed of Cr material,
The x coordinate bonding pad is connected to the FPC bonding pad on the upper surface of the tempered glass layer, the x coordinate bonding pad and the y coordinate bonding pad are formed at the same position on the upper surface of the PET layer and the upper surface of the tempered glass layer, and the x coordinate bonding The pad and the y-coordinate bonding pad are connected to the ACF, while the FPC bonding pad on the upper surface of the tempered glass layer is connected to the FPC. The method of claim 1,
The ITO or ATO film PET and tempered glass layer composite touch sensor, characterized in that formed on the PET layer and the tempered glass layer substantially the same area. The method of claim 1,
When forming the y-coordinate bonding pad, a transparent conductive electrode is formed by performing a patterning process using a transparent conductive material including ITO, and a touch screen PET and tempered glass layer composite touch sensor. The method of claim 1,
In forming the x-coordinate trace, x-coordinate bonding pad, and FPC bonding pad, a material having excellent conductivity including transition metals is selected, and a patterning process is performed to form a patterned touch screen PET and tempered glass layer composite. Type touch sensor. The method of claim 1,
The PET layer is a touch screen PET and tempered glass layer composite touch sensor, characterized in that the number and arrangement of the y-coordinate bonding pads connected to the y-coordinate pattern is selectively designed as needed. The method of claim 1,
The tempered glass layer is a composite of the PET and tempered glass layer of the touch screen, characterized in that the number and arrangement of the x coordinate pattern, the x coordinate trace, the x coordinate bonding pad and the FPC bonding pad are selectively designed on the upper surface. Touch sensor. The method of claim 1,
The PET layer is a touch screen PET and tempered glass layer composite touch sensor, characterized in that the x-coordinate trace, x-coordinate bonding pad and FPC bonding pad selectively designed on the upper surface thereof. The method of claim 1,
The tempered glass layer is a touch screen PET and tempered glass layer composite touch sensor, characterized in that the upper surface is composed of a y coordinate pattern and a y coordinate bonding pads designed. The method of claim 1,
The position of the x coordinate bonding pad and the y coordinate bonding pad is a touch screen PET and tempered glass layer composite touch sensor, characterized in that can be designed in different positions as necessary. 10. The method of claim 9,
The x coordinate bonding pad and y coordinate bonding pad is a touch screen PET and tempered glass layer composite touch sensor, characterized in that the ACF bonding in the process for bonding including the ACA layer. The method of claim 1,
The FPC bonding pad may be located on an upper surface of the PET layer, and the PET and tempered glass layer complex touch sensor of the touch screen, characterized in that it is designed to be composed of a plurality of pads. Preparing a PET layer and a tempered glass layer in which Indium Tin Oxide (ITO) or Antimony Thin Oxide (ATO) is formed;
Patterning a bonding pad region with silver ink on an upper surface of the PET layer to form a y coordinate bonding pad and connecting the y coordinate pattern;
An x coordinate trace, an x coordinate bonding pad, and an FPC bonding pad are formed on the upper surface of the tempered glass layer, and the x coordinate pattern and the x coordinate trace are connected to an FPC bonding pad, and the x coordinate bonding pad is an FPC. Connecting with a bonding pad;
Connecting the x coordinate bonding pads and the y coordinate bonding pads formed at the same positions on the upper surface of the PET layer and the upper surface of the tempered glass layer; And
Connecting the FPC bonding pad to the FPC; forming an ITO pattern, that is, an x coordinate pattern, an x coordinate bonding pad and an FPC bonding pad, on the upper surface of the tempered glass layer, and an ITO pattern on the PET layer. A method for manufacturing a touch screen PET and tempered glass layer composite touch sensor, comprising: forming a y-coordinate pattern and a y-coordinate bonding pad, and manufacturing one FPC bonding pad by performing an FPC and ACF bonding process. The method of claim 12,
The tempered glass layer and the PET layer is a method for manufacturing a touch screen PET and tempered glass layer composite touch sensor, characterized in that for performing a laminating process therebetween. The method of claim 13,
The PET layer is a method for manufacturing a touch screen PET and tempered glass layer composite touch sensor, characterized in that the lamination process using a laminator equipment for adhering the OCA film on the upper surface. The method of claim 12,
The tempered glass layer has an ACA layer on the PET layer upper surface to perform the connection between the x coordinate bonding pad located on the bottom surface and the y coordinate bonding pad located on the upper surface of the PET layer. A method for manufacturing a touch screen PET and tempered glass layer composite touch sensor, which is produced by performing an x-coordinate bonding pad and an ACF bonding process. The method of claim 12,
The tempered glass layer is a method of manufacturing a touch screen PET and tempered glass layer composite touch sensor, characterized in that the ACF bonding process with the FPC by placing the ACF on the FPC bonding pad located on the upper surface.

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