KR101133967B1 - Capacitive overlay touch screen panel integrated with window and mathod for manufacturing there of - Google Patents

Abstract

The present invention relates to a window-integrated capacitive touch screen panel and a method for manufacturing the same, characterized in that a laminate is formed on the window panel substrate in the order of deposition and patterning of the ITO layer and printing and patterning of the color layer. The production method is simple and the productivity is improved. When ITO is deposited on the substrate, ITO is deposited by applying high heat of 250 ℃ or higher to increase the transmittance, and improve the physical and electrical properties of the ITO pattern layer to lower the resistance of the ITO pattern layer. It is expected that demand will increase significantly as it is applied to various electronic products by improving sensing sensitivity and optical characteristics.

Description

CAPACITIVE OVERLAY TOUCH SCREEN PANEL INTEGRATED WITH WINDOW AND MATHOD FOR MANUFACTURING THERE OF

The present invention relates to a window-integrated capacitive touch screen panel and a method of manufacturing the same. More particularly, the present invention relates to a window panel substrate in which a laminate is formed through a process of deposition and patterning of an ITO layer and printing and patterning of a color layer. The present invention relates to a window integrated capacitive touch screen panel characterized by lowering resistance of the ITO layer and increasing transparency to improve sensing sensitivity and optical characteristics.

In general, various types of touch screens are applied, such as resistive, capacitive, ultrasonic (SAW), and infrared (IR) methods. Among these methods, resistive, capacitive, and the like are used. This is most widely applied.

The mezzanine method is a structure in which two substrates coated with a transparent electrode are bonded together, and when the upper and lower electrode layers contact each other by applying pressure such as a finger, an electrical signal is generated to recognize the position, and thus the accuracy is high. While it is advantageous in miniaturization and low cost, there is a problem that is difficult to manufacture. In addition, the capacitive method is a method of sensing and driving static electricity generated in a human body, which is disadvantageous in terms of durability, short reaction time, and good permeability, but high price, but the capacitance method has a higher transmittance than a resistive film method. It is expected to spread rapidly with its excellent and multi-touch function that recognizes more than one place at the same time. As Apple's iPhone began to adopt capacitive touch screen panels in mobile phones, the market adopting this method will grow rapidly. It is expected to be.

Looking at the patent applications of the touch screen panel adopting the capacitive method, Korean Patent Publication No. 10-0942763 is attached to the window panel 211 and the lower portion of the window panel 211 as shown in FIG. A conventional touch screen panel 200 including a capacitive touch sensor 220, wherein the capacitive touch sensor 220 is on the upper surface of the glass or PET film substrate 216 (FIG. 1 (a)). After depositing indium tin oxide (ITO) or the like to coat the transparent conductive film 215 [FIG. 1 (b)], and then forming the electrode pattern 215 using a photolithography process [FIG. 1 (c)], A conductive circuit wiring 214 for electrically connecting with the transparent electrode pattern (FIG. 1 (d)), followed by an adhesive 213 (PSA, Pressure Sensitive Adhesive) [FIG. 1 (e)], and an FPC ( 218 is connected to an end of the conductive wiring pattern 214 with an anisotropic conductive film (ACF) (Fig. 1 (f)). Next, the touch screen panel 200 (FIG. 1 (i)) manufactured by bonding the capacitive touch sensor 220 manufactured by the above process to the window panel 211 on which the decorative layer 212 is printed is manufactured. Although known, the touch screen panel 200 may include the window panel 211 (FIG. 1 (g)] [FIG. 1 (h)) and the capacitive touch sensor 220 in which an opaque decorative layer 212 is formed. In order to adhere, adhesives have to be applied, and problems such as bubble generation or foreign matter mixing when the touch sensor is attached to the window panel, and misalignment occurring during the bonding process have been pointed out.

Accordingly, Korean Patent Publication No. 10-0942763 discloses a window panel substrate 311 made of a transparent material and a transparent window portion WA on the substrate, as shown in FIG. 2 as a method for improving the above problems. ) Is a transparent conductive electrode using a non-conductive opaque decorative layer 312 disposed on one side edge portion E of the substrate, and ITO or the like disposed over the window portion WA and the decorative layer of the substrate. An anti-reflective layer including a pattern layer 313 and a conductive circuit wiring layer 314 disposed on an upper edge portion of the transparent conductive electrode pattern layer 313 and disposed on the transparent conductive electrode pattern layer 313. 315 and a window panel-integrated capacitive touch sensor, which further includes a scattering prevention layer 316 disposed on the anti-reflection layer 315, have been proposed. The right panel integrated capacitive touch sensor has an opaque decorative layer 312 formed inside the ITO deposition layer when high heat of 250 ° C. or higher is applied during ITO deposition to obtain better characteristics when forming the conductive electrode pattern layer 313. ) Dissolves due to high temperature heat and damages the electrical and optical properties of the ITO pattern layer as well as damages the external design and loses its value as a product.

Therefore, in order to solve the above problems, the present invention is different from the conventional capacitive touch screen panel that forms a color pattern layer on a panel substrate and then deposits an ITO layer on the panel substrate, and then color By forming a pattern layer, a window-integrated capacitive touch screen panel is characterized by applying high heat of 250 ° C. or more to the substrate to improve the deposition characteristics of the ITO to increase the transmittance, thereby improving the sensing sensitivity and the light characteristics. And the subject is providing the manufacturing method.

In the conventional capacitive touch screen panel, a color pattern is formed on a panel substrate, and then ITO is deposited, cracked in the ITO pattern layer by a step due to a difference in flatness and color pattern, and a constant thickness on the printing step surface. While it is difficult to obtain uniform resistance because the ITO layer is not formed, the present invention deposits ITO directly on the panel substrate, thereby preventing cracks in the ITO pattern layer, thereby forming a constant resistance of the ITO pattern layer to improve electrical characteristics. Another object of the present invention is to provide a window integrated capacitive touch screen panel and a manufacturing method thereof.

The present invention for achieving the above object is a window panel substrate 10,

A transparent conductive electrode pattern layer 20 disposed over the window portion WA, which is a touch region of the image sensor, on the window panel substrate;

A non-conductive color pattern layer 30 disposed on one side edge portion E of the substrate such that the window portion WA is partitioned on the conductive electrode pattern layer;

A metal electrode pattern layer 40 disposed on one side edge portion E of the substrate such that a window portion WA is partitioned on the conductive electrode pattern layer;

An insulating film pattern layer 50 disposed on the conductive electrode pattern layer and the metal electrode pattern layer, leaving a section in which a flexible printed circuit board (FPCB) is bonded;

A flexible printed circuit board 60 (FPCB) bonded to the metal electrode pattern layer;

The integrated window capacitive touch screen panel comprising a as a problem solving means.

In addition, the manufacturing method of the window-integrated capacitive touch screen panel according to the present invention is classified into the following two manufacturing methods according to the patterning process of the conductive electrode film 20a and the non-conductive color coating film.

In the first manufacturing method of the window-integrated capacitive touch screen panel according to the present invention, the conductive electrode film forming the conductive electrode pattern layer 20 by removing the conductive electrode film 20a at regular intervals from the window panel substrate 10 is formed. Forming / patterning step (P100);

Forming / patterning a non-conductive color coating film for forming a non-conductive color coating film 30a using a non-conductive ink or non-conductive compound on the conductive electrode pattern layer 20 and then forming the non-conductive color pattern layer 30. Step P200;

A metal electrode film forming / patterning step (P300) for forming a metal electrode film 40a on the conductive electrode pattern layer and then forming a metal electrode pattern layer 40;

An insulating film formation / patterning step (P400) of forming an insulating film 50a on the conductive electrode pattern layer and the metal electrode pattern layer, and then forming the insulating film pattern layer 50;

An FPCB bonding step (P500) of bonding a flexible printed circuit board (60, FPCB) to be connected to the metal electrode pattern layer;

Method for manufacturing a window-integrated capacitive touch screen panel, characterized in that it comprises another problem solving means.

The second manufacturing method of the window integrated capacitive touch screen panel according to the present invention includes forming a conductive electrode film 20a on the window panel substrate 10 (S101);

Forming a non-conductive color coating film (30a) using a non-conductive ink or a non-conductive compound on the conductive electrode film (20a) (S102);

A non-conductive color coating film patterning step of forming the non-conductive color coating film 30a as a pattern layer 30 (S201);

A conductive electrode film patterning step of forming the conductive electrode film 20a as a pattern layer 20 (S202);

Forming a metal electrode film 40a on the conductive electrode pattern layer and then forming / patterning a metal electrode pattern layer 40 (S300);

An insulating film formation / patterning step of forming an insulating film 50a on the conductive electrode pattern layer and the metal electrode pattern layer, and then forming an insulating film pattern layer 50;

An FPCB bonding step (S500) of bonding a flexible circuit board 60 (FPCB) to be connected to the metal electrode pattern layer;

Method for manufacturing a window-integrated capacitive touch screen panel, characterized in that it comprises another problem solving means.

According to the present invention by the above problem solving means to produce a window-integrated capacitive touch screen panel by depositing ITO on the window panel substrate and then forming a color pattern layer, the production method is simple, productivity is improved, ITO on the substrate During the deposition, the ITO is deposited by applying high heat of 250 ℃ or higher to increase the transmittance, and there is no crack in the ITO pattern layer, which lowers the resistance of the ITO pattern layer to improve the sensing sensitivity and optical properties to develop various electronic products. It is expected to help.

1 is a view showing a manufacturing process of a conventional window integrated capacitive touch screen panel,
2 is a view showing a manufacturing process of another conventional window integrated capacitive touch screen panel,
3 is a perspective view showing an example of a conventional touch screen panel (TSP),
4 is a view showing a manufacturing process of a window integrated capacitive touch screen panel according to an embodiment of the present invention,
5 is a process block diagram illustrating a manufacturing process of a window integrated capacitive touch screen panel according to an exemplary embodiment of the present invention.
6 is a view showing a manufacturing process of a window integrated capacitive touch screen panel according to another embodiment of the present invention,
7 is a process block diagram illustrating a manufacturing process of a window integrated capacitive touch screen panel according to another exemplary embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail with reference to Figures 3 to 7, the figures and references to the construction and operation that can be easily understood by those skilled in the art in the drawings and detailed description will be briefly described. In particular, in the drawings of the drawings, the size ratio between the elements is somewhat different, or there are parts in which the sizes are different between the parts coupled to each other, but the difference in representation of such drawings is due to those skilled in the art. Since these parts are easily understood, a separate description is omitted.

An embodiment of a window integrated capacitive touch screen panel according to the present invention will be described in detail with reference to FIGS. 3 and 4.

A typical touch screen panel is divided into a window portion WA, which is a touch area of a transparent image sensor in which an image is seen in front, and an edge portion E surrounding the window portion WA, as shown in FIG. A portion WA is an area for receiving a touch input by a finger or the like, and the edge portion E functions to print a trademark or logo of a cellular phone maker or to conceal an opaque conductive wiring pattern.

According to a feature of the invention, the invention is a window panel substrate 10,

A transparent conductive electrode pattern layer 20 disposed over the window portion WA, which is a touch region of the image sensor, on the window panel substrate;

The non-conductive color pattern layer 30 is disposed on one side edge portion E of the substrate so that the window portion WA is partitioned on the conductive electrode pattern layer.

A metal electrode pattern layer 40 disposed on one side edge portion E of the substrate such that a window portion WA is partitioned on the conductive electrode pattern layer;

An insulating film pattern layer 50 disposed on the conductive electrode pattern layer and the metal electrode pattern layer, leaving a section in which a flexible printed circuit board (FPCB) is bonded;

A flexible printed circuit board 60 (FPCB) bonded to the metal electrode pattern layer;

Characterized in that it comprises a.

In addition, the first manufacturing method of the window-integrated capacitive touch screen panel according to the present invention removes the conductive electrode film 20a at regular intervals from the window panel substrate 10 to form the conductive electrode pattern layer 20. A film forming / patterning step (P100);

Forming / patterning a non-conductive color coating film for forming a non-conductive color coating film 30a using a non-conductive ink or non-conductive compound on the conductive electrode pattern layer 20 and then forming the non-conductive color pattern layer 30. Step P200;

A metal electrode film forming / patterning step (P300) for forming a metal electrode film 40a on the conductive electrode pattern layer and then forming a metal electrode pattern layer 40;

An insulating film formation / patterning step (P400) of forming an insulating film 50a on the conductive electrode pattern layer and the metal electrode pattern layer, and then forming the insulating film pattern layer 50;

An FPCB bonding step (P500) of bonding a flexible printed circuit board (60, FPCB) to be connected to the metal electrode pattern layer;

It is prepared through a step comprising a.

Hereinafter, each laminated body constituting the laminated structure of the window-integrated capacitive touch screen panel according to the present invention and the first manufacturing method according to the present invention will be described in detail.

In the present invention, the window panel substrate 10 may be made of a glass material mainly containing SiO ₂ . The window panel substrate 10 is not necessarily limited thereto and may be formed of a transparent plastic material. The plastic material forming the substrate 10 may be an insulating organic material, such as polyethersulphone (PES), polyacrylate (PAR, polyacrylate), polyetherimide (PEI), polyethylene naphthalate (PEN, polyethyelenen napthalate) ), Polyethylene terephthalate (PET, polyethyeleneterepthalate), polyphenylene sulfide (PPS), polyallylate, polyimide, polycarbonate (PC, polycarbonate), cellulose triacetate (TAC), It is preferably selected from the group consisting of cellulose acetate propionate (CAP).

In addition, the conductive electrode pattern layer 20 detects static electricity generated in a human body by connecting a finger to the window portion WA, which is a touch area of the image sensor, and connects the electrical signal to an electric signal.

The conductive electrode pattern layer 20 is a transparent conductive electrode film 20a disposed over the upper portion of the window portion WA, which is a touch area of the image sensor, on the window panel substrate 10 in the forming / patterning of the conductive electrode film P100. ), And then the conductive electrode film 20a is removed at regular intervals to form the conductive electrode pattern layer 20.

In addition, the conductive electrode pattern layer 20 may be formed of indium tin oxide (ITO), indium zinc oxide (IZO), zinc oxide (ZnO), indium zinc oxide (IZTO), cadmium tin oxide (CTO), or PEDOT (poly (3). , 4-ethylenedioxythiophene)), carbon nanotubes (CNT), silver nano wire (silver nano wire) using a conductive compound selected from the deposition of the conductive electrode film (20a) and then photolithography, etching or laser processing It is preferable to form the transparent conductive electrode pattern layer 20.

In addition, the color pattern layer 30 functions to form an opaque decorative layer on the edge of the window panel substrate 20 so that the window portion WA, which is a transparent touch area, is partitioned at the center of the window panel substrate 20. In operation P200, the color coating layer 30a is formed on the conductive electrode pattern layer 20 using an ink or a compound, and then the color coating layer 30a is formed on the touch window part of the image sensor. The color pattern layer 30 is formed to be disposed at the edge of one surface of the substrate so as to be partitioned.

In addition, the metal electrode pattern layer 40 transfers an electrical signal generated from the conductive electrode pattern layer 20 to the FPCB and the IC chip by a touch generated from the touch window part WA of the image sensor. In the coating film forming / patterning step (P300), the metal electrode coating film 40a is formed on the conductive electrode pattern layer and the color pattern layer, and the metal electrode coating film 40a is partitioned so that the touch window part WA of the image sensor is partitioned. The metal electrode pattern layer 40 disposed on the edge of one surface of the substrate is formed.

In addition, the metal electrode pattern layer 40 is formed by a method such as screen printing and vapor deposition. Generally, Ag is mainly used. It is preferable to select one kind to form the metal electrode pattern layer 40.

The insulating film pattern layer 50 prevents contamination and enhances durability by blocking a plurality of layers under the external electrical, physical and chemical shocks. The insulating film forming / patterning step (P400) includes an image sensor. An insulating film coating film 50a disposed over the window portion WA, which is a touch area of the substrate, is formed, and then the insulating film coating film 50a is disposed on an edge of one surface of the substrate so that the window portion WA, which is a touch area of the image sensor, is partitioned. The insulating film pattern layer 50 is formed.

In addition, the insulating film pattern layer 50 is preferably formed by screen printing, vapor deposition, spin coating or curtain flow using an insulating compound to form an insulating film by thermal or UV drying. .

Insulating compounds usable in the present invention are specifically organic compounds such as urethane, polyester, acrylic, or alumina (Al ₂ O ₃ ), silica (SiO ₂ ), magnesia (MgO), etc. It is preferable to select and use 1 type or more from an inorganic compound.

In addition, the flexible printed circuit board 60 (FPCB) is connected to the metal electrode pattern layer to transmit an electrical signal to the IC chip.

In the window integrated capacitive touch screen panel according to the present invention, each laminate has a thickness of 0.3 mm to 3 mm for the window panel substrate 10 and a 100 mW to 1000 mW color pattern layer 30 for the conductive electrode pattern layer 20. Although it is preferable that the 0.3 micrometer-30 micrometers, the metal electrode pattern layer 40 are 0.2 micrometer-20 micrometers, and the insulating film pattern layer 50 is 0.5 micrometer-50 micrometers, the thickness of each laminated body is the range defined above. It is not necessarily applied only to the design and can be adjusted according to the design conditions.

And unlike the first manufacturing method according to the second manufacturing method according to the present invention, as shown in Figs. 3, 6, and 7, the non-conductive color coating film and the conductive electrode film patterning step By forming a conductive electrode film 20a on the window panel substrate 10 (S101);

Forming a non-conductive color coating film (30a) using a non-conductive ink or a non-conductive compound on the conductive electrode film (20a) (S102);

A non-conductive color coating film patterning step of forming the non-conductive color coating film 30a as a pattern layer 30 (S201);

A conductive electrode film patterning step of forming the conductive electrode film 20a as a pattern layer 20 (S202);

Forming a metal electrode film 40a on the conductive electrode pattern layer and then forming / patterning a metal electrode pattern layer 40 (S300);

An insulating film formation / patterning step of forming an insulating film 50a on the conductive electrode pattern layer and the metal electrode pattern layer, and then forming an insulating film pattern layer 50;

An FPCB bonding step (S500) of bonding a flexible circuit board 60 (FPCB) to be connected to the metal electrode pattern layer;

Characterized in that it comprises a.

In the non-conductive color coating film patterning step (S201), the non-conductive color pattern layer 30 is formed to be disposed on the edge portion E of the substrate so that the touch window portion WA of the image sensor is partitioned.

In the conductive electrode film patterning step S202, the conductive electrode film 20a is removed at regular intervals over the window portion WA, which is the touch area of the image sensor, to form the conductive electrode pattern layer 20.

Hereinafter, since the process is carried out by the same method as the first manufacturing method, a description thereof will be omitted here.

Hereinafter, the present invention will be described in detail with reference to Examples. However, the present invention is not necessarily limited to the following Examples.

1. Manufacturing of Integrated Window Capacitive Touch Screen Panel

(Example 1)

A glass substrate 10 having a thickness of 0.7 mm was deposited using indium tin oxide (ITO) over the upper portion of the touch window WA of the image sensor, and then heated to 300 ° C. to form a 150 Å thick transparent ITO electrode film 20a. After forming the ITO electrode film 20a at regular intervals to form the ITO pattern layer 20, and then to form a color coating film 30a of 1㎛ thickness using ink on the top and dried at 100 ℃ After forming the non-conductive color pattern layer 30, the non-conductive color pattern layer 30 is formed on the edge of the substrate so that the window part WA is partitioned, and the metal electrode coating layer 40a is formed on the ITO pattern layer and the non-conductive color pattern layer. ) To a thickness of 1 μm, and then the metal electrode coating layer 40 a to form a metal electrode pattern layer 40 disposed on one edge of the substrate such that the touch window WA of the image sensor is partitioned. Images of the insulating film pattern layer and the metal electrode pattern layer The insulating film 50a was formed to a thickness of 1 μm, dried at 100 ° C., and then the insulating film 50a was formed to form an insulating film pattern layer 50 arranged to leave a section to which the flexible printed circuit board FPCB was bonded. The flexible integrated circuit board 60 (FPCB) was bonded to be connected to the metal electrode pattern layer to manufacture a window integrated capacitive touch screen panel.

(Comparative Example 1)

On the 0.7 mm thick glass substrate 10 over the upper part of the touch window portion WA of the image sensor, first, a color coating film 30a having a thickness of 1 μm was formed using non-conductive ink and dried at 100 ° C., and then After forming the exclusive color pattern layer 30, it is deposited by using indium tin oxide (ITO) on top of it, and then heated to 120 DEG C to form a transparent ITO electrode film 20a, and then the ITO electrode film 20a is formed. The ITO pattern layer 20 was formed by removing the ITO pattern layer at regular intervals, and the subsequent process was performed by the same method as in Example 1 to manufacture a window integrated capacitive touch screen panel.

2. Evaluation of Window Integrated Capacitive Touch Screen Panel

The results of measuring the resistivity and light transmittance of the ITO pattern layer in the window integrated capacitive touch screen panel of Example 1 and Comparative Example 1 manufactured by the above method are shown in Table 1 below.

Item Example 1 Comparative Example 1 Specific resistance (10 ^-4 Ω-cm) 1.4 5.2 ITO layer light transmittance (%) 97 92

Based on the contents of [Table 1], Example 1 has a lower specific resistance than Comparative Example 1, it was confirmed that the excellent light transmittance of the ITO layer.

When the process is performed in the same order as in Comparative Example 1, when the color coating film is formed, it is dried at 100 ° C., a pattern layer is formed, and then an ITO electrode film is deposited and dried at 300 ° C., so that the pattern of the color layer is dissolved. Not only does it adversely affect the electrode film, but the external design of the product is compromised, resulting in loss of value as a product.

As described above, although the preferred embodiment of the present invention has been shown in accordance with the above description and drawings, this is merely an example and various changes and modifications can be made without departing from the spirit of the present invention. Those skilled in the art will appreciate.

In the present invention, the production method is simple, the productivity is improved, and when the ITO is deposited on the window panel substrate, ITO is deposited by applying high heat of 250 ° C. or higher to increase the transmittance, and the ITO pattern layer is not cracked in the ITO pattern layer. It is expected that the ripple effect of the industry will be great by improving the sensing sensitivity and optical properties by lowering the resistance of.

10 window panel substrate 20 conductive electrode pattern layer
30: non-conductive color pattern layer 40: metal electrode pattern layer
50: insulating film pattern layer 60: FPCB

Claims (13)

A window panel substrate 10,
A transparent conductive electrode pattern layer 20 disposed over the window portion WA, which is a touch region of the image sensor, on the window panel substrate;
A non-conductive color pattern layer 30 disposed on one side edge portion E of the substrate such that the window portion WA is partitioned on the conductive electrode pattern layer;
A metal electrode pattern layer 40 disposed on one side edge portion E of the substrate such that a window portion WA is partitioned on the conductive electrode pattern layer;
An insulating film pattern layer 50 disposed on the conductive electrode pattern layer and the metal electrode pattern layer, leaving a section in which a flexible printed circuit board (FPCB) is bonded;
A flexible printed circuit board 60 (FPCB) bonded to the metal electrode pattern layer;
Including,
The window panel substrate 10 is glass or PET film,
The conductive electrode pattern layer 20 may be formed of indium tin oxide (ITO), indium zinc oxide (IZO), zinc oxide (ZnO), indium zinc oxide (IZTO), cadmium tin oxide (CTO), or PEDOT (poly (3, 4-ethylenedioxythiophene)), carbon nanotube (CNT), silver nano wire (silver nano wire) is a window integrated capacitive touch screen panel, characterized in that formed by selecting one type.

delete delete The method of claim 1,
The metal electrode pattern layer 40 is formed of one of a material such as Ag, Mg, Al, Pt, Au, Ni, Cr, Pd, Mo, window integrated capacitance, characterized in that formed by screen printing or deposition method Touch screen panel.
The method of claim 1,
The insulating film coating layer 50 is a window, characterized in that the coating layer is formed by screen printing, vapor deposition, spin coating method or curtain flow method using an insulating compound and then dried by heat or UV Integrated capacitive touch screen panel.
A conductive electrode film formation / patterning step (P100) for removing the conductive electrode film 20a on the window panel substrate 10 at regular intervals to form the conductive electrode pattern layer 20;
Forming / patterning a non-conductive color coating film for forming a non-conductive color coating film 30a using a non-conductive ink or non-conductive compound on the conductive electrode pattern layer 20 and then forming the non-conductive color pattern layer 30. Step P200;
A metal electrode film forming / patterning step (P300) for forming a metal electrode film 40a on the conductive electrode pattern layer and then forming a metal electrode pattern layer 40;
An insulating film formation / patterning step (P400) of forming an insulating film 50a on the conductive electrode pattern layer and the metal electrode pattern layer, and then forming the insulating film pattern layer 50;
An FPCB bonding step (P500) of bonding a flexible printed circuit board (60, FPCB) to be connected to the metal electrode pattern layer;
Including,
In the forming / patterning of the conductive electrode film P100, a transparent conductive electrode film 20a disposed over the window portion WA, which is a touch area of the image sensor, is formed on the window panel substrate 10, and then the conductive electrode film is formed. 20a is removed at regular intervals to form a conductive electrode pattern layer 20,
In the forming / patterning of the non-conductive color coating film (P200), a non-conductive color coating film 30a is formed on the conductive electrode pattern layer 20, and then the non-conductive color coating film 30a is a window portion which is a touch area of the image sensor. A non-conductive color pattern layer (30) is formed to be disposed on one side edge portion (E) of the substrate so as to partition (WA).
Forming a conductive electrode film 20a on the window panel substrate 10 (S101);
Forming a non-conductive color coating film (30a) using a non-conductive ink or a non-conductive compound on the conductive electrode film (20a) (S102);
A non-conductive color coating film patterning step of forming the non-conductive color coating film 30a as a pattern layer 30 (S201);
A conductive electrode film patterning step of forming the conductive electrode film 20a as a pattern layer 20 (S202);
Forming a metal electrode film 40a on the conductive electrode pattern layer and then forming / patterning a metal electrode pattern layer 40 (S300);
An insulating film formation / patterning step of forming an insulating film 50a on the conductive electrode pattern layer and the metal electrode pattern layer, and then forming an insulating film pattern layer 50;
An FPCB bonding step (S500) of bonding a flexible circuit board 60 (FPCB) to be connected to the metal electrode pattern layer;
Including,
In the non-conductive color coating film patterning step (S201), the non-conductive color pattern layer 30 is formed to be disposed at one edge portion E of the substrate so that the touch window portion WA of the image sensor is partitioned.
The conductive electrode film patterning step (S202) may form the conductive electrode pattern layer 20 by removing the conductive electrode film 20a at regular intervals over the window portion WA, which is a touch area of the image sensor. Method of manufacturing a window integrated capacitive touch screen panel.
delete delete delete delete The method according to any one of claims 6 to 7,
In the forming / patterning of the metal electrode coating film (P300) (S300), the metal electrode coating film 40a is formed on the conductive electrode pattern layer and the non-conductive color pattern layer, and then the metal electrode coating film 40a is touched by the image sensor. And forming a metal electrode pattern layer (40) disposed at one edge (E) of the substrate so that the window (WA), which is an area, is partitioned.
The method according to any one of claims 6 to 7,
In the insulating film forming / patterning step (P400) (S400), an insulating film 50a is formed on the conductive electrode pattern layer and the metal electrode pattern layer, and then the insulating film 50a is divided into sections where the flexible printed circuit board (FPCB) is bonded. A method of manufacturing a window-integrated capacitive touch screen panel, comprising: forming an insulating layer pattern layer (50) left over.

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