KR101251413B1 - Touchscreen panel having one-layered structure to minimize the impact of the transparent electrode impedance - Google Patents

Abstract

PURPOSE: A TSP(Touch Screen Panel) including a single accumulation structure which minimizes impedance effects of a transparent electrode is provided to minimize characteristic differences in each position of a touch area by uniformly maintaining the absolute impedance of G1 and G2. CONSTITUTION: Pattern sensor sensing units(110) comprise a combination of transparent electrodes for sensing a touch position. A pattern sensor connecting unit(120) includes a G1 connection unit(121) and a G2 connection unit(122) connected to the transparent electrodes. An FPCB(Flexible Printed Circuit Board)(200) includes a touch controller(300) sensing a touch signal and is connected to the G1 and the G2 connection unit connected to the transparent electrodes. A bezel unit(130) is formed at a left side or a right side of a touch area in which the pattern sensor sensing units are vertically arranged. The G1 or the G2 connection unit is arranged in the bezel unit and is connected to the FPCB. [Reference numerals] (300) Touch controller;

Description

TOUCHSCREEN PANEL HAVING ONE-LAYERED STRUCTURE TO MINIMIZE THE IMPACT OF THE TRANSPARENT ELECTRODE IMPEDANCE}

The present invention relates to a touch screen panel, and more particularly, to a touch screen panel having a single stacked structure that minimizes the influence of impedance of a transparent electrode.

A touchscreen panel, also referred to as a touch panel, refers to a computing input device that makes it possible to easily operate a computer by enabling interactive and intuitive operations by touching a button displayed on a display. A capacitive touch panel uses a capacitance in a human body. In the capacitive touch panel, a touch is recognized by measuring a change in resistance and current caused by a capacitance of a person using an alternating voltage, and a method of determining whether there is a touch by comparing the amount of charge of a capacitor. Can be divided. Such a capacitive touch panel is superior in durability compared to a resistive film method using a film, and thus does not interfere with operation even with moisture or small damage. In addition, the touch accuracy is relatively high, and the optical characteristic is excellent, so that the screen is clear. In particular, the touch panel using the capacitive charging method is multi-point and can be manufactured in a small size, which is widely used in mobile smart devices.

Conventional capacitive touch panels mainly use indium tin oxide (ITO), and use ITO as a transparent electrode on a glass substrate to sense a touch signal. In this case, a method of detecting a touch signal and detecting a position using two layers is used as the transparent electrode. Such a method is known as the most convenient and safe touch recognition method. However, such a method has a disadvantage in that the manufacturing cost increases because two or more transparent electrodes must be used. In order to solve this problem, various studies have been attempted to produce the same effect as using two layers using only one transparent electrode layer.

FIG. 1 is a diagram illustrating a plan view of a touch screen panel having a single stack structure, and FIG. 2 is a diagram illustrating a connection configuration of a touch screen panel having a single stack structure according to FIG. 1. 1 and 2 is a touch screen panel having a single laminated structure developed and implemented by the present applicant, and has a single laminated structure that minimizes the influence of impedance of the transparent electrode according to an embodiment of the present invention. In order to contrast with the touch screen panel, the configuration before the invention is shown as an example.

As shown in FIG. 1, the touch screen panel having a single stacked structure includes a plurality of pattern sensor detection units 11, a G1 connection unit 12, and a G2 connection unit 13. The FPCB 20 and the touch controller 30 are configured. As shown in FIGS. 1 and 2, the touch screen panel includes a G1 connection part for connecting to the pattern sensor detecting unit 11 and the final FPCB 20, which are composed of transparent electrodes of the touch screen panel TSP. 12) and the G2 connecting portion 13 are configured to be concentrated in one direction. The touch screen panel TSP includes impedances of the G1 connection part 12 and the G2 connection part 13 for applying and detecting a signal to the pattern sensor detection part 11 on the upper side of the FPCB 20. , Z (G2_m)] are all small, and the impedance of the G1 connection part 12 and the G2 connection part 13 for applying and detecting a signal to the pattern sensor detection part 11 at the lower part of the touch screen panel TSP. [Z (G1_n), Z (G2_m)] are both large. Due to this difference, non-uniformity of various characteristics of the touch screen panel, such as sensitivity, occurs, and there is a problem in that the limitation of using the absolute impedance of the transparent electrode is small to reduce such side effects. In order to reduce the absolute impedance of the G1 connection part 12 and the G2 connection part 13, there is a problem in that the pattern sensor detection part 11 becomes small, and it is also solved by using a material having a small impedance of the transparent electrode. There is a problem that the manufacturing cost of the screen panel is increased. In other words, ITO is generally used as a transparent electrode, and in the case of ITO, some impedances are small and some are large. In this case, 150 ohms is generally used. When a small impedance is required, 80 ohms or less may be used. However, 80 ohms or less are expensive in terms of cost and price, thereby increasing the manufacturing cost of the touch screen panel.

The present invention has been proposed to solve the above problems of the conventionally proposed methods, G1 connection portion by arranging the G1 connection portion or G2 connection portion on the bezel portion formed on the left and right sides of the touch area without using an expensive transparent electrode And a connection structure that improves the connection structure of the G2 connection unit to maintain a uniform absolute impedance of the G1 and G2, thereby minimizing the effect of the positional characteristic difference of the touch region, thereby minimizing the impedance effect of the transparent electrode. It is an object of the present invention to provide a touch screen panel having a laminated structure.

In addition, the present invention, the total impedance across the network of the G1 connection and the G2 connection with each impedance is equalized to reduce the difference in the characteristics of the touch area by position, thereby reducing the constraint on the material of the transparent electrode of the touch screen panel Another object of the present invention is to provide a touch screen panel having a single stacked structure that minimizes the influence of the impedance of the transparent electrode, so that the manufacturing cost can be reduced.

In order to achieve the above object, a touch screen panel having a single stacked structure for minimizing the impedance effect of a transparent electrode according to a feature of the present invention is provided.

One side of the pattern sensor detection unit is formed of a combination of transparent electrodes of Tx and Rx for the detection of the touch position, G1 connecting portion and G2 connecting portion electrically connected to the transparent electrodes of the Tx and Rx of the pattern sensor detection, respectively A touch panel forming a pattern sensor connection unit provided thereon; And

Flexible Printed Circuit Board (FPCB) 200 electrically connected to the G1 connection part and the G2 connection part connected to the transparent electrodes of the Tx and Rx of the plurality of pattern sensor detection parts formed on the touch panel, and having a touch controller sensing a touch signal. ),

The touch panel,

The bezel part may be further formed on the left and right sides of the touch area in which the plurality of pattern sensor detectors are vertically arranged, and the bezel part may be connected to the FPCB by arranging one of a G1 connection part or a G2 connection part, and the bezel part may be connected to G1. When the connection part is arranged, the G1 connection part is connected from the bottom up through the bezel part, and the G2 connection part is configured from the top to the bottom part so that the sum of the total impedances through the network of the G1 connection part and the G2 connection part is kept constant. It is characterized by the configuration thereof.

Preferably, the sum of the total impedance is

As the impedance of the G1 connection increases and increases, the impedance of the G2 connection decreases and decreases.

Preferably, the sum of the total impedance is

As the impedance of the G1 connection decreases and decreases, the impedance of the G2 connection increases and increases.

Preferably, the G2 connection portion,

To adjust the thickness of the connection line (G2_0 ~ G2_n) of the G2 connection portion differently in detail so that the sum of the impedance of the G1 connection portion and the impedance of the G2 connection portion can be kept constant, the connection line is formed to be thicker toward the G2_0 Can be.

More preferably, the touch panel,

In the case where the G2 connection part is disposed in the bezel part, the G2 connection part may further include an insulated connection part for connecting the connection lines G2_0 to G2_n of the G2 connection part to the same line at the opposite position where the FPCB is disposed, and the G1 connection part may be disposed from top to bottom. And the G2 connection is configured to be connected from the bottom up so that the sum of the total impedance through the network of the G1 connection and the G2 connection is kept constant.

Even more preferably, the pattern sensor detection unit,

The transparent electrode of Tx for applying the driving signal and the transparent electrode of Rx for touch sensing may be formed of indium tin oxide (ITO) of a transparent conductive material.

Even more preferably, the pattern sensor connection portion,

The G1 connection part connecting and connecting to the transparent electrode of Tx and the G2 connection part connecting and connecting to the transparent electrode of Rx may be composed of indium tin oxide (ITO) of a transparent conductive material.

Even more preferably, the pattern sensor connection portion,

The G1 connection part connecting and connecting to the transparent electrode of Rx and the G2 connection part connecting and connecting to the transparent electrode of Tx may be composed of indium tin oxide (ITO) of a transparent conductive material.

Even more preferably, the touch panel,

It may be configured as one of a transparent substrate base substrate or a transparent window of the display device.

According to the touch screen panel having a single stack structure minimizing the impedance effect of the transparent electrode proposed in the present invention, the G1 connection part or the G2 connection part is disposed on the bezel parts formed on the left and right sides of the touch area without using an expensive transparent electrode. By doing so, the connection structure of the G1 connection unit and the G2 connection unit may be improved to maintain the absolute impedance of the G1 and G2 uniformly, thereby minimizing the difference in characteristics of each touch region.

In addition, according to the present invention, the total impedance across the network of the G1 connection portion and the G2 connection portion having each impedance is equalized to reduce the difference in characteristics of each touch area, thereby reducing the constraint on the material of the transparent electrode, thereby reducing the touch screen panel. It is possible to reduce the manufacturing cost of the.

1 is a plan view showing a touch screen panel having a single laminated structure.
2 is a conceptual diagram illustrating a connection configuration of a touch screen panel having a single stack structure according to FIG. 1.
3 is a plan view illustrating a touch screen panel having a single stacked structure for minimizing an impedance effect of a transparent electrode according to an exemplary embodiment of the present invention.
4 is a plan view illustrating a touch screen panel having a single stacked structure for minimizing an impedance effect of a transparent electrode according to another exemplary embodiment of the present disclosure.
FIG. 5 is a diagram illustrating a configuration of an insulation connection part applied to the touch screen panel according to FIG. 4.
FIG. 6 is a conceptual diagram illustrating a connection configuration of a touch screen panel having a single stacked structure for minimizing an impedance effect of a transparent electrode according to an exemplary embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . In addition, the term 'comprising' of an element means that the element may further include other elements, not to exclude other elements unless specifically stated otherwise.

3 is a plan view illustrating a touch screen panel having a single stacked structure for minimizing an impedance effect of a transparent electrode according to an exemplary embodiment of the present invention. As shown in FIG. 3, the touch screen panel having a single stacked structure for minimizing the impedance effect of the transparent electrode according to the exemplary embodiment of the present invention includes a touch panel 100, an FPCB 200, and a touch controller 300. It may be configured to include).

The touch panel 100 includes a plurality of pattern sensor detection units 110 formed of a combination of transparent electrodes of Tx and Rx on one surface of the touch panel, and the Tx and Rx of the pattern sensor detection unit 110 are formed. A pattern sensor connection part 120 having a G1 connection part 121 and a G2 connection part 122 electrically connected to the transparent electrode is formed. Here, the touch panel 100 further forms a bezel part 130 on the left and right sides of the touch area in which the plurality of pattern sensor detection parts 110 are vertically arranged, and the G1 connection part 121 is connected to the bezel part 130. Alternatively, one of the G2 connection units 122 may be disposed to connect and connect the FPCB 200 to be described later. At this time, when the G1 connection part 121 is disposed on the bezel part 130, the G1 connection part 121 is connected from the bottom up through the bezel part 130, and the G2 connection part 122 is configured to be connected from the top down. The sum of the total impedances through the network of the G1 connection part 121 and the G2 connection part 122 may be maintained to be constant.

In addition, as shown in FIG. 4, when the G2 connection part 122 is disposed on the bezel part 130, the touch panel 100 has a connection line of the G2 connection part 122 at an opposite position where the FPCB 200 is disposed. (G2_0 to G2_n) further includes an insulated connection part 140 for connecting the same lines, the G1 connection part 121 is connected from the top to the bottom, and the G2 connection part 122 is configured to be connected from the bottom to the G1 connection part ( 121 and the sum of the total impedance through the network of the G2 connection 122 may be configured to be kept constant. That is, as shown in FIGS. 3 and 4, the touch panel 100 is configured by arranging the G1 connection part 121 or the G2 connection part 122 using the bezel part 130 formed on the left and right sides of the touch area. By configuring the G1 connecting portion 121 and the G2 connecting portion 122 in a structure opposite to each other through the lower portion, the impedance sum of the G1 and G2 is equalized, thereby reducing the difference in characteristics of each touch region. To help.

The sum of the total impedances of the G1 connection part 121 and the G2 connection part 122, which are the absolute impedance values set and implemented in the touch panel 100, increases as the impedance of the G1 connection part 121 increases, so that the impedance of the G2 connection part 122 increases. It can be configured to decrease and become smaller. On the contrary, the sum of the total impedance may be configured such that as the impedance of the G1 connection portion 121 decreases and decreases, the impedance of the G2 connection portion 122 increases and increases. The G2 connection part 122 is configured by differently configuring the thicknesses of the connection lines G2_0 to G2_n of the G2 connection part 122 so that the sum of the impedance of the G1 connection part 121 and the impedance of the G2 connection part 122 is kept constant. Fine tuning is possible, and this fine tuning can be realized by forming thicker lines towards G2_0. For example, in the present invention, G2_0 is configured farther than G2_n. That is, it means that G2_0 is thick, which means that G2_0 has a large impedance. Here, the meaning of the adjustment in detail, the impedance of the G1 connection portion 121 also becomes larger as 0 → n depending on the position where the G2 connection portion 122 meets. In other words, the impedance increases, and conversely, the impedance of G2 going to the FPCB 200 at the location where it meets decreases. At large, the total impedance across the two networks, the larger and smaller impedance, will remain constant, but there may be an inconsistent change depending on the magnitude and magnitude of the impedance. In the case of such a change, it means that the thickness of the connection line of the G2 connection part 122 is adjusted to keep the impedance of the total network constant.

The pattern sensor detecting unit 110 of the touch panel 100 may configure a transparent electrode of Tx for applying a driving signal and an indium tin oxide (ITO) of a transparent conductive material. . In addition, the pattern sensor connection unit 120 of the touch panel 100 may include a G1 connection unit 121 connecting and connecting the transparent electrode of Tx, and a G2 connection unit 122 connecting and connecting the transparent electrode of Rx to ITO (Indium) of a transparent conductive material. Tin Oxide). Here, the pattern sensor connection unit 120 may be configured to connect and connect the transparent electrode of Tx and the G2 connection unit 122, and to connect the transparent electrode of the Rx and the G1 connection unit 121. The touch panel 100 may be configured as one of a base substrate made of a transparent material or a transparent window of the display device. That is, the touch panel 100 is a single laminated structure in which all of the pattern sensor detection units 110 formed of a combination of a Tx transparent electrode and an Rx transparent electrode are disposed on one surface, and a glass substrate or a base substrate of tempered glass is formed. It may be configured to further include a transparent window of the display device as a cover, or to form a plurality of pattern sensor detection unit 110 directly on the cover of the transparent window.

The FPCB 200 is electrically connected to the G1 connection part 121 and the G2 connection part 122 connected to the transparent electrodes of Tx and Rx of the plurality of pattern sensor detection parts 110 formed on the touch panel 100, and touched. The touch controller 300 may detect a signal. In the touch screen panel according to the present invention, for example, the FPCB 200 is positioned above the touch panel 100. However, the present invention is not limited thereto, and the FPCB 200 is disposed below the touch panel 100. It can be configured to be located. In the present invention, the G1 connection portion 121 or G2 connection portion 122 directly connected to and connected from the FPCB 200 and the G1 connection portion 121 or G2 connection portion 122 connected and connected in opposite directions through the bezel portion 130. ), The total impedance across the network of the G1 connection portion 121 and the G2 connection portion 122 having each impedance is equalized, thereby reducing the difference in characteristics of each touch area and reducing the constraints according to the material of the transparent electrode. It is possible to reduce the manufacturing cost of the touch screen panel. The touch controller 300 is electrically connected and connected to the FPCB 200, and when a touch signal is input to the pattern sensor detector 110 formed on the touch panel 100, the touch controller 300 receives a touch signal corresponding to the pattern sensor detector 110. It can be detected. The touch controller 300 may be configured in a form mounted on the FPCB 200.

FIG. 4 is a diagram illustrating a plan view of a touch screen panel having a single stacked structure to minimize impedance effects of transparent electrodes according to another exemplary embodiment of the present invention, and FIG. 5 is an insulation applied to the touch screen panel of FIG. 4. It is a figure which shows the structure of a connection part. As shown in FIG. 4, the touch screen panel having a single stacked structure for minimizing the impedance effect of the transparent electrode according to another embodiment of the present invention includes a touch panel 100, an FPCB 200, and a touch controller 300. ), And the configuration and function of the touch panel 100, the FPCB 200, and the touch controller 300 are mostly the same as those of the touch screen panel according to the exemplary embodiment of the present invention illustrated in FIG. 3. Only the configuration of the touch panel 100 of similar or identical and different parts will be described.

The touch panel 100 further includes a bezel part 130 on the left and right sides of the touch area in which the plurality of pattern sensor detection parts 110 are vertically arranged, and the G2 connection part 122 is disposed on the bezel part 130. In the case of being connected to the FPCB 200 to be described later, the FPCB 200 is disposed on the upper portion, the connection line (G2_0 ~ G2_n) of the G2 connection portion 122 in the lower position of the FPCB 200 opposite the same line Insulated connecting portion 140 for connecting with each other is disposed. The G1 connection portion 121 is directly connected to the FPCB 200 at the upper portion, and the G2 connection portion 122 is lowered through the insulating connection portion 140 disposed at the lower portion through the bezel portion 130 as shown in FIG. 5. Is connected from. That is, the G1 connection portion 121 is connected from the top to the bottom, and the G2 connection portion 122 is configured to be connected from the bottom up, so that the sum of the total impedances through the network of the G1 connection portion 121 and the G2 connection portion 122 is constant. It is configured to be maintained, thereby reducing the difference in characteristics of each position of the touch area.

FIG. 6 is a diagram illustrating a connection configuration of a touch screen panel having a single stack structure to minimize the impedance effect of the transparent electrode according to an exemplary embodiment of the present invention. 6A illustrates a case in which the G1 connection part 121 is disposed and connected to the bezel part 130 of the touch panel 100, and the G1 connection part 121 is connected from the bottom up through the bezel part 130. , G2 connection portion 122 represents a configuration connected directly from the top down from the FPCB 200 located at the top. 6B illustrates a bezel part 130 formed on the touch panel 100 and a G2 connection part through an insulated connection part 140 disposed in an opposite direction to the FPCB 200 positioned at an upper part thereof, that is, at a lower part thereof. Reference numeral 122 is connected from the bottom up, G1 connecting portion 121 is shown in the configuration from the top directly connected from the top down in the FPCB (200).

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics of the invention.

100: touch panel 110: pattern sensor detection unit
120: pattern sensor connection 121: G1 connection
122: G2 connecting portion 130: bezel portion
140: insulated connection 200: FPCB
300: touch controller

Claims (9)

On one surface, a plurality of pattern sensor detectors 110 formed of a combination of transparent electrodes of Tx and Rx are formed to detect the touch position, and electrically connected to the transparent electrodes of Tx and Rx of the pattern sensor detector 110, respectively. A touch panel 100 forming a pattern sensor connection part 120 having a G1 connection part 121 and a G2 connection part 122 connected thereto; And
A touch for electrically connecting and connecting the G1 connection part 121 and the G2 connection part 122 connected to the transparent electrodes of Tx and Rx of the plurality of pattern sensor detection parts 110 formed on the touch panel 100, and detecting a touch signal. It includes a flexible printed circuit board (FPCB) 200 having a controller 300,
The touch panel 100,
The bezel part 130 is further formed on the left and right sides of the touch area in which the plurality of pattern sensor detection parts 110 are vertically arranged, and the G1 connection part 121 or the G2 connection part 122 is formed on the bezel part 130. Place one of the connection and the connection to the FPCB 200, when the G1 connection portion 121 is disposed on the bezel portion 130, the G1 connection portion 121 through the bezel portion 130 from the bottom up Is connected, the G2 connection portion 122 is configured to be connected from the top to the bottom so that the sum of the total impedance through the network of the G1 connection portion 121 and G2 connection portion 122 is kept constant,
The touch panel 100,
The bezel part 130 is further formed on the left and right sides of the touch area in which the plurality of pattern sensor detection parts 110 are vertically arranged, and the G1 connection part 121 or the G2 connection part 122 is formed on the bezel part 130. Place one of the connection and the connection to the FPCB 200, when the G2 connection portion 122 is disposed on the bezel portion 130, the G2 connection portion 122 of the opposite position where the FPCB 200 is disposed It further comprises an insulated connecting portion 140 for connecting the connecting lines (G2_0 ~ G2_n) between the same line, the G1 connecting portion 121 is connected from the top to the bottom, the G2 connecting portion 122 is configured to be connected from the bottom up to G1 Touch panel panel having a single laminated structure to minimize the impact of the impedance of the transparent electrode, characterized in that the sum of the total impedance through the network of the connection portion 121 and the G2 connection portion 122 is kept constant.
The method of claim 1 wherein the sum of the total impedance,
The touch screen panel having a single stack structure to minimize the impact of the impedance of the transparent electrode, characterized in that configured to reduce the impedance of the G2 connection portion 122 decreases as the impedance of the G1 connection portion 121 increases.
The method of claim 1 wherein the sum of the total impedance,
Touch screen panel having a single stack structure to minimize the impact of the impedance of the transparent electrode, characterized in that configured to increase the impedance of the G2 connection portion 122 increases as the impedance of the G1 connection portion 121 decreases smaller .
According to any one of claims 1 to 3, The G2 connection portion 122,
The thickness of the connection lines G2_0 to G2_n of the G2 connection part 122 may be differently adjusted in detail so that the sum of the impedance of the G1 connection part 121 and the impedance of the G2 connection part 122 may be kept constant. The touch screen panel having a single stack structure to minimize the impact of the impedance of the transparent electrode, characterized in that the connecting line is formed thicker toward the G2_0.
delete The method of claim 4, wherein the pattern sensor detecting unit 110,
A single stacked structure that minimizes the influence of impedance of the transparent electrode, characterized in that the transparent electrode of Tx for applying a drive signal and the transparent electrode of Rx for touch sensing are composed of indium tin oxide (ITO) of a transparent conductive material. Touch screen panel having a.
The method of claim 4, wherein the pattern sensor connection portion 120,
The G1 connecting portion 121 connecting to the Tx transparent electrode and the G2 connecting portion 122 connecting to the transparent electrode of Rx are composed of ITO (Indium Tin Oxide) of a transparent conductive material. Touchscreen panel with a single stack structure that minimizes impedance effects.
The method of claim 4, wherein the pattern sensor connection portion 120,
The G1 connection part 121 connecting and connecting to the transparent electrode of Rx and the G2 connection part 122 connecting and connecting to the transparent electrode of Tx are composed of indium tin oxide (ITO) of a transparent conductive material. Touchscreen panel with a single stack structure that minimizes impedance effects.
The method of claim 4, wherein the touch panel 100,
A touch screen panel having a single stack structure that minimizes the influence of impedance of a transparent electrode, characterized in that it is configured as one of a transparent substrate base substrate or a transparent window of a display device.

Images