KR20110049512A - Capacitance type touch panel - Google Patents

Abstract

PURPOSE: An electrostatic capacity touch panel is provided to remove or reduce a correction work of a driver chip of the touch panel. CONSTITUTION: A power outage electrode(20) has an effective area which diminishes from the lead line(30). The effective area decrement of the power outage electrode is comprised of an inner void(120) of the power outage electrode. The inner void is a micro hollow which is uniformly distributed in a power outage electrode. The power outage electrode exists about one-axis in parallel.

Description

Capacitive Touch Panels {CAPACITANCE TYPE TOUCH PANEL}

The present invention relates to a capacitive touch panel, and it is possible to reduce a task of correcting a difference in electrical characteristics of each of the electrostatic electrodes spaced apart from each other by a lead wire in a separate touch panel driving chip, The present invention relates to a capacitive touch panel capable of evenly distributing lead wires to both sides without having to undergo modification to reduce bezel width.

In general, a touch panel is an input device that can be easily used by anyone by touching a button with a finger and interactively and intuitively operating a computer. It is an input device to perform.

As described above, the touch panel uses a resistive film type, a capacitive type film, an infrared type film, an ultrasonic type, and the like, and a resistive film type is currently used. The use of capacitive methods, which is advantageous for this, will be increased.

Such a capacitive touch panel, particularly a touch screen, has a structure in which an ITO made of a light-transmitting conductor on a transparent insulator film such as PET or glass, and a pad made of lead wire such as silver paste are bonded to the edge of the ITO. A layer or an insulator layer is added and laminated up and down.

Here, the ITO is composed of X-axis ITO having X-axis electrostatic electrodes formed at equal intervals and Y-axis ITO having Y-axis electrostatic electrodes formed at equal intervals, so as to be stacked in multiple layers in the lamination process.

The touch screen formed as above is a controller that receives a touch signal according to a user's touch and outputs a coordinate signal.

However, since the electrostatic electrodes arranged side by side on the X-axis or the Y-axis are arranged at different distances from the lead wires, and the different electrostatic electrodes are disposed between them, so that when viewed from the part where the lead wires are connected, Electrostatic electrodes have different electrical characteristics.

Therefore, in manufacturing a driving chip for driving such a capacitive touch panel or a touch screen, it is common to perform a separate calibration procedure for each electrostatic electrode because the electrical characteristics of the electrostatic electrode are different. There is a problem in that the amount of work is increased and the driving chip is complicated. In particular, when the lead wire is pulled out on only one side, the bezel width of the touch screen is increased, and thus the lead wire is distributed to both sides and drawn out. There is a problem that the correction operation is more complicated, and therefore does not consider the method of withdrawing to both sides.

Accordingly, there is an urgent need to develop a capacitive touch panel structure capable of solving the above-described problems and changing one side drawing of the lead wire to both sides drawing without additional correction.

In order to solve the above problems, the present invention can reduce the operation of the difference in the electrical characteristics for each of the electrostatic electrode spaced apart from the lead wire in a separate touch panel driving chip, and the correction value of the chip An object of the present invention is to provide a capacitive touch panel capable of evenly distributing lead wires to both sides without having to undergo modification to reduce bezel width.

In order to achieve the above object, the present invention

A translucent insulator film, a series of electrostatic insulators having at least two equally shaped electrostatic electrodes spaced apart from each other along the uniaxial direction by a translucent conductor on the translucent insulator film, and formed on the translucent insulator film In the capacitive touch panel having a lead wire connected to one end of the series of electrostatic electrodes to transfer a signal,

Each of the same outer shape of the electrostatic electrode constituting the series of the plurality of electrostatic electrodes provides a capacitive touch panel, characterized in that the effective area of the electrostatic electrode decreases as it is spaced apart from the lead line side.

According to the capacitive touch panel of the present invention, a separate touch panel driving chip is used in order to remove a difference in electrical characteristics of each of the electrostatic electrodes spaced at different distances from the lead wire, and to compensate for the difference occurring therebetween. Can reduce or eliminate bezel width by eliminating or modifying the chip's compensation value and by evenly distributing lead wires from both sides of the electrostatic electrode without having to modify the chip's compensation value. Can be obtained.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a capacitive touch panel, comprising a transparent insulator film (10) and a transparent conductor formed on the transparent insulator film (20) and spaced apart from each other while being spaced apart from each other along a uniaxial direction. Capacitive touch having a series of electrostatic electrodes 20 having a plurality of leads, and a lead wire 30 formed on the translucent insulator film 10 and connected to one end of the series of electrostatic electrodes 20 to transmit a signal. In the panel, each of the same contoured electrostatic electrodes constituting the series of plurality of electrostatic electrodes 20 has a configuration in which the effective area of the electrostatic electrode decreases as it is spaced apart from the lead line side.

That is, in the case of a series of multiple electrostatic electrodes connected to each other and extending in the uniaxial direction shown in FIG. 1, when the lead wire and the electrostatic electrode are viewed from the combined point, the separation distances from the respective electrostatic electrodes are different from each other. Since the shape and number of electrodes existing between the sections are different, the electrical characteristics of each of the electrostatic electrodes, which are felt at the point where the lead wire and the electrostatic electrode are coupled, are changed. Therefore, in order to remove the difference between each electrostatic electrode felt at the point where the lead wire and the electrostatic electrode are coupled, as shown in the specific examples in FIGS. The effective area of the electrostatic electrode (the area of the actual transmissive conductor) is reduced, and the amount of reduction is different for each electrostatic electrode, so that the same outer electrostatic electrodes forming the series of electrostatic electrodes 20 are spaced apart from the lead line side. As the effective area of the electrostatic electrode decreases as much as possible, the electrical characteristics of each electrostatic electrode felt at the point where the lead wire and the electrostatic electrode are combined may be the same.

The reduction of the effective area may be configured by reducing the outer size of the electrostatic electrode itself. Preferably, the size of each electrostatic electrode is used so that the touch can be sensed evenly with respect to the entire area of the touch panel, and the fabrication is facilitated. And the shape is the same, it can be configured by forming the internal void 120 in each electrostatic electrode as shown in Figs.

2 to 3 illustrate a case in which the shapes of the electrostatic electrodes of each row are different for convenience, and it is, of course, more general to configure the electrostatic electrodes of each row in the same shape.

Also, as in the series of electrostatic electrodes of the first row of FIG. 2, the same number of internal pores may be formed while the numbers thereof are different, and the number of internal pores is kept the same, and the size thereof is gradually reduced or increased. It may be configured, or may be produced by mixing the two, it does not necessarily have a uniform distribution, it may be configured as a random distribution, preferably in a series of multiple electrostatic electrode of the second row of FIG. As described above, it is preferable to configure the internal pores as minute pores uniformly distributed in the electrostatic electrodes so as to reduce even touch detection and variation in touch sensitivity in the entire panel.

In particular, the difference in electrical characteristics of each of the electrostatic electrodes felt at the point where the lead wire and the electrostatic electrode are combined in the related art is mainly a difference in electric resistance and capacitance, and this characteristic affects the design of the driving chip. As the effective area is reduced, the electrical characteristics that allow each electrostatic electrode to have the same characteristics are preferably aspects related to electrical resistance and capacitance.

Also, if the electrical characteristics of each of the electrostatic electrodes sensed at the point where the lead wire and the electrostatic electrode are coupled to each other are not the same, there is no need to draw the lead wire to the left side or the right side of the electrostatic electrode or change the correction value of the driving chip. It is possible to configure the lead wires in various ways while using the as is. Of course, the pattern shape of each electrostatic electrode should be changed to the left and right symmetry in the lead wire direction change.

A specific example of this is shown in FIG. 3. That is, when the lead wire lead-out direction of the touch panel is changed from the case having the configuration as shown in FIG. 2 to the structure as shown in FIG. 3, the configuration of the electrostatic electrode is changed without changing the driving chip. You can do it.

Accordingly, in the case where at least two of the series of electrostatic electrodes are present in parallel with respect to the one axis, the lead wires extend from one end of the plurality of electrostatic electrodes of the series and the other end thereof. It is configured to extend in the form to reduce the number of lead wires passing through both sides of the panel, to narrow the width of the lead wire placement section on both sides of the panel, it is possible to reduce the bezel width of the touch screen, more preferably both sides The lead wires can be evenly arranged.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various modifications and changes made by those skilled in the art without departing from the spirit and scope of the present invention described in the claims below. Changes are also included within the scope of the invention.

1 is a schematic plan view of a pad applied to a conventional capacitive touch panel.

2 is a schematic top view of an embodiment of a pad applied to the capacitive touch panel of the present invention.

3 is a schematic top view of another embodiment of a pad applied to the capacitive touch panel of the present invention.

Explanation of symbols on the main parts of the drawings

10: insulator film 20: transparent conductor (ITO layer)

30: lead wire 120: internal void

Claims (4)

A translucent insulator film, a series of electrostatic insulators having at least two equally shaped electrostatic electrodes spaced apart from each other along the uniaxial direction by translucent conductors on the translucent insulator film, and formed on the translucent insulator film In the capacitive touch panel having a lead wire connected to one end of the series of electrostatic electrodes to transfer a signal, Capacitive touch panel, characterized in that the effective area of the capacitive electrode of each of the same outer shape of the series of the plurality of capacitive electrode is reduced from the lead line side. The method of claim 1, The reduction of the effective area of the capacitive electrode is a capacitive touch panel, characterized in that made of the internal void of each of the capacitive electrode. The method of claim 2, The internal voids are capacitive touch panels, characterized in that the fine pores uniformly distributed in each of the electrostatic electrodes. The method according to any one of claims 1 to 3, The plurality of electrostatic electrodes are present in at least two parallel to the one axis, And the lead wire extends at one end of the plurality of capacitive electrodes and extends at the other end of the series of capacitive electrodes.

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