KR102120184B1 - Touch Sensor - Google Patents

Abstract

The present invention provides a touch sensor capable of improving signal delay due to channel resistance by forming a conductive pattern constituting the sensing cell and a bridge connecting the conductive pattern in an alternating form in the Tx/Rx channel region.

Description

Touch sensor

The present invention relates to a large-area high-speed touch sensor, and specifically, a conductive pattern constituting a sensing cell and a bridge connecting the conductive pattern are formed in an alternating form in the Tx/Rx channel region to improve signal delay due to channel resistance. It is related to the touch sensor.

Recently, touch sensors have been widely applied in various electronic products such as mobile phones, personal digital assistants (PDAs), and handheld personal computers, where capacitive touch sensors are most widely used.

Currently, the structure of a single glass type capacitive touch sensor is the main structure used for touch sensors.

For prior art single glass type capacitive touch sensors, the material for forming the touch sensing electrode layer is usually indium tin oxide (ITO). The ITO layer is formed directly on the glass substrate by sputtering and then patterned to form a pattern of the touch sensing electrode layer.

The pattern of the touch sensing electrode layer includes an X-axis sensing electrode pattern and a Y-axis sensing electrode pattern, in which one axis of the sensing electrode pattern crosses another axis of the sensing electrode pattern (bridge structure) Use a conductive layer to form.

The insulating layer is formed at positions of the X-axis sensing electrode pattern and the Y-axis sensing electrode pattern, crisscrossing each other to electrically insulate the X-axis sensing electrode pattern from the Y-axis sensing electrode pattern.

In the prior art single-glass type capacitive touch sensor, the material of the conductive layer for forming the bridge structure is generally metal, and an insulating layer for electrically separating the X-axis sensing electrode pattern from the Y-axis sensing electrode pattern. The material is usually silicon dioxide.

As described above, although an ITO-based conductive film is frequently used as the sensing electrode pattern, the recognition speed is low due to its own RC delay when applied to a large-area touch panel.

The structure of the touch sensor of the related art is to form sensing patterns of the X and Y axes on the same surface and connect the sensing patterns 11 of the X axis using the transparent conductive bridge 13 as shown in FIG. 1.

Here, the sensing patterns 12 of the Y-axis are not connected by a transparent conductive bridge, but are patterned in such a way that the sensing patterns are connected when the sensing pattern is formed, and the sensing patterns 11 of the X-axis are patterned to be separated respectively. It is connected by a transparent conductive bridge 13 in the process. [See Korean Patent Publication No. 10-2012-0092004 and Korean Patent Publication No. 10-2013-0116583]

However, in the case of the touch sensor having such a structure, if the resistance of the sensing pattern and the transparent conductive bridge is not sufficiently low, the sensitivity is deteriorated, and large area is difficult.

In particular, since the sensing patterns of the Y-axis are not connected by the transparent conductive bridge, they are patterned to be connected to each other when the sensing pattern is formed, and the sensing patterns of the X-axis are patterned to be separated from each other and connected by the transparent conductive bridge, so that the X-axis and Y The difference in the resistance value of the shaft occurs.

Such a difference in resistance value reduces the touch response speed, making it difficult to implement a high-speed touch sensor.

Republic of Korea Patent Publication No. 10-2012-0092004 Republic of Korea Patent Publication No. 10-2013-0116583

The present invention is to solve the problem of the touch sensor of the prior art, and forms a bridge connecting the conductive pattern and the conductive pattern constituting the sensing cell in an alternating form in the Tx/Rx channel region, thereby causing a signal due to channel resistance. The purpose is to provide a touch sensor that can improve the delay.

The present invention is to insert the electrode pattern and the bridge connecting the electrode pattern in an alternating form, one electrode pattern belonging to a cell constituting any one sensing region and another electrode pattern belonging to a cell constituting another neighboring sensing region. An object of the present invention is to provide a touch sensor which is arranged to cross conductive patterns having a structure that is connected to each other.

The present invention is a touch sensor having an auxiliary electrode line formed on one electrode pattern belonging to one unit sensing cell constituting a conductive pattern and another electrode pattern belonging to another neighboring unit sensing cell and extending to each edge portion. The purpose is to provide.

The objects of the present invention are not limited to the objects mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

A touch sensor according to the present invention for achieving the above object is described; a first electrode pattern constituting any one sensing cell and a second electrode pattern constituting another neighboring sensing cell connected to the first electrode pattern And a first conductive pattern having a third electrode pattern constituting one sensing cell and a fourth electrode pattern connected to the third electrode pattern constituting another neighboring sensing cell. On the substrate, it is characterized in that the first conductive pattern and the second conductive pattern are repeatedly arranged such that the central axes in the longitudinal direction intersect each other.

Here, a first conductive pattern bridge electrically connecting one first conductive pattern and another first conductive pattern that is not electrically connected to the first conductive pattern bridge, and one second conductive pattern and an electrically connected neighbor thereof It characterized in that it further comprises a second conductive pattern bridge for electrically connecting another second conductive pattern.

In addition, the first conductive pattern bridge and the second conductive pattern bridge are preferably alternately formed in regions where the central axes of the first and second conductive patterns in the longitudinal direction cross each other.

A touch sensor according to the present invention for achieving a different object is a substrate; A first auxiliary electrode line for electrically connecting any one first conductive pattern formed on the substrate and another first conductive pattern adjacent thereto; The substrate A second auxiliary electrode line electrically connecting any one of the second conductive patterns formed on the other second conductive pattern adjacent thereto; and the first auxiliary electrode line and the second auxiliary electrode line being the first. ,2 It characterized in that the central axis of the longitudinal direction of the conductive patterns alternately cross each other.

The touch sensor according to the present invention has the following effects.

First, by forming a bridge connecting the conductive pattern and the conductive pattern in an alternating shape in the Tx/Rx channel region, signal delay due to channel resistance may be improved.

Second, the bridge is formed in an alternating shape in the Tx/Rx channel region to eliminate the difference in resistance values between the X-axis and the Y-axis, thereby improving the touch response speed and realizing a high-speed touch sensor.

Third, it is possible to secure ease of design and process by arranging conductive patterns having a structure in which one electrode pattern and other electrode patterns belonging to cells constituting other neighboring sensing regions are connected to each other.

Fourth, by forming an auxiliary electrode line on the electrode pattern, it is possible to reduce the resistance in the entire area, thereby enabling a large area.

1 is a configuration diagram of a prior art touch sensor
2A and 2B are basic configuration diagrams of a conductive pattern of a touch sensor according to the present invention.
Figure 3 is a cross-sectional arrangement of conductive patterns according to the present invention
4A and 4B are diagrams showing a structure in which bridges are alternately arranged in a touch sensor according to an embodiment of the present invention.
5A and 5B are configuration diagrams of a touch sensor having an auxiliary electrode line according to another embodiment of the present invention

Hereinafter, a preferred embodiment of the touch sensor according to the present invention will be described in detail as follows.

Features and advantages of the touch sensor according to the present invention will become apparent through a detailed description of each embodiment below.

2A and 2B are basic configuration diagrams of a conductive pattern of a touch sensor according to the present invention.

The present invention is to solve the decrease in the response speed due to the RC delay of the touch sensor. RC delay is determined by charging/discharging time of the capacitor by the resistance and capacitor capacity values in the RC circuit.

Charge: V(t) = V ₀ (1-e ^{-t/ RC} ), Discharge: V(t) = V ₀ e ^{-t/ RC}

Therefore, since t = R*C = τ [sec], if the RC value is small, the time required for charging and discharging the capacitor can be reduced.

The present invention is to minimize the RC Delay by lowering the circuit resistance (R) constituting the touch sensor, and to insert the bridge connecting the electrode pattern and the electrode pattern in an alternating form.

The present invention, in order to insert the bridge connecting the electrode pattern and the electrode pattern in an alternating form, one electrode pattern belonging to a cell constituting any one sensing region and another electrode belonging to a cell constituting another neighboring sensing region The conductive patterns of the structures in which the patterns are connected to each other are arranged to cross.

The basic structure of the conductive pattern according to the present invention for this is as in FIGS. 2A and 2B.

FIG. 2A shows the basic structure of a conductive pattern in which the central axis in the longitudinal direction is continuously arranged in the X-axis, wherein one conductive pattern 200 is located in any one first sensing cell area and has a certain area. The first electrode pattern 20 and the second electrode pattern 21 having a predetermined area located in another neighboring second sensing cell area, the first electrode pattern 20 and the second electrode pattern 21 are ( A) It is a structure connected by the connection pattern of the region.

FIG. 2B shows a basic structure of a conductive pattern in which the central axis in the longitudinal direction is continuously arranged in the Y-axis, wherein any one conductive pattern 200 is located in any one first sensing cell area and has a certain area. The third electrode pattern 22 and the fourth electrode pattern 23 positioned in another neighboring second sensing cell area and having a predetermined area, the third electrode pattern 22 and the fourth electrode pattern 23 are ( B) It is a structure connected by the connection pattern of the region.

Here, although the basic structure of the conductive pattern according to the present invention is described in a rhombus shape, it is not necessary to have a rhombus shape, and one electrode pattern belonging to a cell constituting any one sensing region and another sensing region neighboring each other are configured. It is natural that other electrode patterns belonging to the cell can be configured in different forms as long as they are connected to each other.

And the basic structure of the first conductive pattern according to the present invention is that the first electrode pattern, the second electrode pattern, and the connection pattern connecting the first and second electrode patterns are formed on the same surface by the same patterning process.

Similarly, the basic structure of the second conductive pattern is that the third electrode pattern, the fourth electrode pattern, and the connection pattern connecting the third and fourth electrode patterns are formed on the same surface by the same patterning process.

A configuration in which the conductive patterns according to the present invention having such a structure are arranged such that the central axes in the longitudinal direction cross each other in the X direction and the Y direction are as follows.

3 is a block diagram of conductive patterns arranged in accordance with the present invention.

3A, the conductive pattern having the same structure as in FIG. 2A is arranged such that the central axis in the longitudinal direction is continuous along the X axis, and the conductive pattern having the same structure as in FIG. 2B is arranged such that the central axis in the longitudinal direction is continuous along the Y axis. It shows the structure.

That is, the first conductive patterns 30 in which the first electrode patterns belonging to the cells constituting one of the sensing regions and the second electrode patterns belonging to cells constituting the other sensing regions adjacent to each other are connected to each other in the longitudinal direction along the X axis. The second conductive pattern 31 is disposed such that the central axis thereof is continuous, and a third electrode pattern belonging to a cell constituting one sensing region and a fourth electrode pattern belonging to a cell constituting another neighboring sensing region are connected to each other. ) Are arranged such that the central axis in the longitudinal direction is continuous in the Y axis, so that the first conductive pattern 30 and the second conductive pattern 31 are repeatedly arranged so that the central axis in the longitudinal direction intersects each other as a whole. .

Here, the connection between the first conductive pattern 30 and another first conductive pattern 30 that is not electrically connected to the first conductive pattern 30 is connected by a bridge, and the second conductive pattern 31 is not electrically connected to the neighbor. The other second conductive patterns 31 are connected by a bridge, and detailed configuration thereof is as follows.

4A and 4B are diagrams illustrating a structure in which bridges are alternately arranged in a touch sensor according to an embodiment of the present invention.

The touch sensor according to an embodiment of the present invention, the first conductive pattern 41 disposed on the X-axis and the other electrically conductive neighboring first conductive pattern 42 adjacent to the first electrically connected 1 conductive pattern bridge 45, a second conductive pattern that electrically connects any one of the second conductive patterns 43 disposed in the Y-axis and another second conductive pattern 44 that is not electrically connected to the second conductive pattern Includes bridge 46.

Here, the first conductive pattern bridge 45 and the second conductive pattern bridge 46, the central axis of the longitudinal direction of the first conductive pattern (41, 42) and the first conductive pattern (43, 44) The central axes in the longitudinal direction are alternately formed in areas perpendicular to each other.

And, as shown in Figure 4b, the first conductive pattern bridge 45 formed on the substrate 40 belongs to a cell constituting any one sensing region constituting the second conductive pattern 43, 44 One electrode pattern Y1 and another electrode pattern Y2 belonging to a cell constituting another neighboring sensing region are formed with an insulating film 47 interposed above the portion 48 connected to each other.

And the second conductive pattern bridge 46, the other conductive region adjacent to one electrode pattern (X1) belonging to a cell constituting any one of the sensing region constituting the first conductive pattern (41, 42). The insulating layer 47 is formed on the upper side of the portion 49 in which other electrode patterns X2 belonging to the cells constituting each other are connected to each other.

The touch sensor according to the present invention having such a structure is for minimizing signal delay (RC delay) due to high channel resistance of electrodes constituting the touch sensor, and alternating conductive pattern bridges to reduce the difference in resistance between Tx/Rx channels. It was formed as an enemy.

The material of the substrate for manufacturing the touch sensor according to the present invention may be appropriately selected according to the field to which the conductive pattern and the conductive pattern bridge according to the present invention are applied, and specific examples include glass or inorganic materials. Substrates, plastic substrates, films, or other flexible substrates, but are not limited thereto.

In addition, the conductive pattern (transparent electrode) may be formed using a conductive material having transparency such as ITO/Ag NW/PEDOT, and is used as a main electrode for forming the capacitance of the touch sensor.

In addition, it is preferable to form a Tx/Rx conductive pattern in an In-Plane pattern that forms on the same plane, and is produced by pattern formation through an exposure process after PR coating.

In addition, the insulating film is to electrically separate the conductive pattern and the conductive pattern bridge, and is formed through an exposure process after coating the organic insulating film.

It is preferable to use a thermosetting resin having transparency for the formation of such an insulating film, and an island-shaped pattern method that is formed only on a certain lower portion of the conductive pattern bridge is preferable.

And the conductive pattern bridge is to electrically connect the conductive pattern and other electrically conductive patterns adjacent to it, and a metal having low specific resistance to improve conductivity, such as molybdenum, silver, aluminum, copper, palladium, gold, It is preferred to use metals such as platinum, zinc, tin, titanium or alloys thereof.

In the touch sensor according to the present invention, it is preferable that a passivation film is further formed in order to suppress that the conductive pattern constituting the electrode is affected by the external environment (moisture, air, etc.).

In addition, a polymer material such as OCR (Optical Clear Resin) may be applied to bond the manufactured touch sensor panel with the display panel, and then adhered through photo-curing and heat-curing.

Alternatively, a polymer material such as OCA (Optically Clear Adhesive) can be used to bond the cover window or the display panel.

OCA (Optically Clear Adhesive) is a film type that bonds by applying physical force.

And the structure of inserting the electrode pattern and the bridge connecting the electrode pattern in an alternating form according to the present invention can be applied to both a structure in which a transparent electrode/organic insulating film/bridge is stacked and a structure in which a bridge/organic insulating film/transparent electrode is stacked. Do.

Another embodiment of the present invention is to make it possible to lower the overall resistance of Tx/Rx by cross-applying the metal auxiliary electrode.

5A and 5B are configuration diagrams of a touch sensor having an auxiliary electrode line according to another embodiment of the present invention.

As shown in FIGS. 5A and 5B, an auxiliary pattern is formed on one electrode pattern belonging to one unit sensing cell constituting a conductive pattern and another electrode pattern belonging to another neighboring unit sensing cell to extend to each edge portion It is formed to have an electrode line so that resistance in the entire region can be reduced.

Here, the first auxiliary electrode line formed on the X-axis conductive pattern and the second auxiliary electrode line formed on the Y-axis conductive pattern cross the areas where the central axes of the first and second conductive patterns in the longitudinal direction cross each other. Form to pass alternately.

The touch sensor according to another embodiment of the present invention, the first conductive pattern 51 disposed on the X-axis and the first electrically conductive pattern 52 that is not electrically connected to the other electrically connected to the first A second auxiliary electrode that electrically connects the first auxiliary electrode line 55 and one second conductive pattern 53 disposed on the Y axis and another second conductive pattern 54 that is not electrically connected to the second auxiliary electrode Line 56 is included.

And, as shown in Figure 5b, the first auxiliary electrode line 55 formed on the substrate 50 belongs to a cell constituting any one sensing region constituting the second conductive pattern 53, 54 One electrode pattern Y1 and another electrode pattern Y2 belonging to a cell constituting another neighboring sensing region are formed with an insulating layer 57 interposed therebetween on an upper portion of the portion 58 connected to each other.

In addition, the second auxiliary electrode line 56 may be configured to detect another sensing area adjacent to one electrode pattern X1 belonging to a cell constituting any one sensing area constituting the first conductive patterns 51 and 52. The insulating layer 57 is formed on the upper side of the portion 59 where the other electrode patterns X2 belonging to the cells constituting each other are connected to each other.

2A and 2B, the basic structure of the conductive pattern is similarly applied to the touch sensor according to another embodiment having the auxiliary electrode line.

The basic structure of the conductive pattern in which the central axis in the longitudinal direction is continuously arranged in the X-axis is a first electrode pattern 20 having a certain area in which any one first conductive pattern is located in any one first sensing cell region , Located in another neighboring second sensing cell region, has a second electrode pattern 21 having a predetermined area, and the first electrode pattern 20 and the second electrode pattern 21 are connected to the connection pattern of the region (a). It is a structure connected by.

The basic structure of the conductive pattern that is arranged such that the central axis in the longitudinal direction is continuous in the Y-axis is a third electrode pattern 22 having a certain area in which one second conductive pattern is located in any one first sensing cell region , Located in another neighboring second sensing cell region, has a fourth electrode pattern 23 having a predetermined area, and the third electrode pattern 22 and the fourth electrode pattern 23 are connected to the connection pattern of the region (B). It is a structure connected by.

In addition, the first and second conductive patterns are repeatedly arranged such that the central axes in the longitudinal direction intersect each other, and the first and second auxiliary electrode lines are connected to one electrode pattern belonging to any one unit sensing cell constituting the conductive pattern. It is preferable to form a line formed on different electrode patterns belonging to different neighboring unit sensing cells and extending to each edge portion.

The results of simulating line resistance by manufacturing the touch sensor according to the present invention as follows are shown in Table 1 below.

In the following description,'ITO electrode pitch' refers to an interval in which ITO patterns of the same type constituting the electrode pattern are periodically repeated as in FIG. 1, and'ITO width' constitutes a conductive pattern as in FIG. 2B. It means the width of the part connecting the electrode pattern to another electrode pattern.

In order to simulate the line resistance, a touch sensor is formed on the X/Y main electrode on one side, the X electrode is connected through a metal bridge, and a metal bridge is applied to the transparent electrode (ITO) to simulate a line resistance of 2 x 2 units. .

The manufactured touch sensor has an ITO sheet resistance of 150 [Ω/□], an ITO electrode pitch in the X/Y axis direction of 4 mm, a bridge forming material Cu thickness of 2000 mm 2, and a metal bridge width of 8 μm.

In addition, in order to simulate the line resistance, in the comparative example (Ref.) and in Examples 1 and 2, the ITO widths of the parts connecting the electrode patterns constituting the conductive pattern and the other electrode patterns are manufactured in two different cases. use.

This is to reduce the metal bridge length in order to improve visibility, it is necessary to reduce the width of the ITO constituting the Y electrode of the X/Y intersection, and this is to confirm a problem in which the difference in the X/Y resistance that occurs in this case becomes large.

First, in the comparative example (Ref.) of the touch sensor manufactured by applying the previous metal bridge in only one direction, the ITO width constituting the Y electrode is 50 μm, and the case 2) is constituting the Y electrode. The ITO width was 25 µm.

In the case of Comparative Example (Ref.), it was confirmed that the result of the line resistance simulation was 1552 Ω for the X electrode, 2022 Ω for the Y electrode, and 1638 Ω for the X electrode and 2375 Ω for the Y electrode for case 2). Can be.

And in the case of Example 1, in which the bridge connecting the electrode pattern and the electrode pattern is inserted alternately, case 1) has an ITO width constituting the Y electrode 50 μm, and case 2) an ITO constituting the Y electrode. The width is 25 µm.

In case 1) in Example 1, it can be seen that the result of the line resistance simulation is 1788 Ω for the X electrode and 1787 Ω for the Y electrode, and in case 2), the result is 2006 Ω for the X electrode and 2005 Ω for the Y electrode.

Also, in the case of Example 2, in which the total resistance of Tx/Rx was lowered by cross-applying the metal auxiliary electrode, case 1) made the ITO width constituting the Y electrode 50 μm, and case 2) constituting the Y electrode. The ITO width was 25 µm.

In Example 2, it can be confirmed that in case 1), the result of the line resistance simulation is 303 Ω for the X electrode and 304 Ω for the Y electrode, and in case 2), the result is 446 Ω for the X electrode and 446 Ω for the Y electrode.

As shown in Table 1, as the ITO width constituting the Y electrode of the X/Y cross section decreases, it can be seen that the resistance difference of the X/Y electrode increases, and this alternates the bridge connecting the electrode pattern and the electrode pattern. It can be confirmed that the resistance of the X/Y electrode can be adjusted to the same level by inserting with.

In addition, it was confirmed that the overall resistance of the Tx/Rx can be lowered by cross-applying the metal auxiliary electrode, and it can be seen that it is possible to manufacture a touch sensor having a large area/high-speed response.

The touch sensor according to the present invention is to form a bridge connecting the conductive pattern and the conductive pattern constituting the sensing cell in an alternating form in the Tx/Rx channel region so as to improve signal delay due to channel resistance.

It will be understood that the present invention is implemented in a modified form without departing from the essential characteristics of the present invention as described above.

Therefore, the specified embodiments should be considered in terms of explanation rather than limitation, and the scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the equivalent range are included in the present invention. Should be interpreted.

41.42. First conductive pattern 43.44. Second conductive pattern
45. First conductive pattern bridge 46. Second conductive pattern bridge
47. Insulation film

Claims (10)

A first conductive pattern in the form of a set having a first electrode pattern constituting any one sensing cell and a second electrode pattern integrally connected to the first electrode pattern in a first direction to form another neighboring sensing cell; And
A set having a third electrode pattern constituting any one sensing cell and a fourth electrode pattern integrally connected to the third electrode pattern in a second direction perpendicular to the first direction to form another neighboring sensing cell A second conductive pattern of the form,
The first conductive pattern and the second conductive pattern are repeatedly arranged such that the central axes in the longitudinal direction intersect each other, and the longitudinal central axis of the second conductive pattern is the first conductive pattern in the center of the first conductive pattern. Intersects the longitudinal central axis of
A first conductive pattern bridge electrically connecting any one first conductive pattern to another first conductive pattern adjacent to the first conductive pattern in the first direction; And
And a second conductive pattern bridge electrically connecting any one second conductive pattern to another second conductive pattern adjacent to the second conductive pattern in the second direction,
The first conductive pattern bridge and the second conductive pattern bridge are alternately formed in regions where the central axes of the first and second conductive patterns in the longitudinal direction intersect each other. delete delete According to claim 1, The first conductive pattern bridge,
The third electrode pattern constituting the second conductive pattern and the fourth electrode pattern constituting another neighboring sensing cell connected to the third electrode pattern are formed with an insulating layer interposed above the portion connected to each other. Characterized in that the touch sensor. According to claim 1, The second conductive pattern bridge,
The first electrode pattern constituting the first conductive pattern and the second electrode pattern constituting another neighboring sensing cell connected to the first electrode pattern are formed with an insulating layer interposed above the portion connected to each other. Characterized in that the touch sensor. According to claim 1,
A first auxiliary electrode line electrically connecting one first conductive pattern with another first conductive pattern adjacent thereto; And
And a second auxiliary electrode line electrically connecting one second conductive pattern to another second conductive pattern adjacent thereto,
The first auxiliary electrode line and the second auxiliary electrode line alternately pass through regions in which the central axes of the first and second conductive patterns in the longitudinal direction cross each other. delete delete The method of claim 6, wherein the first auxiliary electrode line,
The third electrode pattern constituting the second conductive pattern and the fourth electrode pattern constituting another neighboring sensing cell connected to the third electrode pattern are formed with an insulating layer interposed above the portion connected to each other. Characterized in that the touch sensor. The method of claim 6, wherein the second auxiliary electrode line,
The first electrode pattern constituting the first conductive pattern and the second electrode pattern constituting another neighboring sensing cell connected to the first electrode pattern are formed with an insulating layer interposed above the portion connected to each other. Characterized in that the touch sensor.

Images