KR200492943Y1 - Single layer projection type capacitive touch sensor with double bridge connection - Google Patents

Abstract

The present invention provides a single layer projection type capacitive touch sensor having a double bridge connection, wherein the touch sensor includes a plurality of sensing arrays, and each sensing array includes one common sensing electrode and a plurality of driving electrodes. And, the above-described driving electrodes, which have a large quantity, are divided into two groups, each connected to the electrical terminals in the two bridge connections installed on the rim through electrode connection lines, and each bridge connection is covered with an insulating film and installed, on the insulating film. A through hole is opened at a position corresponding to the electrical terminal as described above, and the driving electrode signal lead electrically connects the electrical terminals of the driving electrode located on the same axis of each sensing array on the touch sensor through the through hole as described above. To form one signal channel in series, and the signal lead electrically connecting the common sensing electrode as described above passes through one of the bridge connecting portions, and is insulated and cross-installed with the signal lead of each driving electrode of the signal channel. , The electrode extension part of the common sensing electrode as described above is extendedly installed to the other bridge connection part, and is insulated and intersected with each driving electrode signal conductor of the signal channel.

Description

Single layer projection type capacitive touch sensor with double bridge connection {SINGLE LAYER PROJECTION TYPE CAPACITIVE TOUCH SENSOR WITH DOUBLE BRIDGE CONNECTION}

The present invention relates to a projection-type capacitive touch sensor, and more particularly, to a single-layer projection-type capacitive touch sensor having a double bridge connection in an independent matrix sensing element structure.

Projection-type capacitive touch sensors are widely used in various electronic products because they have a multitouch function. Among them, the projected capacitive touch sensor having an independent-matrix sense element structure is composed of a plurality of sensing arrays wired on a single layer conductive film, and each sensing array has a common sensing electrode and a plurality of drives. An electrode is provided, and the sensing electrode and the driving electrode are each connected to an electric terminal through one electrode connection line, and the electric terminal is installed on the edge of the touch panel, and signal wiring (FPC or FFC) is By being connected to, the touch signal captured by the touch sensor is transmitted to the detection signal processing unit. As shown in FIG. 7, the driving electrode and the sensing electrode of the independent matrix sensing element structure are all installed on a single conductive layer, and each electrode is an electrical terminal 10' installed on the rim through a direct electrode connection line CW. And the number of electrical terminals 10' is large, so the size of the width of the signal wiring that is matched and connected to it increases considerably, and it may cause contact failure of some electrical terminals and the touch panel may not operate normally. have.

8 and 9, in order to reduce the installation area of the edge of the touch panel, an independent matrix sensing element structure having a bridge connection structure has been proposed, and the bridge connection structure is mainly used for sensing electrodes having a large number of sensing electrodes in each sensing array. And the electric terminal 10' of the driving electrode is distributed and installed on the edge of one side of the touch panel, and is then covered again on the electric terminal 10' as described above using an insulating film 20', corresponding to the electric terminal on the insulating film. After opening the through hole 30 ′ at the location of the driving electrode, the drive electrode electrical terminal located on the same axis of each sensing array through the through hole 30 ′ of the insulating film as described above through the signal lead line TX of the driving electrode (10') is electrically connected to each other to form a signal channel in series, thereby reducing the number of electrical terminals connected to the signal wiring and reducing the number of signal lead wires at the edge of the touch panel, thereby reducing the width of the edge of the touch panel. Achieve the goal of reducing However, in the above-described bridge connection structure, since the signal lead (RX) of the sensing electrode and the signal lead (TX) of the driving electrode as described above are distributed and installed in parallel on the same side plane, the technology of the above-described wiring structure is applied to a large area. Alternatively, when applied to a high-sensitivity touch panel, a large amount of sensing arrays installed on the touch panel cannot effectively reduce the size of the edge by doubling the number of wires of the signal wires (RX) of the sensing electrodes and the signal wires (TX) of the driving electrodes. Will face As a result of this, not only the rim becomes larger and the appearance becomes ugly, but also the effective touch manipulation area can be pushed to reduce touch sensitivity.

In the above-described defect of the structure of an independent matrix sensing element having a bridge connection, an independent matrix sensing element structure having a double bridge connection has been additionally proposed to overcome the problem of application of a large area touch panel. Its approximate structure is similar to the structure of the independent matrix sensing element having the above-described bridge connection. The main difference is that one bridge connection structure is installed on each of the two opposite side edges of the touch panel, and the number of the touch sensing layer is increased. Divide many drive electrodes into two drive electrode groups, connect each to the electrical terminal of the two bridge connection structure through the electrode connection line, then cover again with an insulating film with through-holes installed, and the signal wires of the drive electrodes are located on the same axis. It is to achieve the purpose of reducing the width of the edge by connecting the electric terminals of the driving electrodes in series to form one signal channel, and by distributing the number of wirings of the driving electrode signal conductors to both sides evenly. However, according to the installation of the above-described structure, since the signal lead (PX) of the common sensing electrode of each sensing array can pass through one of the two bridge connection portions, the signal lead (RX) passing through the bridge connection portion is a signal channel. Insulation cross-installed with the signal lead (TX) of each driving electrode used to form a series can form a capacitance node structure, whereby the driving electrode signal lead (TX) as described above passes through the node point. The corresponding node capacitance value may be increased by being coupled to the signal conductor RX. However, since the capacitance node structure is not formed because the common sensing electrode signal conductor (RX) does not pass through the other bridge connection, the node capacitance value increases even on the driving electrode signal conductor (TX) as described above. Does not appear. As a result of this, there is a significant difference in the node capacitance value passing over the driving electrode signal conductor TX of the two bridge connections (refer to the node capacitance value distribution diagram shown in FIG. 10), and the difference in charge and discharge characteristics Because it is excessively large, the touch function is degraded and it becomes difficult by design to increase the sensing signal processing unit.

The present invention provides a single layer projection type capacitive touch sensor having an improved double bridge connection, the touch sensor having an independent matrix sensing element structure, including a plurality of sensing arrays, each sensing array is one A common sensing electrode and a plurality of driving electrodes are provided, and the driving electrodes with a large quantity are divided into two groups, each connected to two electrical terminals in the bridge connection part installed on the edge through an electrode connection line, and each bridge An insulating film is covered and installed at the connection part, a through hole is opened on the insulating film at a position corresponding to the electrical terminal, and the driving electrode signal conductor is on the same axis of each sensing array on the touch sensor through the through hole. The electric terminals of the driving electrodes located at are electrically connected to each other to form one signal channel in series, and the signal lead electrically connecting the common sensing electrodes as described above passes through one of the aforementioned two bridge connections, Each driving electrode that forms one signal channel in series and is insulated and cross-installed, an electrode extension is further installed on the common sensing electrode, and the electrode extension is extended and installed on the other bridge connection, and the aforementioned signal Each driving electrode signal conductor forming a channel in series is intersected with each other insulated, thereby achieving the purpose of reducing the width of the edge of the touch sensor, and balancing the node capacitance values passing through the driving electrode signal conductors of the two bridge connections. It achieves the effect of implementing.

The following describes other functions and technical features of the present invention in more detail, and those skilled in the art to which the present invention belongs may implement the present invention after reading the following specification.

1 is a schematic diagram of a stacking combination according to an embodiment of the present invention.
2 is an exploded view of parts according to an embodiment of the present invention.
3 is a plan view of a component combination according to an embodiment of the present invention.
4 is a plan view of a sensing array according to an embodiment of the present invention.
5 is an enlarged plan view of portion A of FIG. 3.
6 is a distribution diagram of node capacitance values of a first upper signal lead and a first lower signal lead according to an embodiment of the present invention.
7 is a plan view of a conventional touch sensor structure.
8 is a plan view of another conventional touch sensor structure.
9 is an exploded view of a component of the conventional touch sensor structure of FIG. 7.
10 is a diagram illustrating a distribution of node capacitances on a driving electrode signal lead among two bridge connections in a conventional touch sensor.

A relatively preferred embodiment of the present invention described in the accompanying drawings is a single-layer projection type capacitive touch sensor having a double bridge connection, and in order to explain the technical features of the present invention more clearly and easily understandable, Each part was not drafted according to the relative size, some sizes were exaggerated compared to other related sizes, and the drawings were concisely illustrated by not completely drafting unrelated details.

As shown in Figs. 1 to 3, this embodiment mainly includes a transparent base layer 1, a transparent touch sensing layer 2, a bridge connection insulating layer 3, and a signal conducting layer 4. Here, the base layer 1 is a transparent thin layer having a high light transmittance, and can be selected from a high light transmittance thin plate having excellent mechanical strength such as a glass plate or polymethyl methacrylate, and can be selected from polyethylene terephthalate or poly A transparent flexible thin film such as a polycarbonate thin film may be selected, but the kind of the material is not limited to the above scope. An edge 1a formed by coating an insulating material having a opaque or low light transmittance on the circumferential edge of the surface of the base layer 1 is installed, and the central portion on the base layer 1 through the installation of the opaque edge 1a The visible portion 11 forming the is separated, the shielding portion 12 forming the circumferential edge is formed, and the above-described insulating material can be selected from materials such as ink or photoresist, but the range of possible materials is Not limited.

The touch sensing layer 2 is made of a conductive material having a high light transmittance, and the above-described transparent conductive material is made of a transparent thin film made of indium tin oxide, indium zinc oxide, zinc aluminum oxide, or polyethylene dioxythiophene. It is selected from the group, but is not limited thereto. The transparent touch sensing layer has a structure of a slightly independent-matrix sense element, and a plurality of sensing arrays 2a and a ground row are installed in parallel while being spaced apart from each other along a first direction (i.e., Y-axis direction). (2b), and the sensing array 2a as described above is formed within the range of the visible portion 11 described above. In an embodiment of the large-area touch sensor, a plurality of sensing arrays 2a are included in the independent matrix sensing element structure, and each sensing array 2a has one common sensing electrode and a plurality of driving Since the electrode (Driving Electrode) is formed jointly, in this embodiment, as described above, the driving electrode having a large quantity is divided into an upper driving electrode group and a lower driving electrode group, and the number of wires of the signal lead is evenly distributed to both edges. This achieves the purpose of reducing the required wiring space and reducing the width of the border. Referring back to FIG. 4, each sensing array 2a includes a plurality of first upper sensing electrodes 21 (ie, an upper driving electrode group), and a plurality of first lower sensing electrodes 24 (ie, a lower driving electrode group). ) And one second sensing electrode 27 (i.e., sensing electrode), wherein both the first upper sensing electrode 21 and the first lower sensing electrode 24 have a short comb shape, and a side surface thereof A plurality of driving conductors extending along a second direction (ie, the X-axis direction) are provided, and the second sensing electrode 27 has a long comb shape, and a second direction (ie, the X-axis direction) A plurality of sensing conductors extending along) are provided, and the first upper sensing electrode 21, the first lower sensing electrode 24, and the second sensing electrode 27 are provided in a mutually complementary shape. In addition, each first upper sensing electrode 21 is electrically connected to the first upper electrical terminal 212 in the upper bridge connection 28 through an electrode connection line 211, and each first lower sensing electrode 24 The silver electrode connection line 241 is electrically connected to the first lower electrical terminal 242 in the lower bridge connection 29. The first end (ie, the upper end) of the second sensing electrode 27 is electrically connected to the second electrical terminal 272 through the above-described upper bridge connection 28 through the electrode connection line 271, and the second An electrode extension part 273 is installed at the second end (ie, the lower end) of the sensing electrode 27, the electrode extension part 273 is formed in the lower bridge connection part 29, and the electrode extension part ( The extension length of the 273 is at least greater than the position of the first lower electrical terminal 242 installed at the bottom of the first lower electrical terminals 242 as described above, or passes through the lower bridge connecting portion 29 described above. The upper bridge connecting portion 28, the lower bridge connecting portion 29 and the second electrical terminal 272 are all formed within the range of the shielding portion 12 described above. The first end of the ground column 2b described above is formed in the upper bridge connection part 28, and the second end is formed in the lower bridge connection part 29.

The bridge connection insulating layer 3 includes an upper bridge connection insulating film 31 and a lower bridge connection insulating film 35, wherein the upper bridge connection insulating film 31 is covered and installed on the upper bridge connection part 28 described above. And, a plurality of through holes 32 are provided on the upper bridge connection insulating layer 31 to correspond to the positions of the first upper electrical terminals 212 and the first ends of the ground row 2b, respectively. . The lower bridge connection insulating film 35 is covered and installed in the above-described lower bridge connection part 29, and a plurality of through-holes 36 are installed on the lower bridge connection insulating film 35 so that each of the aforementioned first lower electricity Each corresponds to the position of the terminal 242.

The signal conductor layer 4 is installed within the range of the shielding portion 12 described above, which is a plurality of first upper signal conductors 41 (ie, upper driving signal conductors) and a plurality of first lower signal conductors 42 ), a plurality of second signal leads 43 (i.e., a lower driving signal lead), a ground signal lead 44 and a signal output terminal 48, wherein each of the first upper signal leads 41 The first electrical terminals 212 are electrically connected to the first upper electrical terminals 212 through the through holes 32 on the upper bridge connection insulating film 31, and are positioned on the same axis in the second direction of each sensing array 2a. The upper electrical terminal 212 is electrically connected to form a signal channel in series, the end of the first upper signal conductor 41 is electrically connected to the signal output terminal 48, and the signal output terminal 48 is It is installed on the outer edge of the shielding portion 12 described above. Each of the first lower signal conductors 42 is electrically connected to the first lower electrical terminal 242 through the through hole 36 on the lower bridge connection insulating layer 35 described above, and the first lower signal conductor 42 is A signal channel is formed in series by electrically connecting the first lower electrical terminals 242 located on the same axis in two directions, and the end of the first lower signal conductor 42 is electrically connected to the signal output terminal 48. Connected. Each second signal lead 43 is electrically connected to each second electrical terminal 272, respectively, and an end of the second signal lead 43 is electrically connected to the signal output terminal 48. The ground signal conductor 44 is electrically connected to the first end of the ground column 2b through the through hole 32 on the upper bridge insulating layer 31 described above, and each ground column 2b forms a signal channel. And the end of the ground signal lead 44 is electrically connected to the signal output terminal 48. The signal conductor layer 4 is made of a conductive material with a low resistivity, for example, by etching a conductive thin film of gold, silver, copper, aluminum, molybdenum, nickel, or the aforementioned material alloy, or conductive silver paste or conductive ink It is formed by printing with, but the implementation method is not limited to the above-described implementation range.

According to the touch sensor structure described above, a signal of the first upper sensing electrode 21 (ie, an upper driving electrode) is transmitted using a first upper signal lead (ie, an upper driving signal lead), and the first lower signal The signal of the first lower sensing electrode 24 (ie, the lower driving electrode) is transmitted using the conductor 42 (ie, the lower driving signal conductor), and the second signal conductor 43 (that is, the sensing signal conductor) is After transmitting the signal of the second sensing electrode 27 (i.e., sensing electrode) by using, and transmitting the same signal to the signal output terminal 48, the signal output terminal 48 again using an FFC or FPC connector. It connects to and transmits a touch detection signal to the signal processing circuit to perform calculations. In this embodiment, a driving electrode having a large quantity on the touch sensing layer is divided into two groups, an upper driving electrode and a lower driving electrode, and a signal is connected by wiring in the upper bridge connection part 28 and the lower bridge connection part 29. By distributing the number of wires of the signal connection evenly across the edges of both sides, and installing the upper bridge connection insulating film 31 and the lower bridge connection insulating film 35 having through holes as described above, the first upper signal conductor 41 , So that the first lower signal conductor 42 connects a plurality of electrical terminals (first upper electrical terminal 212, first lower electrical terminal 242) of the related driving electrode in series to form a signal channel. In this way, the number of signal wires disposed on the signal wire layer 4 is significantly reduced, and the width of the shielding part 12 is reduced to facilitate application to a design that narrows the edge of the touch panel.

In addition, as shown in FIG. 5, in the upper bridge connection part 28 of the present embodiment, the crossing point of the electrode connection line 271 of the first end of the second sensing electrode 27 and the first upper signal conductor 41 Since the capacitance node structure is formed, the first upper signal lead 41 is coupled with the electrode connection line 271 of the second sensing electrode 27 through the node point, thereby increasing the corresponding node capacitance value, Likewise, the intersection of the second sensing electrode 27, the second end electrode extension 273 and the first lower signal conductor 42 in the lower bridge connection 29 also forms a capacitance node structure. The lower signal lead 42 is coupled with the electrode extension 273 of the second sensing electrode 27 through the node point to increase the corresponding node capacitance value, thereby increasing the upper bridge connection 28 and the lower Slightly the same node capacitance value increase value is provided through the first upper signal lead 41 and the first lower signal lead 42 of the bridge connection 29 (node capacitance value distribution diagram shown in FIG. 6), Achieves the purpose of parallelizing the change in the node capacitance value of both the upper and lower drive electrode groups, thereby preventing various unfavorable characteristics caused by excessively large differences in the node capacitance values of the upper and lower drive electrode groups. do.

Claims (8)

The single-layer projection type capacitive touch sensor having a double bridge connection comprises a base layer 1, a touch sensing layer 2, a bridge connection insulating layer 3, and a signal conductor layer 4,
The base layer 1 is a visible part 11 having a transparent central part, and a rim 1a is installed at the rim to form a shield 12;
The touch sensing layer 2 is an independent matrix sensing element structure made of a conductive material having a high light transmittance, and includes a plurality of sensing arrays 2a and ground columns 2b that are spaced apart from each other and installed in parallel along a first direction. And a plurality of the sensing arrays 2a are formed within the range of the visible portion 11, wherein each of the sensing arrays 2a is a plurality of first upper sensing electrodes 21 and a plurality of Including 1 lower sensing electrode 24 and one second sensing electrode 27, each of the first upper sensing electrode 21 is installed in the upper bridge connection part 28 through the electrode connection line 211 1 It is electrically connected to the upper electrical terminal 212, and each of the first lower sensing electrodes 24 is connected to the first lower electrical terminal 242 installed in the lower bridge connection part 29 through the electrode connection line 241. Electrically connected, the upper bridge connection part 28 and the lower bridge connection part 29 are both formed within the range of the shielding part 12, and the first end of the second sensing electrode 27 is an electrode connection line ( It is electrically connected to the second electrical terminal 272 by passing through the upper bridge connecting part 28 through 271, and an electrode extension part 273 is installed at the second end of the second sensing electrode 27, The electrode extension part 273 is formed in the lower bridge connection part 29, the first end of the ground column 2b is formed in the upper bridge connection part 28, and the second end is formed in the lower bridge connection part 29 ) Is formed within;
The bridge connection insulating layer 3 includes an upper bridge connection insulating film 31 and a lower bridge connection insulating film 35, wherein the upper bridge connection insulating film 31 is covered by the upper bridge connection part 28 Is installed, and a plurality of through holes 32 are installed on the upper bridge connection insulating film 31 to be positioned at the first end of the plurality of first upper electrical terminals 212 and the plurality of ground rows 2b Corresponding to each, the lower bridge connection insulating film 35 is installed by being covered with the lower bridge connection part 29, and a plurality of through holes 36 are installed on the lower bridge connection insulating film 35 1 each corresponding to the position of the lower electrical terminal 242;
The signal conducting layer 4 is provided within the range of the shielding part 12, and is provided with a plurality of first upper signal leads 41, a plurality of first lower signal leads 42, and a plurality of second signal leads ( 43), a ground signal lead 44 and a signal output terminal 48, wherein the first upper signal lead 41 is the through hole 32 on the upper bridge connection insulating film 31 The first upper electrical terminals 212 are electrically connected to the first upper electrical terminals 212 and located on the same axis in the second direction of each of the sensing arrays 2a to electrically connect the signal channels in series. And the end of the first upper signal conductor 41 is electrically connected to the signal output terminal 48, and the signal output terminal 48 is installed on the outer edge of the shielding part 12, , The first lower signal conductor 42 is electrically connected to the first lower electrical terminal 242 through a through hole 36 on the lower bridge connection insulating layer 35, and each of the sensing arrays 2a A signal channel is formed in series by electrically connecting each of the first lower electrical terminals 242 positioned on the same axis in the second direction of the signal, and the end of the first lower signal conductor 42 outputs the signal Electrically connected to a terminal 48, the second signal wire 43 is electrically connected on the second electrical terminal 272, and an end of the second signal wire 43 is the signal output terminal ( 48), and the ground signal conductor 44 is electrically connected to the first end of the ground row 2b through the through hole 32 on the upper bridge insulating film 31, and each of the The ground column 2b forms a signal channel in series, and an end of the ground signal lead 44 is electrically connected to the signal output terminal 48,
Here, among the upper bridge connecting portions 28, the electrode connecting lines 271 of the plurality of second sensing electrodes 27 and the plurality of first upper signal leads 41 are intersected insulatedly, and the lower bridge connecting portion 29 ), the electrode extension portions 273 of the plurality of second sensing electrodes 27 and the plurality of first lower signal conductors 42 are intersected with insulation, and the plurality of insulated cross-installing points form a capacitance node. A single layer projection type capacitive touch sensor having a double bridge connection, characterized in that. The method of claim 1,
The conductive material of the transparent touch sensing layer (2) is a single-layer projection type capacitive touch sensor having a double bridge connection selected from the group consisting of indium tin oxide, indium zinc oxide, zinc aluminum oxide, or polyethylenedioxythiophene. The method of claim 1,
The first upper sensing electrode 21 and the first lower sensing electrode 24 are driving electrodes, and the second sensing electrode 27 is a single-layer projection type capacitive type having a double bridge connection that is a common sensing electrode. Touch sensor. The method of claim 1,
The signal conductor layer 4 is a single-layer projection type capacitive touch sensor having a double bridge connection formed by etching a conductive thin film of gold, silver, copper, aluminum, molybdenum, nickel, or the aforementioned material alloy. The method of claim 1,
The signal conductor layer 4 is a single-layer projection type capacitive touch sensor having a double bridge connection formed by printing from a conductive silver paste or conductive ink. The method of claim 1,
The rim 1a is a thin film layer formed of an insulating material having opaque or low light transmittance, and the insulating material is a single-layer projection type capacitive touch sensor having a double bridge connection selected from the group consisting of ink or photoresist. The method of claim 1,
The electrode extension part 273 is formed in the lower bridge connection part 29, and the extension length is at least the position of the first lower electrical terminal 242 installed at the bottom of the plurality of first lower electrical terminals 242 A single layer projection type capacitive touch sensor having a double bridge connection in excess of. The method of claim 1,
A single layer projection type capacitive touch sensor having a double bridge connection through which the electrode extension portion 273 passes through the lower bridge connection portion 29.

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