KR20160027479A - Touch sensor integrated type liquid crystal display device - Google Patents

Abstract

The present invention relates to a touch sensor integrated type liquid crystal display device to prevent an increase in a bezel region and a decrease in image quality. The touch sensor integrated type liquid crystal display device includes gate lines and data lines, pixel electrodes, touch electrodes for common electrodes, touch routing lines, compensation routing lines, and a source driving and touch sensing IC. The source driving and touch sensing IC drives and senses a plurality of touch electrodes functioning as common electrodes; senses each common voltage of at least part of the touch electrodes functioning as common electrodes through the compensation routing lines; and supplies a compensation voltage for removing the ripple voltage of the at least part of the touch electrodes functioning as common electrodes to the at least part of the touch electrode functioning as common electrodes, respectively.

Description

TECHNICAL FIELD [0001] The present invention relates to a touch sensor integrated liquid crystal display LIQUID CRYSTAL DISPLAY DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a touch sensor built-in liquid crystal display, and more particularly, to a touch sensor built-in display device capable of preventing an increase in bezel area and deterioration in image quality.

In recent years, there has been a demand for display devices that can be enlarged in size, cost is low, and display quality (video expression power, resolution, brightness, contrast ratio, color reproduction power, etc.) (Hereinafter simply referred to as "display device") has been developed. In these flat display devices, various input devices such as a keyboard, a mouse, a trackball, a joystick, and a digitizer are used to configure an interface between a user and a display device.

However, the use of the above-described input device has a drawback in that it is required to learn how to use it and occupies a space, which makes it difficult to improve the completeness of the product. Accordingly, there is a growing demand for an input device for a display device that is convenient and simple and can reduce malfunctions. In response to such a request, a touch sensor has been proposed that allows a user to directly touch the screen with a hand or a pen or the like while looking at the display device, and to recognize information when the information is input.

The touch sensor is simple, has little malfunction, can be input without using a separate input device, and is also applicable to various display devices because of convenience that the user can quickly and easily operate the contents displayed on the screen have.

The touch sensor used in the above-described display device can be classified into an add-on type, an on-cell type, and an integrated type or an in-cell type according to its structure. In the top plate attaching type, the touch sensor module is attached to the upper plate of the display device after separately manufacturing the display device and the touch sensor module. The top plate integral type is a method of directly forming the touch sensor elements on the upper glass substrate surface of the display device. The built-in type incorporates touch sensor elements in the display device to achieve a thin display device and enhance durability.

Among these touch sensors, a built-in touch sensor can commonly use a common electrode of a display device as a touch electrode, thereby making it possible to reduce the thickness of the touch sensor, and a touch device is formed in the display device to increase its durability.

Since the built-in touch sensor has durability and thinness, attention is focused on it because it can solve the disadvantages of the top-mounted touch sensor and the top-plate integrated touch sensor. The built-in touch sensor is divided into an optical type and a capacitive type according to a method of sensing a touched portion, and the electrostatic type is subdivided into a self capacitance type and a mutual capacitance type. do.

The self-capacitance type touch sensor forms a plurality of independent patterns in the touch area of the touch sensing panel and measures the change of the capacitance of each independent pattern to determine whether or not the touch is detected. The mutual capacitance type touch sensor includes a plurality of X-axis electrode lines (for example, driving electrode lines) and Y-axis electrode lines (for example, sensing electrode lines) A drive pulse is applied to the X-axis electrode lines, and a change in voltage appearing at sensing nodes defined as the intersection of the X-axis electrode lines and the Y-axis electrode lines through the Y-axis electrode lines is detected To determine whether or not a touch is made.

The mutual capacitance type touch sensor has a very small mutual capacitance generated during the touch recognition, whereas the parasitic capacitance between the gate line and the data line constituting the display device is very large. Therefore, It is difficult to accurately recognize the image.

In addition, since the mutual capacitance type touch sensor requires a plurality of touch driving lines for touch driving and a plurality of touch sensing lines for touch sensing on the common electrode for multitouch recognition, a very complicated wiring structure is required .

The self-capacitance type touch sensor has a wider wiring structure than the mutual capacitance type touch sensor and can be used to increase the touch accuracy.

The self-capacitance type touch sensor has a wider wiring structure than the mutual capacitance type touch sensor and can be used to increase the touch accuracy.

Hereinafter, a conventional liquid crystal display device with a self-capacitance type touch sensor (hereinafter referred to as a "touch sensor built-in type display device") will be described with reference to Figs. FIG. 1 is a plan view of a conventional touch sensor built-in type display device, FIG. 2 is a plan view showing a partial region R1 shown in FIG. 1, FIG. 3 is a sectional view taken along a line I- FIG. 4 is a waveform diagram showing that ripples are generated in a common voltage by a parasitic capacitance formed between a touch electrode (common electrode), a gate line, and a data line in a conventional touch sensor built-in display device.

Referring to FIG. 1, the touch sensor built-in type display device includes touch electrodes, an active area AA for displaying data, a plurality of wirings, a source driving and a touch sensing IC 10 disposed outside the active area AA, And a bezel area BA formed therein.

The active area AA includes a plurality of touch electrodes Tx11 to Tx14 and Tx21 to Tx24 that are divided in a first direction (for example, an x-axis direction) and a second direction (for example, Tx31 to Tx34, Tx41 to Tx44 and Tx51 to T54 and the plurality of touch electrodes Tx11 to Tx14, Tx21 to Tx24, Tx31 to Tx34, Tx41 to Tx44 and Tx51 to T54, TW21 to TW24, TW31 to TW34, TW41 to TW44, and TW51 to TW54 arranged in parallel with each other.

The plurality of touch electrodes Tx11 to Tx14, Tx21 to Tx24, Tx31 to Tx34, Tx41 to Tx44 and Tx51 to T54 in the active area AA are formed by dividing the common electrode of the display device, And operates as a common electrode while the touch operation for recognizing the touch position operates as a touch electrode.

The bezel area BA is disposed outside the active area AA, and includes a source driving and touch sensing IC 10, and various wirings. The display driver IC and the touch driver IC 10 drive the gate lines (not shown) of the display device at the time of display driving, supply display data to the data lines, and apply common voltage . The source driving and touch sensing IC 10 also supplies a touch driving voltage to the touch electrodes at the time of touch operation and scans the capacitance change of the touch electrodes before and after the touch to determine the position of the touch electrode . The various wirings include touch routing wirings (TW11 to TW14, TW21 to TW24, TW31 to TW34, TW41 to TW44) connected to the touch electrodes (Tx11 to Tx14, Tx21 to Tx24, Tx31 to Tx34, Tx41 to Tx44, Tx51 to T54) (Not shown), data lines (not shown), and touch routing lines TW11 to TW14, TW21 to TW24, TW31 to TW34, and TW31 to TW34 connected to the source driving and touch sensing IC 10 , TW41 to TW44, TW51 to TW54).

2 and 3, a conventional touch sensor built-in type display device includes a thin film transistor (TFT) formed on a substrate SUB, a pixel electrode Px connected to a drain electrode DE of the thin film transistor, And a touch electrode Tx11 formed so as to overlap the electrode and form a horizontal electric field.

The thin film transistor TFT includes a gate electrode GE extending from a gate line GL formed on a substrate SUB and a gate electrode GE extending over a gate insulating film GI covering the gate line GL and the gate electrode GE. A semiconductor active layer A formed so as to overlap a part of the electrode GE and a source electrode SE and a drain electrode DE formed on the semiconductor active layer and spaced apart at regular intervals. The data line DL is formed on the same layer as the drain electrode DE.

The pixel electrode Px is formed on the gate insulating film GI and the drain electrode DE and is directly connected to the drain electrode DE.

The data line DL and the source electrode SE and the drain electrode DE of the thin film transistor TFT and the pixel electrode Px are covered with the first passivation film PAS1. A touch routing wiring TW11 is formed on the first passivation film PAS1 so as to overlap the data line DL. The touch routing wiring TW11 formed on the first passivation film PAS1 is covered with the second passivation film PAS2.

The touch electrodes Tx11 are formed on the second passivation film PAS2. The touch electrode Tx11 has a plurality of slits SL to form a horizontal electric field with the pixel electrode Px formed on the gate insulating film INS.

When a conductive metal such as a finger or a stylus pen is touched to the active area AA of the display device in the touch sensor built-in display device having the above-described structure, the touch sensor built- The touch position can be sensed by recognizing the change in capacitance. That is, a driving pulse is applied to the touch electrodes Tx11 to Tx14, Tx21 to Tx24, Tx31 to Tx34, Tx41 to Tx44, and Tx51 to Tx54 formed in the active area AA, and then the touch electrodes Tx11 to Tx14 and Tx21 To Tx24, Tx31 to Tx34, Tx41 to Tx44, and Tx51 to Tx54) to sense touch positions of the touch electrodes before and after touching.

However, as the size and the resolution of the conventional touch sensor built-in type display device increases, the load on the touch electrode (common electrode) remote from the source driving and the touch sensing IC 10 increases. As a result, a ripple is generated in the common voltage supplied to the touch electrode (common electrode) as shown in FIG. 4, causing an error in the image displayed on the display device. In order to prevent such a ripple, a common voltage compensation circuit can be designed. In this case, however, there is a problem that a bezel region increases or a parasitic capacitance due to a compensation design of the common electrode may be additionally generated.

SUMMARY OF THE INVENTION The present invention provides a touch sensor built-in type display device capable of preventing a ripple from being generated in a common voltage without increasing a bezel area according to a compensation design of a common electrode, .

A touch sensor built-in display device for achieving the above object is provided with a plurality of gate lines and data lines, a plurality of pixel electrodes, a plurality of touch electrodes serving as common electrodes, a plurality of touch routing lines, a compensation routing line, Touch IC. The source driver and the touch IC drive and sense a plurality of common electrode touch electrodes by touch routing wiring, sense common voltages of at least some of common electrode common touch electrodes through compensating routing wirings, And a compensation voltage for removing the ripple voltage of the electrode-combined touch electrodes is supplied to the at least one common electrode and the touch electrodes.

In this configuration, the plurality of touch routing wirings and the compensation routing wirings are arranged in parallel with each other and overlap with the data lines, and the number of the plurality of touch routing wirings can be determined to be equal to or greater than the number of the compensation routing wirings.

In addition, the plurality of touch routing wirings are connected to the plurality of common electrode touch electrodes at a ratio of 1: 1, and the compensation routing wirings are connected to the common electrode and the touch electrode arranged from the farthest line to the predetermined line, 1: 1 < / RTI >

In addition, the display device with a touch sensor of the present invention may further include a plurality of thin film transistors arranged at intersections of a plurality of gate lines and a plurality of data lines. The pixel electrode may be formed on a gate insulating film covering the gate lines formed on the substrate and connected to the drain electrode of the thin film transistor. The touch routing wirings and compensating routing wirings may be formed to overlap the data lines on the first passivation film covering the thin film transistors. The common electrode and the touch electrode may be formed to overlap the pixel electrode on the second passivation film covering the routing wirings.

In addition, the touch routing wiring is connected to the common electrode and the touch electrode through the contact hole formed in the second passivation film, and the compensating routing wiring is connected to at least a part of the common electrode by the other contact hole formed in the second passivation film. Lt; / RTI >

According to the touch sensor built-in type display device of the present invention, the compensation routing wiring can be connected to each touch electrode together with the touch routing wiring, so that the ripple voltage generated in each touch electrode can be removed. Therefore, it is possible not only to prevent an increase in the bezel area due to the compensation design of the common electrode and the touch electrode, but also to prevent the generation of the parasitic capacitance and to prevent the deterioration of the image quality.

1 is a plan view schematically showing a conventional touch sensor built-in type display device,
FIG. 2 is a plan view showing a partial region R1 shown in FIG. 1,
3 is a cross-sectional view taken along the line I-I 'shown in FIG. 2,
4 is a waveform diagram showing ripples generated in a common voltage due to parasitic capacitances formed between a touch electrode (common electrode), a gate line, and a data line in a conventional touch sensor built-
5 is a partially exploded perspective view schematically showing a touch sensor built-in type display device according to an embodiment of the present invention,
6 is a plan view showing the wiring relationship with the common electrode and the touch electrode of the touch sensor built-in display device according to the embodiment of the present invention,
7 is a plan view schematically showing the relationship between the common electrode serving as the touch electrode and the pixel electrode in the region R3 shown in Fig. 6,
FIG. 8 is a plan view showing in detail the region R4 shown in FIG. 7,
9 is a cross-sectional view taken along line I-I 'of FIG. 8,
10 is a waveform diagram conceptually illustrating removal of a ripple voltage generated in a touch electrode serving as a common electrode by using a compensation voltage.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a touch sensor built-in type display device of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals refer to like elements throughout the specification. In the following description, a touch sensor built-in liquid crystal display device will be described as an example of the touch sensor built-in display device.

First, with reference to Figs. 5 and 6, description will be given of a touch sensor built-in display device according to an embodiment of the present invention

The FIG. 5 is a partially exploded perspective view schematically showing a touch sensor built-in type display device according to an embodiment of the present invention. FIG. 6 is a cross-sectional view of a touch electrode (touch electrode) Fig.

5, the touch sensor built-in type display device according to the embodiment of the present invention includes a thin film transistor array (TFTA) formed with a liquid crystal layer (not shown) therebetween and a liquid crystal display panel (LCP).

The thin film transistor array TFTA includes a plurality of gate lines G1 and G2 formed on a first substrate SUB1 in a first direction (for example, x direction), a plurality of gate lines G1, The data lines D1 and D2 formed to be parallel to each other in the second direction (e.g., the y direction) so as to intersect with the gate lines G1 and G2, the gate lines G1 and G2 and the data lines D1 and D2, A plurality of pixel electrodes Px for charging a data voltage to the liquid crystal cells, and common electrodes (not shown) arranged to face the plurality of pixel electrodes Px (Not shown).

The color filter array CFA includes a black matrix and a color filter (not shown) formed on the second substrate SUB2. Polarizers POL1 and POL2 are attached to the outer surfaces of the first substrate SUB1 and the second substrate SUB2 of the liquid crystal display panel LCP and the polarizers POL1 and POL2 are attached to the outer surfaces of the first and second substrates SUB1 and SUB2 And an orientation film (not shown) for setting the pretilt angle of the liquid crystal is formed on the inner surface. A column spacer for maintaining a cell gap of the liquid crystal cell may be formed between the color filter array CFA and the thin film transistor array TFTA of the liquid crystal display panel LCP.

Meanwhile, the common electrodes are formed on the second substrate SUB2 in a vertical electric field driving method such as TN (Twisted Nematic) mode and VA (Vertical Alignment) mode, and in the IPS (In Plane Switching) mode and the FFS The pixel electrode Px is formed on the first substrate SUB1. In the following embodiments of the present invention, the horizontal electric field driving method will be described as an example.

Referring to FIG. 6, a liquid crystal display device with a touch sensor according to an embodiment of the present invention includes an active area AA and a bezel area BA. The active area AA is a region where common electrode and touch electrodes are formed and data is displayed. The bezel area BA is disposed outside the active area AA and is an area where the source driving and touch sensing IC 100 and various wirings are formed.

The active area AA of the touch sensor built-in liquid crystal display device is divided into a plurality of common electrode-touching touches (not shown) divided in a first direction (for example, an x-axis direction) and a second direction And a plurality of touch electrodes arranged in parallel with each other in the second direction so as to be connected to the respective electrodes (hereinafter, simply referred to as touch electrodes) (Tx11 to Tx16, Tx21 to Tx26, Tx31 to Tx36, Tx41 to Tx46, and Tx51 to Tx56) And the touch electrodes Tx11 to Tx16, Tx21 to Tx26, Tx31 to Tx36, Tx41 to Tx46, Tx51 to Tx56, And a plurality of touch routing lines TL11 to TL16 and TL21 to TL21 are connected to the touch electrodes Tx11 to Tx16, Tx21 to Tx26, and Tx31 to Tx36 located farther from the source driving and touch sensing IC 100, CL16, CL21 to CL26, and CL31 to CL36 arranged in parallel with the transmission lines WL31 to TL26, TL31 to TL36, TL41 to TL46, and TL51 to TL56.

In the touch sensor built-in type display device according to the embodiment of the present invention, as described above, the touch wiring lines (Tx11 to Tx16, Tx21 to Tx26, Tx31 to Tx36, Tx41 to Tx46, and Tx51 to Tx56) (Tx11 to Tx16 (TL1 to TL16, TL21 to TL26, TL31 to TL36, TL41 to TL46 and TL51 to TL56) connected to the source line and the touch sensing IC 100, The compensating routing lines CL11 to CL16, CL21 to CL26, and CL31 to CL36 are connected to the touch electrodes Tx31 to Tx36, respectively, which are located from a predetermined position to a predetermined line.

A source driver and a touch IC 100 are disposed in the bezel area BA. The source driving and touch IC 100 includes touch routing wirings TL11 to TL16, TL21 to TL26, TL31 to TL36, TL41 to TL46 and TL51 to TL56 and compensation routing wirings CL11 to CL16, CL21 to CL26, CL36 to detect the presence or absence of the touch of the touch electrodes Tx11 to Tx16, Tx21 to Tx26, Tx31 to Tx36, Tx41 to Tx46 and Tx51 to Tx56 and supplies a compensation voltage capable of removing the ripple voltage.

The number of touch electrodes to which the compensating routing wirings of the present invention are connected depends on the number of all the pixel electrodes of the display device and the number of the touch electrodes. For example, assume that the number of touch electrodes in the horizontal direction and the vertical direction is 70, and the number of the pixel electrodes corresponding to one touch electrode is 81 in the touch sensor built-in type display device. Since at least one touch routing wiring for touch sensing should be connected to each of the touch electrodes, the number of touch routing wirings connected to the longitudinally arranged touch electrode is 70, and the number of the touch routing wirings connected to the pixel electrodes corresponding to one touch electrode The number of data lines for supplying the voltage is 81. Since the touch routing wiring is formed so as to overlap the data lines in order to prevent the aperture ratio of the display device from being reduced, eleven additional routing wirings can be formed so as to overlap with the data lines. Since these eleven routing wirings are redundant wirings, a compensating voltage for canceling the ripple voltage generated in the touch electrode (common electrode) can be used as a compensating routing wiring for supply. Accordingly, the compensating routing lines can be allocated to the touch electrodes located in the top row from the touch electrodes to the eleventh line, respectively.

In the embodiment of the present invention, for convenience of explanation, 30 touch electrodes are arranged in 5 rows and 6 columns (refer to FIG. 6), and pixel electrodes corresponding to the respective touch electrodes are arranged in 5 rows and 8 columns (See Fig. 7) is described as an example. Therefore, in the embodiment of the present invention, three routing wirings can be used as redundant wirings, and compensating routing wirings can be assigned to the touch electrodes arranged up to three rows.

The touch electrodes to which the compensation routing wirings are allocated are related to the source driving and the position of the touch sensing IC 100 for supplying the touch driving voltage and the common voltage. In the embodiment of the present invention, the source driving and the touch sensing IC 100 are active Side bezel area BA of the area AA.

Hereinafter, the relationship among the touch electrodes disposed in five rows and six columns, the touch routing wires connected to the touch electrodes, and the compensation routing wires will be described with reference to FIGS. 7 through 9. FIG. 7 is a plan view schematically showing the relationship between the common electrode and the common electrode in the region R3 shown in Fig. 6 and the pixel electrode, Fig. 8 is a plan view showing in detail the region R4 shown in Fig. 7, 8 is a cross-sectional view taken along the line I-I 'in Fig.

First, the relationship between the touch electrodes disposed in the active area AA and the touch routing wires and the compensation routing wires will be described in more detail with reference to FIGS. 6 and 7. FIG.

The first row of the active area AA and the 1-1 th touch electrode Tx11 disposed in the first column are connected to the source driving and touch sensing IC 100 through the 1-1 th touch electrode Tx11, 1 touch routing wiring (TL11) and the 1-1 compensation routing wiring (CL11) are connected. The 1-1 touch routing wiring TL11 and the 1-1 compensation routing wiring CL11 are arranged in parallel with each other and are arranged to overlap with the data lines as shown in Fig.

The first and second touch electrodes Tx12 arranged in the first row and the second column of the active area AA are connected to the source driving and touch sensing IC 100 through the first- 2 touch routing wiring (TL12) and the 1-2 compensation routing wiring (CL12) are connected. The 1-2 touch routing wiring TL12 and the 1-2 com- pensation routing wiring CL12 are arranged in parallel with each other and are arranged to overlap with the data line as shown in Fig.

The first to third touch electrodes Tx13 arranged in the first row and the third column of the active area AA are connected to the source driving and touch sensing IC 100 through the first- 3 touch routing wiring TL13 and the first-third compensation routing wiring CL13 are connected. The first-third touch routing wiring TL13 and the first-second compensation routing wiring CL13 are arranged in parallel with each other and are arranged to overlap with the data lines as shown in Fig.

The first to fourth touch electrodes Tx14 disposed in the first row and the fourth column of the active area AA are connected to the source driving and touch sensing IC 100 through the first to fourth touch electrodes Tx14, 4 Touch routing wiring (TL14) and the 1-4th compensation routing wiring (CL14) are connected. The first to fourth touch routing wiring TL14 and the first to fourth compensation routing wiring CL14 are arranged in parallel with each other and arranged to overlap with the data lines as shown in Fig.

The first to fifth touch electrodes Tx15 disposed in the first row and the fifth column of the active area AA are connected to the source driving and touch sensing IC 100 through the first- 5 The touch routing wiring (TL15) and the 1-5th compensation routing wiring (CL15) are connected. The first to fifth touch routing wiring TL15 and the first to fifth compensation routing wiring CL15 are arranged in parallel with each other and are arranged to overlap with the data lines as shown in Fig.

The first 1-6 touch electrode Tx16 disposed in the first row and the sixth column of the active area AA is connected to the source driving and touch sensing IC 100 through the 1- 6 The touch routing wiring (TL16) and the 1-6 compensation routing wiring (CL16) are connected. The 1-6 touch routing wiring TL16 and the 1-6 compensation routing wiring CL16 are arranged in parallel with each other and are arranged to overlap with the data lines as shown in Fig.

In this manner, the first to sixth touch electrodes Tx21 to Tx26 disposed in the second row, the first column to the sixth column of the active area AA are subjected to the second- The second to the sixth compensation wiring lines CL21 to CL26 are connected to the wirings TL21 to TL26 and the third to seventh- The 3-1 to 3-6 touch routing wirings TL31 to TL36 and the 3-1 to 3-6 compensation routing wirings CL31 to CL36 are connected to the six touch electrodes Tx31 to Tx36, do.

The 4-1th touch electrode Tx41 disposed in the fourth row and the first column of the active area AA is connected to the source driving and touch sensing IC 100 through the 4-1th touch electrode Tx41, 4-1 Touch routing wiring (TL41) is connected. The 4-1 touch routing wiring TL41 is arranged so as to overlap the data lines as shown in Fig.

The fourth-second touch electrode Tx42 disposed in the fourth row and the second column of the active area AA is connected to the source driving and the touch sensing IC 100 through the fourth- 2 Touch routing wiring (TL42) is connected. The fourth-2-th touch routing wiring TL42 is arranged so as to overlap the data lines as shown in Fig.

The fourth-third touch electrode Tx43 disposed in the fourth row and third column of the active area AA is connected to the fourth-third touch electrode Tx43 through the fourth- 3 Touch routing wiring (TL43) is connected. The fourth 4-3 touch routing wiring TL43 is arranged so as to overlap the data lines as shown in Fig.

The fourth and fourth touch electrodes Tx44 disposed in the fourth row and the fourth column of the active area AA are connected to the source driving and the touch sensing IC 100 through the fourth 4- 4 Touch routing wiring (TL44) is connected. The fourth to fourth touch routing wiring TL44 is arranged so as to overlap the data lines as shown in Fig.

The fourth-fifth touch electrode Tx45 disposed in the fourth row and the fifth column of the active area AA is connected to the fourth-fifth touch electrode Tx45 connected to the source driving and the touch sensing IC 100, 5 Touch routing wiring (TL45) is connected. The 4-5th touch routing wiring TL45 is arranged so as to overlap the data lines as shown in Fig.

The fourth-sixth touch electrode Tx46 disposed in the fourth row and the sixth column of the active area AA is connected to the fourth-sixth touch electrode Tx46 through the fourth- 6 Touch routing wiring (TL46) is connected. The fourth 4-6 touch routing wiring TL46 is arranged so as to overlap the data lines as shown in Fig.

In this manner, the 5-1th to 5-6th touch electrodes (Tx51 to Tx56) arranged in the fifth row, the first column to the sixth column of the active area (AA) And the routing wirings TL51 to TL56 are respectively connected.

Next, a touch sensor built-in display device according to an embodiment of the present invention will be described in more detail with reference to FIGS. 7 to 9. FIG. In the following description, three pixel regions will be mainly described for convenience of explanation. 7 is a plan view schematically showing the relationship between the common electrode serving as the touch electrode and the pixel electrode in the region R3 shown in Fig. 6, Fig. 8 is a plan view showing in detail the region R4 shown in Fig. 7, 8 is a cross-sectional view taken along the line I-I 'in Fig.

7 to 9, a touch sensor built-in type display device according to an embodiment of the present invention includes gate lines G21 to G25 formed to intersect each other on a substrate SUB1 of a thin film transistor array (TFTA) Thin film transistors TFT formed at intersections of the lines D1 to D8 and the gate lines G21 to G25 and the data lines D1 to D8 and gate lines G21 to G25, The pixel electrodes P11 to P58 formed in the region defined by the intersection of the data lines D1 to D8 and the common electrode touch electrode Tx51 facing the pixel electrodes P11 to P58 are arranged do. The touch electrode Tx51 serving as the common electrode performs a function of a common electrode at the time of display driving and performs a function of a touch electrode at the time of touch operation.

In the above structure, a plurality of gate lines G21 to G25 are formed on the substrate SUB1 and a gate insulating film GI is formed on the substrate SUB1 to cover the plurality of gate lines G21 to G25 . The active layer A, the source electrode SE and the drain electrode DE constituting the thin film transistor TFT are formed on the gate insulating film GI.

That is, the thin film transistor TFT includes gate electrodes GE extending from the gate lines G21 to G23 formed on the substrate SUB1, gate lines G21 to G25 and gate electrodes GE (A) formed on the gate insulating film (GI) so as to expose a part of the active layer (A), and a source electrode (SE) and a drain electrode (DE). The source electrode SE extends from each of the data lines D1 to D8.

Although the thin film transistor of the gate bottom structure in which the gate electrode is formed under the source / drain electrode is described as an example in the above embodiment, the present invention is not limited thereto, But it is to be understood that the thin film transistor of the gate top structure formed on the source / drain region is also included. The structure of the gate top structure of the thin film transistor is already known, so a detailed description thereof will be omitted.

Pixel electrodes P11 to P58 are formed on the gate insulating film GI on which the thin film transistors TFT and the data lines D1 to D8 are formed to be connected to the drain electrode DE of the thin film transistor TFT. A first passivation film PAS1 covering the source electrode SE and the drain electrode DE of the thin film transistors TFT, the data lines D1 to D8 and the pixel electrodes P11 to P58, . The touch routing lines TL11, TL21, TL31, TL41 and TL51 and the compensation routing lines CL11, CL21 and CL31 are formed on the first passivation film PAS1 so as to overlap with the data lines D1 to D8. Although the touch routing lines TL11, TL21, TL31, TL41 and TL51 and the compensation routing lines CL11, CL21 and CL31 are shown as being partially overlapped with the data lines D1 to D8 in FIG. 7, The touch routing wirings TL11, TL21, TL31, TL41 and TL51 and the compensation routing wirings CL11, CL21 and CL31 are arranged such that the data lines D1 to D8 overlap each other. .

TL21, TL31, TL41, TL41, TL41 and TL31 are formed on the first passivation film PAS1 on which the touch routing wirings TL11, TL21, TL31, TL41 and TL51 and the compensation routing wirings CL11, The second passivation film PAS2 is formed so as to cover the compensation routing lines CL11, CL21 and CL31. The second passivation film PAS2 is formed with a contact hole CH exposing a part of the touch routing wiring TL51.

A common electrode and a touch electrode Tx51 are formed on the second passivation film PAS2 so as to overlap the plurality of pixel electrodes P11 to P58. A plurality of slits SL are formed between the common electrode Tx51 and the pixel electrodes P11 to P58 to facilitate formation of a horizontal electric field therebetween.

The common electrode and the touch electrode Tx51 are connected to the touch routing line TL51 exposed through the contact hole CH formed in the second passivation film PAS2.

7 to 9, only the contact hole CH exposing a part of the touch routing line TL51 is shown in the second passivation film PAS2. However, in the first to third rows, The second passivation film PAS2 covering the third to sixth touch electrodes Tx11 to Tx16, Tx21 to Tx26 and Tx31 to Tx36 is connected to the touch routing wirings TL11 to TL16, TL21 to TL26, TL31 to TL36, Contact holes for exposing a part of the routing wirings CL11 to CL, CL21 to CL26, CL31 to CL36 are formed, and the fourth to fifth to sixth touch electrodes arranged in the fourth row and the fifth row are formed, Contact holes for exposing a part of the touch routing wirings TL41 to TL46 and TL51 to TL56 are formed in the second passivation film PAS2 covering the first passivation films Tx41 to Tx46 and Tx51 to Tx56.

The touch routing wirings TL11 to TL16, TL21 to TL26, TL31 to TL36, TL41 to TL46 and TL51 to TL56 are connected to all the touch electrodes Tx11 to Tx16, Tx21 to Tx26, Tx31 to Tx36, Tx16 to Tx26 and Tx31 to Tx36 and the compensating routing lines CL11 to CL16 and CL21 to CL26 and CL31 to CL36 are connected to the touch electrodes Tx11 to Tx16, Tx21 to Tx26, and Tx31 to Tx36, Lt; / RTI > However, by adjusting the number of pixel electrodes corresponding to one touch electrode and the number of touch electrodes arranged in the column direction, it is possible to secure the number of routing wirings overlapping the data lines, . Therefore, it is to be understood that the present invention is not limited to what is described in the embodiments of the present invention but includes the scope of the claims.

According to the touch sensor built-in type display device according to the present invention, the compensation voltage can be supplied to the touch electrodes arranged from the source line and the touch IC 100, . Therefore, even if a ripple voltage is generated in the touch electrode serving as the common electrode, the voltage of each touch electrode can be sensed and removed, so that the compensation voltage can be supplied.

FIG. 10 is a graph showing a relationship between a compensation voltage for eliminating a ripple voltage generated in a common electrode and a touch electrode after sensing a common voltage of a common electrode and a touch electrode using a compensation routing wiring in a touch sensor built- To remove the ripple voltage. In the present invention, since the compensation routing wiring can be connected to each touch electrode along with the touch routing wiring, the ripple voltage generated in each touch electrode can be removed as shown in FIG. Therefore, it is possible not only to prevent an increase in the bezel area due to the compensation design of the common electrode and the touch electrode, but also to prevent the generation of the parasitic capacitance and to prevent the deterioration of the image quality.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. For example, it should be understood that the number of touch electrodes described in the embodiments of the present invention is merely illustrative and is not intended to affect the scope of the present invention. In addition, in the embodiment of the present invention, the compensation routing wiring is described as being connected to the source electrodes and the touch electrodes disposed on a certain line from the farthest from the source and the touch IC. However, the present invention is not limited thereto, It can be configured to be connected. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the invention but should be defined by the claims

100: Source Driven and Touch IC
CL11 to CL16, CL21 to CL26, CL31 to CL36: Compensating routing wiring
TL11 ~ TL16, TL21 ~ TL26, TL31 ~ TL36, TL41 ~ TL46, TL51 ~ TL56: Touch routing wiring
Tx11 to Tx16, Tx21 to Tx26, Tx31 to Tx36, Tx41 to Tx46, Tx51 to Tx56: Common electrode and touch electrode (touch electrode)

Claims (5)

A plurality of gate lines and a plurality of data lines arranged to cross each other;
A plurality of pixel electrodes respectively formed in regions defined by intersections of the plurality of gate lines and data lines;
A plurality of common electrode common touch electrodes each formed in the active area so as to overlap with some of the plurality of pixel electrodes;
A plurality of touch routing wirings connected to the plurality of common electrode common touch electrodes; And
Compensating routing lines disposed in parallel with the touch routing lines and connected to at least a portion of the plurality of common electrode-touch electrodes; And
Sensing and driving the plurality of common electrodes and the touch electrodes through the touch routing wiring and sensing the common voltage of each of the at least some common electrodes and the common touch electrodes through the compensation routing lines, And a source driver and a touch IC for supplying a compensation voltage for eliminating the ripple voltage of the dual-purpose touch electrodes to the at least a part of the common electrodes and the touch electrodes, respectively.
The method according to claim 1,
Wherein the plurality of touch routing wires and the compensating routing wires are arranged side by side and overlap the data lines, wherein the number of touch routing wires is greater than or equal to the number of compensating routing wires. Display with integrated sensor.
The method according to claim 1,
Wherein the plurality of touch routing wires are connected to the plurality of common electrode common touch electrodes in a one-to-one relationship, and the compensation routing wires are connected to a common electrode- And the electrodes are connected to each other at a ratio of 1: 1.
3. The method of claim 2,
Further comprising a plurality of thin film transistors disposed at intersections of the plurality of gate lines and the plurality of data lines,
Wherein the pixel electrode is formed on a gate insulating film covering the gate lines formed on the substrate and connected to a drain electrode of the thin film transistor,
Wherein the touch routing wirings and the compensation routing wirings are formed to overlap with the data lines on a first passivation film covering the thin film transistors,
Wherein the common electrode and the touch electrode are formed to overlap with the pixel electrode on a second passivation film covering the routing wirings.
5. The method of claim 4,
Wherein the touch routing wiring is connected to the common electrode and the touch electrode through a contact hole formed in the second passivation film,
Wherein the compensation routing wiring is connected to at least a part of the common electrode and the touch electrode via another contact hole formed in the second passivation film.

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