TW201044054A - Capacitive touch board structure and capacitive touch panel structure - Google Patents

Abstract

A capacitive touch board structure and a capacitive touch panel structure are provided. The capacitive touch board structure includes a transparent substrate, a plurality of touch pads, a dielectric layer, a signal line, at least one scan line, and a plurality of conduct via. The touch pads are disposed on the transparent substrate, and the dielectric layer is disposed on the transparent substrate and covers the touch pads. The signal line and the scan line are disposed on a same surface of the dielectric layer and contacted thereon. The conduct via penetrate the dielectric layer, and electrical contact the touch pad and the scan line respectively, so that the touch pads and the scan line and electrical connect with each other. The capacitive touch panel structure includes the capacitive touch board structure and a light emitting module disposed on the dielectric layer.

Description

The invention relates to a touch substrate and a touch panel, in particular to a capacitive touch substrate structure and a capacitive touch panel structure. [Prior Art] In recent years, the touch-sensing technology (touch pane) related production technology has advanced by leaps and bounds such as resistive touch panels, capacitive touch panels, sonic touch panels, and optical touch panels. It is widely used in communication products, computer devices, and consumer electronic products to greatly increase the efficiency and ease of use of the electronic products used. For example, the application is used as a mouse pad for a notebook computer, a capacitive touch panel with virtual touch buttons, or generally configured in a personal digital assistant (PDA), an electronic dictionary, a mobile phone, a digital player, The GPS (Gk) bal Positioning System, GPS) resistive touchpad used on the screen of small electronic products such as screens eliminates the buttons, keyboards or joysticks that must be configured for traditional electronic devices. The capacitive touch panel can be input by a finger, and has the convenience of input operation, and the input operation does not need to be touched, and the panel does not have the disadvantage of stress, deformation and damage caused by the text, and the The touchpad has a simple structure, a small number of parts, a high product yield, and is suitable for mass production to reduce costs. The structure of the capacitive touch panel includes -X minus stitches and -Y axis sensing stitches, so that the X, Y axis sensing stitches are insulatedly disposed on the glass substrate, and the user's fingers or conductors touch each other. The change in capacitance value determines the position of the finger or conductor. 201044054 . In addition, the current combination of capacitive touch elements and panels is based on the combination of capacitive touch elements and panels. The way the capacitive touch component is attached to the panel can reduce the interference between the touch signal and the display component, but it also produces misalignment _ the situation, resulting in an unsatisfactory manufacturing yield, so that the capacitance of the touch panel The sensitivity and accuracy of the inductive signal is greatly reduced, and the overall thickness of the manufactured panel is relatively thick. In addition, the manufacturing of the capacitive touch panel mostly uses a transparent conductive material as a transparent component of the touch component in the conductive region of the touch (four) pin and the conductive region of the small block, and the conductive region of the cell block If the impedance value is too large, it is not easy to make the electric valley touch panel face large. U.S. Patent Application Serial No. 20/7,291, No. 9 discloses a device for detecting a touch sensing pad and a method thereof. The device includes a mechanical measuring device and an f brain processing device. Sensing »The additional rib deflection guide (such as a finger) is present, and the computer processing equipment is electrically sensitive to the sensing device to identify multiple actions. The method includes recognizing a flicking action, q double-twisting action, dragging action, and swinging action. SUMMARY OF THE INVENTION [The above problem is provided by the present invention - the Wei Rong type touch substrate structure and the capacitive touch panel structure, and the alignment of the capacitive touch elements of the good capacitive touch panel Inaccurate, poor manufacturing yield, too complicated process steps, thicker L-panel, and poor resolution of the touch panel. The capacitive touch substrate structure disclosed in the present invention comprises a transparent substrate, a plurality of touch pads, a dielectric layer, a signal line, at least one scanning line segment, and a plurality of conductive columns. The touch t8 is placed on the side of the flip substrate, and each touch (4) is located on the same line as the straight line 201044054. The dielectric layer is disposed on the side of the transparent substrate and covers the touch pad. The signal lines and the scanning line segments are disposed on the same plane of the dielectric layer. The conductive pillars pass through the dielectric layer, and the conductive pillars are electrically contacted with the touch pads and the scanning line segments, respectively, so that the touch pads and the scanning line segments are electrically connected. The capacitive touch panel structure disclosed in the present invention includes a capacitive touch substrate and a light emitting module. The light emitting module is disposed on the dielectric layer of the capacitive touch substrate to emit a light to the transparent substrate. The electric valley type touch substrate structure and the capacitive touch panel structure of the invention directly manufacture the capacitive touch element in the panel in an in-cell manner, instead of the conventional bonding method, and greatly improve the manufacturing time. The alignment accuracy effectively reduces the number of reticle used and reduces the wire resistance, thereby improving the yield and resolution of the touch panel. The above description of the present invention and the following description of the embodiments are intended to illustrate and explain the principles of the invention, and to provide a further explanation of the scope of the invention. [Embodiment] The capacitive touch substrate structure disclosed in the present invention can be applied to a lower light emitting organic light emitting diode (OLED) panel, a thin film transistor liquid crystal display (TFT_LCD) panel, a bistable cholesterol liquid crystal display, and an electrophoresis type. Display (Eiectr〇ph〇resis

Display ' EPD), electrowetting display (Eiectr 〇 wetting DiSpiay, EWD>, etc. 'but not limited to this. "1" is a schematic diagram of the composition of the touch pad and the scanning line segment of an embodiment, 201044054 2 is a top view of a capacitive touch substrate according to a first embodiment of the present invention, and FIG. 3 is a schematic structural view of a capacitive touch substrate according to a first embodiment of the present invention. The capacitive touch substrate 100 includes a transparent substrate n〇, a plurality of first touch pads 120, a first dielectric layer 130, a first signal line 14〇, a first scan line segment 150, and a plurality of A conductive pillar 160, a second scanning line segment 17〇, and a plurality of second touch pads 180. The material of the transparent substrate 110 is selected from Indium Tin Oxide (!T0) or polyethylidene. Dioxethiophene (PED〇T), but not limited to this. The first touchpad 120 is defined as the γ-axis direction in this embodiment, and the first touchpad 120 is set in the 11Q - on the side, and each of the first touch pads 120 is located on the γ axis (as shown in "i" ), and each row of the first touch pad (10)

They are set side by side. The second touch panel (10) is defined in the implementation of the financial system as a buffering direction: 3⁄4•帛一塾塾18〇 is disposed on the transparent substrate and disposed on the side of the first touchpad 120. A touch pad 12A and the second touch pad (10) are on the same plane and each of the second touch pads 18 is located on the X axis (as shown in FIG. 1).塾(10) is set side by side. Please continue to refer to "1st Figure 5 "Chu Chuan" to 3rd figure" "The first dielectric layer no is placed on the transparent substrate 110, #艾 汲盍 and the first touch pad 120 and the second touch Pad 180. Wherein, the first __a ^ 3 形成 is formed by evaporation, de-plating, spin plating (yin (7) her), and the first dielectric layer 130 of the present invention has a thickness of at least 200 nm ( Nm). The first signal line 14 is provided on the other side of the first dielectric layer 130 with respect to the transparent substrate ,, and the first signal line 140 and the seventh 201044054 - the scanning line segment 15G are The first dielectric layer 13() is in contact, that is, the first signal line (10) and the first scanning line segment 15G are in the same plane. The second scanning line segment 17() and the first scanning line segment 150 are perpendicular to each other and are staggered. The second scanning line segment 170 of the embodiment is disposed on the transparent button 11 and has a second touch surface 18 (ie, The second scanning line segment 170 and the second touch pad 18G are tied to the same side of the transparent material (10) and the second touch pads 180 are electrically connected to the second scanning line segment 17 to form electrical properties. Connection relationship. It should be noted that the first signal line 14 本 disclosed in the present invention may be coplanar with a gate line/dectrode or a data line/dectr〇. In addition, the first scanning line segment 150 of the embodiment is inserted through the first touch pads 120 on the same straight line (γ axis), and is electrically connected to each other, and the second scanning line segment 17 is connected through the same straight line (X axis). The second touch pads 18 are electrically connected to each other. The first conductive pillars 160 of the present embodiment are connected to the first dielectric layer 13 〇 and electrically contact with the first touch pads 120 and the first scan line segments 150 respectively to make the first touch pads 120 and the first An electrical connection relationship is formed between the scan line segments 150. Fig. 4 is a schematic view showing the structure of a second embodiment of the present invention. The capacitive touch panel 100 of the second embodiment of the present invention includes a transparent substrate 11 , a plurality of first touch pads 120 , a first dielectric layer 13 , a first signal line 14 , and a first A scanning line segment 150, a plurality of first conductive pillars 16A, a second scanning line segment 17〇, and a plurality of second touch pads 180 further include a second dielectric layer 19〇 and a second signal line. 200, and a plurality of second conductive pillars 210. The second touch pad 180 and the first touch pad 120 of the embodiment are disposed on one side of the transparent substrate 110, that is, the first touch pad 120 and the second touch pad 180 are on the same plane. . The first dielectric layer 130 is disposed on the transparent substrate no and covers the first touch pad 120 and the second touch pad 180. The first dielectric layer I30 is formed by vapor deposition, sputtering, spin-coating, etc., and the dielectric layer 13 of the present invention has a thickness of at least 200 nanometers (nm). The first signal line 140 and the first scanning line segment 150 are disposed on the other side of the first dielectric layer 13 〇 relative to the transparent substrate 11 , and the first signal line 140 and the first scanning line segment 15 and the first 1; the electrical layer 130 is in contact with each other, that is, the first signal line 14A is in the same plane as the first scanning line segment 15〇. Please continue to refer to FIG. 4 , the second dielectric layer 19 is disposed on the side of the first dielectric layer 130 having the first signal line 140 and the first scanning line segment 150 , and the second scanning line segment 170 and the first scanning The line segments 15 are perpendicular to each other and are alternately arranged. The second scanning line segment 170 of the embodiment is disposed on the other side of the second dielectric layer 19 〇 relative to the first dielectric layer 130. The second signal line 2〇〇 and the second scanning line segment 17 are disposed on the same side of the second dielectric layer, and the second signal line and the second scanning line segment 170 are in contact with the second dielectric layer 190. It is worthy of Zhuang Ren's first signal line (10) disclosed in the present invention can be coplanar with the interpolar line/electrode (gate line/dee_eM data line/electrician coffee (6), and the second signal line 200 can be connected with the gate Line/electrode line/dectr〇de) or data line / 'electrode _ 1 off 1e_de) coplanar. In addition, the first scanning line segment 150 of the embodiment penetrates the first touch pad 12A located on the same-straight line (Y-axis), and is electrically connected to each other. The second scanning line segment 170 is connected through the same line (four). The second touch 9 201044054 塾 180 ' and electrically connected to each other. The first conductive pillars 160 of the present embodiment are electrically connected to the first touch panel 120 and the first scan line segment 150 to make the first touch pads 120 and the first scan. The second conductive pillar 210 penetrates the first dielectric layer 丨3〇 and the second dielectric layer 190, and is respectively connected to the second touch pad 180 and the second layer. The scanning line segment 170 is electrically connected to form an electrical connection relationship between each of the second touch pads 180 and the second scanning line segment 170. Fig. 5 is a schematic view showing the structure of a third embodiment of the present invention. The capacitive touch panel 1 of the third embodiment of the present invention includes a transparent substrate 11 , a plurality of first touch pads 120 , a first dielectric layer 130 , and a first signal line 14 — The first scanning line segment 150, the plurality of first conductive pillars 160, the second scanning line segment 丨7〇, and the plurality of second touch pads 180 further include a second dielectric layer 19〇, a third medium The electrical layer 220, a second signal line 200, and a plurality of second conductive pillars 21A. The first touch pad 120 of the present embodiment is disposed on one side of the transparent substrate 11 , and the first dielectric layer 130 is disposed on the transparent substrate 110 and covers the first touch pad 120 . The first dielectric layer 130 is formed by vapor deposition, sputtering, spin-coating, etc., and the first dielectric layer 13 of the present invention has a thickness of at least 200 nanometers (nm). The second touch pad 18 is disposed on the other side of the first dielectric layer 13 〇 relative to the transparent substrate 110. The second dielectric layer 19 is disposed on the plane of the first dielectric layer 130 having the second touch pad 180 and covers the second touch pad 180. The first signal line 140 and the first scanning line segment 150 are disposed on the other side of the second dielectric layer 190 with respect to the first dielectric layer 130, and the first signal line 201044054 and the first scanning line segment 150 and the second medium The electrical layer 190 is in contact with each other, that is, the first signal line (4) is in the same plane as the first scanning line segment 150. Please continue to refer to FIG. 5, the third dielectric layer 22 is disposed on the side of the second dielectric layer 190 having the first imaginary line 14 〇 and the first scanning line segment 丨5 ,, and the second scanning line segment 170 and the first scanning line segment 150 are perpendicular to each other and staggered. The first signal line 200 and the second scanning line segment 17 are disposed on the other side of the third dielectric layer 22 opposite to the second dielectric layer 190, and the second signal line 2 and the second signal line The second scan line segment 170 is in contact with the third dielectric layer 220. The first signal line 140 disclosed in the present invention may be coplanar with a gate line/electrode (line/electrode) or a data line/electrode, and the second signal line 200 may be connected to a gate line/electrode. (gate line/electf〇de) or data line/electrode (d her lme/electrode) coplanar. In addition, the first scanning line segment 15 of the present embodiment is connected to the first touch pads 12A on the same straight line (γ axis), and is electrically connected to each other, and the second Q scanning line segment 170 is connected through the same straight line (X). The second touch pads 120 on the shaft are electrically connected to each other. The first conductive pillar 160 of the embodiment penetrates through the first dielectric layer 13 and the second dielectric layer 190, and is electrically contacted with the first touch pad 12 and the first scan line 15 respectively. An electrical connection is formed between the first touch pad 120 and the first scan line segment 150. The second conductive pillar 210 extends through the second dielectric layer 19 and the third dielectric layer 220, and is respectively connected to the second The touch pad 180 and the second scan line segment 17 are electrically connected to each other to form an electrical connection relationship between each of the second touch pads 180 and the second scan line segment 170. 201044054 "Figure 6" shows the composition of the touch pad and the scanning line segment of the present invention (4) - the embodiment is not intended. The first touch pad 120 in the capacitive touch panel of the fourth embodiment of the present invention is defined as a touch lens in the γ pumping direction in the present embodiment. Each of the first touch pads 120 is located on the γ axis. In the embodiment, the second touch panel 18 is defined as a touch pad in the direction of the x-axis, and each of the second touch pads (10) is located on the x-axis. The at least one first touch (four) 〇 in the direction of the x-axis is electrically connected to the middle of the plurality of first scan segments 150, and the remaining first touch pads 12 以 are also at least one first touch塾12G is electrically connected to the strip-scanning line segment 15(), so that the plurality of first-touch (four) 12() of the embodiment is divided into a plurality of groups and respectively corresponding to the corresponding first-scan segment 15G. Connecting; at least the second touch pad 180 in the direction of the x-axis is electrically connected to the middle of the plurality of second scanning line segments 17〇, and the remaining second touch pads (10) are also The at least one second touch pad 180 is electrically connected to one of the second scan line segments m, so that the plurality of first touch pads 18〇 of the embodiment are divided into a plurality of groups and respectively corresponding to the second scan line segments. 170 electrical connection. The need for the actual impedance value of the visual line segment 15〇, m of the present invention, and the capacitive touch button/φ board of the present invention are suitable for the use of displays of different sizes', and correspondingly changing the configuration of the scanning, line segments 15〇, 170 Quantity and routing method. Therefore, in addition to the above embodiments, the embodiment uses a single-strip scanning line segment 1SG, .17() to electrically connect the rows of touch pads 120 ν 180, and the embodiment can be further configured according to actual conditions. According to the ten requirements, the plurality of first touch pads 12〇 are divided into a plurality of groups, or the plurality of second touch pads 18G are divided into a plurality of groups, and the plurality of first touches 12G are respectively drawn with the plurality of first scans 12 201044054 The electrical connection of the segment 150 and the second scanning line segment no; or, at the same time, the plurality of first touch pads 120 and the plurality of second touch pads 18 are divided into a plurality of groups, and corresponding plural numbers The stripe first scan line segment 15〇 and the second scan line segment are electrically connected. The first touch pad and the second touch pad 180 of the present invention can be as shown in FIG. 7 and are adjacent to four touch pads. (10) equally overlapping the position of the same pixel (pixel) 7〇〇, so that the touch resolution is 1/4 of the resolution of the 素0 prime; or the arrangement as shown in “Fig. 8”, so that A touch pad 120, 18 is correspondingly overlapped with a pixel 7 , so that the touch resolution is equal to the pixel resolution. Those skilled in the art can also change the setting relationship between the touch pads 120, 180 and the pixel 700, so that the relationship between the touch resolution and the pixel resolution is 1/n, where n is greater than or equal to i. Integer. The structure of the capacitive touch panel of the present invention is shown in Fig. 9A to Fig. 14 . The capacitive touch panel 600 disclosed in the present invention includes the capacitive touch substrate 100, the flat layer 400, and the light emitting module 300. Please refer to FIG. 9A and FIG. 9B. The capacitive touch panel 600 of the present invention includes a transparent substrate 11 , a plurality of first touch pads 12 , a first dielectric layer 130 , and a first The first signal line 140, a first scanning line segment 150, a plurality of first conductive pillars 160, a second scanning line segment 170, a plurality of second touch pads 180, a flat layer 400, and a light emitting module 300. The material of the transparent substrate 11 is selected from Indium Tin Oxide (ITO) or polyethylene dioxythiophene (PEDOT), but is not limited thereto. The first touch pad 120 is defined. a touch pad in the Y-axis direction, and a 13th 201044054 touch pad 120 is disposed on one side of the transparent substrate no. The second touch pad 18 is defined as a touch pad in the X-axis direction, and is set The first touch pad 120 and the second touch pad 180 are located on the same plane on the side where the transparent substrate no is disposed on the first touch pad 120. The first dielectric layer 130 is disposed on the transparent substrate 110. The first touch line 120 and the first touch line 150 are disposed on the other side of the first dielectric layer 130 opposite to the transparent substrate 110. And the first sensing line segment 150 and the first sensing line segment 150 are in contact with the first dielectric layer 130, that is, the first signal line 140 is in the same plane as the first scanning line segment 15〇. The second scanning line segment 170 is perpendicular to and perpendicular to the first scanning line segment 15 . The second scanning line segment 170 is disposed on the transparent substrate 11 On the side of the second touch pad 18〇 (ie, the second scan line segment 17〇 and the second touch pad 180 are tied on the same side of the transparent substrate 110) and each of the second touch pads 180 and the second The scanning line segments 17 are electrically connected to each other to form an electrical connection relationship. The first signal line 14 本 disclosed in the present invention can be connected to a gate line/electrode or a data line/electrode (data iine/eiectr) 〇de) coplanar, the second signal line 200 can be coplanar with the gate line/electrode (gate iine/eiectr〇(je) or data line/electrode (blood line/electrode). The first conductive column 160 is through the first A dielectric layer 13 is electrically connected to the first touch pad 120 and the first scan line 15 to form an electrical connection between each of the first touch pads 12 and the first scan line 150. Please continue to refer to "Picture 9A" and "Picture 9B". The flat layer 400 is provided with 14 201044054 on the other side of the first dielectric layer 130 opposite to the transparent substrate 11 for subsequent illumination modules. The 3GG process can be paste-formed. In this embodiment, the fine group 3〇〇 is a lower-emitting organic electroluminescent diode (〇rganic Light_) Emitting

Diodes, OLED) 'includes an organic light-emitting diode 311, an active layer (four) ^1 & net 312, a passivation layer (ρ-η) 313, and an electrode layer 314, which are sequentially disposed on a flat layer shed' The capacitive touch panel constitutes an organic electroluminescent diode display panel. However, it is noted that the flat layer described in this embodiment can be disposed on a flat surface in order to provide the hair-emitting module 300, thereby improving the yield of the light-emitting module 3 when manufactured. . The light emitting module 300 can also be disposed directly on the upper surface of the first dielectric layer 13A. In addition, please refer to the "9th figure" and the "9th figure". The capacitive touch panel of the present embodiment also includes an anti-electromagnetic interference layer 51 or a parasitic capacitance interference layer 520' which is disposed on the first dielectric. On the layer 13, the electromagnetic or parasitic capacitance generated by the light-emitting module is prevented from being disturbed, and the performance of the capacitive touch panel is prevented from being affected. The capacitive touch panel 600 of the present invention includes a transparent substrate 11A, a plurality of first touch pads 12A, a first dielectric layer 130, and a first dielectric layer 130. The first signal line 14〇, the first-female line segment 15〇, the plurality of first conductive pillars 160, the second scanning line segment 170, the plurality of second touch electrodes 18〇, a flat layer 400, and the light emitting module 300. The material of the transparent substrate 11 is made of indium tin oxide (Indium Tin Oxide, ΙΤ0) or polydioxythiophene (pED〇T), but is not limited thereto. The first touch pad 120 The touchpad is defined as a gamma-axis direction, and 15 201044054 is disposed on one side of the transparent substrate HO. The second touchpad 180 is defined as a touchpad in the X-axis direction, and The first touch pad 120 and the second touch pad 180 are disposed on the same plane. The first dielectric layer 130 is disposed on the transparent substrate. The first touch line 120 and the first touch line segment 150 are disposed on the first dielectric layer 130 relative to the transparent substrate 11 On the other side, the first signal line 140 and the first scanning line segment 150 are in contact with the first dielectric layer 13A, that is, the first signal line 140 is in the same plane as the first scanning line segment 150. The line segment 170 and the first scanning line segment 150 are perpendicular to each other and are staggered. The second scanning line segment 17 is disposed on the transparent substrate. The second touch pad 18 is on the side of the second touch pad 18 (ie, the second scan line segment 170 and the second touch pad 180 are on the same side of the transparent substrate 110) and each of the second touch pads 180 is connected to the second scan. The line segments 17〇 are electrically in contact with each other to form an electrical connection relationship. The first signal line 14〇 disclosed in the present invention can be connected to a gate line/electrode or a data line/electrode (data iine/eiectr〇). De) coplanar, the second signal line 200 can be coplanar with the gate line/electrode (gate丨ine/electr〇de) or the data line/electrode/blood line/electrode. The first conductive pillars 160 are electrically connected to the first touch pads 120 and the first scan lines 15 to respectively distinguish the first touch pads from the first scan lines. An electrical connection relationship is formed between 150. Please continue to refer to "Picture 10A" and "Ten Figure". The flat layer 4 〇〇 16 16 201044054 is placed on the other side of the first dielectric layer i3 〇 relative to the transparent substrate 11 () for subsequent The process of the light-emitting module 300 can be smoothly carried out. The light-emitting module 300 of the present embodiment is a Thin Film Transistor Liquid Crystal Display (TFT-LCD), which includes a plurality of thin film transistors (Thin Film).

Transistor, TFT) 32 passivation layer 322, liquid crystal layer 323, color filter 324, electrode layer 325, and backlight 326 are sequentially disposed on the flat layer 400. A thin film G transistor liquid crystal display panel is formed with the capacitive touch substrate 100. It should be noted that the flat layer 4 described in this embodiment can be disposed on a flat surface in order to provide the light-emitting module 300, so as to improve the yield of the light-emitting module 300 at the time of manufacture. The light emitting module 3 can also be directly disposed on the upper surface of the first dielectric layer 130. In addition, the capacitive touch panel 600 of the present embodiment also includes an anti-electromagnetic interference layer 51 or a parasitic capacitance interference layer 520, which is disposed on the first dielectric. On the layer 13 ,, the electromagnetic or parasitic capacitance generated by the illuminating module 3 防止 is prevented from being disturbed, and the performance of the capacitive touch panel 6 避免 is prevented from being affected. The capacitive touch panel 600 of the present invention includes a transparent substrate no, a plurality of first touch pads 12A, a first dielectric layer 130, and a first A signal line 14A, a first scanning line segment 150, a plurality of first conductive pillars 160, a second scanning line segment no, a plurality of second touch pads 18A, a flat layer 400, and a light emitting module 300. Among them, the material of the transparent substrate 11 is selected from Indium Tin Oxide (ITO) or polyethylene dioxythiophene (PED〇T), but 17 201044054 is not limited thereto. The pad 12 is defined as a touch pad in the γ-axis direction, and the first touch pad 120 is disposed on one side of the transparent substrate 110. The second touch pad 18 is defined as a touch pad in the X-axis direction. And disposed on the side of the transparent substrate 11 () provided with the first touch pad 120, that is, the first touch pad 12 and the second touch pad 18 are on the same plane. The first dielectric layer 130 The first touch line 120 and the first touch line 150 are disposed on the first dielectric layer 13 relative to the first touch pad 120 and the second touch pad 180. On the other side of the transparent substrate n〇, and the first imaginary line 140 and the first scanning line segment 150 are in contact with the first dielectric layer 13 ,, that is, the first signal line 140 is connected to the first scanning line segment 丨5 The first scanning line segment 17 is perpendicular to the first scanning line segment 15 and is staggered. The second scanning line segment 170 is disposed in the same direction. The substrate 11 has a second touch pad 18 〇 on the side (ie, the second scan line segment 170 and the second touch pad 18 〇 are on the same side of the transparent substrate no)) and each of the second touch pads The 180 series and the second scanning line segment 17 are electrically in electrical contact with each other to form an electrical connection relationship. The first signal line MO disclosed in the present invention can be connected to a gate line/electrode or a data line/electrode ( The data line/electr〇de) is coplanar, and the second signal line 200 can be coplanar with the gate line/electr〇de or the data line/electrode (4)& line/electrode. The first conductive pillar 160 is electrically connected to the first touch panel 120 and the first scan line segment 15G, so that each of the first touch pads 12 and the first scan line segment 150 Form an electrical connection relationship. 18 201044054 "Monthly continue to refer to "Dimensions 11A" and "1 iB", the flat layer 400 is disposed on the other side of the first dielectric layer 130 opposite to the transparent substrate 11 for subsequent illumination The process of module 300 can be carried out smoothly. The illumination module 3 of the embodiment is an electrophoretic display (EPD), which includes a plurality of thin film transistors (TFTs) 331, passivation layers 332, and electrophoresis layers (e! The ectr〇ph〇resis iayer 333, the color filter 334, the electrode layer 335, and the substrate 336′ are sequentially disposed on the flat layer 〇40〇 to form an electrophoretic type with the capacitive touch substrate 100. Display panel. It should be noted that the flat layer 4 of the embodiment can be disposed on a flat surface in order to provide the light-emitting module 3, thereby improving the yield of the light-emitting module 3 during manufacturing. . The light emitting module 300 can also be directly disposed on the upper surface of the first dielectric layer 13 (). If the capacitive touch panel 6 of the embodiment is in a black and white display manner, the color filter 334 in the light emitting module 300 can be removed. In addition, please refer to "11A" and "11B". The capacitive touch panel 600 of the present embodiment also includes an anti-electromagnetic interference layer 51 or a parasitic capacitance interference layer 520. The electrical layer 13 is used to prevent the electromagnetic or parasitic capacitance generated by the light-emitting module 3 from being disturbed, thereby preventing the performance of the capacitive touch panel 6 from being affected. Please refer to FIG. 12 , the capacitive touch panel 6 本 of the present invention includes a transparent substrate 110 , a plurality of first touch pads 12 , a first dielectric layer 13 , and a second dielectric . The layer 190, a first signal line 140, a first scan line segment 150, a plurality of first conductive pillars 160, a second scan line segment 170, a plurality of second touch pads 18A, - 201044054 flat layer 400, and illumination Module 300. Among them, the material of the transparent substrate 11 is made of indium tin oxide (ITO) or polyethylene dioxin (ped〇t), but it is not limited thereto. The 120 is defined as a touch pad in the γ-axis direction, and the first touch pad 120 is disposed on one side of the transparent substrate 11 . The second touch pad 180 is defined as a touch pad in the X-axis direction, and The first touch pad 12 is disposed on the same plane as the second touch pad 120. The first dielectric layer 130 is disposed on the same surface of the first touch pad 120. On the transparent substrate no, and covering the first touch pad 120 and the second touch pad 180. The first signal line 14 〇 and the first scan line segment 150 are disposed on the first dielectric layer 13 〇 relative to the transparent substrate On the other side of the 11th turn, the first signal line 140 and the first scan line segment 15A are in contact with the first dielectric layer i3, that is, the first signal line 140 is in the same plane as the first scan line segment 150. The second scanning line segment 170 and the first scanning line segment 150 are perpendicular to each other and staggered. The second scanning line segment no is disposed on the transparent substrate 110. The second touch pad 18 is on the side of the second touch pad 18 (ie, the second scan line 170 and the second touch pad 18 are on the same side of the transparent substrate no), and each of the second touch pads 180 is connected to the second The scanning line segments 17 are electrically connected to each other to form an electrical connection relationship. The first signal line 14 本 disclosed in the present invention can be connected to a gate line/electrode or a data line/electrode (eg, iine/ The eiectr〇(je) is coplanar, and the second signal line 200 can be coplanar with the gate line/electrode (gate iine/eiectr〇de) or the data line/electrode (4)& line/electrode. The first dielectric layer 130 is in electrical contact with the first touch pad 20 201044054 120 and the first scan line segment 150 respectively to form an electrical connection between each of the first touch pads 12A and the first scan line segment 150. Please continue to refer to "Fig. 12", the flat layer 4 is disposed on the other side of the second dielectric layer 19 〇 relative to the transparent substrate 110 for subsequent illumination module 3 The light-emitting module 3 of the present embodiment is a color filter on touch (COT), The plurality of color filters 341, the plurality of gate electrodes 342, the -electrode layer 343, and the plurality of thin film transistors 344 are included. The color filter 341 is disposed on the first dielectric layer 130. And is completely covered by the second dielectric layer 190, the gate electrode 342 is disposed on the second dielectric layer 19, and is completely covered by the flat layer 400, the electrode layer 343 is disposed on the flat layer 4 (9), the thin film transistor 344 Then, it is electrically disposed on the electrode layer 343. The components of the light-emitting module 3 are sequentially disposed on the flat layer 400 to form a contact-type color aerial film (CQT) display panel with the capacitive touch substrate 1A. However, it should be noted that the flat layer 400 described in the embodiment of the present invention can be disposed on a flat surface in order to provide the light-emitting module 3, thereby improving the brightness of the light-emitting module 3 during manufacture. rate. The light emitting module 300 can also be disposed directly on the upper surface of the second dielectric layer 19A. In addition, the capacitive touch panel of the present embodiment also includes an anti-electromagnetic interference layer or a parasitic capacitance interference layer (not shown) disposed on the second dielectric layer 19 ' to prevent the illumination module 300 from being The generated electromagnetic or parasitic capacitance interference prevents the performance of the capacitive touch panel 600 from being affected. Please refer to the structure diagram of the light-emitting module of the "Nth Map". The light-emitting module of the present type is connected to the "Fig. 12" phase 21 201044054. The present invention includes a plurality of color filters 351, a plurality of gate electrodes 352, an electrode layer 353, and a plurality of thin film transistors 354. And a black matrix for mamtrix)355. The color filter 351 and the black matrix 355 are disposed on the first dielectric layer 130 and completely covered by the second dielectric layer 19, and the gate electrode 352 is disposed on the second dielectric layer 190. The electrode layer 353 is disposed on the flat layer 400, and the thin film transistor 354 is electrically disposed on the electrode layer 353. The components of the light-emitting module 300 are sequentially disposed on the flat layer 4A to form a contact-type color filter (c〇T) display panel with the electric valley touch substrate 1A. However, it is to be noted that the flat layer 4 (10) of the present embodiment is provided to provide a light-emitting module 300 on a flat surface during manufacture, thereby improving the yield of the light-emitting module 300 at the time of manufacture. The light emitting module 3 can also be directly disposed on the upper surface of the second dielectric layer 190. In addition, the capacitive touch panel 600 of the present embodiment also includes an anti-electromagnetic interference layer or a parasitic capacitance interference layer (not shown) disposed on the second dielectric layer 19 , to prevent the illuminating module 300 . The generated electromagnetic or parasitic capacitance interference prevents the performance of the capacitive touch panel 600 from being affected. Please refer to FIG. 14 , the capacitive touch panel of the present invention includes a transparent substrate 110 , a plurality of first touch pads 12 , a first dielectric layer 13 , a first signal line 140 , and a first The first scanning line segment 15 , the plurality of first conductive pillars 16 , the second scanning line segment 170 , the plurality of second touch pads 18 , the flat layer 4 , and the light emitting module 300 . The material of the transparent substrate 110 is selected from the group consisting of tin oxide ((μ··································································· The 120 touch panel is a touchpad in the Y-axis direction, and the first touchpad I% is disposed on one side of the transparent substrate 110. The second touchpad 180 is defined as a touchpad in the x-axis direction. The first touch pad 12 is disposed on the same plane as the second touch pad 180. The first dielectric layer 130 is disposed on the transparent substrate. 110, and covering the first touch pad 120 and the second touch pad 180. The first signal line 14 and the first scan line segment 150 are disposed on the first dielectric layer 13 〇 relative to the transparent substrate (10) On the side, the first signal line 140 and the first scanning line segment 150 are in contact with the first dielectric layer 13A, that is, the first signal line 140 is in the same plane as the first scanning line segment 15〇. The scanning line segment 170 and the first scanning line segment 15Q are perpendicular to each other and staggered. The second scanning line segment 17 is disposed on the transparent substrate 11 and has a second The control pad is on the side of the Ο (ie, the second scanning line segment 17 〇 and the second touch pad 18 〇 are on the same side of the transparent substrate no), and each of the second touch 塾 18 与 and the second scanning The line segments 17 are electrically connected to each other to form an electrical connection relationship. 0 The first signal line of the road revealed by this month can be connected to the gate line/electrode (spike lme/electrode) or data line/electrode (data line/eiectr). 〇de) coplanar, the second signal line 200 may be coplanar with the gate line/electrode (4) e line/electr〇de) or the data line/electrode _ line/electrode. The first conductive pillar 160 is through the first dielectric layer (10), and electrically contacting the first touch pad 120 and the first scan line segment 15 respectively to form an electrical connection relationship between each of the first touch pads and the first scan line segment 150. 14, the flat layer 400 is disposed on the first dielectric layer 13〇23 201044054 on the other side of the transparent substrate 110 for the subsequent illumination module 3 to be smoothly processed. The light-emitting module 300 of the embodiment is a schematic diagram of a light-emitting module of a color filter on array (COA), which comprises an electrode layer 361, a plurality of thin film transistors 362, and a plurality of color filters. A sheet 363 and a fourth dielectric layer 364. The electrode layer 361 is disposed on the flat layer 4, the thin film transistor 362 and the color filter 363 are respectively disposed on the electrode layer 361, and the fourth dielectric layer 364 is disposed on the flat layer and completely covered. The electrode layer 361, the thin film transistor 362, and the color filter 363 are housed. The components of the light-emitting module 3 are sequentially disposed on the flat layer 400 to form a matrix color filter (COA) display panel with the capacitive touch substrate. However, it is to be noted that the flat layer 400 of the present embodiment is provided to provide a light-emitting module 3 (8) which can be disposed on a flat surface during manufacture to improve the yield of the light-emitting mold and the assembly. The light-emitting module can also be directly disposed on the upper surface of the first dielectric layer. In addition, the electric valley touch panel of the present embodiment also includes an anti-electromagnetic interference layer or a parasitic capacitance interference layer (not shown) disposed on the first dielectric layer 13 , to prevent the light-emitting module 300 from being disposed. The electromagnetic or parasitic capacitance generated by the interference prevents the performance of the electric valley touch panel 6 from being affected. The capacitive touch panel of the various embodiments of the present invention is in the form of a capacitive touch panel leakage according to various embodiments of the present invention, and the type of the light emitting module 300 is not It is limited to the types of the above embodiments, and is familiar with the capacitive touch substrate excitation ± provided in the embodiments of the present invention to form various types of capacitive type 24 201044054 The control panel is not limited to the embodiments disclosed in the present invention. Please refer to the "Figure 15" to "Divided Scanning Line Segments. 帛 View" of different types of touch 塾 and as shown in Figure #15, this type of embodiment board 6〇0 is composed A display panel on the coffee, but on the overall film touch sulfur 'Ben Wei _ 杂 方式 何 何 ( ( ( 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分 区分The second line is designed by the shortest distance method. The first scanning line segment 7..., the train 1G is pulled on the same side, and the second scanning line segment Π0 _ is divided into two sides and the short distance is drawn. As shown in the "Please" figure, this type of embodiment can be regarded as a two-piece touch panel _ composition-display secret _, but in terms of the overall process, it is still a single-chip touch panel, this implementation The example can be divided into a plurality of smaller size control panel areas in the single-chip touch panel by means of wiring. The first scanning line segment (9) The drawing of the second scanning line segment 170 adopts the design that the same signal is arranged on the same side. At this time, the first scan line segment 15〇 and the second scan line segment 17〇 can be displayed

The array 8 _ pull line ' can also be reversed to pull the line, and the pull line can be obtained by shifting one or several fine pixels in the same direction of different touch panels. As shown in Figure 15C, this type of embodiment can be regarded as four touch panels _ on the - display panel _, but it is difficult to say, still a single month touch panel, this The embodiment can be divided into a plurality of smaller sizes 150 and second scanning line segments 17 in a single piece of touch surface 25 201044054 by means of wiring. Touch panel area. Wherein, the drawing of the first scanning line segment is set to the shortest distance between the two sides, as shown in FIG. 5D. This embodiment can be regarded as a four-touch panel 600 minus the -I-hoofed 8 (10). However, in the case of the overall system (4), the single-touch panel is still a single-piece touch panel that can be divided into a plurality of smaller sizes by the wiring method. The drawing lines of the first scanning task 150 and the second scanning line segment 17G adopt the same signal design with _ line arrangement. At this time, the first scanning line segment and the second scanning line segment 17A can be pulled on the same side as the display array 810, or a reverse pulling wire can be used. As shown in FIG. 15E, the first line segment 150 and the second scanning line segment 170 of the first type are designed with the same side wire, and the second scanning line segment is cut by the conductive via (via撼). The electrical connection of 900 is such that the second scan line segment (7) and the scan line segment 150 are in the same plane. At this time, the first and second scanning line segments 15A and 17G may be pulled or reversed to achieve the effect of lowering the resistance or matching the wiring design. The capacitive touch substrate structure and the capacitive touch panel structure disclosed in the present invention directly manufacture a capacitive touch component in an in-cell manner in an in-cell manner, instead of using each of the electric valley touch components to fit The combination means arranged on the panel effectively reduces the number of use of the mask and reduces the resistance of the wire, and avoids the problem of the drift of the alignment between the touch pad and the element, thereby greatly improving the resolution of the capacitive touch panel. In addition, the capacitive touch substrate of the present invention can be combined with various types of light-emitting modules 26 201044054 to form various types of capacitive display panels. The embodiments of the present invention are disclosed above, but are not intended to limit the present invention, and those skilled in the art, without departing from the spirit and scope of the present invention, A summary of the changes may be made to the extent that the scope of the application of the invention is defined by the scope of the application. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing the composition of a touch pad and a scanning line segment according to a first embodiment of the present invention; FIG. 2 is a top view of a capacitive touch substrate according to a first embodiment of the present invention; FIG. 4 is a schematic structural view of a capacitive touch panel according to a second embodiment of the present invention; FIG. 5 is a schematic structural view of a capacitive touch substrate according to a second embodiment of the present invention; FIG. 6 is a schematic diagram showing the composition of a touch panel and a scanning line segment according to another embodiment of the present invention; FIG. 7 is a schematic diagram showing the structure of the touch and the pixel in the embodiment of the present invention; FIG. 9A is a schematic structural view of a capacitive touch panel according to a first embodiment of the present invention; FIG. 9A is a schematic structural view of a capacitive touch panel according to a first embodiment of the present invention; The structure of another aspect of the capacitive touch panel is not intended; FIG. 10A is a schematic structural view of a capacitive touch panel according to a second embodiment of the present invention; Another kind of scale composition of the panel FIG. 11A is a schematic structural view of a capacitive touch panel according to a third embodiment of the present invention. FIG. 11B is a perspective view of a capacitive touch panel according to a third embodiment of the present invention. 12 is a structural diagram of a capacitive touch panel according to a fourth embodiment of the present invention. FIG. 13 is a schematic structural view of a capacitive touch panel according to a fifth embodiment of the present invention. FIG. 15A is a schematic diagram showing the composition of different types of touch pads and scanning lines according to the present invention; FIG. 15B is a view showing different types of touch pads and scanning according to the present invention; Schematic diagram of the composition of the line segment; the 1SC diagram is a schematic diagram of the composition of the touch pad and the scanning line segment of different types of the invention; the second figure is a schematic diagram of the composition of the touch pad and the scanning line segment of the same type of the hair piece; The schematic diagram of the composition of the touch 塾 and the scanning line segment of different types of the invention [main component symbol description] 100 capacitive touch substrate 110 transparent substrate 120 first touch pad 130 first dielectric layer 140 first signal line 150 First scan line segment 160 first conductive pillar 170 second scan line segment 180 second touch pad 190 second dielectric layer 28 201044054

200 second signal line 210 second conductive pillar 220 third dielectric layer 300 light emitting module 311 organic light emitting diode 312 active layer 313 passivation layer 314 electrode layer 321 thin film transistor 322 passivation layer 323 liquid crystal layer 324 color filter light Sheet 325 Electrode Layer 326 Backlight 331 Thin Film Transistor 332 Purified Layer 333 Electrophoretic Layer 334 Color Matte Sheet 335 Electrode Layer 336 Substrate 341 Color Filter Light Sheet 342 Gate Electrode 29 201044054 343 Electrode Layer 344 Thin Film Transistor 351 Color Filter Sheet 352 Gate electrode 353 Electrode layer 354 Thin film transistor 355 Black matrix 361 Electrode layer 362 Thin film transistor 363 Color filter 364 Fourth dielectric layer 400 Flat layer 510 Anti-electromagnetic interference layer 520 Protection parasitic capacitance interference layer 600 Capacitive Touch panel 700 halogen 800 display panel 810 display array 900 conductive vias 30

Claims (1)

201044054 VII. Shen 5 Green Patent Range: 1. A capacitive touch substrate structure comprising: a transparent substrate; a plurality of first touch pads disposed on one side of the transparent substrate, and the like The first touch pads are located on the same line; the first "electric layer" 5 is placed on the side of the transparent substrate, and covers the first touch 等 such as § hai; 〇 - the first signal line, set On the first dielectric layer, and in contact with the first dielectric layer; at least one first scanning line segment disposed on the first dielectric layer and contacting the first dielectric layer, and the first The scan line segment is on the same plane as the first signal line; and _ a plurality of turns of the conductive pillars are penetrating the first dielectric layer, and the first guides f-columns are divided into the first scale--the pad and the first - Sweeping the segments to avoid contact, so that the first touch pads and the first scanning line segments are electrically connected to each other. 2. The capacitive touch substrate structure of claim 1, further comprising at least one first-sweeping field segment and a plurality of second touch pads, each of the second touch pads being on the same line. The second scanning line segment and the first scanning line segment are perpendicular to each other, and each of the second touch pads is electrically connected to the second scanning line segment. 3. The capacitive touch substrate structure of claim 2, wherein the second scan line segment runs through the second touch pads on the same line and is electrically connected to each other. 4. The capacitive touch substrate structure of claim 2, further comprising a plurality of strips 31 201044054, the second scan line segment, at least one of the second touch lines on the same-line and the One of the two scanning line segments is electrically connected to the second scanning line segment. 5. The capacitive touch panel structure of claim 2, wherein the second touch pads and the second scan lines are disposed on the side of the transparent substrate, and each of the second touches The pad is electrically connected to the second scan line segment. 6. The capacitive touch substrate structure of claim 2, further comprising a second; a second electrical layer, a second signal line, and a plurality of second conductive pillars, the second dielectric layer being disposed on In the plane of the first dielectric layer, the second signal line is disposed on the first dielectric layer and is in contact with the second dielectric layer, and the second touch tethers are disposed on the transparent substrate. On the side of the material, the second scanning line segment is disposed on the second 71 electrical layer and is in contact with the second dielectric layer, and the second scanning line segment is in the same plane as the second signal line. The second conductive pillar penetrates the first dielectric layer and the second dielectric layer ′, and the second conductive pillars are in electrical contact with the second touch potential and the second _ line segment, respectively. Each of the second touch pads and the second scan line segments are electrically connected to each other. 7. The capacitive touch substrate structure of claim 2, further comprising a second 'I electrical layer, a second dielectric layer, a second signal line, and a plurality of second conductive columns, The second touch pad is disposed on the first dielectric layer, and the second dielectric layer is disposed on a plane of the first dielectric layer having the second touch pads, the first signal line and The first scanning line is disposed on the second dielectric layer and is in contact with the first dielectric layer. The third dielectric layer is disposed on the second dielectric layer and has the first signal line and the first The second scanning line segment and the 32nd 201044054 two signal line are disposed on the third dielectric layer, and the (IV)-conductive pillar penetrates the first dielectric layer and the second dielectric And the first conductive strips are in electrical contact with the first touch panel and the first scan line segment to interconnect the first touch pads and the scan lines, the second a conductive pillar penetrating the second dielectric layer and the third dielectric layer, and the second conductive pillars and the second touch pads and the second Segment described electrical contact, in order to make each of the second and the second touch Sook scan line electrically connected to each other. Ο &<> The capacitive touch substrate structure as described in claim i, wherein the capacitive touch substrate structure is described in the same-line, and the capacitive touch substrate structure described in the second item Further comprising a plurality of the first scan line segments, at least on the same line, the first touches are electrically connected to one of the first scan line segments of the f-the first scan line segment. The capacitive touch substrate structure of claim 1, wherein the transparent substrate is made of indium tin oxide or polyethylene dioxin. 11. A capacitive touch panel structure comprising: a capacitive touch substrate comprising: a transparent substrate; a plurality of first touch pads disposed on a side of the transparent substrate, and The first touch pads are located on the same line; the first-dielectric layer is disposed on the side of the transparent substrate and covers the first touch pads; the first-signal line setting On the first dielectric layer, and in contact with the 33 201044054 first dielectric layer; at least one first scan line segment disposed on the first dielectric layer and contacting the first dielectric layer 'and The first scanning line segment is located on the same plane as the first signal line; and the plurality of first conductive pillars extend through the first dielectric layer, and the first conductive pillars are respectively associated with the first touch pads and The first scanning line segment is electrically connected to electrically connect the first touch pad and the first scanning line segment to each other; and a light emitting module is disposed on the first dielectric layer for emitting a light To the transparent substrate. 12. The capacitive touch panel structure of claim 11, further comprising a flat layer disposed between the first dielectric layer and the light emitting module. 13. The capacitive touch panel structure of claim 11, further comprising an anti-electromagnetic interference layer disposed on the first dielectric layer. 14. The capacitive touch panel structure of claim 11, further comprising a protective parasitic capacitance interference layer disposed on the first dielectric layer. The capacitive touch panel structure of claim η, further comprising at least one second scan line segment and a plurality of second touch pads, each of the second touch pads being located on the same line The second scanning segment is perpendicular to the first scanning line segment, and each of the second pads is connected to the second scanning line segment. The capacitive touch panel structure of claim 6, wherein the second scanning line segment runs through the second touch pads located on the same line, and is electrically connected to each other 34 201044054. 17. The structure of the remaining control panel as claimed in claim 15, wherein the shot further comprises a plurality of lines of at least one line of the same line on the same line, and the second touch line is respectively connected to the second scanning line segment. - the second scan line segment is electrically connected. 18. The f_control panel structure as described in _17, the second touch pad and the second scan line are disposed on the side of the transparent substrate, and each of the second touch pads and the first The two scanning line segments are electrically connected to each other. 19. The capacitive touch panel structure of claim 1 , further comprising a second dielectric layer, a second signal line, and a plurality of second conductive columns, wherein the second dielectric layer is disposed on the In the plane of the first dielectric layer, the second signal line is disposed on the second dielectric layer and is in contact with the second dielectric layer, and the second touch tether is disposed on the transparent material The second sweeping section is disposed on the second dielectric layer and is in contact with the second dielectric layer, and the second scanning line segment is on the same plane as the second signal line. The second conductive pillars are electrically connected to the second conductive pads and the second conductive segments, respectively. Each of the second touch pads and the second scan line segments are electrically connected to each other. 20. The capacitive touch panel structure of claim 1 , further comprising a second dielectric layer and a second signal line, wherein the second dielectric layer is disposed on the plane of the first dielectric layer The second signal line is disposed on the second dielectric layer and is in contact with the second dielectric layer. The second touch pads and the second scan line are disposed on the second dielectric layer. And the second touch pads are electrically connected to the second scan line segment 35 201044054. The capacitive touch panel structure according to claim 15, wherein the capacitive touch panel structure is simply (four) lined and is divided into a plurality of control panel areas. 22. The capacitive touch panel structure of claim 21, further comprising a plurality of display arrays, wherein the first scan line segment and the second scan line segment are respectively shouted by the same side pull line _ and the _ control panel area is electrically connected. The capacitive touch panel structure of claim 21, further comprising a plurality of display arrays, and wherein the first scan line segment and the second scan line segment are respectively reversed and connected The display array and the touch panel regions are electrically connected. The capacitive touch panel structure of claim 21, further comprising at least one conductive via, the first scan line segment and the second scan line segment being electrically connected to the §H conductive via The first scan line segment and the second scan line segment are located on the same plane. The capacitive touch panel structure of claim U, wherein the first scan line is respectively connected to the first touch pads on the same line and electrically connected to each other. The capacitive touch panel structure of claim η, further comprising a plurality of the first scan line segments, at least one of the first touch pads on the same line and the first scan line segments respectively One of the first scan line segments is electrically connected. The capacitive touch panel structure of claim 11, wherein the transparent substrate 36 201044054 is made of ITO or polyethylene dioxin. The capacitive touch panel structure of claim 11, wherein the light-emitting module comprises at least an organic light-emitting diode, an active layer, a purification layer, and an electrode layer. On the first dielectric layer. The capacitive touch panel structure of claim η, wherein the light emitting module comprises a plurality of thin film transistors, a purification layer, a liquid crystal layer, a color filter, an electrode layer, and The backlights are sequentially disposed on the first dielectric layer. The capacitive panel structure of claim u, wherein the illuminating module comprises a plurality of _ transistors, a passivation layer, an electrophoretic layer, a color glazing sheet, a 31-electrode layer, and a substrate. The system is sequentially disposed on the first dielectric layer. According to the item u, the light-capacity control panel structure is provided, and the light-emitting module includes a thin layer, a light sheet, a __ pole, a layer, and a plurality of 〇32 systems, which are sequentially disposed on the first dielectric layer. . The capacitor_control panel structure described in 31, wherein the light-emitting module has a 33.1^1 color matrix, and is located on the same plane as the color light-emitting sheets. The capacitive touch panel structure described in the right 2 U, wherein the light-emitting module includes: a polar layer, a plurality of thin film transistors, a plurality of color warfare films, and a) an electrical layer' is sequentially arranged _ first - on the dielectric layer. 37