TW201928619A - Touch display panel - Google Patents

Abstract

The invention discloses a touch display panel. The touch display panel comprises a liquid crystal display module, a first flexibility transparent electrode module and a transparent cover plate from bottom to top. The area of the first flexibility transparent electrode module is larger than that of the liquid crystal display module, the first flexibility transparent electrode module is provided with multiple first conductor wires and multiple first outer edges, the first flexibility transparent electrode module and the first conductor wires are bent downwards to be attached to the liquid crystal display module, and the distance between the first conductor wire on the outmost side and the first outer edge closest to the first conductor wire is larger than 4 cm to avoid the oxidation phenomenon that the first conductor wires on a bent region of the first flexibility transparent electrode module extend to the inner side from the outer side.

Description

Touch display panel

The present invention relates to a display panel, and more particularly to a touch display panel.

In recent years, touch panels have been widely used in various electronic products, such as: global positioning system (GPS), personal digital assistant (PDA), mobile phone (cellular phone) and palm-type Computer (Hand-held PC), etc. to replace traditional input devices (such as: keyboard and mouse, etc.). This drastic change in design not only improves the human-machine interface affinity of these electronic devices, but also frees up more space by omitting traditional input devices, allowing the installation of larger display panels for users to browse data. .

In summary, existing touch panels include resistive, capacitive, sonic and optical types. Under the principle of various large projects, many different types of production methods have been derived. For example, the resistance type has 8-wire, 7-wire, 6-wire, 5-wire, 4-wire, digital resistance, etc .; the capacitive type has a projection type. Capacitance, surface capacitance, digital capacitance (multi-touch capacitive type), etc .; optical types include infrared shielding type, total reflection suppression type, etc. The projected capacitive touch screen detects the presence or absence of touch by detecting the coupling capacitance between the driving electrode and the receiving electrode. There are usually two types of projected capacitive touch screens, one is a double-layer conductive layer, such as double-layer indium tin oxide (DITO), and the other is a single-layer conductive layer, such as single-layer indium tin oxide (SITO). For the DITO structure, the specific implementation structure can be as shown in FIG. 1. This projected capacitive touch screen includes a first transparent substrate 10, a second transparent substrate 12, a receiving electrode layer 14, a driving electrode layer 16, A transparent optical adhesive layer 18 and a cover plate 20, wherein the first transparent substrate 10, the driving electrode layer 16, the transparent optical adhesive layer 18, the second transparent substrate 12, the receiving electrode layer 14 and the cover plate are sequentially stacked from bottom to top. 20. The first transparent substrate 10 has a sensing area and a frame area around it. The driving electrode layer 16 includes a plurality of electrode strings and a plurality of wirings. The electrode strings are located on the sensing area and the wirings are located on the frame area. Similarly, the second transparent substrate 12 has a sensing area and a surrounding frame area. The receiving electrode layer 14 includes a plurality of electrode strings and a plurality of wirings. The electrode strings are located in the sensing area and the wirings are located on the border area. However, in this structure, the traces are all designed on the same plane, which makes it increasingly difficult to reduce the line width and distance. In order to achieve narrow bezels, there are currently technologies to bend the electrode layer to meet the needs of customers' ultra-narrow bezels, but this will cause the oxidation of the lines on the bent area extending from the outside to the inside.

Therefore, the present invention proposes a touch display panel to solve the problems mentioned above in order to solve the above-mentioned problems.

The main object of the present invention is to provide a touch display panel, which is designed by designing the outermost conductive wire in the flexible transparent electrode module to be closest to the outer edge of the flexible transparent electrode module. The distance is greater than 4 cm to avoid oxidation of the conductive wires on the bendable area of the flexible transparent electrode module from the outside to the inside, thereby improving the reliability and stability of the bendable area.

To achieve the above object, the present invention provides a touch display panel including a liquid crystal display module, a first flexible transparent electrode module, and a transparent cover plate arranged from bottom to top. The area of the first flexible transparent electrode module is larger than the area of the liquid crystal display module. The first flexible transparent electrode module has a plurality of first conductive wires and a first outer edge, and the first flexible transparent electrode module The first conductive line is bent downward to be attached to the liquid crystal display module, and the distance between the outermost first conductive line and the closest first outer edge is greater than 4 cm.

In one embodiment of the present invention, the first flexible transparent electrode module further includes a first flexible transparent substrate, a first sensing layer, a second sensing layer, a plurality of second conductive wires, and a The first protective adhesive layer and a second protective adhesive layer. The area of the first flexible transparent substrate is larger than that of the liquid crystal display module. The first flexible transparent substrate has a first sensing area and a first frame area around the first flexible area. The first frame area has a first outer edge. And all the first conductive lines are disposed on the top of the first frame area. The first sensing layer and the second sensing layer are respectively disposed on the top and the bottom of the first sensing region. The second conductive line is disposed at the bottom of the first frame area, and the distance between the outermost second conductive line and the closest first outer edge is greater than 4 cm. The first protective adhesive layer covers the second sensing layer and all the second conductive lines, and is located between the second sensing layer and the top of the liquid crystal display module. The first frame area, the second conductive line and the first protective adhesive layer are bent downward, so as to be attached to the liquid crystal display module by using the first protective adhesive layer. The second protective adhesive layer covers the first sensing layer and all the first conductive lines, and is located between the first sensing layer and the transparent cover. The first frame area, the first conductive line and the second protective adhesive layer on the first frame area are bent downward to be attached to the liquid crystal display module with an adhesive.

In an embodiment of the present invention, a material of the first conductive line and the second conductive line is copper or a copper alloy.

In one embodiment of the present invention, the thickness of the first protective glue layer and the second protective glue layer is 1-10 microns.

In one embodiment of the present invention, the bending region of the first protective adhesive layer and the second protective adhesive layer is made of transparent material or opaque material.

In one embodiment of the present invention, the first flexible transparent electrode module further includes a first protective adhesive layer, a first flexible transparent substrate, a first sensing layer, and a second protective adhesive layer. The first protective adhesive layer is disposed on the top of the liquid crystal display module. The first flexible transparent substrate is disposed on the first protective adhesive layer. The area of the first flexible transparent substrate is larger than the area of the liquid crystal display module. The first flexible transparent substrate has a first sensing area and its surroundings. A first border region, the first border region has a first outer edge, and all first conductive lines are disposed on top of the first border region. The first sensing layer is disposed on top of the first sensing area. The second protective adhesive layer covers the first sensing layer and all the first conductive lines, and is located between the first sensing layer and the transparent cover plate, and the first frame area and the first conductive lines and the second protective adhesive layer thereon. Bend down to attach to the LCD module with a first adhesive.

In an embodiment of the present invention, the touch display panel further includes a second flexible transparent electrode module having an area larger than that of the liquid crystal display module, and the second flexible transparent electrode module is disposed on the second protection. Between the adhesive layer and the transparent cover plate, the second flexible transparent electrode module has a plurality of second conductive lines and a second outer edge, and the second flexible transparent electrode module and the second conductive line are bent downward to A second adhesive is attached to the liquid crystal display module, and the distance between the outermost second conductive line and the closest second outer edge is greater than 4 cm.

In one embodiment of the present invention, the second flexible transparent electrode module further includes a second flexible transparent substrate, a second sensing layer, and a third protective glue layer. The second flexible transparent substrate is disposed on the second protective adhesive layer. The area of the second flexible transparent substrate is larger than that of the liquid crystal display module. The second flexible transparent substrate has a second sensing area and its surroundings. A second frame region, the second frame region has a second outer edge, and all second conductive lines are disposed on top of the second frame region. The second sensing layer is disposed on top of the second sensing area. The third protective adhesive layer covers the second sensing layer and all the second conductive lines, and is located between the second sensing layer and the transparent cover plate, and the second frame area and the second conductive lines and the third protective adhesive layer thereon Bend down to attach to the LCD module with the second adhesive.

In an embodiment of the present invention, a material of the first conductive line and the second conductive line is copper or a copper alloy.

In one embodiment of the present invention, the thickness of the second protective glue layer and the third protective glue layer is 1-10 microns.

In one embodiment of the present invention, the bending area of the second protective rubber layer and the third protective rubber layer is made of transparent material or opaque material.

In order to make the reviewers of the Guigui have a better understanding and understanding of the structural features of the present invention and the effects achieved, I would like to refer to the preferred embodiment diagram and the detailed description, as described below:

Embodiments of the present invention will be further explained by cooperating with related drawings below. Wherever possible, in the drawings and the description, the same reference numerals represent the same or similar components. In the drawings, shapes and thicknesses may be exaggerated based on simplification and convenient labeling. It can be understood that elements not specifically shown in the drawings or described in the description have the forms known to those skilled in the art in the art. Those skilled in the art can make various changes and modifications according to the content of the present invention.

Please refer to FIG. 2, FIG. 3, FIG. 4, FIG. 5, FIG. 6, FIG. 7, and FIG. 8 to introduce the first embodiment of the touch display panel of the present invention. The touch display panel 22 of the present invention includes a liquid crystal display module 24, a first flexible transparent electrode module 26 and a transparent cover plate 28. The first flexible transparent electrode module 26 is disposed on the top of the liquid crystal display module 24, and the transparent cover plate 28 is disposed on the first flexible transparent electrode module 26. The area of the first flexible transparent electrode module 26 is larger than the area of the liquid crystal display module 24. The first flexible transparent electrode module 26 has a plurality of first conductive wires 30 and a first outer edge, and the first flexibility is The transparent electrode module 26 and the first conductive wire 30 are bent downward to be attached to the liquid crystal display module 24, for example, attached to the side or the bottom of the liquid crystal display module 24. Take the bottom as an example. The material of the first conductive wire 30 is, for example, copper or a copper alloy. The distance D1 between the outermost first conductive line 30 and the closest outer edge is greater than 4 cm. Because the maximum distance that water vapor enters the first flexible transparent electrode module 26 is 4 cm, as long as the distance D1 between the outermost first conductive wire 30 and its closest first outer edge is greater than 4 cm, that is, The oxidation phenomenon of the first conductive wire 30 on the bending area of the first flexible transparent electrode module 26 from the outside to the inside can be avoided, thereby improving the reliability and stability of the bending area.

The first flexible transparent electrode module 26 further includes a first flexible transparent substrate 32, a first sensing layer 34, a second sensing layer 36, a plurality of second conductive wires 38, and a first protective adhesive. The material of the layer 40 and a second protective glue layer 42, the second conductive wire 38 is, for example, copper or a copper alloy, and the thickness of the first protective glue layer 40 and the second protective glue layer 42 is 1-10 μm. The area of the first flexible transparent substrate 32 is larger than that of the liquid crystal display module 24. The first flexible transparent substrate 32 has a first sensing region 44 and a first frame region 46 and a first frame region 46 around the first sensing region 44. It has a first outer edge, and all the first conductive lines 30 are disposed on the top of the first frame area 46. The first sensing layer 34 and the second sensing layer 36 are respectively disposed on the top and the bottom of the first sensing region 44. All the second conductive lines 38 are disposed at the bottom of the first frame area 46, and the distance D2 between the outermost second conductive line 38 and the closest first outer edge thereof is greater than 4 cm to avoid the first flexible transparent electrode. The second conductive wire 38 on the bending area of the module 26 undergoes an oxidation phenomenon extending from the outside to the inside, thereby improving the reliability and stability of the bending area. The first protective adhesive layer 40 covers the second sensing layer 36 and all the second conductive lines 38, and is located between the second sensing layer 36 and the top of the liquid crystal display module 24. The first frame area 46 and the second conductive line 38 and the first protective adhesive layer 40 are bent downward to be attached to the liquid crystal display module 24 by using the first protective adhesive layer 40, for example, to be attached to a liquid crystal display. The side or bottom of the module 24. Here, the bottom of the liquid crystal display module 24 is taken as an example. The second protective adhesive layer 42 covers the first sensing layer 34 and all the first conductive lines 30, and is located between the first sensing layer 34 and the transparent cover plate 28. The first frame area 46 and the first conductive wire 30 and the second protective adhesive layer 42 are bent downward to be attached to the liquid crystal display module 24 with an adhesive 48, for example, to the liquid crystal display module. 24 on the bottom. The bending area of the first protective adhesive layer 40 and the second protective adhesive layer 42 is made of transparent material or opaque material. Generally, the first protective adhesive layer 40 and the second protective adhesive layer 42 can be transparent optical adhesive layers or insulating adhesives. In design, the shortest distance d1 between the outermost position of the first flexible transparent substrate 32 above the bending area of the first protective adhesive layer 40 and the side surface of the liquid crystal display module 24 is 0.5-3 cm. The shortest distance d2 between the outermost position of the bending area of the second protective adhesive layer 42 and the side surface of the liquid crystal display module 24 is 0.5-3 cm.

Please refer to FIGS. 9, 10, 11, 12, 13, 14, 15, and 16 to introduce the second embodiment of the touch display panel of the present invention. The touch display panel 50 of the present invention includes a liquid crystal display module 52, a first flexible transparent electrode module 54, a second flexible transparent electrode module 56, and a transparent cover plate 58. The first flexible transparent electrode module 54 is disposed on the top of the liquid crystal display module 52. The area of the first flexible transparent electrode module 54 is larger than the area of the liquid crystal display module 52. The first flexible transparent electrode module 54 has a plurality of first conductive wires 60 and a first outer edge, and the first flexibility is The transparent electrode module 54 and the first conductive wire 60 are bent downward to be attached to the liquid crystal display module 52, for example, attached to the side or the bottom of the liquid crystal display module 52. Take the bottom as an example. The material of the first conductive wire 60 is, for example, copper or a copper alloy. The distance D3 between the outermost first conductive wire 60 and its nearest first outer edge is greater than 4 cm. Because the maximum distance that water vapor enters the first flexible transparent electrode module 54 is 4 cm, as long as the distance D3 between the outermost first conductive wire 60 and the closest first outer edge thereof is greater than 4 cm, that is, The first conductive wire 60 on the bending area of the first flexible transparent electrode module 54 can be prevented from oxidizing from the outside to the inside, thereby improving the reliability and stability of the bending area. The transparent cover plate 58 is provided on the first flexible transparent electrode module 54 through the second flexible transparent electrode module 56.

The first flexible transparent electrode module 54 further includes a first protective adhesive layer 62, a first flexible transparent substrate 64, a first sensing layer 66, and a second protective adhesive layer 68. The second protective layer The thickness of the adhesive layer 68 is 1-10 microns. The first protective adhesive layer 62 is disposed on the top of the liquid crystal display module 52. The first flexible transparent substrate 64 is disposed on the first protective adhesive layer 62. The area of the first flexible transparent substrate 64 is larger than the area of the liquid crystal display module 52. The first flexible transparent substrate 64 has a first sense. The measurement area 70 and the first frame area 72 around it, the first frame area 72 has a first outer edge, and all the first conductive lines 60 are disposed on top of the first frame area 72. The first sensing layer 66 is disposed on top of the first sensing area 70. The second protective adhesive layer 68 covers the first sensing layer 66 and all the first conductive lines 60, and is located between the first sensing layer 66 and the transparent cover plate 58, and is also located between the first sensing layer 66 and the second flexible layer. Between transparent electrode modules 56. The first frame region 72 and the first conductive wire 60 and the second protective adhesive layer 68 are bent downward to be attached to the liquid crystal display module 52 using a first adhesive 74, such as to be attached to a liquid crystal display. The bottom of the module 52. The bent area of the second protective adhesive layer 68 is made of transparent material or opaque material. Generally, the second protective adhesive layer 68 may be a transparent optical adhesive layer or an insulating adhesive. In design, the shortest distance d3 from the outermost position of the bent area of the second protective adhesive layer 68 to the side of the liquid crystal display module 52 is 0.5-3 cm.

The area of the second flexible transparent electrode module 56 is larger than that of the liquid crystal display module 52. The second flexible transparent electrode module 56 is disposed between the second protective adhesive layer 68 and the transparent cover plate 58. The second flexible transparent electrode module 56 has a plurality of second conductive wires 76 and a second outer edge. The material of the second conductive wires 76 is, for example, copper or a copper alloy. The second flexible transparent electrode module 56 and the second conductive wire 76 are bent downward to be attached to the liquid crystal display module 52 with a second adhesive 78, for example, attached to the side of the liquid crystal display module 52 or Bottom, here the bottom of the liquid crystal display module 52 is taken as an example. The distance between the outermost second conductive wire 76 and the nearest second outer edge is greater than 4 cm. Because the maximum distance D4 of water and gas entering the second flexible transparent electrode module 56 is 4 cm, as long as the distance D4 of the outermost second conductive wire 76 from its closest second outer edge is greater than 4 cm, In this way, the oxidation phenomenon of the second conductive wire 76 on the bent area of the second flexible transparent electrode module 56 extending from the outside to the inside can be avoided, thereby improving the reliability and stability of the bent area.

The second flexible transparent electrode module 56 further includes a second flexible transparent substrate 80, a second sensing layer 82, and a third protective adhesive layer 84. The thickness of the third protective adhesive layer 84 is 1- 10 microns. The second flexible transparent substrate 80 is disposed on the second protective adhesive layer 68. The area of the second flexible transparent substrate 80 is larger than the area of the liquid crystal display module 52. The second flexible transparent substrate 80 has a second sense. The measurement area 86 and the surrounding second frame area 88 have a second outer edge, and all the second conductive lines 76 are disposed on the top of the second frame area 88. The second sensing layer 82 is disposed on top of the second sensing area 86. The third protective adhesive layer 84 covers the second sensing layer 82 and all the second conductive lines 76, and is located between the second sensing layer 82 and the transparent cover plate 58. The second frame area 88 and the second conductive lines thereon. 76 and the third protective adhesive layer 84 are bent downward to be attached to the liquid crystal display module 52 with the second adhesive 78, for example, attached to the bottom of the liquid crystal display module 52. The bending area of the third protective adhesive layer 84 is made of transparent material or opaque material. Generally, the third protective adhesive layer 84 can be a transparent optical adhesive layer or an insulating adhesive. In design, the shortest distance d4 from the outermost position of the bending area of the third protective adhesive layer 84 to the side of the liquid crystal display module 52 is 0.5-3 cm.

In summary, in the present invention, the outermost conductive wire in the flexible transparent electrode module is designed to be more than 4 cm away from the outer edge of the closest flexible transparent electrode module to avoid being flexible. The conductive wire on the bending area of the transparent transparent electrode module undergoes an oxidation phenomenon extending from the outside to the inside, thereby improving the reliability and stability of the bending area.

The above is only a preferred embodiment of the present invention, and is not intended to limit the scope of implementation of the present invention. Therefore, all equivalent changes and modifications in accordance with the shape, structure, characteristics, and spirit described in the scope of the patent application for the present invention are provided. Shall be included in the scope of patent application of the present invention.

10‧‧‧ the first transparent substrate

12‧‧‧Second transparent substrate

14‧‧‧Receiving electrode layer

16‧‧‧Drive electrode layer

18‧‧‧ transparent optical adhesive layer

20‧‧‧ Cover

22‧‧‧Touch display panel

24‧‧‧LCD Display Module

26‧‧‧The first flexible transparent electrode module

28‧‧‧ transparent cover

30‧‧‧The first conductive wire

32‧‧‧ the first flexible transparent substrate

34‧‧‧first sensing layer

36‧‧‧Second sensing layer

38‧‧‧Second Conductive Wire

40‧‧‧first protective adhesive layer

42‧‧‧Second protective adhesive layer

44‧‧‧first sensing area

46‧‧‧The first border area

48‧‧‧Viscose

50‧‧‧Touch display panel

52‧‧‧LCD Module

54‧‧‧The first flexible transparent electrode module

56‧‧‧Second flexible transparent electrode module

58‧‧‧Transparent cover

60‧‧‧The first conductive wire

62‧‧‧The first protective rubber layer

64‧‧‧ the first flexible transparent substrate

66‧‧‧first sensing layer

68‧‧‧Second protective rubber layer

70‧‧‧first sensing area

72‧‧‧ the first border area

74‧‧‧The first adhesive

76‧‧‧Second Conductive Wire

78‧‧‧Second viscose

80‧‧‧Second flexible transparent substrate

82‧‧‧Second sensing layer

84‧‧‧Third protective rubber layer

86‧‧‧Second sensing area

88‧‧‧ second border area

FIG. 1 is a structural cross-sectional view of a double-layer indium tin oxide (DITO) structure of the prior art. FIG. 2 is a structural top view of the first embodiment of the touch display panel of the present invention. Fig. 3 is a schematic diagram of the liquid crystal display module corresponding to Fig. 2 of the present invention. FIG. 4 is a schematic diagram of a first flexible transparent substrate corresponding to FIG. 2 of the present invention. Fig. 5 is a schematic view of the transparent cover plate corresponding to Fig. 2 of the present invention. Fig. 6 is a sectional view of the structure taken along line A-A 'in Fig. 2 of the present invention. FIG. 7 is a schematic diagram of a first flexible transparent substrate corresponding to FIG. 2 and a first sensing layer and a first conductive line thereon. FIG. 8 is a schematic diagram of the first flexible transparent substrate corresponding to FIG. 2 and the second sensing layer and the second conductive line thereon. FIG. 9 is a structural plan view of a second embodiment of a touch display panel according to the present invention. FIG. 10 is a schematic diagram of a liquid crystal display module corresponding to FIG. 9 according to the present invention. FIG. 11 is a schematic diagram of a first flexible transparent substrate corresponding to FIG. 9 of the present invention. FIG. 12 is a schematic diagram of a second flexible transparent substrate corresponding to FIG. 9 of the present invention. FIG. 13 is a schematic diagram of the transparent cover plate corresponding to FIG. 9 according to the present invention. Fig. 14 is a sectional view of the structure taken along line B-B 'in Fig. 9 of the present invention. FIG. 15 is a schematic diagram of a first flexible transparent substrate corresponding to FIG. 9 and a first sensing layer and a first conductive line thereon. FIG. 16 is a schematic diagram of a second flexible transparent substrate corresponding to FIG. 9 and a second sensing layer and a second conductive line thereon.

Claims (11)

A touch display panel includes: a liquid crystal display module; a first flexible transparent electrode module having an area larger than that of the liquid crystal display module; and the first flexible transparent electrode module is disposed on the liquid crystal. On the top of the display module, the first flexible transparent electrode module has a plurality of first conductive lines and a first outer edge, and the first flexible transparent electrode module and the first conductive line are bent downward to Attached to the liquid crystal display module, and the distance between the outermost first conductive line and the first outer edge closest to it is greater than 4 cm; and a transparent cover provided on the first flexibility On a transparent electrode module. The touch display panel according to claim 1, wherein the first flexible transparent electrode module further comprises: a first flexible transparent substrate having an area larger than the area of the liquid crystal display module, and the first The flexible transparent substrate has a first sensing area and a first frame area around the first sensing area, the first frame area has the first outer edge, and the first conductive lines are disposed on top of the first frame area; A first sensing layer is disposed on the top of the first sensing region; a second sensing layer is disposed on the bottom of the first sensing region; a plurality of second conductive lines are disposed on the first frame region The distance between the bottom and outermost second conductive lines and the closest first outer edge thereof is greater than 4 cm; a first protective adhesive layer covering the second sensing layer and the second conductive lines, and Located between the second sensing layer and the top of the liquid crystal display module, the first frame region and the second conductive line thereon and the first protective adhesive layer are bent downward to utilize the first A protective adhesive layer is attached to the liquid crystal display module; and a second protective adhesive layer covers the first A sensing layer and the first conductive lines are located between the first sensing layer and the transparent cover plate. The first frame region and the first conductive line and the second protective adhesive layer thereon Bend down to attach to the LCD module with an adhesive. The touch display panel according to claim 2, wherein a material of the first conductive line and the second conductive line is copper or a copper alloy. The touch display panel according to claim 2, wherein the thickness of the first protective adhesive layer and the second protective adhesive layer is 1-10 microns. The touch display panel according to claim 2, wherein the bending area of the first protective adhesive layer and the second protective adhesive layer is made of transparent material or opaque material. The touch display panel according to claim 1, wherein the first flexible transparent electrode module further comprises: a first protective adhesive layer provided on the top of the liquid crystal display module; a first flexible A transparent substrate is disposed on the first protective adhesive layer. The area of the first flexible transparent substrate is larger than the area of the liquid crystal display module. The first flexible transparent substrate has a first sensing area and A surrounding first border region, the first border region has the first outer edge, and the first conductive lines are disposed on top of the first border region; a first sensing layer is disposed on the first sensing The top of the area; and a second protective adhesive layer covering the first sensing layer and the first conductive lines, and located between the first sensing layer and the transparent cover plate, the first frame area and the The first conductive line and the second protective adhesive layer are bent downward to be attached to the liquid crystal display module with a first adhesive. The touch display panel according to claim 6, further comprising a second flexible transparent electrode module having an area larger than that of the liquid crystal display module. The second flexible transparent electrode module is provided in the first flexible transparent electrode module. Between two protective adhesive layers and the transparent cover, the second flexible transparent electrode module has a plurality of second conductive lines and a second outer edge, and the second flexible transparent electrode module and the second conductive The wire is bent downward to be attached to the liquid crystal display module with a second adhesive, and the distance between the outermost second conductive wire and the second outer edge closest to it is greater than 4 cm. The touch display panel according to claim 7, wherein the second flexible transparent electrode module further comprises: a second flexible transparent substrate provided on the second protective adhesive layer, and the second flexible The area of the transparent transparent substrate is larger than that of the liquid crystal display module. The second flexible transparent substrate has a second sensing area and a second frame area around the second flexible area. The second frame area has the second outer edge. And the second conductive lines are disposed on the top of the second frame area; a second sensing layer is disposed on the top of the second sensing area; and a third protective glue layer covers the second sensing layer Layer and the second conductive lines, and located between the second sensing layer and the transparent cover plate, the second frame area and the second conductive lines and the third protective adhesive layer on the second frame area are bent downward To use the second adhesive to attach to the liquid crystal display module. The touch display panel according to claim 8, wherein the material of the first conductive line and the second conductive line is copper or a copper alloy. The touch display panel according to claim 8, wherein the thickness of the second protective adhesive layer and the third protective adhesive layer is 1-10 microns. The touch display panel according to claim 8, wherein the bending area of the second protective adhesive layer and the third protective adhesive layer is made of transparent material or opaque material.