Abstract: The present disclosure provides a touch panel structure, which includes a conductive channel region and a second dummy metal pattern. The conductive channel region includes a metal mesh and a first dummy metal pattern. The metal mesh is a conductive channel. The first dummy metal pattern is intersecting the metal mesh and has at least one breakpoint at every point of intersection with the metal mesh. The metal mesh is separated from the first dummy metal pattern to be insulated from the first dummy metal pattern at the at least one breakpoint. The second dummy metal pattern is disposed on the both sides of the conductive channel region.

Abstract: A touch panel, comprising: a substrate; a plurality of sensing electrodes on the substrate, each of the plurality of sensing electrodes being formed by a plurality of metal meshes; and a plurality of traces on the substrate, the plurality of traces electrically coupled to the plurality of sensing electrodes, and each of the plurality of traces are a metal wire; wherein a blackening layer is formed on each of the plurality of sensing electrodes, and no blackening layer is formed on the plurality of traces. The blackening layers of the touch panel of the present invention only cover the sensing electrodes and do not cover the traces, which can avoid chemical substances remaining on the traces and traces being corroded and disconnection when the black layers are manufactured.

Abstract: A touch display panel is provided. The touch display panel includes a cover and a touch sensing layer. The cover has a touch-sensing section, a first bending section, and a first side section. The first side section and the touch-sensing section are not coplanar and the first bending section is located between the touch-sensing section and the first side section. The touch sensing layer is located under the cover and includes a first metal mesh layer and a second metal mesh layer. Only one of the first metal mesh layer and the second metal mesh layer is located under the first bending section.

Abstract: A touch display panel is provided. The touch display panel includes a cover and a touch sensing layer. The cover has a touch-sensing section, a first bending section, and a first side section. The first side section and the touch-sensing section are not coplanar and the first bending section is located between the touch-sensing section and the first side section. The touch sensing layer is located under the cover and includes a first metal mesh layer and a second metal mesh layer. Only one of the first metal mesh layer and the second metal mesh layer is located under the first bending section.

Abstract: The present disclosure provides a touch panel structure, which includes a conductive channel region and a second dummy metal pattern. The conductive channel region includes a metal mesh and a first dummy metal pattern. The metal mesh is a conductive channel. The first dummy metal pattern is intersecting the metal mesh and has at least one breakpoint at every point of intersection with the metal mesh. The metal mesh is separated from the first dummy metal pattern to be insulated from the first dummy metal pattern at the at least one breakpoint. The second dummy metal pattern is disposed on the both sides of the conductive channel region.

Abstract: A touch panel includes a substrate, a first electrode layer on a first surface of the substrate, and a second electrode layer on a second surface of the substrate. The first electrode layer has a plurality of first sensing lines configured to send touch signals and a plurality of first dummy lines coupled to the plurality of first sensing lines. The second electrode layer has a plurality of second sensing lines configured to receive the touch signals and a plurality of second dummy lines coupled to the plurality of second sensing lines. Each second dummy line defines at least one breaking point. Each first sense line has a projection at the second electrode layer which overlaps with one breaking point.

Abstract: A metal mesh structure capable of reducing breakpoint short circuits, including a plurality of first main channel wires, a plurality of second main channel wires, a plurality of first virtual wires and a plurality of second virtual wires. The first main channel wires are spaced apart and aligned in a first direction. The second main channel wires are spaced apart and aligned in a second direction. The second main channel wires cross the first main channel wires to form a plurality of main channel meshes. A method of manufacturing a metal mesh structure capable of reducing breakpoint short circuits is further provided. Given the aforesaid structure and method, the metal mesh is effective in reducing breakpoint short circuits.