A colored thin covering film is provided, including an upper detached layer, a colored ink film, a low dielectric glue layer, and a lower detached layer. The color ink layer is formed between the upper detached layer and the low dielectric glue layer. The low dielectric glue layer is formed between the colored ink layer and the lower detached layer. The thickness of the colored ink layer is between 1 to 10 m, and the thickness of the low dielectric glue layer is between 3 to 25 m, such that a total thickness of the colored ink layer and the low dielectric glue layer is allowed to be between 4 to 35 m. The colored thin covering film has an extremely low dielectric constant and loss, extremely low ion migration, good adhesion, heat dissipation, high flexibility, and low resilience, and can be processed in a low temperature.

A photosensitive dry film and uses of the same are provided. The photosensitive dry film comprises a support layer and a photosensitive resin layer disposed on the support layer, wherein the support layer has a first surface and a second surface opposite the first surface, and the first surface is in contact with the photosensitive resin layer and has a non-smooth structure.

Electronic sticker technology that enables assembly of circuits at ambient temperature without the use of any special tools.

A photosensitive element 1 comprises a support film 10, a protective film (polypropylene film) 30, and a photosensitive layer 20 which is arranged between the support film 10 and the protective film 30, wherein the protective film 30 has a principal surface 30a at a side of the photosensitive layer 20 and a principal surface 30b at an opposite side of the principal surface 30a, and the principal surface 30a and the principal surface 30b are smooth.

A resin film configured to hold a conductive metallic track against a panel. The resin film partially covers the conductive metallic track, such that the conductive metallic track has at least one region which does not have the resin film, so as to allow an electrical connection by contact. Thus, in the context of assembly on a panel, the metallic track incorporated between the panel and the resin film is protected, thus rendering this technical solution particularly robust. Furthermore, the resin film electrically insulates the metallic track from surrounding elements, and the regions which do not have resin film allow an electrical connection by contact.

A substrate structure includes a dielectric layer, a metal foil, a patterned metal layer, a first patterned solder-resist layer, a release layer and a second patterned solder-resist layer. The dielectric layer includes a first surface having a plurality of recesses and a second surface. The metal foil is disposed on the second surface. The patterned metal layer is disposed on the first surface, the patterned metal layer has a plurality of openings, and the openings are respectively corresponding to and expose the recesses. The first patterned solder-resist layer is filled in each of the recesses and corresponding to each of the openings. A top surface of the first patterned solder-resist layer is substantially coplanar with a top surface of the patterned metal layer. The second patterned solder-resist layer is disposed on the first patterned solder-resist layer and in the openings, and covers a portion of the patterned metal layer.

A substrate structure includes a dielectric layer, a metal foil, a patterned metal layer, a first patterned solder-resist layer, a release layer and a second patterned solder-resist layer. The dielectric layer includes a first surface having a plurality of recesses and a second surface. The metal foil is disposed on the second surface. The patterned metal layer is disposed on the first surface, the patterned metal layer has a plurality of openings, and the openings are respectively corresponding to and expose the recesses. The first patterned solder-resist layer is filled in each of the recesses and corresponding to each of the openings. A top surface of the first patterned solder-resist layer is substantially coplanar with a top surface of the patterned metal layer. The second patterned solder-resist layer is disposed on the first patterned solder-resist layer and in the openings, and covers a portion of the patterned metal layer.

Electronic sticker technology that enables assembly of circuits at ambient temperature without the use of any special tools.

A substrate structure includes a dielectric layer, a metal foil, a patterned metal layer, a first patterned solder-resist layer and a second patterned solder-resist layer. The dielectric layer includes a first surface and a second surface, and the first surface has a plurality of recesses. The metal foil is disposed on the second surface. The patterned metal layer is disposed on the first surface, the patterned metal layer has a plurality of openings, and the openings are respectively corresponding to and expose the recesses. The first patterned solder-resist layer is filled in each of the recesses and corresponding to each of the openings. A top surface of the first patterned solder-resist layer is substantially coplanar with a top surface of the patterned metal layer. The second patterned solder-resist layer is disposed on the first patterned solder-resist layer and in the openings, and covers a portion of the patterned metal layer.

A printed circuit board comprises a support structure, a conductive layer operably coupled to the support structure, a mask structure formed on the conductive layer, and a cover layer. The conductive layer comprises first and second portions of conductive material separated by a gap that defines a spacing between the first and second portions that does not contain conductive material. The mask structure defines first and second regions on the conductive layer. The first region is enclosed by a first boundary defined by the mask structure and includes the gap. The second region lies outside of the first boundary. The cover layer is sized to fit within the first region and comprises a laminatible insulating material that flows within the first region during lamination. During lamination, the first boundary prevents the laminatible insulating material from flowing into the second region, and the laminatible insulating material flows to fill the gap.