A method of processing component carriers is disclosed. The method includes providing a plurality of arrays each comprising a plurality of component carriers, providing a plurality of separator bodies, forming an alternating stack of the arrays and the separator bodies so that each adjacent pair of stacked arrays is spaced by a respective separator body, and carrying out at least one process, in particular at least one back-end process, using the stack. A separator sheet for spacing arrays and a method of using separator sheets for spacing arrays during processing the arrays are also provided.

A mini smart card and a method of manufacturing the mini smart card are introduced. The method includes disposing bilayered print layers on a top side and a bottom side of a circuit layer, respectively; performing a heat-compression treatment and then a printing treatment on the circuit layer and the bilayered print layers; removing surface layers from the bilayered print layers; and disposing transparent protective layers on the bilayered print layers, respectively. The bilayered print layers are prevented from deforming under the heat generated during the printing treatment. Removal of the surface layers from the bilayered print layers effectively reduces the thickness of the mini smart card.

A method for manufacturing a flexible panel is provided, and the method includes following steps. A column is formed on a carrier substrate. A flexible layer is formed on the carrier substrate, where at least a part of a side surface of the column is surrounded by the flexible layer, so as to form a through hole in the flexible layer. A component layer is formed on the flexible layer, and the column and the carrier substrate are removed. No chars, cracks, and cutting marks are formed on an edge of the through hole of the flexible panel.

A method for manufacturing printed circuit boards for electrical and electronic circuits, comprising an electrically nonconductive substrate (4) and electrically conductive tracks of homogenous thickness applied thereon, wherein the electrically conductive tracks are made of a material with a melting temperature higher than the melting temperature of soldering tin so that they will withstand the soldering of electronic components thereon by soldering tin without melting, characterized in that a print medium (3) comprising the material of the electrically conductive tracks is provided as a two-dimensional layer above the electrically nonconductive substrate (4) and is imprinted on the electrically nonconductive substrate (4) according to the desired conductor track layout, under the influence of heat selectively applied by a print head (2) onto the printing medium (3), whereby the printing medium (3) is transferred onto the substrate (4) by selectively melting or sintering the material for the electrically conductive tracks, wherein the print head (2) does not come into direct contact with the printing medium (3), since at least a foil-shaped carrier material carrying the two-dimensional layer of the printing medium (3) is situated between the print head (2) and the two-dimensional layer of the printing medium (3).

Provided is a process for fabricating a conductive pattern on a three-dimensional (3D) object, involving hydroprinting a 2-dimensional (2D) conductive planar pattern on a 2D sacrificial substrate, and transferring the pattern to the 3D object.

A semifinished product with a sacrificial structure and two component carriers releasably formed on opposing main surfaces of the sacrificial structure. The sacrificial structure includes a central structure and releasing layers on or over both opposing main surfaces of the central structure The central structure includes a dummy core being covered, in particular fully, on or over both main surfaces thereof with a respective one of two spatially separated sections of separate material, in particular separate dielectric material.

A photosensitive film of the present invention includes a carrier film having a first surface whose surface roughness is 0.1 to 0.4 μm, and a photosensitive layer formed on the first surface, in which a haze of the carrier film is 30 to 65%, and a spectral haze at a wavelength of 405 nm of the carrier film, as measured by providing a transparent resin layer in which a difference between a refractive index of the transparent resin layer and a refractive index of the photosensitive layer is within ±0.02 on the first surface, is 0.1 to 9.0%.

A component carrier includes a stack having at least one electrically insulating layer structure and/or at least one electrically conductive layer structure; a heat removing and electrically conductive base structure; a component which is connected to the base structure so as to at least partially protrude from the base structure and so as to be laterally at least partially covered by an electrically insulating material of the stack; and an electrically conductive top structure on or above a top main surface of the component. A method of manufacturing such a component carrier is disclosed.

A method for applying at least one electronic component to a surface is described. The method includes placing a component stencil on a support. At least one electronic component is arranged in a corresponding opening of the component stencil with a top surface of the electronic component on the support. A contact material stencil is positioned on the component stencil such that at least one opening in the contact material stencil is over a corresponding contact region on the bottom surface of the at least one electronic component. A contact material is applied on the at least one contact region of the at least one electronic component within the corresponding opening of the contact material stencil. The contact material stencil is removed from the component stencil. The component stencil is removed from the support. The at least one electronic component is applied to the surface.

A pressure-sensitive adhesive sheet-including wiring circuit board includes a wiring circuit board including a base insulating layer, a conductive layer disposed on a one-side surface in a thickness direction of the base insulating layer, and a cover insulating layer disposed on the one-side surface in the thickness direction of the base insulating layer so as to cover the conductive layer, and a pressure-sensitive adhesive sheet disposed on the surface of either one side or the other side in the thickness direction of the wiring circuit board.