A method for manufacturing a component carrier includes i) providing a metal layer, in particular a copper layer; ii) forming a film on the metal layer; iii) patterning the film in order to expose a part of the metal layer; iv) carrying out a first etch, thereby thinning the film and removing a further part of the exposed metal layer; and thereafter v) carrying out a second etch, thereby forming at least one metal trace that is spatially separated from the metal layer. A component carrier made by the method is further described.

Embodiments of the invention include LED lighting systems and methods. For example, in some embodiments, an LED lighting system is included. The LED lighting system can include a flexible layered circuit structure that can include a top thermally conductive layer, a middle electrically insulating layer, a bottom thermally conductive layer, and a plurality of light emitting diodes mounted on the top layer. The LED lighting system can further include a housing substrate and a mounting structure. The mounting structure can be configured to suspend the layered circuit structure above the housing substrate with an air gap disposed in between the bottom thermally conductive layer of the flexible layered circuit structure and the housing substrate. The distance between the layered circuit structure and the support layer can be at least about 0.5 mm. Other embodiments are also included herein.

A manufacturing method of tape includes the steps of providing a tape including substrate units, providing a die device and a cutting and/or pressing process. Each of the substrate units includes a carrier, a circuit layer, an adhesive and a heat spreader, the heat spreader is attached onto the carrier by the adhesive. In the cutting and/or pressing process, the die device is provided to press the tape to generate separation protrusions on the heat spreader and allow the separation protrusions to protrude from a heat dissipation surface of the heat spreader. When rolling the tape, the separation protrusions can separate the stacked substrate units to prevent the adhesive from being squeezed out to contaminate the tape.

Provided is a method for producing a wiring circuit board having excellent transportability. The method for producing a wiring circuit board includes a first step to a third step. In the first step, an assembly sheet is overlapped with a supporting sheet in a thickness direction. The assembly sheet includes a plurality of wiring circuit boards and a supporting portion supporting the plurality of wiring circuit boards. The supporting portion supports the assembly sheet. In the second step, the plurality of wiring circuit boards are separated from the supporting portion by cutting. In the third step, the assembly sheet including the plurality of wiring circuit boards separated from the supporting portion is conveyed, while being supported by the supporting sheet.

Methods include receiving at least one electronic device including a sensor or an emitter, placing a cover over the sensor or emitter, placing the electronic device, including the cover, into a transfer mold system, encapsulating the electronic device with charge material, and removing a portion of the encapsulating charge material and the cover to expose the sensor or emitter to the environment.

A method for producing a wiring circuit board includes a first step of preparing a wiring circuit board assembly sheet including a support sheet, a plurality of wiring circuit boards supported by the support sheet, and a joint connecting the support sheet to the plurality of wiring circuit boards, having flat-shaped one surface and the other surface facing one surface at spaced intervals thereto in a thickness direction, and having a thin portion in which the other surface is recessed toward one surface and a second step of forming a burr portion protruding toward the other side in the thickness direction and cutting the thin portion.

Disclosed is a packaging solution, such as a lead frame for circuit board packaging, a packaged integrated circuit board, a power chip, and a circuit board packaging method. The lead frame includes a plurality of frame units disposed in parallel in a first direction. The frame unit includes a hollow bezel, and a plurality of pins and connecting ribs that are disposed in the bezel. Each pin includes a first pin part and a second pin part that extend in a second direction and are integrally formed. The first pin part is disposed in the bezel, the first pin part is configured to electrically connect to a circuit board, and the second pin part is connected and fastened to the bezel. The second direction is perpendicular to the first direction. The connecting ribs are connected among the plurality of pins and the bezel.

Disclosed is an electronic card, in the form of a flexible smart card provided with a flexible circuit, that includes a bottom face receiving electronic components and a top face provided with contact tabs intended to be connected to conductive tracks of a garment textile. The flexible circuit being covered on its bottom face with at least one bottom layer of bonding adhesive, first polymer layers provided with cutouts for receiving components and second polymer layers for encapsulating the components, and covered on its top face with a top layer of bonding adhesive and at least one top layer forming an outer face of the card made from polymer material provided with cutouts for accessing the contact tabs, in which at least some of the contact tabs are produced on the rim of the card and provided with an end part on the edge of the card.

A flexible circuit comprises a laminated substrate, a layer of a protective coating, and first and second components. The laminated substrate comprises a support layer and a conductive layer arranged on the support layer. The conductive layer includes conductive traces. Edges of the conductive traces taper outwardly and towards the support layer. The layer of the protective coating is deposited on the conductive traces. The first component is soldered at a first connection point on one of the conductive traces. The soldering sublimates the protective coating. The second component is connected to the conductive layer at a second connection point. The second connection point is free of the protective coating.

An electronic device module may include: a board; a ground electrode disposed on a first surface of the board; a sealing portion disposed on the first surface of the board; electronic devices mounted on the first surface of the board such that at least one of the electronic devices is embedded in the sealing portion; a first shielding wall connected to the ground electrode and disposed along a side surface of the sealing portion; and a shielding layer formed of a conductive material and disposed along a surface formed by the sealing portion and the first shielding wall.