A laminating apparatus for a provisionally laminated body is provided and is configured to form an end laminated body including one of a first resin film and a second resin film conforming to protruding and recessed portions of a substrate. The laminating apparatus may include first and second laminating mechanisms. The first laminating mechanism may include a first enclosed space forming receiver, a depressurizer, a heater, and a first pressure laminator to form an intermediate laminated body from the provisionally laminated body. The second laminating mechanism may include a second enclosed space forming receiver, and a second pressure laminator to form the end laminated body from the intermediate laminated body.

A packaging structure and a packaging method of an electronic product are disclosed. The packaging structure of an electronic product includes a supporting structure, a flexible board and a covering layer. The supporting structure has a shape. The flexible board is stacked on the supporting structure, and has an electronic device disposed thereon. The covering layer is attached on the stacked supporting structure and flexible board and covering the electronic device. The shapes of the flexible board and the covering layer conform to the shape of the supporting structure, and the flexible board and the electronic device are tightly interposed between the covering layer and the supporting structure. The covering layer includes a thermoforming film and at least a function film stacked on the thermoforming film.

To provide a surface-treated copper foil that can favorably decrease the transmission loss even used in a high frequency circuit board, and has improved acid resistance. A surface-treated copper foil containing a copper foil, and a surface treatment layer containing a roughening treatment layer on at least one surface of the copper foil, wherein the surface treatment layer contains Ni, the surface treatment layer has a content ratio of Ni of 8% by mass or less (excluding 0% by mass), and an outermost surface of the surface treatment layer has a ten-point average roughness Rz of 1.4 m or less.

Systems and methods describe herein provide a solution to the technical problem of creating a wearable electronic devices. In particular, these systems and methods enable electrical and mechanical attachment of stretchable or flexible electronics to fabric. A stretchable or flexible electronic platform is bonded to fabric using a double-sided fabric adhesive, and conductive adhesive is used to join pads on the electronic platform to corresponding electrical leads on the fabric. An additional waterproofing material may be used over and beneath the electronic platform to provide a water-resistant or waterproof device. This stretchable or flexible electronic platform integration process allows the platform to bend and move with the fabric while protecting the conductive connections. By using flexible and stretchable conductive leads and adhesives, the platform is more flexible and stretchable than traditional rigid electronics enclosures.

A packaging structure and a packaging method of an electronic product are disclosed. The packaging structure of an electronic product includes a supporting structure, a flexible board and a covering layer. The supporting structure has a shape. The flexible board is stacked on the supporting structure, and has an electronic device disposed thereon. The covering layer is attached on the stacked supporting structure and flexible board and covering the electronic device. The shapes of the flexible board and the covering layer conform to the shape of the supporting structure, and the flexible board and the electronic device are tightly interposed between the covering layer and the supporting structure. The covering layer includes a thermoforming film and at least a function film stacked on the thermoforming film.

According to various aspects, exemplary embodiments are disclosed of stretchable and/or flexible electromagnetic interference (EMI) shields. In an exemplary embodiment, a shield generally includes a stretchable and/or flexible shielding layer including a first side and a second side. One or more adhesion and/or dielectric layers are along at least the first side and/or the second side of the stretchable and/or flexible shielding layer.

A circuit board device of the embodiment includes: a mount board having an electronic component and a printed circuit board having at least one surface where the electronic component is mounted; a heat path arranged to a position facing the mount surface of the mount board, a sheet arranged on the mount surface, and a resin portion arranged between the sheet and the heat path. A cavity surrounded by the sheet and the mount surface is formed in a step portion between the electronic component and the printed circuit board.

An electronic component-containing module includes a board, electronic components, and a sealing resin and includes a space provided between the board and at least one of the electronic components. The dryness factor of the sealing resin is about 60% or more where, after the electronic component-containing module is moisturized, the electronic component-containing module is heated to the re-melting temperature of a brazing filler metal.

According to one embodiment, a laminated film includes a first adhesive layer, a first insulating layer which faces the first adhesive layer, a first metal layer which is located between the first adhesive layer and the first insulating layer, and a first porous layer which is located between the first adhesive layer and the first insulating layer and faces the first metal layer.

A shielding film comprises multiple layers including one or more of a structured adhesive layer, an electrically conductive layer, an electrically insulative thermally conductive layer, and an electrically conductive adhesive layer. The electrically conductive shielding layer extends laterally beyond the structured adhesive layer. The electrically insulative thermally conductive layer is disposed between the electrically conductive shielding layer and the structured adhesive layer and is coextensive with the structured adhesive layer. The electrically conductive adhesive layer is disposed between the electrically conductive shielding layer and the thermally conductive layer and is coextensive with the electrically conductive shielding layer. When the multilayer shielding film is placed on an electronic device mounted on a circuit board and under application of one or more of heat, vacuum, and pressure, the multilayer shielding film conforms to the electronic device and the electrically conductive adhesive layer adheres to the circuit board providing a seal between the multilayer shielding film and the circuit board.