A modular deformable electronics platform is attachable to a deformable surface, such as skin. The platform is tolerant to surface deformation and motion, can flex in and out of a plane of the platform without hindering operability of electrical components included on the platform, and is formed via arrangement of discrete flexible tiles, with corners of adjacent tiles connected by a flexible connection material so that individual tiles can translate and rotate relative to each other. Interconnects disposed on bases of separate tiles electrically connect adjacent tiles via their connected corners, and electrically connect components disposed on different tiles. Each pair of adjacent corner connections defines an axis about which at least a portion of the platform can flex without deformation and without hindering connections between tiles. The flexible material and/or bases of the tiles can include Parylene.

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.

An intermediate connection layer interposed between a wiring substrate and an electronic part includes a rigid substrate and a flexible substrate. A plurality of conductor portions are formed on opposed principal surfaces of the respective flexible and rigid substrates. The rigid substrate is provided with an opening, and a fuse portion on the flexible substrate faces the opening. The flexible substrate and the rigid substrate are bonded together with solders. The respective rigid and flexible substrates are separately made, solder pastes are applied to the rigid substrate, both substrates are overlaid on each other, and the solder pastes are heated and solidified to make the intermediate connection layer.

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.

Peristaltic pump comprising a housing (100), containing an electric motor (130) and a reduction gear (120, 122, 124, 126) configured to be driven by the electric motor (130), and a head (200) configured to be removably coupled to the housing (100), the head (200) housing a tube comprising two accessible ends and a rotor provided with two or more squeezing elements configured to squeeze the tube, the rotor being provided with a hub configured to be mechanically connected to the reduction gear when the head (200) is coupled to the housing (100), wherein the housing (100) further houses one or more alignment plates (140, 150) for aligning the reduction gear (120, 122, 124, 126), said one or more alignment plates (140, 150) being coupled to the housing (100) through snap-fit connection means.

A method of producing electronic components each including a substrate-type terminal and a device connected to the substrate-type terminal including a substrate body with first and second principal surfaces opposite to each other and an electrode configured to be connected to the device on the first principal surface, wherein the device is disposed on the first principal surface, includes forming grooves in a substrate from one of the first and second principal surfaces of the substrate such that the substrate is divided into the substrate-type terminals, the grooves each having a depth less than a thickness of the substrate, cutting the substrate from another principal surface opposite to the principal surface of the substrate body such that the grooves penetrate through the substrate in a thickness direction thereof, and mounting the device on each of the first principal surfaces.

To improve, in an encapsulated circuit module having a metal shield layer covering a surface of a resin layer containing filler, a shielding property of the shield layer against electromagnetic waves.

The encapsulated circuit module has a substrate 100 on which electronic components are mounted, covered with a first resin 400. A surface of the first resin 400 is covered with a shield layer 600 including a first metal covering layer 610 made of copper or iron and a second metal covering layer 620 made of nickel. Each of the first metal covering layer 610 and the second metal covering layer 620 is thicker than 5 μm.

To provide a method of manufacturing power module substrate board at high productivity and a ceramic-copper bonded body in which warps are reduced. In a bonded body-forming step, a circuit layer-forming copper layer consisting of a plurality of first copper layers is formed by arranging and bonding a plurality of first copper boards on a first surface of a ceramic board, and a metal layer-forming copper layer consisting of a second copper layer with a smaller arrangement number than that of the first copper layers is formed by bonding a second copper board having a larger planar area than that of the first copper board and a smaller thickness than that of the first copper board so as to cover at least two of adjacent substrate board-forming areas on a second surface of the ceramic board among the substrate board-forming areas partitioned by the dividing groove.

Techniques are disclosed for forming a package substrate with integrated stiffener. A panel of package substrates are provided. An adhesion layer is then formed on each package substrate of the panel of package substrates. A panel of stiffeners are then attached to the panel of package substrates by the adhesion layer, each stiffener corresponding to a respective package substrate. The panel of package substrates is then singulated into individual package substrates with integrated stiffeners. The stiffeners on the singulated package substrates include tabs that extend to the edges of the package substrates.

A multi-piece wiring substrate includes a matrix substrate including first and second insulating layers, and interconnection substrate regions arranged in a matrix. The matrix substrate includes dividing grooves opposing each other and disposed along boundaries between the interconnection substrate regions, and through-holes penetrating the matrix substrate in a thickness direction at positions where the dividing grooves are disposed. The inner surface conductor gradually decreases in thickness from a thick portion in a middle of the inner surface conductor, to thin portions disposed on a side of a boundary between the first and second insulating layers and on a first main surface side, and includes inclination portions each of which gradually increases in thickness from a boundary between corresponding one of the dividing grooves and the inner surface conductor to an inner surface of the inner surface conductor, in vertical sectional view.