A stacked body includes a first resin layer including a thermoplastic first resin as a main material, a pattern including a conductor layer on one principal surface of the first resin layer, and a second resin layer including a thermoplastic second resin as a main material. The first resin layer is softer than the second resin layer. The first resin layer has a lower dielectric constant than the second resin layer. A pattern including the conductor layer is at least partially embedded in the first resin layer, and includes a portion in contact with the first resin layer along a layer direction (X-Y plane) of the first resin layer and a portion in contact with the first resin layer along a stacking direction (X-Z plane) of the first resin layer, the second resin layer, and the pattern including the conductor layer.

A method for inserting preformed solder members into connector pins for use with electrical connectors. The method generally includes a connector pin having an open cavity at one end, into which a preformed solder member can be first inserted and then pressed, rather than melted, in place, such that voids and air spaces within the cavity are substantially eliminated. The method allows for inserting solder members in high quantities, where the preformed solder members are placed in a fixture and the fixture is placed on a shaker table, so that solder members can be inserted into large numbers of connector pins that are pre-installed in connector grommets, largely simultaneously.

A driver mounting apparatus 40 includes a pressing device 50 that collectively presses drivers 21 to be mounted on terminals 23, 24 of bonded substrates 11ab, 11ab each of which is obtained by bonding a CF substrate 11a and an array substrate 11b having terminals 23, 24 with the terminals 23, 24 being uncovered, and substrate support members 41, 41 supporting the bonded substrates 11ab, 11ab, respectively. The pressing device 50 includes a driver-side pressing portion 51 and a substrate-side pressing portion 52. The substrate support members 41, 41 are movable independently from each other to position each of the bonded substrates 11ab, 11ab supported on the substrate support members 41, 41 with respect to the driver-side pressing portion 41.

According to one embodiment, a metal base circuit board includes a metal base substrate, a first circuit pattern, and a first insulating layer between the metal base substrate and the first circuit pattern. The first insulating layer covers a lower surface of the first circuit pattern and at least part of a side surface of the first circuit pattern, the lower surface facing the metal base substrate, the at least part of the side surface being adjacent to the lower surface.

The invention is related to an electrical circuitry assembly as well as a method for manufacturing such an electrical circuitry assembly, wherein the assembly basically but not exclusively comprising of an electrically conductive metal plate and a circuit including a conductive layer and wherein both the metal plate and the circuit shall be electrically connected to each other.

A method for manufacturing a light-emitting module includes a step of providing a bonded board including a board including, on a first surface, a circuit pattern and wiring pads that are continuous with the circuit pattern and each have bottomed holes and light-emitting segments connected on a second surface of the board with an adhesive sheet interposed therebetween and including an array of light-emitting devices; a step of supplying electrically conductive paste inside the bottomed holes and on portions of the surface of the wiring pad around the bottomed holes through openings of a mask; and a step of performing thermal compression to harden the electrically conductive paste such that the thickness of the electrically conductive paste on the portions of the surface of the wiring pad is smaller than the electrically conductive paste at the timing of being disposed through the openings of the mask.

An object of the present disclosure is to provide a component crimping device and a component crimping method that make it possible to improve accuracy of attaching a component onto a substrate by preventing the component from being excessively elongated due to rapid thermal expansion when the component is pressed against the substrate. A lower surface side of a substrate-side terminal part of a substrate held by a substrate holding table is supported by a support, a component placed on a placing table is picked up by a crimping head while heating the component, the component is compressed against a compressing table so as to be elongated, and then the component is pressed against the substrate-side terminal part.

A mounting jig for a semiconductor device includes an insulated circuit board positioning jig having a concave part in which an insulated circuit board is placed, a tubular contact element positioning jig disposed on an upper side of the insulated circuit board and having a plurality of positioning holes at predetermined positions to insert a plurality of tubular contact elements respectively, and a tubular contact element press-down jig having a flat plate and a plurality of projections extending from a lower surface of the flat plate. The plurality of projections includes a first length from the flat plate on a side closer to an outer circumference of the insulated circuit board, and a second length from the flat plate inside the outer circumference of the insulated circuit board. The first length is shorter than the second length.

Embodiments disclosed include a multilayer substrate for semiconductor packaging. The substrate may include a first layer with a first side with an xy-plane and individual locations on the first side have a first side distance below the first side xy-plane, and a second side with a second side xy-plane and individual locations on the second side may have a second side distance below the second side xy-plane; and a second layer with a first side coupled to the second side of the first layer and a second side opposite the first side of the second layer, wherein a thickness of the second layer at the individual locations on the second layer may be comprised of the first side distance plus the second side distance. Other embodiments may be described and/or claimed.

While a substrate is placed on a substrate placement stage provided in a central substrate transfer unit, the substrate is transferred to a component loading operation unit, after operation for loading a component on the substrate has been performed by the component loading operation unit, the central substrate transfer unit is moved to the side of a first component crimping operation unit to thereby transfer the substrate that remains placed on the substrate placement stage to the first component crimping operation unit, and the component is crimped to the substrate by the first component crimping operation unit.