In a processor fastening structure, when a compression spring (23) is compressed by shortening a distance between the other end of a screw (24) and a heat sink base (22), the compression spring (23) provides elastic force for both the screw (24) and the heat sink base (22). In addition, because the screw (24) passes through the compression spring (23) to connect to a fastening assembly (21), the elastic force of the compression spring (23) is converted into pressure from the heat sink base (22) to a CPU.

An electrical connector assembly for connecting the CPU and the printed circuit board, includes an electrical connector and a back plate respectively mounted upon two opposite surfaces of the printed circuit board. A fastening seat partially surrounds the connector for securing a heat sink which is downwardly seated upon the CPU for heat dissipation. The back plate forms a plurality of securing studs extending through the fastening seat. The heat sink further includes a plurality of tubular securing nuts respectively surrounded by the corresponding coil springs and secured to the corresponding securing studs in an adjustable manner so as to impose the downward force upon the heat sink to urge the heat sink to abut downwardly against the CPU for heat dissipation of the CPU.

An electronic control unit includes: a substrate (10); a heat generating component (20) provided on one surface (11) of the substrate and generates heat during operation; a heat conducting component (40) formed of a material having a heat conductivity equal to or higher than a predetermined value and provided on the one surface of the substrate such that at least a part of the heat conducting component is located in a range (R1) of a predetermined distance (L) from the heat generating component; a controller (60) provided on the substrate and controlling the operation of the heat generating component to control the object to be controlled; and a radiator (70) provided adjacent to the one surface of the substrate to radiate heat from the heat generating component and the heat conducting component. A distance (d1, d3) between the heat generating component and the radiator is equal to or shorter than a distance (d2, d4) between the heat conducting component and the radiator.

An integrated circuit package comprising an integral structural member embedded within dielectric material and at least partially surrounding a keep-out zone of a co-planar package metallization layer. The integral structural member may increase stiffness of the package without increasing the package z-height. The structural member may comprise a plurality of intersecting elements. Individual structural elements may comprise conductive vias that are non-orthogonal to a plane of the package. An angle of intersection and thickness of the structural elements may be varied to impart more or less local or global rigidity to a package according to a particular package application. Intersecting openings may be patterned in a mask material by exposing a photosensitive material through a half-penta prism. Structural material may be plated or otherwise deposited into the intersecting openings.

One example heat sink includes a heat dissipation substrate, a connector, and a fastener. The heat dissipation substrate is configured to dissipate heat for a packaged chip located on a circuit board, and the heat dissipation substrate is located on a surface that is of the packaged chip and that is opposite to the circuit board. A first heat dissipation substrate and a second heat dissipation substrate of the heat dissipation substrate each have a heat conduction surface that conducts heat with a chip in the packaged chip. Different heat conduction surfaces correspond to different chips.

Reliability of a semiconductor module is improved. In a resin mold step of assembly of a semiconductor module, an IGBT chip, a diode chip, a control chip, a part of each of chip mounting portions are resin molded so that a back surface of each of the chip mounting portions is exposed from a back surface of a sealing body. After the resin molding, an insulating layer is bonded to the back surface of the sealing body so as to cover each back surface (exposed portion) of the chip mounting portions, and then, a TIM layer is bonded to an insulating layer. Here, a region of the TIM layer in a plan view is included in a region of the insulating layer.

Embodiments disclosed herein include electronic packages for optical to electrical switching. In an embodiment, an electronic package comprises a first package substrate and a second package substrate attached to the first package substrate. In an embodiment, a die is attached to the second package substrate. In an embodiment, a plurality of photonics engines are attached to a first surface and a second surface of the first package substrate. In an embodiment, the plurality of photonics engines are communicatively coupled to the die through the first package substrate and the second package substrate.

A semiconductor device includes: a first chip to restrict current flow in a first direction through a current path; a second chip to restrict the current flow in a second direction opposite to the first direction, through the current path; a wiring having one end connected to the first chip and the other end connected to the second chip, and provided as a part of the current path by relaying the first chip and the second chip; a lead frame having a first lead arranged and fixed with the first chip and a second lead is arranged and fixed with the second chip; and molding resin sealing the first chip, the second chip, the wiring and the lead frame. The wiring is a shunt resistor having a resistive body. The lead frame further has a sense terminal to detect a voltage drop across the resistive body.

A semiconductor device including an insulated circuit board on which a semiconductor chip is mounted, and a housing implemented by a plurality of side-walls including at least a first pair of facing side-walls, each of the facing side-walls having joint edges configured to be jointed with the insulated circuit board, and each of the joint edges has an arc-shape such that a center in an extending direction of the joint edge protrudes toward the insulated circuit board more than both ends of the extending direction of the joint edge.

A device for cooling a plurality of electrical components, each having a component cooling surface to be cooled, includes a first heat sink, a second heat sink, and a plurality of fasteners. The first heat sink has a first heat-sink cooling surface, and the second heat sink has a second heat-sink cooling surface. The first and second heat-sink cooling surfaces are positioned in a planar arrangement such that the first and second heat-sink cooling surfaces face each other. The first heat-sink cooling surface is configured to receive a first sub-set of the component cooling surfaces of the plurality of electrical components, and the second heat-sink cooling surface is configured to receive a second sub-set of the component cooling surfaces. The fasteners are configured to fasten the first and second heat-sink cooling surfaces to the corresponding component cooling surfaces of the plurality of electrical components to be applied.