A substrate assembly includes a printed circuit (PC) substrate, first and second microchips, components or substrates mounted on a surface of the PC substrate, and a projection extending in spaced relation to the surface of the PC substrate. In one example, the projection extends between (i) a downward facing surface and/or an edge of a side facing surface proximate the downward facing surface of the first microchip, component or substrate and (ii) an upward facing surface and/or an edge of a side facing surface proximate the upward facing surface of the first microchip, component or substrate. The first and second microchips, components or substrates may be mounted on different levels of the PC substrate surface. In another example, the projection extends between a upward and/or side facing surface of a first microchip, component or substrate and a slot or cavity in a second microchip, component or substrate.

According to various aspects, exemplary embodiments are disclosed of laser weldable brackets for attachment of heat sinks to EMI shields, such as a board level shield, etc. In an exemplary embodiment, an assembly generally includes an electromagnetic interference (EMI) shield, a heat sink, and a bracket laser weldable to the EMI shield for attachment of the heat sink to the EMI shield. In another exemplary embodiment, a method of attaching a heat sink to an EMI generally includes laser welding a bracket to the EMI shield whereby the bracket retains the heat sink in place relative to the EMI shield.

A heat dissipation module is adapted for a circuit board, which has an M.2 bonding hole. The heat dissipation module includes a supporting bracket and a heat dissipation element. The supporting bracket has a first side and a second side opposite to each other, and an accommodating space, which is located between the first side and the second side, and is adapted for installing an SSD interface card. The first side has a first mounting hole and a second mounting hole. The heat dissipation element is combined to the first side through the first mounting hole. When the SSD interface card is installed in the accommodating space, the SSD interface card and the supporting bracket are combined to the M.2 bonding hole through the second mounting hole so that the second side faces the circuit board.

A power converter comprises a chassis and an AC connector, a low-voltage DC connector and a high-voltage DC connector at an exterior surface of the chassis. An AC-DC converter circuit is positioned at least partially within the chassis and is coupled to the AC connector. A first converter circuit is positioned at least partially within the chassis and is coupled to the AC-DC converter circuit and to a high-voltage DC bus. The high-voltage DC bus is connected to the high-voltage DC connector. A second converter circuit is positioned at least partially within the chassis and is coupled to the high-voltage DC bus to a low-voltage DC bus. The low-voltage DC bus is connected to the low-voltage DC connector.

Embodiments include a microelectronic device package structure having an inductor within a portion of a substrate, wherein a surface of the inductor is substantially coplanar with a surface of the substrate. One or more thermal interconnect structures are on the surface of the inductor. A conductive feature is embedded within a board, where a surface of the conductive feature is substantially coplanar with a surface of the board. One or more thermal interconnect structures are on the surface of the conductive feature of the board, where the thermal interconnect structures provide a thermal pathway for cooling for the inductor.

The invention relates to a component carrier for an electronic device, the component carrier comprising at least one heat-releasing component that is embedded within at least one carrier layer of the component carrier, and wherein the at least one embedded heat-releasing component is thermoconductively coupled to a heat spreader layer, characterized in that the heat spreader layer forms at least an outside section of a casing of said electronic device. Also an electronic device that comprises at least one component carrier according to the invention, as well as a method to produce a respective component carrier are indicated.

A semiconductor device includes a semiconductor die having a first side having a first terminal and an opposite second side having at least two second terminals. A lead frame has a first part and a second part. The second part of the lead frame is both electrically and mechanically spaced from the first part. The second side of the die is attached to the lead frame such that the first and second lead frame parts are respectively connected to the at least two second terminals. The first and second lead frame parts include respective first and second extensions that project past a side of the die and provide first and second terminal surfaces that are co-planar with the first terminal on the first side of the die. The device makes use of the terminals on the both sides of the die. The device second side is exposed for thermal performance.

A microwave generator for a microwave device includes a single component carrier for control components and power components, which includes a continuous carrier material. Two power regions and one control region are provided on the component carrier. In the control region, electrically functional components are arranged on both flat sides of the component carrier, while in the power regions, electrically functional components with at least one power switch are arranged only on an upper flat side, heat sinks being arranged on the lower flat side. An RF substrate is provided in regions on the upper flat side of the power region.

A method of manufacturing a wiring board according to one embodiment of the present disclosure includes: providing at least one first conductive member that serves as part of a wiring; covering the at least one first conductive member with an insulating member that has at least one opening; disposing at least one second conductive member on the opening of the insulating member, the second conductive member serving as part of the wiring; electrically joining the at least one first conductive member and the at least one second conductive member to each other at the opening; and cutting a region including the at least one first conductive member, the insulating member, and the at least one second conductive member, to form an element mounting surface.

An illumination assembly includes a polymeric substrate, an electrical circuit including two conductors supported by the polymeric substrate, an LED electrically coupled to the two conductors, and a heat spreader thermally coupled to the LED. The two conductors can be printed on the polymeric substrate, embedded within the polymeric substrate, or lie atop the polymeric substrate. The illumination assembly may be fabricated in three-dimensional form factors.