An electronics module (100), especially a power electronics module, comprising a metal-ceramic substrate (1) serving as a carrier and having a ceramic element (10) and a primary component metallization (21), an insulation layer (40) directly or indirectly connected to the primary component metallization (21), and a secondary component metallization (22) which is connected to the side of the insulation layer (40) facing away from the metal-ceramic substrate (1) and is especially isolated from the primary component metallization (21) using the insulation layer (40), wherein the ceramic element (10) has a first size (L1, D1) and the insulation layer (40) has a second size (L2, D2) and a ratio of the second size (L2, D2) to the first size (L1, D1) has a value smaller than 0.8, to form an island-like insulation layer (40) on the primary component metallization (21).

Thermal management for modular electronic devices is provided. In one embodiment, a modular electronic device comprises: a primary electronics assembly comprising a least one module bay configured to receive a pluggable electronics module, wherein the pluggable electronics module comprises at least one heat conduction riser that protrudes from the pluggable electronics module; a heat management mechanism coupled to the primary electronics assembly, wherein the heat management mechanism includes at least one floating heat sink thermally coupled to the heat conduction riser of the pluggable electronic module by a heat pipe that defines a direct thermal conductive heat path between the pluggable electronics module and the floating heat sink. The heat pipe is mounted to the primary electronics assembly by a spring loaded floating heat pipe interface that applies a clamping force against the heat pipe, and maintains contact between the interface and the heat conduction riser.

Particular embodiments described herein provide for an electronic device can include a support structure, a radiation source on the support structure, and a radiation shield around the radiation source. The radiation shield includes a wall secured to the support structure, a vacuum bag on the wall, where the vacuum bag has an inside air pressure less than an air pressure outside the vacuum bag, and a lid. The air pressure inside the vacuum bag is less than the atmospheric pressure outside the vacuum bag. When the vacuum is created in the vacuum bag, the vacuum bag deforms and compresses to help provide a vacuum-based mechanical loading that helps to create an applied load on the one or more radiation sources by the lid.

A copper-ceramic bonded body includes a copper member made of copper or a copper alloy, and a ceramic member made of silicon nitride, the copper member and the ceramic member being bonded to each other, in which a maximum length of a Mg—N compound phase which is present at a bonded interface between the copper member and the ceramic member is less than 100 nm, and in a unit length along the bonded interface, the number density of the Mg—N compound phase in a range of a length of 10 nm or more and less than 100 nm is less than 8 pieces/μm.

A circuit board according to an embodiment includes an insulating portion; and a pattern portion disposed on the insulating portion, wherein the insulating portion includes: a first insulating region, and a second insulating region disposed outside the first insulating region and spaced apart from the first insulating region with a separation region therebetween; wherein the pattern portion includes: a first pattern portion for signal transmission; and a second pattern portion including a dummy pattern separated from the first pattern portion, wherein the first pattern portion includes: a first terminal portion disposed on the first insulating region; a second terminal portion disposed on the second insulating region; and a connection portion disposed on the separation region and connecting between the first terminal portion and the second terminal portion, wherein the second pattern portion includes: a second-first pattern portion disposed on the first insulating region; and a second-second pattern portion disposed on the second insulating region and separated from the second-first pattern portion.

An apparatus is described. The apparatus includes a DIMM cooling assembly. The DIMM cooling assembly includes first and second heat spreaders to be respectively disposed on first and second sides of the DIMM's circuit board. The first and second sides having respective memory chips. The DIMM cooling assembly includes a heat dissipative structure. The DIMM's circuit board is to be disposed between the heat dissipative structure and a printed circuit board that the DIMM is to be plugged into. The DIMM cooling assembly includes fixturing elements to apply compressive forces toward the respective side edges of the DIMM's circuit board to the heat spreaders.

A multiple layer printed circuit board including a plurality of layers, vertical interconnect accesses (VIAs), and a vertical interconnect access (VIA) bridge. The layers may include signal layers, prepreg substrate layers disposed between the signal layers, ground plane layers, wherein each of the ground plane layers abuts one of the prepreg substrate layers, inner signal layers, wherein each of the inner signal layers abuts one of the prepreg substrate layers, and a core substrate layer disposed between the signal layers, wherein two of the inner signal layers abut opposed sides of the core substrate layer. The VIAs extend through at least some of the layers, wherein each of the VIAs is formed by aligned apertures through adjoining ones of the prepreg substrate layers, ground plane layers, and inner signal layers. The VIA bridge is coupled to the VIAs to convey heat to a heat sink.

A surface mountable laser driver circuit package is configured to mount on a host printed circuit board (PCB). A surface mount circuit package includes a lead-frame. A plurality of laser driver circuit components is mounted on and in electrical communication with the lead-frame of the surface mount circuit package. A dielectric layer is located between the lead-frame and the host PCB and includes portals through the dielectric layer each arranged to accommodate an electrical connection between the lead-frame and the host PCB. The lead-frame and the dielectric layer are arranged such that a first lead-frame portion and a first dielectric layer portal align with a first end of a host PCB trace configured to provide a current return path for the surface mount laser driver, and a second lead-frame portion and a second dielectric layer portal align with a second end of the host PCB trace.

A heat dissipation device includes a heat conductor. The heat conductor includes a heat dissipation side and a heat absorption side opposite to each other. The heat absorption side is formed by at least two contact planes. The at least two contact planes are arranged in parallel to each other, and a height difference exists between the at least two contact planes.

A lighting element is disclosed that provides a projection of light forming a substantially uniform bright light on a surface a known distance from the lighting element. The lighting elements includes a dome lens that is removably positioned on a light source, such that the light source is retained at a location within a focal length of a projection lens and at or within a focal length of the dome lens. The dome lens magnifies the light outputted by the light source, such that the projected light is brighter than the light generated by the light source.