Solid state lights (SSLs) including a back-to-back solid state emitters (SSEs) and associated methods are disclosed herein. In various embodiments, an SSL can include a carrier substrate having a first surface and a second surface different from the first surface. First and second through substrate interconnects (TSIs) can extend from the first surface of the carrier substrate to the second surface. The SSL can further include a first and a second SSE, each having a front side and a back side opposite the front side. The back side of the first SSE faces the first surface of the carrier substrate and the first SSE is electrically coupled to the first and second TSIs. The back side of the second SSE faces the second surface of the carrier substrate and the second SSE is electrically coupled to the first and second TSIs.

A printed circuit board (PCB) having an engineered thermal path and a method of manufacturing are disclosed herein. In one aspect, the PCB includes complementary cavities formed on opposite sides of the PCB. The complementary cavities are in a thermal communication and/or an electrical communication to form the engineered thermal path and each cavity is filled with a thermally conductive material to provide a thermal pathway for circuits and components of the PCB. The method of manufacturing may further include drilling and/or milling each cavity, panel plating the cavities and filling the cavities with a suitable filling material.

An electronic device includes a top plate having a first surface and a second surface that is positioned at an elevation that is lower than an elevation of the first surface, the second surface extending from a first end part of the top plate to a second end part of the top plate, a bottom plate provided under the top plate, and a circuit board placed between the top plate and the bottom plate and mounted with an electronic component. The top plate has opposing first and second edges and opposing third and fourth edges that are perpendicular to the first and the second edges, the first end part being formed at the first edge and the second end part being formed at the second edge.

A cooling system for a circuit board includes a conforming layer that conforms to the profile of the circuit board, including a base and at least one heat generating component. A cap is connected to the conforming layer and offset from the conforming layer with a gap. A working fluid is flowed through the gap and used to cool the heat generating component. This allows for a low-cost and flexible cooling system for a circuit board without a redesign of a cold plate with each change to the circuit board.

This disclosure relates to a liquid cooling device including a first heat exchanger that has a first inlet and a first outlet, a second heat exchanger that has a second inlet and a second outlet, a heat dissipation component that has a first heat inlet, a second heat inlet, and a heat outlet, and a fluid driving component that has a fluid inlet, a first fluid outlet, and a second fluid outlet. The first heat inlet and the second heat inlet are in fluid communication with the heat outlet. The first heat inlet is in fluid communication with the first outlet. The second heat inlet is in fluid communication with the second outlet. The fluid inlet is in fluid communication with the heat outlet. The first fluid outlet and the second fluid outlet are respectively in fluid communication with the first heat inlet and the second heat inlet.

Various systems and methods for configuring a pluggable computing device are described herein. A pluggable computing device may be configured to be compatible with a pluggable host system using a default communication channel to obtain configuration settings and configure a programmable logic device on the pluggable computing device. The pluggable computing device may perform chain of trust processing on the pluggable host system. The pluggable computing device may be disposed on a compute card, which may include a heat sink in a particular configuration.

In aspects of processor heat dissipation in a stacked PCB configuration, a computing device includes a processor for executable instructions processing during which the processor generates heat. The computing device also includes a main printed circuit board (PCB) in a stacked PCB configuration, and the processor is affixed to the main printed circuit board. The stacked PCB configuration forms an enclosed cavity through which heat dissipation is restricted. The computing device includes a heat spreader having a first end connected to the processor via the main printed circuit board by a conductive material, and a second end connected to a heat sink located external to the stacked PCB configuration. The heat spreader exits the enclosed cavity via an opening in the enclosed cavity between the stacked PCB configuration, and the heat spreader transfers the heat away from the processor to the heat sink.

A electronic device includes: a plurality of substrates each including a substrate main body and a heat generating element, the plurality of substrates being provided side by side in a plate thickness direction; a cooler which is provided between the substrates adjacent to each other, and configured to cool the heat generating element; and a piping which is made of metal, and is connected to the cooler. The piping includes: an inner piping portion which is arranged in an inter-substrate region, and is connected to the cooler; an inner piping extending portion provided so as to extend from the inner piping portion to an outer side of the inter-substrate region; and an outer piping portion which is arranged to be shifted from the inter-substrate region, and is connected to the inner piping extending portion. The outer piping portion includes a movable piping portion that is deformable.

A battery module, a vehicle, and a method of manufacturing a battery module, the battery module including a housing accommodating a plurality of secondary batteries; and a thermoelectric element assembly on the housing and in contact with the plurality of secondary batteries through at least one contact opening in the housing, the thermoelectric element assembly being configured to heat or cool the plurality of secondary batteries.

A carrier substrate (1) for electrical components, in particular metal-ceramic substrate (1) for electrical components, comprising an insulation layer (10), the insulation layer (10) preferably having a material comprising a ceramic or a composite comprising at least one ceramic layer, a component metallization (20) which is formed on a component side (BS) and has a first primary structuring (21), and a cooling part metallization (30) which is formed on a cooling side (KS) opposite the component side (BS) and has a second primary structuring (31), wherein the insulation layer (10), the component metallization (20) and the cooling part metallization (30) are arranged one above the other along a stacking direction (S), and
wherein the first primary structuring (21) and the second primary structuring (31), as viewed in the stacking direction (S), run congruently at least in portions.