An electronic assembly with phase-change material for thermal performance comprises a substrate and a semiconductor device mounted on the substrate. A sealed first thermal channel comprises a first evaporator section, a first fluid transport section, and a first condenser section. A phase-change material is contained in the sealed first thermal channel. The first evaporator section overlies the semiconductor device. The first fluid transport section extends between the first evaporator section and the first condenser section. The first evaporator section is spaced apart from the first condenser section. The first condenser section is in thermal communication with the heat sink.

Provided is a circuit board supporting structure capable of easily detaching a circuit board on a base. The circuit board supporting structure is configured to support a circuit board on a base, in which the base has a concave portion formed in a placement surface of the circuit board, and a rotational operation member configured to be rotatably accommodated in the concave portion and extend and retract in a direction perpendicular to the placement surface by a rotational operation, in which the circuit board has a through hole formed at a position corresponding to the concave portion, in which the rotational operation member has a reference surface formed approximately in parallel with the placement surface, and an operation portion formed on a rotational axis of the rotational operation member so as to be exposed from the through hole.

In one example, a first tubular member has a first diameter and is configured to attach to a printed circuit board. A second tubular member has a second diameter different from the first diameter and is configured to hold an environmental sensor for collecting data relating to an environment of the printed circuit board. The second tubular member is vertically adjustable relative to the first tubular member.

Embodiments described herein may include apparatuses, systems and/or processes to encapsulate a circuit board to be cooled with a liquid coolant, that includes a first part dimensioned to receive the circuit board coupled with one or more heat sinks; a second part dimensioned to mate with the first part, and with a portion of a side of the circuit board around the one or more heat sinks to create a volume surrounding the circuit board, with a portion of the one or more heat sinks are outside the volume and is to be exposed to the liquid coolant, and a sealer to seal areas where the second part mates with the first part and the portion of the side of the circuit board, to prevent the liquid coolant from entering the volume. Other embodiments may be described and/or claimed.

Embodiments of the present disclosure relate to a fixing device for a double-sided heat sink and an associated heat dissipating system. There is exemplarily provided a fixing device for mounting the double-sided heat sink on a carrier. The fixing device comprises: a first holder including a first cylindrically-shaped rod, wherein the first cylindrically-shaped rod can pass through a first cooling portion of the double-sided heat sink and a mounting hole of the carrier to fix the first cooling portion to a first side of the carrier, and the first cylindrically-shaped rod comprises a through-hole extending along a longitudinal direction; and a second holder including a second cylindrically-shaped rod, wherein the second cylindrically-shaped rod can pass through a mounting hole of a second cooling portion of the double-sided heat sink and the through-hole of the first holder, such that the second holder is coupled with the first holder to fix the second cooling portion to a second side of the carrier opposite to the first side.

A device may include a temperature controlled chamber. The temperature controlled chamber may be coupled to a plurality of strengthening coated capillary tubes. The strengthening coated capillary tubes may support the temperature controlled chamber and provide thermal insulation to the temperature controlled chamber.

An electrical conveyance assembly includes a substrate that may include an electrically insulating material. The electrical conveyance assembly may include a plurality of electrical conductors connected to the substrate via additive manufacturing. The substrate may include an internal lattice structure formed via additive manufacturing. The substrate may include an internal fluid channel.

A circuit board includes: an electrically insulating part and an electrically conductive part; at least one semiconductor chip embedded into the electrically insulating part in a part of the circuit board; and a cooling area above and below the at least one semiconductor chip. The electrically conductive part includes a first outer conductive layer on the first surface, a second outer conductive layer on the second surface, and a first inner conductive layer which is electrically connected to the semiconductor chip. The first inner conductive layer is electrically insulated from the first outer conductive layer and from the second outer conductive layer by the electrically insulating part in the cooling area, or is electrically connected to the first outer conductive layer outside the cooling area.

An electronic system is described that comprises a first board and a first processing unit, wherein the first processing unit comprises a first semiconductor chip arranged on a first surface of the first board; a first cooling unit facing the first surface of the first board and configured to cool the first semiconductor chip; at least one further board and a second processing unit, wherein the second processing unit comprises a further semiconductor chip arranged on a first surface of the at least one further board; and a second cooling unit facing the first surface of the at least one further board and configured to cool the further semiconductor chip. The first board and the at least one further board are spaced apart from each other. The first cooling unit is a passive cooling unit, and the second cooling unit is an active cooling unit.

Embedded cooling systems and methods of forming the same are disclosed. A system may include a PCB stack comprising a first major substrate opposite a second major substrate, a pre-preg layer disposed between the first and second major substrates, a power device stack embedded within the PCB stack and comprising a substrate, a power device coupled to the substrate of the power device stack, and a vapor chamber embedded within at least the pre-preg layer of the PCB stack and the power device stack being coupled to the vapor chamber.