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.

A system includes a power device unit coupled to a substrate. An upper cooling assembly is thermally coupled to an upper side of the substrate. A lower cooling assembly is thermally coupled to a lower side of the substrate. A gate driver unit is coupled to the upper cooling assembly. At least one upper via is formed through the upper cooling electrically coupling the gate driver unit to the power device unit. A capacitor unit is coupled to the lower cooling assembly. At least one lower via formed through the lower cooling assembly electrically coupling the capacitor unit to the power device unit.

A heat exchanger assembly includes a housing having at least one area of heat flux and a fluid circuit arranged within an interior of the housing. The fluid circuit having an inlet manifold, an outlet manifold, and at least one fluid passage connecting the inlet manifold and the outlet manifold. The at least one fluid passage is positioned relative to the housing to perform localized cooling of the housing at the at least one area of heat flux. A cooling medium circulates through the fluid circuit.

A cooling device includes a heat-receiving block, a heat conductor, and first heat pipes. The heat-receiving block has a first main surface to which a heating element is fixed. The heat conductor extends along the first main surface and is fixed to the heat-receiving block. The first heat pipes are arranged in a direction in which the heat conductor extends and are fixed to the heat-receiving block at positions farther from the first main surface than the heat conductor is.

A coolant for cooling an electrical/electronic element by direct immersion cooling, comprising a partially fluorinated ether with the structure (of compound 1) wherein R.sup.1, R.sup.2, R.sup.3, R.sup.4 are independently selected from the group CF.sub.3, alkyl, fluoroalkyl, perfluoroalkyl, haloalkyl perfluorohaloalkyl.

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A cooling system is provided. The cooling system includes a condenser configured to condense a coolant from a vapor state to a liquid state and an evaporator configured to evaporate the coolant from the liquid state to the vapor state. The evaporator defines a reservoir configured to contain a volume of the coolant in the liquid state. The cooling system further includes a vapor channel fluidly coupled to the condenser and the evaporator and configured to convey the coolant in the vapor state from the evaporator to the condenser, a liquid channel coupled to the condenser and the evaporator and configured to convey the coolant in the liquid state from the condenser to the evaporator, and a heat generating component disposed in the reservoir and immersed in the volume of the coolant in the liquid state. The heat generating component is configured to dissipate heat into the coolant.

Thermal structures and, more particularly, improved thermal structures for heat transfer devices and spatial power-combining devices are disclosed. A spatial power-combining device may include a plurality of amplifier assemblies and each amplifier assembly includes a body structure that supports an input antenna structure, an amplifier, and an output antenna structure. One or more heat sinks may be partially or completely embedded within a body structure of such amplifier assemblies to provide effective heat dissipation paths away from amplifiers. Heat sinks may include single-phase or two-phase materials and may include pre-fabricated complex thermal structures. Embedded heat sinks may be provided by progressively forming unitary body structures around heat sinks by additive manufacturing techniques.

The invention relates to an air heat exchanger 1 for cooling a power electronics component 2, comprising: a carrier plate 3 having an accommodating region 4 for accommodating the power electronics component 2; a heat exchanger plate 7 which is coupled to the carrier plate 3, wherein at least one hermetically sealed cavity 10 for accommodating a working medium 13 is formed and delimited by the carrier plate 3 and the heat exchanger plate 7, wherein the cavity 10 comprises an evaporator 11 and a condenser 12, wherein the evaporator 11 is arranged so as to be spaced apart from the condenser 12 in a heat transport direction 14; cooling ribs 15 which are coupled to the heat exchanger plate 7.

The invention relates to a method for joining a power semiconductor component (1.1) to a heat pipe (2), wherein, during joining, the external pressure (p2) acting on the heat pipe (2) is changed proportionally to the internal pressure (p1) of the heat pipe (2), which internal pressure changes under heat during joining. The invention also relates to a device for carrying out the method, a power module, a converter and a vehicle.

A power converter includes: a plurality of semiconductor devices; a heat receiving plate; and a first partition member. The semiconductor devices constitute a power conversion unit. The heat receiving plate includes a first surface supporting the semiconductor devices. The first partition member is fixed to the heat receiving plate and partitions the semiconductor devices.