The power conversion device includes a semiconductor module having a connection terminal, a cooler, a control board, a capacitor module, a cover, a case, and a connection busbar. The semiconductor module, the cooler, the control board, and the capacitor module are arranged in an overlapped manner as seen in the direction perpendicular to the top surface of the cooler. The capacitor module has a capacitor cell, a capacitor case, resin, and a capacitor busbar. The capacitor busbar has an inner extending portion, an opening-side extending portion, and an outer extending portion. The connection busbar extends from the connection terminal of the semiconductor module to an outer surface of the outer extending portion and has a part extending in parallel to the extending direction of the outer extending portion. The connection busbar has a capacitor connection portion at an end thereof on the outer extending portion side.

A central compute unit, configured for a vehicle, a vehicle central compute unit, to a pocket module, to an electronic module, and to a printed circuit board, to a cooling blade, and to a main frame. The main frame for mounting and connecting vehicular components in a vehicle includes a plurality of slots configured to support a plurality of pocket modules. A main frame interface is configured to connect the plurality of pocket modules with a communication network, and to couple the plurality of pocket modules with a cooling circuit.

A cooling device has a flat flow path formed between a first wide surface and a second wide surface, the second wide surface including protrusion portions protruding into the flow path, extending in a flow path width direction, and arranged side by side in a fluid flow direction. The first wide surface has no protrusion portions. The protrusion portions each include a first inclined surface inclined to come close to the first wide surface from upstream to downstream in the fluid flow direction, and a second inclined surface disposed alternately with the first inclined surface in the fluid flow direction and inclined to be distanced from the first wide surface from upstream to downstream in the fluid flow direction. The protrusion portions are formed such that a virtual first circle is inscribed at three points on the first wide surface, the second inclined surface, and the first inclined surface.

A wearable electronic device is disclosed. The device can include a support structure and an electronic component disposed in or on the support structure. A heat exchanger element can be thermally coupled with the electronic component, the heat exchanger element comprising a fluid inlet port and a fluid outlet port. A first conduit can be fluidly connected to the fluid inlet port of the heat exchanger, the first conduit configured to convey, to the heat exchanger, liquid at a first temperature. A second conduit can be fluidly connected to the fluid outlet port of the heat exchanger, the second conduit configured to convey, away from the heat exchanger, liquid at a second temperature different from the first temperature.

A cooling system for a medium voltage switchgear includes a conductor, a fluid conduit, and an insulator, wherein, the conductor extends in a longitudinal axis, wherein, the conductor is configured to carry electrical current in the longitudinal axis direction, wherein a first part of the fluid conduit is located around an outer surface of the conductor and extends around the longitudinal axis, wherein, a second part of the fluid conduit is connected to the first part of the fluid conduit and extends substantially perpendicularly to the longitudinal axis, wherein the insulator is located around the conductor at the position of the fluid conduit and covers the first part of the fluid conduit, and wherein the cooling system is configured such that a fluid can flow into the second part of the fluid conduit and from the second part of the fluid conduit into the first part of the fluid conduit.

A heat dissipation device includes: a rigid tube, including a first cavity; a first capillary structure, at least a portion of the first capillary structure being positioned within the first cavity; a flexible tube, including a second cavity, the flexible tube being more flexible than the rigid tube; and a second capillary structure, at least a portion of the second capillary structure being positioned within the second cavity, wherein the heat dissipation device is deformable via the flexible tube.

The present invention relates to a heat exchanger for cooling an electrical element and a heat exchanger assembly for cooling an electrical element, and more particularly, to a heat exchanger for cooling an electrical element and a heat exchanger assembly for cooling an electrical element into which the electrical element may be easily inserted and in which both surfaces of the electrical element and a tube through which a coolant flows are formed to contact each other to improve cooling performance.

A cooling system includes a diaphragm, at least one conductor layer disposed on the diaphragm, at least one dielectric film layer, and a controller. The controller is programmed to operate the cooling system in a contact mode and in a non-contact mode. In the contact mode, the diaphragm is controlled to oscillate at a first amplitude such that the conductor layer contacts the dielectric film layer. In the non-contact mode, the diaphragm is controlled to oscillate at a second amplitude such that the conductor layer does not contact the dielectric film layer while the diaphragm oscillates.

A composition includes a perfluorinated propenylamine represented by the following general formula (1):

Each occurrence of R.sub.f1 and R.sub.f2 is: (i) independently a linear or branched perfluoroalkyl group having 1-8 carbon atoms and optionally comprises one or more catenated heteroatoms; or (ii) bonded together to form a ring structure having 4-8 carbon atoms and that optionally comprises one or more catenated heteroatoms.

At least 60 wt. % of the perfluorinated propenylamine is in the form of the E isomer, based on the total weight of the perfluorinated propenylamine in the composition.

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A method, apparatus, and system for stopping a flow of a liquid coolant into, and drawing away a residual portion of the liquid, a portion of a cooling system, e.g., for resistance welding electrodes. The disclosed system does not require more than a single actuator, and in one case uses only a single actuator, coupled to both i) one or more liquid shutoff valves and ii) one or more liquid drawback apparatus. The liquid drawback apparatus draws on the liquid at approximately a same time that the one or more liquid shutoff valves shut off the flow of the liquid from the coolant supply. The liquid drawback apparatus includes a non-return check valve, disposed in the fluid passageway and biased against a normal flow of the liquid from the coolant supply.