Abstract: The power conversion apparatus includes electronic components constituting a power conversion circuit, a cooler for cooling at least some of the electronic components, and a case housing the electronic components and the cooler. The at least some of the electronic components and the cooler are fixed to and integrated in a frame as an internal unit . The internal unit including therein the semiconductor modules also includes a control circuit board fitted to board fixing sections formed in the frame so as to project from the frame in the height direction perpendicular to the plane of the frame. Each of the board fixing sections has a board abutment surface at a position closer to the frame than the tips of control terminals of the semiconductor modules formed so as to project in the height direction.

Abstract: A power conversion apparatus includes electronic components configuring a power conversion circuit, a cooler for cooling at least part of the electronic components, and a case housing the electronic components and the cooler. The at least part of the electronic components and the cooler are fixed to and integrated in a frame as an internal unit. The internal unit is fixed within the case through the frame. The frame has such a shape that the at least part of the electronic components is surrounded by the frame from four sides.

Abstract: A semiconductor module socket apparatus including a socket main body in which a socket groove corresponding to a semiconductor module is formed; a socket pin mounted in the socket groove of the socket main body so as to be electrically connected to a module pin of the semiconductor module; and a heat radiating member mounted in the socket main body so as to externally radiate heat that is generated in the semiconductor module and then is delivered from the socket groove and the socket pin. According to the semiconductor module socket apparatus, it is possible to prevent the heat generated in the semiconductor module from being delivered to the main board, to increase the heat radiation efficiency, to significantly save an installation space, to reduce the installation costs, and to realize no-noise and no-vibration of the semiconductor module socket apparatus.

Abstract: Power inverters include a frame and a power module. The frame has a sidewall including an opening and defining a fluid passageway. The power module is coupled to the frame over the opening and includes a substrate, die, and an encasement. The substrate includes a first side, a second side, a center, an outer periphery, and an outer edge, and the first side of the substrate comprises a first outer layer including a metal material. The die are positioned in the substrate center and are coupled to the substrate first side. The encasement is molded over the outer periphery on the substrate first side, the substrate second side, and the substrate outer edge and around the die. The encasement, coupled to the substrate, forms a seal with the metal material. The second side of the substrate is positioned to directly contact a fluid flowing through the fluid passageway.

Abstract: The object is to provide a power converter which is capable of minimizing an extent to which the power converter components other than the semiconductor module are thermally affected by the heat originating from the semiconductor module. A casing houses: semiconductor modules 20, 30 constituting a main circuit for power conversion; a capacitor 50 electrically connected to the main circuit; drive circuits 70, 71 that provide main circuit with a drive signal used in power conversion operation; a control circuit 74 that provides the drive circuit with a control signal used to prompt the drive circuit to provide the drive signal. Within the casing, a cooling chamber including a coolant passage 28 is formed, and a chamber wall of the cooling chamber is formed with a thermally conductive material.

Abstract: A power source apparatus includes a power source module which is formed of a plurality of power source elements, a case which houses the power source module and a cooling liquid, a fan which is placed in the case in a state in which the fan is immersed in the cooling liquid together with the power source module, the fan forming a laminar flow of the cooling liquid, the laminar flow having a width at least substantially the same as a length of the power source element in a length direction of the power source element.

Abstract: The object is to provide a power converter which is capable of minimizing an extent to which the power converter components other than the semiconductor module are thermally affected by the heat originating from the semiconductor module. A casing houses: semiconductor modules 20, 30 constituting a main circuit for power conversion; a capacitor 50 electrically connected to the main circuit; drive circuits 70, 71 that provide the main circuit with a drive signal used in power conversion operation; a control circuit 74 that provides the drive circuit with a control signal used to prompt the drive circuit to provide the drive signal. Within the casing, a cooling chamber including a coolant passage 28 is formed, and a chamber wall of the cooling chamber is formed with a thermally conductive material. At least the semiconductor modules 20, 30 are housed inside the cooling chamber, and at least the capacitor 50 and the control circuit 74 are disposed outside the cooling chamber.

Abstract: A power conversion apparatus includes a power module, four corners of which are fastened to a cooling jacket from its front surface by a front surface side fastening apparatus that includes nuts which are screwed with bolts projecting from the rear face of the cooling jacket to fasten the power module. An AC terminal of the power module, a DC positive electrode terminal connection portion, and a DC negative electrode terminal are arranged on the top surface of the cooling jacket facing the bolts.

Abstract: Systems and apparatus are provided for power electronics substrates adapted for direct substrate cooling. A power electronics substrate comprises a first surface configured to have electrical circuitry disposed thereon, a second surface, and a plurality of physical features on the second surface. The physical features are configured to promote a turbulent boundary layer in a coolant impinged upon the second surface.

Abstract: A high voltage bushing including an elongated electric conductor, a tubular insulator surrounding the conductor, and cooling mechanism for cooling the conductor. The cooling mechanism includes at least one cooling element extending along a fraction of the length of the conductor and in thermal connection with the conductor.

Abstract: A PCB can include an insulating member, a cooling member, and a circuit pattern. The cooling member can be built into the insulating member. The cooling member can have a cooling passageway through which a cooling fluid can flow. The circuit pattern can be formed on the insulating member. Thus, high heat in the circuit pattern can be rapidly dissipated by the cooling fluid flowing through the cooling passageway.

Abstract: A housing comprising a liquid-tight electric bushing is provided. The housing comprises an opening and a printed circuit board comprising at least first and second layers. The first layer is a top side of the printed circuit board and spans the opening. A first contact element is disposed on the top side and in a blind bore through the first layer that extends to the second layer. The second layer is a conductor track in the interior of the printed circuit board.

Abstract: A power inverter comprises at least a box-shaped housing; and a power module, a smoothing capacitor, a base plate made of a flat plate, and a rotating electric machine control circuit board arranged in order in the housing. The base plate is arranged with the fringes fixed to the inner wall surfaces of the housing, and the smoothing capacitor and rotating electric machine control circuit board are fixed.

Abstract: Systems and methods for controlling the temperature of an electrical device is described. The system includes a heat sink system in conjunction with a thermoelectric assembly. The systems and methods are particularly suitable in NEMA-4 electrical enclosures used in electrical submersible pump applications.

Abstract: A semiconductor device of the present invention includes a wiring substrate, a plurality of semiconductor chips mounted on the wiring substrate, and a radiation plate arranged over a plurality of semiconductor chips, and having a cooling passage to flow water in a horizontal direction to the wiring substrate. A plurality of semiconductor chips are arranged along the cooling passage, and out of the plurality of semiconductor chips, the semiconductor chip arranged on an inflow side of the cooling passage, has a smaller amount of heat generation than the semiconductor chip arranged on an outflow side of the cooling passage. For example, a memory chip is arranged on the inflow side of the cooling passage, and a logic chip is arranged on the outflow side of the cooling passage.

Abstract: The invention relates to a circuit board unit and a method for production thereof. The circuit board unit comprises a circuit board topmost laminate with conductive tracks on the upper side for mounting surface-mountable devices. The circuit board topmost laminate features a thickness dimensioned such that the anticipated heat dissipated by the surface-mountable devices is transported from the upper side to the underside of the circuit board laminate to good effect. The circuit board unit further comprises an electrically insulating laminate arranged under the circuit board topmost laminate, inserts made of a material with good heat conductivity and electrical insulation embedded in the electrically insulating laminate at sites below surface-mountable devices with high heat dissipation, and a cooling plate arranged below the electrically insulating laminate and the inserts.

Abstract: The invention provides an integrated circuit packaging and method of making the same. The integrated circuit packaging includes a substrate, a semiconductor die, a heat-dissipating module, and a protection layer. The substrate has an inner circuit formed on a first surface, and an outer circuit formed on a second surface and electrically connected to the inner circuit. The semiconductor die is mounted on the first surface of the substrate such that the plurality of bond pads contact the inner circuit. The heat-dissipating module includes a heat-conducting device, and the heat-conducting device, via a flat end surface thereof, contacts and bonds with a back surface of the semiconductor die. The protection layer contacts a portion of the first surface of the substrate and a portion of the heat-conducting device, such that the semiconductor die is encapsulated therebetween.

Abstract: An air conditioning system provides air to an enclosure associated with a satellite antenna that houses an amplifier or other electronic component. The air conditioning system supplies conditioned air to the bottom of the enclosure and receives return air from the top of the enclosure for improved airflow. Various implementations may also provide redundancy through the use of common supply and return plenums, or other features. In some embodiments, the air conditioning system may be conveniently retrofit onto existing satellite antenna installations to provide improved efficiency and redundancy.

Abstract: A self-contained cooling system for a phased array antenna includes a cooling structure, a heat exchanger, and a pump for circulating a fluid coolant around a coolant loop. The cooling system receives power from a remote power source. The cooling structure includes a plurality of coolant inlet pipes, a plurality of coolant outlet pipes, and a plurality of cooling platforms. Each of the cooling platforms has a coolant channel that begins at one of the plurality of coolant inlet pipes, terminates at one of the plurality of coolant outlet pipes, and provides a flow path for a fluid coolant. The cooling structure further includes at least one base plate releasably mounted to at least one of the plurality of cooling platforms. One or more antenna elements associated with the phased array antenna are mounted on the base plate releasably mounted to at least one of the plurality of cooling platforms.

Abstract: According to one embodiment of the disclosure, an integrated antenna structure comprises a plurality of radiating elements, cooling channels embedded directly within each of the plurality of radiating elements, a fluid inlet, and a fluid outlet. Each of the plurality of radiating elements receive or transmit electromagnetic energy. The cooling channels are formed by an internal surface of the radiating elements. The fluid inlet and the fluid outlet are in communication with each of the cooling channels. Each of the cooling channels provides a heat exchanging function by receiving at least a portion of a fluid coolant from the fluid inlet, transferring a least a portion of the thermal energy from the respective radiating element to the received portion of the fluid coolant, and dispensing of at least a portion of the received fluid coolant out of the cooling channel to the fluid outlet.

Abstract: A blade server including a cooling structure to be loaded with a CPU of high performance is provided. In order to enhance draining performance of a condensed working fluid which stays between fins, a vapor condensing pipe is used, in which grooves are formed in a direction substantially parallel direction with a pipe axis direction on the above described pipe inner surface, a section of a row of the above described fins is exposed on a side surface of the above described groove, the above described groove is disposed at a lower side in the vertical direction from the center line in the pipe axis direction of the vapor condensing pipe when the above described groove is installed in the above described vapor condensing pipe, and a wick with a wire space smaller than the fin space of the above described fin row is filled inside the above described groove.

Abstract: The present invention relates to an integrated-circuit device and to a method for fabricating an integrated-circuit device with an integrated fluidic-cooling channel. The method comprises forming recesses in a dielectric layer sequence at desired lateral positions of electrical interconnect segments and at desired lateral positions of fluidic-cooling channel segments. A metal filling is deposited in the recesses of the dielectric layer sequence so as to form the electrical interconnect segments and to form a sacrificial filling in the fluidic-cooling channel segments. Afterwards, the sacrificial metal filling is selectively removed from the fluidic-cooling channel segments.

Abstract: A power electronics assembly is provided. The assembly includes a housing defining at least one cavity and having a fluid passageway extending therethrough, the fluid passageway having first and second portions on respective first and second opposing sides of the at least one cavity, and a plurality of inductors housed within the at least one cavity of the housing such that the first and second portions of the fluid passageway are on first and second opposing sides of each of the plurality of inductors.

Abstract: A cooling system for an outdoor electronic enclosure, with separate compartments for electronics and batteries, includes separate cooling devices for each compartment so that optimal temperatures are provided to each compartment. The batteries are cooled by a thermo-electric type air-conditioner, while the electronics are cooled by direct air cooling device or a heat exchanger.

Abstract: According to one embodiment of the disclosure, an integrated antenna structure comprises a plurality of radiating elements, cooling channels embedded directly within each of the plurality of radiating elements, a fluid inlet, and a fluid outlet. Each of the plurality of radiating elements receive or transmit electromagnetic energy. The cooling channels are formed by an internal surface of the radiating elements. The fluid inlet and the fluid outlet are in communication with each of the cooling channels. Each of the cooling channels provides a heat exchanging function by receiving at least a portion of a fluid coolant from the fluid inlet, transferring a least a portion of the thermal energy from the respective radiating element to the received portion of the fluid coolant, and dispensing of at least a portion of the received fluid coolant out of the cooling channel to the fluid outlet.

Abstract: The invention relates to an electronic board that comprises: a planar projection plate (42) provided between an intake opening (70) and a discharge opening (72); and a plurality of rectilinear nozzles (86-90) extending through said plate along a projection direction, the projection direction of each nozzle defining an angle relative to a direction perpendicular to a sole (78) of the electronic component (6) to be cooled, the angle ? being comprised in a range of ?30 and +30°.

Abstract: An electronic assembly includes a casing structure defining an interior space for receiving at least one electronic component, an exterior space isolated from the interior space and a heat dissipating path along which heat generated by the electronic component is expelled from the interior space to the exterior space. The casing structure includes a first casing part and a would-be coupling unit. The first casing part includes an engagement unit having a bottom seat extending into the interior space and defining at least one flow passage along the heat dissipating path and a first coupling member projecting from the bottom seat. The would-be coupling unit includes a second coupling member coupled to the first coupling member within the interior space.

Abstract: Electronic device enclosures providing improved heat dissipation are described herein. An example enclosure for holding an electronic circuit board includes a housing having a first portion coupled to a second portion to form a cavity to hold the electronic circuit board. Each of the first and second portions comprises openings to direct convention airflow across opposing faces of the electronic circuit board at the same time. A baffle is coupled to the housing to substantially visually obscure the openings and to define a gap between the housing and the baffle to direct the convection airflow across the opposing faces of the electronic circuit board.

Abstract: A flat panel display including a base frame, a display panel module, and a heat-conductive structure is provided. The base frame includes a control unit. The display panel module is disposed in the base frame and includes a back bracket, a first heating element, and a second heating element. The first heating element and the second heating element are disposed in the back bracket and electrically connected to the control unit. A first distance is formed between the back bracket and the base frame to define a first air passage, a second distance is formed between the back bracket and the base frame to define a second air passage, and the first distance is shorter than the second distance. The heat-conductive structure is disposed in the first air passage, and the position of the heat-conductive structure is corresponding to the position of the first heating element.

Abstract: A method for cooling a semiconductor including passive cooling including transferring heat via passive cooling components; active cooling including transferring heat via active cooling components; and controlling the active cooling based on temperature of the semiconductor. A cooling system for a semiconductor including: a passive component in thermal contact with the semiconductor; an active cooling component in thermal contact with the semiconductor; and a controller controlling the active cooling component.

Abstract: There is disclosed a self-contained electronic apparatus containing at least some power-dissipating components which may require cooling. The self-contained electronic apparatus may also include a removable and replaceable energy storage module. The removable and replaceable energy storage module may include a power element to provide electrical energy for the self-contained electronic apparatus and a cooling element to cool at least a portion of the power dissipating components.

Abstract: To accommodate high power densities associated with high-performance integrated circuits, an integrated circuit (IC) package includes a heat-dissipating structure in which heat is dissipated from a surface of one or more dice to a heat spreader. The heat spreader has a fluid-conducting channel formed therein, and a fluid coolant may be circulated through the channel via a micropump. In an embodiment, the channel is located at or near a surface of the heat spreader, and a heat-generating IC is in thermal contact with the heat spreader. In an embodiment, the IC is a thinned die that is coupled to the heat spreader via a thinned thermal interface material. Methods of fabrication, as well as application of the package to an electronic assembly and to an electronic system, are also described.

Abstract: A cooling system for electronics in a gas turbine engine system comprises an electronic device cooled by a fluid recirculation loop. The fluid recirculation loop comprises a fluid line to carry coolant fluid, a heat pump on the fluid line for removing heat from the coolant fluid, and a fluid pump on the fluid line to circulate the coolant fluid through the loop. The electronic device is in thermal communication with the fluid circulation loop.

Abstract: This rack (1) houses rackable electronic gear modules (2, 3) and has cooling by natural convection thanks to ventilation orifices (20, 21) provided in its bottom (10) and top (11) walls and forced air cooling thanks to internal air distribution ramps (30) fed with air under pressure through the intermediary of a distribution box (31) connected to a forced air circulation duct (37). The use of internal distribution ramps for the forced air makes it possible to produce a pulsed air circulation providing only a slight obstacle to the air circulation obtained by natural convection. Compared to usual configurations, this makes it possible to lower the operating temperature reached by the equipment in the event of loss of the forced ventilation.

Abstract: Electronic circuitry comprises a circuit board (34) and at least one component (30,32) mounted on the circuit board (34), wherein the at least one component (30,32) generates heat in use, the circuit board (34) includes at least one aperture (48, 50) aligned with the component (30,32) or a respective one of the components, and the electronic circuitry is configured to provide, in use, a path for coolant fluid to flow through the or each aperture (48, 50) and past the at least one component (30,32).

Abstract: An electronic assembly includes a casing structure defining an interior space for receiving at least one electronic component, an exterior space isolated from the interior space and a heat dissipating path along which heat generated by the electronic component is expelled from the interior space to the exterior space. The casing structure includes a first casing part and a would-be coupling unit. The first casing part includes an engagement unit having a bottom seat extending into the interior space and defining at least one flow passage along the heat dissipating path and a first coupling member projecting from the bottom seat. The would-be coupling unit includes a second coupling member coupled to the first coupling member within the interior space.

Abstract: According to one embodiment, a heat sink includes an extended end screwed to a printed circuit board. The extended end includes a screw hole and an engagement projection. A notch is formed by cutting the side of the printed circuit board to a position at which the notch does not interfere with signal lines. The notch is engaged with an engagement projection extending from the extended end, thereby preventing the heat sink from rotating when the heat sink is screwed to the printed circuit board.

Abstract: A rotatable cooling module includes a cooling coil. An input line is coupled to the cooling coil via a coupler that allows the cooling coil to rotate independent of the input line. An output line is coupled to the cooling coil via a second coupler that allows the cooling coil to rotate independent of the output line. A coolant flows through the input line and the first coupler and passes through the cooling coil, which removes heat from an electronic assembly to which the cooling unit is attached. The coolant then flows through the second coupler and through the output line and returns to a heat exchanger, which cools the liquid before recirculating through the cooling unit. The couplers are disposed about a single axis which allows the cooling module to be rotated, and the couplers prevent damage from occurring to any of the elements of the cooling module.

Abstract: Cooling apparatuses and methods are provided for facilitating cooling of an electronic device utilizing a cooling subassembly, a pump and a controller. The cooling subassembly includes a jet impingement structure, and a thermosyphon. The jet impingement structure directs coolant into a chamber of the subassembly onto a surface to be cooled when in a jet impingement mode, and the thermosyphon, which is associated with the chamber, facilitates convective cooling of the surface to be cooled via boiling of coolant within the chamber when in a thermosyphon mode. The controller, which is coupled to the pump to control activation and deactivation of the pump, also controls transitioning between the jet impingement mode and the thermosyphon mode based on a sensed temperature of the electronic device.

Abstract: An automotive power electronics system is provided. The automotive power electronics system includes a support member and at least one electronic die mounted to the support member. The at least one electronic die has an integrated circuit formed thereon comprising at least one wide band gap transistor.

Abstract: Power pedestals are provided with an electrical ground connection to rebar encased in a foundation slab of a facility to thereby establish a EUFER ground for the power pedestal. Many pieces of rebar may be present within the foundation slab and may be interconnected to form a rebar network. In addition to the EUFER ground provided by the rebar, other grounding techniques may also be included such as a ground ring formed by ground rods spaced around the foundation slab and interconnected by a buried conductor that encircles the foundation slab. The rebar may be electrically connected to the ground ring to establish the conductivity to the earth. The power pedestal and EUFER ground may be present at various facilities, such as those including outdoor electronics equipment closures such as remote terminals and base stations.

Abstract: An inverter unit includes a reactor and switching elements that form a voltage boost circuit that boosts a power supply voltage; a switching element for an inverter that forms an inverter circuit to be supplied with the power supply voltage boosted by the voltage boost circuit; and a cooling unit provided with a coolant passage that carries coolant along a cooling face with which the reactor and the switching elements of the voltage boost circuit and the switching element of the inverter circuit are in contact.

Abstract: A 3-level power converter is provided, which is reduced in size of the converter, reduced in floating inductance of each of wirings interconnecting between respective elements, and easily attached with a snubber circuit. The 3-level power converter performs on/off control of first to fourth switching elements 1 to 4 so as to output a 3-level voltage from an AC output terminal AC, wherein the power converter has a first module 11 including the first and fourth switching elements 1 and 4 as a configuration unit, a second module 12 including the second and third switching elements 2 and 3 as a configuration unit, a third module 14 including a first coupling diode 5 as a configuration unit, and a fourth module 13 including a second coupling diode as a configuration unit, and the second module 11, the fourth module 14, the third module 13, and the first module 11 are sequentially arranged in a line from a position near the AC output terminal AC.

Abstract: A stacked busbar assembly includes two or more busbar subassemblies, each including a plurality of busbars having one or more power semiconductor devices bonded thereto (e.g., IGBTs, power diodes, and the like). Each busbar has an internal integrated cooling system including one or more fluid channels in communication with an inlet and an outlet. The busbar assemblies are stacked such that their respective inlets and outlets are aligned and a coolant may then flow in parallel therethrough.

Abstract: A method is generally described which includes operating an electrical energy storage device or an electrochemical energy generation device includes providing at least one thermal control structure formed of a high thermal conductive material. The high thermal conductive material having a high k-value, the high k-value being greater than approximately 410 W/(m*K). The thermal control structures are disposed adjacent at least a portion of the electrical energy storage device or the electrochemical energy generation device. The thermal control structures are configured to provide heat transfer away from the portion of the electrical energy storage device or the electrochemical energy generation device. The method also includes configuring a controller with a control algorithm to control the actions of a controllable fluid flow device as a function of a mobile device states. The mobile device using electricity from the electrical energy storage device or the electrochemical energy generation device.

Abstract: A cooling device for a circuit breaker which comprises a case having a front wall, a rear wall, an upper wall, a lower wall, two flanks, and a first series of side-by-side terminals and a second series of side-by-side terminals that protrude outside from the case for the connection of the circuit breaker with an electrical circuit. The cooling device includes at least one first body made of a thermal conducting material and which has a central portion suitable for being positioned transversally along and facing the first series of terminals so as to absorb heat generated at the first series of terminals, and a first end portion and a second end portion that protrude from the central portion and are configured so as to receive the heat absorbed by the central portion and to diffuse it outside the cooling device itself.

Abstract: A method is generally described which includes operating an electrical energy storage device or an electrochemical energy generation device includes placing an electrical load to draw current from the electrical energy storage device or the electrochemical energy generation device. The electrical energy storage device or the electrochemical energy generation device includes a housing having an external surface and an internal surface. The method also includes generating electricity by at least one component within the housing. At least one component is configured to generate electrical energy in combination with other components, chemicals, or materials residing within the housing. Further, the method includes thermal control of the electrical energy storage device or the electrochemical energy generation device by transferring heat to a plurality of microchannels coupled to at least one of the internal surface of the housing or the at least one internal components.

Abstract: According to the invention, an apparatus for transferring heat with a target is disclosed. The apparatus may include a body which defines a surface, inlet port, inlet manifold passages, heat transfer passages, outlet manifold passages, and outlet port. The surface may couple the target with the body. The inlet port may be configured to receive and direct a fluid into inlet manifold passages. The inlet manifold passages may be configured to receive and direct the fluid to the heat transfer passages. The heat transfer passages may be configured to receive and direct the fluid in a direction substantially parallel to the surface and substantially perpendicular the input manifold passages. The outlet manifold passages may be configured to receive and direct the fluid to an outlet port. The outlet port may be configured to receive and output the fluid.

Abstract: One embodiment of the present invention uses plasma-driven gas flow to cool down electronic devices. The cooling device may comprise micro heat sink fins assembly, micro plasma actuators assembly, and magnetic circuit assembly. The plasma actuator assembly comprises electrodes and dielectric pieces. Voltages are applied to electrodes to drive the plasma gas flow. A magnetic circuit assembly may be used to provide the magnetic field to couple with plasma actuators to induce the plasma gas flow to cool down the heat sink fins and heat source.

Abstract: A semiconductor package comprises a semiconductor chip, through electrodes and cooling parts. The semiconductor chip has bonding pads on an upper surface thereof. The through-electrodes are formed in the semiconductor chip. The cooling parts are formed in the semiconductor chip and on the upper surface of the semiconductor chip in order to dissipate heat.