A choke structure with water cooling includes a water-cooled device, a choke assembly mounted on the water-cooled device, a ceramic heat spreader with high thermal conductivity set between the choke assembly and the water-cooled device, a metal housing having upper and lower openings installed on the water-cooled device to surround the choke assembly and the ceramic heat spreader with high thermal conductivity, and a printed circuit board is arranged on the upper opening of the metal housing, wherein the generated heat while operating the choke assembly is transmitted through a first heat conduction path formed by the ceramic heat spreader with high thermal conductivity in contact with the choke assembly and the water-cooled device for dissipating heat.

A modular system applied to transformers, particularly power transformers, which comprises a structure having modules coupled between each other by fixation means, in such a manner that, the set thus formed, is positioned in the perimeter of the tank of the transformer and to which it is possible to connect several equipment and components, so that the referred components and equipment are positioned in the interior of the tank of the transformer, thus permitting the access to the referred components and equipment, when carrying out maintenance, supervision or control work, as well as to permit the optimization in the manufacture thereof, assembly, transport and installation.

A temperature sensor arrangement includes a housing having on opposite sides thereof a spring element and cover, and a temperature sensor lead and thermal pad such that the spring element is disposed between one of the sides and the cover, the temperature sensor lead is disposed between the other of the sides and the thermal pad, and the cover and thermal pad define opposite exterior sides of the temperature sensor arrangement. The housing carries and permits relative movement of the cover. The spring pushes the cover away from the one of the sides.

A transformer includes a housing having a base wall, a first side wall, a second side opposing wall, a third side wall joining the first side wall and the second side wall at a first end including a first cooling channel joining the first side wall and the second side wall at a first end, and a fourth side wall including joining the first side wall and the second side wall at a second end. The first, second, third, and fourth side walls collectively define an interior portion. A cover extends across each of the first side wall the second side wall, the third side wall, and the fourth side wall. A cooling system includes a first cooling channel disposed in the third side wall, a second cooling channel disposed in the fourth side wall, and a third cooling channel disposed in the cover.

An electromagnetic induction charging device for an inductive, in particular contactless, charging of an at least partially electrified motor vehicle with electrical energy, with a housing, formed in a pot-like manner, which comprises a pot base and a pot collar, wherein the pot collar facing away from the pot base surrounds a pot opening, and with a thermally conductive cover which covers the pot opening and with an electromagnetic resonator arranged in the housing interior, wherein the housing includes a thermal insulation which is arranged at the pot collar and at the pot base for the thermal insulating of the housing interior with respect to the ex-ternal environment.

An inductor assembly includes a housing including a base, a sidewall, and an insert. The base and the sidewall define a cavity and the insert being positioned within the cavity. A core assembly is positioned within the cavity. The core assembly includes a core and a plurality of windings wrapped about the core and disposed between the sidewall and the insert. A flow path is formed in the housing for receiving a coolant to remove heat from the core assembly.

A transformer having a transformer core that forms a magnetic flux path between and through a top yoke, leg, and bottom yoke of the transformer core. A winding can be disposed about the leg. Further, a flitch plate, which can have at least one slot that is configured to reduce eddy losses generated by the winding, can be disposed adjacent to the leg and extend between the top yoke and the bottom yoke. The flitch plate can be clamped to the top and bottom yokes by top and bottom clamps, respectively. The top and bottom clamps can each include at least one cutout that reduces an attraction of stray flux from the winding and into the corresponding top and bottom clamps. Additionally, at least one of the top clamp and the bottom clamp can include an internal lattice structure.

A novel transformer includes a first coil, at least one secondary coil magnetically coupled with the first coil and an electrically insulating holder. The first coil and the at least one secondary coil face each other with the holder therebetween. The holder has at least one through hole at a portion sandwiched between the first coil and the at least one second coil. The transformer also includes at least one electric insulating heat radiation member disposed in the at least one through hole in contact with the first coil and the at least one second coil. The heat radiation member has a higher heat conductivity than the holder.

A method of manufacturing a wireless power reception apparatus includes: forming a lower tray that includes a thermally conductive material and accommodates and fix a coil winding; arranging a coil winding on the lower tray; forming a magnetic field shielding plate so as to accommodate and fix a plurality of magnetic tiles at predetermined intervals; forming a coupled member of a magnetic tiles-magnetic field shielding plate by arranging the plurality of magnetic tiles at the predetermined intervals on the magnetic field shielding plate; forming a thermally conductive polymer molding layer by applying a thermally conductive polymer molding solution to fill spaces between the coil winding and the coupled member of a magnetic tiles-magnetic field shielding plate and bonding the plurality of magnetic tiles and the coil winding such that the plurality of magnetic tiles are positioned over the coil winding; and curing the thermally conductive polymer molding layer.

An electric device for connection to a high voltage includes an active part having a magnetizable core and at least one winding arrangement, each surrounding a core section of the core and having windings inductively coupled together, forming cooling channels in the windings. A boiler is filled with insulating fluid and the active part is completely disposed therein. The boiler has at least one insulating fluid inlet and at least one insulating fluid outlet interconnected by a circulation system outside of the boiler having a cooling unit and a pump for circulating the insulating fluid. The electric device has improved cooling achieved by each insulating fluid inlet being connected to a distributing unit, which is disposed on one of the end sides of the winding assembly, via an insulating fluid line extending in the boiler, the distributing unit distributing cooled insulating fluid to the cooling channels.