Disclosed is a phase shift transformer for supplying voltage to a plurality of unit power cells in a medium voltage inverter system. The phase shift transformer according to the present invention comprises a first bushing arranged by the side of a tank and connected to a first winding to apply high voltage and a plurality of second bushings arranged on the top of a cover and connected to each of a plurality of second windings to output low voltage, wherein three outputs of the plurality of second bushings can be applied to unit power cells.

Disclosed is a phase shift transformer for supplying voltage to a plurality of unit power cells in a medium voltage inverter system. The phase shift transformer according to the present invention comprises a first bushing arranged by the side of a tank and connected to a first winding to apply high voltage and a plurality of second bushings arranged on the top of a cover and connected to each of a plurality of second windings to output low voltage, wherein three outputs of the plurality of second bushings can be applied to unit power cells.

A power transmission device that transmits electric power to a power reception device in a contactless manner includes a power transmission coil unit, an electrical device connected to the power transmission coil unit, and an enclosure storing the power transmission coil unit and the electrical device. The enclosure includes an installation wall, an outer wall, a partitioning wall, and a cover portion closing an opening formed in a power transmission surface of the outer wall and allowing transmission of electric power by the power transmission coil unit. The partitioning wall is provided to partition the space in the enclosure into a coil-unit storing portion in which the cover portion is located and the power transmission coil unit is stored, and an electrical-device storing portion in which the electrical device is stored. The outer wall and the partitioning wall are made of metal.

A power transmission device that transmits electric power to a power reception device in a contactless manner includes a power transmission coil unit, an electrical device connected to the power transmission coil unit, and an enclosure storing the power transmission coil unit and the electrical device. The enclosure includes an installation wall, an outer wall, a partitioning wall, and a cover portion closing an opening formed in a power transmission surface of the outer wall and allowing transmission of electric power by the power transmission coil unit. The partitioning wall is provided to partition the space in the enclosure into a coil-unit storing portion in which the cover portion is located and the power transmission coil unit is stored, and an electrical-device storing portion in which the electrical device is stored. The outer wall and the partitioning wall are made of metal.

A multilayer coil component including: a magnetic part that contains Fe, Zn, V, and Ni and optionally contains Mn and/or Cu; and a conductor part that contains copper. In the magnetic part, Fe is in an amount of 34.0 to 48.5 mol % expressed as Fe.sub.2O.sub.3 equivalent, Zn is in an amount of 6.0 to 45.0 mol % expressed as ZnO equivalent, Mn is in an amount of 0 to 7.5 mol % expressed as Mn.sub.2O.sub.3 equivalent, Cu is in an amount of 0 to 5.0 mol % expressed as CuO equivalent, and V is in an amount of 0.5 to 5.0 mol % expressed as V.sub.2O.sub.5 equivalent, with respect to the total amount of Fe expressed as Fe.sub.2O.sub.3 equivalent, Zn expressed as ZnO equivalent, V expressed as V.sub.2O.sub.5 equivalent, and Ni expressed as NiO equivalent, and optionally present Cu expressed as CuO equivalent and optionally present Mn expressed as Mn.sub.2O.sub.3 equivalent.

A bushing for a transformer is provided, the bushing comprising an elongate enclosure body to accommodate a conductor extending along a longitudinal axis, the conductor having a first terminal end a second terminal end, the ends extending from opposite sides of the enclosure body; and a mounting flange fitted to the enclosure body to enable the bushing to be mounted to an enclosure of the transformer. The enclosure body comprises two electrically insulating layers partially surrounding the conductor, a first layer of the insulating layers being substantially provided by a first polymeric material and a second layer of the insulating layers being substantially provided by a second polymeric material, the layers being arranged about the conductor in such a manner that the bushing is substantially cavity-free. In an embodiment, the first layer defines an inner core, with the second layer providing an outer cover which at least partially covers the inner core.

A bushing for a transformer is provided, the bushing comprising an elongate enclosure body to accommodate a conductor extending along a longitudinal axis, the conductor having a first terminal end a second terminal end, the ends extending from opposite sides of the enclosure body; and a mounting flange fitted to the enclosure body to enable the bushing to be mounted to an enclosure of the transformer. The enclosure body comprises two electrically insulating layers partially surrounding the conductor, a first layer of the insulating layers being substantially provided by a first polymeric material and a second layer of the insulating layers being substantially provided by a second polymeric material, the layers being arranged about the conductor in such a manner that the bushing is substantially cavity-free. In an embodiment, the first layer defines an inner core, with the second layer providing an outer cover which at least partially covers the inner core.

An inductor module comprising one or several wound inductors in a metallic housing, held in place by potting compound, wherein a surface of the metallic housing is a mechanical and thermal interface to a heat sink, and the distance between the coils and the inner side of the surface is predetermined by a suitable insulating space of potting compound. The invention may be used as PFC inductor in an on-board vehicle charger, among other uses.

An annular block of polymer comprising an inductive coupler assembly configured to fit within a groove in the shoulder of a drill pipe joint. The assembly comprises a ferrite channel arranged around the interior of the block. At least one turn of a conductive wire is deposed within the channel. The block comprises a bumper comprising jutting from the block. The block comprises internal void openings adjacent its vertical side surfaces. A void opening is disposed proximate the bumper. The block further comprises an internal gasket partially extending from the bottom surface of the block. The external portion of the gasket being formed to fit within a gasket seat in the bottom of the groove. The wire passes through the gasket as it exits the block. When the block is installed into the groove, the gasket seals the wire and the block's components from the downhole environment.

A high-voltage transformer includes a magnetic core; at least a secondary coil unit including at least one secondary winding; at least a primary coil unit, comprising at least one primary winding and a first insulating portion, the first insulating portion forming at least one through hole, the primary winding encircling the through hole and being wrapped by the first insulating portion and fixed in the first insulating portion, the magnetic core passing through the through hole, a shielding layer being formed on a surface of the first insulating portion, and the shielding layer being used for connecting a safety ground; a second insulating portion formed by extending the first insulating portion; a first retaining wall presented in a closed ring shape, arranged on an end periphery of the second insulating portion; and a second retaining wall arranged in the first retaining wall.