An actuating device comprising at least one magnetic drive (12) with a solenoid coil (34) which, accommodated in a housing (10), generates heat during operation affecting the performance of the device, wherein said heat is dissipated at least partially into the environment as power loss via the housing (10), is disclosed, which is characterized in that, for improved heat dissipation, parts (40, 42) of the device consist of at least one special plastic material, which has a thermal conductivity coefficient of 0.25 to 1.25 W/(m.Math.K).

A surface mountable housing for a power transmitter for wireless power transfer includes a connector system configured for use to mount, at least, a transmitter antenna to an underside of a structural surface, such that the transmitter antenna is configured to couple with a receiver antenna of a power receiver when the receiver antenna is proximate to a top side of the structural surface. The surface mountable housing further includes a heat sink, the heat sink configured to rest, at least in part, below the transmitter antenna, when the power transmitter is connected to the structural surface, and configured to direct heat generated by the power transmitter away from the structural surface, and an antenna housing, the antenna housing substantially surrounding a side wall of the transmitter antenna, the antenna housing connected to the heat sink and positioned between the heat sink and the structural surface.

A wireless power transmitter includes a charging coil, an electronics housing, and a top side. The charging coil housing houses a charging coil and includes a top surface, wherein the charging coil wirelessly transmits power to a receiver placed on the top surface of the charging coil housing. The electronics housing houses one or more electronics and a fan. The top side is located adjacent to the electronics housing, wherein a top surface of the top side faces a bottom surface of the receiver. An intake cooling path is defined by a region between the bottom surface of the receiver and the top surface of the top side and an exhaust cooling path is located on a side of the charging coil housing opposite the intake cooling path and defined by a region between the receiver and the top surface of the top side.

Provided is an ignition coil device for an internal combustion engine with which a reduction in performance can be suppressed. In an ignition coil device for an internal combustion engine, a case main body houses an ignition coil device main body and an igniter. The igniter includes a circuit board and lead frames provided on the circuit board. The circuit board includes a substrate having a first surface and a second surface formed thereon. The substrate is arranged in a state in which the first surface faces a connector, and the second surface faces the ignition coil device main body. The connector includes connector conductors. The lead frames are provided on the first surface in a state of being opposed to the connector conductors.

A transformer includes: a base that is a plate-like member and has a first surface and a second surface, a core attached to the first surface of the base, coils wound around the core, coil terminals attached to the second surface of the base, and a cooling unit that is thermally connected to the core and is to release heat transferred from the core. The coil terminals are disposed on the second surface of the base opposite to the first surface of the base to which the core is attached. The cooling unit is disposed on a side of the core opposite to the base.

A thermal management includes an inductor, a housing in thermal communication with the inductor, the housing defining a wall, and a conductor. The conductor has greater thermal conductivity than the wall and is positioned within a groove and/or an aperture formed in the wall. The conductor is configured to conduct heat through the wall more efficiently than if the conductor were not present. A method of manufacturing a thermal management system includes forming a housing by additive manufacturing. The housing defines a wall having at least one of a groove and an aperture defined therein. The method includes positioning a conductor in at least one of the groove and the aperture. The conductor has a greater thermal conductivity than the wall. The method includes positioning an inductor into thermal communication with the housing.

A power reception apparatus includes a secondary coil which receives power in a non-contact state from a power transmission apparatus having a primary coil, while being disposed opposite to the power transmission apparatus, a housing which accommodates the secondary coil to form a space between the secondary coil and the housing, an insulating fluid filled in the space, a measurement unit which measures efficiency of a non-contact power transmission between the primary coil and the secondary coil, and a detection unit which detects damage made to the housing based on a change in the efficiency during the non-contact power transmission.

A wireless power transmission device for a vehicle is provided. A wireless power transmission device for a vehicle includes: a wireless power transmission module including at least one wireless power transmission antenna for transmitting wireless power, and a magnetic field shielding sheet arranged on one surface of the wireless power transmission antenna; a radiation case having one side to which the wireless power transmission module is coupled, having at least one circuit board embedded therein so as to drive the wireless power transmission module, and radiating heat generated by a heat source; a radiation plate arranged between the wireless power transmission module and the radiation case, and dispersing heat generated in the wireless power transmission antenna; an insulating layer arranged on one surface of the radiation plate so as to block thermal transferring between the radiation case and the radiation plate; and a cover detachably coupled to the radiation case.

Provided is a static electric induction arrangement including: a static electric induction device arranged in a static electric induction device tank; an accessory tank including at least one opening configured to receive an accessory therein; the static electric induction device tank and the accessory tank are intended to be filled with dielectric fluid and are connected via a fluid connection, an upper portion of a cross section of the fluid connection, is located at a first height, the arrangement comprises a heat exchanger connected to the device tank, the device tank includes an outlet that is arranged to lead the dielectric fluid to the heat exchanger and an inlet that is arranged to return the dielectric fluid from the heat exchanger.

A transformer is provided that includes an enclosure configured to house a core and a coil assembly mounted to the core. The enclosure includes a number of vertically extending sidewalls, at least one top wall connecting the sidewalls, and a bottom end opposite the at least one top wall. At least one of the sidewalls is joined to an access panel that is angled below the at least one top wall and extends between the bottom end of the enclosure and the vertically extending at least one sidewall. A first ventilation opening is provided in the angled access panel and a second ventilation opening is provided in the at least one sidewall adjacent to and/or in the top wall.