An inductive charging device may include a charging assembly with at least one induction coil and at least one magnet plate, which may be ferrimagnetic or ferromagnetic at least on some regions, and an emission protection assembly fastened to the charging assembly, with a metal shielding plate, in order to shield field emissions arising during an inductive charging process. The emission protection assembly may have an active cooling assembly lying against the metal shielding plate so as to allow heat transfer and fastened thereto. The cooling assembly may have: at least one boundary insert lying against the metal shielding plate, by which a cooling region of the cooling assembly may be delimited; at least one channel structure insert lying against the metal shielding plate in the cooling region, through which a channel structure for a cooling medium may be provided; and a cooling cover, fastened to the boundary insert in a fluid-tight manner, in order to cover the cooling assembly.

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.

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 includes two first cores, a primary winding and a secondary winding. The secondary winding has a first section and a second section. The first section has a first outlet end, a second outlet end, and a first connection end, wherein the first outlet end and the second outlet end are located at a side of the first section, the first connection end is located at an opposite side of the first section. The second section has a third outlet end, a fourth outlet end, and a second connection end. The third outlet end and the fourth outlet end are located at a side of the second section, and the second connection end is located at an opposite side of the second section. A portion of the primary winding is located between the first section and the second section of the secondary winding.

A transformer includes two first cores, a primary winding and a secondary winding. The secondary winding has a first section and a second section. The first section has a first outlet end, a second outlet end, and a first connection end, wherein the first outlet end and the second outlet end are located at a side of the first section, the first connection end is located at an opposite side of the first section. The second section has a third outlet end, a fourth outlet end, and a second connection end. The third outlet end and the fourth outlet end are located at a side of the second section, and the second connection end is located at an opposite side of the second section. A portion of the primary winding is located between the first section and the second section of the secondary winding.

An inductive charging device may include a charging assembly with at least one induction coil and at least one magnet plate, which may be ferrimagnetic or ferromagnetic at least on some regions, and an emission protection assembly fastened to the charging assembly, with a metal shielding plate, in order to shield field emissions arising during an inductive charging process. The emission protection assembly may have an active cooling assembly lying against the metal shielding plate so as to allow heat transfer and fastened thereto. The cooling assembly may have: at least one boundary insert lying against the metal shielding plate, by which a cooling region of the cooling assembly may be delimited; at least one channel structure insert lying against the metal shielding plate in the cooling region, through which a channel structure for a cooling medium may be provided; and a cooling cover, fastened to the boundary insert in a fluid-tight manner, in order to cover the cooling assembly.

Two through-holes (7a) are formed in a portion of a second cover (7), the portion facing a second core (9) and a secondary coil (5). Heat radiation members (11) are provided in the through-holes (7a). The heat generated by the secondary coil (5) is radiated to the second core (9) via the heat radiation members (11).

Two through-holes (7a) are formed in a portion of a second cover (7), the portion facing a second core (9) and a secondary coil (5). Heat radiation members (11) are provided in the through-holes (7a). The heat generated by the secondary coil (5) is radiated to the second core (9) via the heat radiation members (11).

An induction assembly may include a coil carrier, a coil winding, a core assembly, and a heat exchanger. The coil carrier may include an upper wall, a lower wall located opposite the upper wall, and a receiving space. The coil winding may be disposed in the receiving space. The core assembly may form a coil with the coil winding. The core assembly may include at least two core bodies that are spaced apart from one another by a gap. The heat exchanger may include an inner panel spaced apart from the core assembly and an outer wall located opposite the inner panel. The outer wall may limit a flow space through which a flow path of a cooling fluid for controlling a temperature of the induction assembly leads.

An inductive device comprises a toroidal core and at least one electric conductor wound around the toroidal core and constituting at least one winding. The inductive device comprises a cooling element constituting a cylindrical cavity that contains the toroidal core and the electric conductor so that the axial direction of the toroidal core is parallel with the axial direction of the cylindrical cavity. The shape of the cylindrical cavity and the cross-section of the electric conductor are adapted to match each other to improve heat transfer from the electric conductor to the wall of the cylindrical cavity so that a wall of the cylindrical cavity is provided with axially directed grooves occupied by portions of the electric conductor on an outer perimeter of the winding.