The present disclosure relates to electrical windings for a dry transformer which allows construction of a compact dry transformer even in relatively high voltage classes. For this purpose, the electrical winding has multiple windings of a winding conductor wound to form a coil. The coil has been embedded into a solid insulation body. In some embodiments, a coating of an electrically conductive material, comprising a resin matrix with at least 0.05% by weight of nanoscale filler, has been applied to at least one surface of the insulation body.

The present embodiment relates to a coil device. The coil device according to the present embodiment includes: first to third coils including a connecting portion; and a coil frame including an upper receiving portion for housing the first coil, a lower receiving portion for housing the second and third coils, and a cable fixing portion for fixing each connecting portion of the first to third coils.

A laminated transformer-type transmitter-receiver device for transmitting or delivering electrical signals and/or power. The laminated device can include two metal shielding layers disposed between transmit and receive windings, which, in turn, are disposed between two magnetic layers. The laminated device further includes a dielectric isolation layer disposed between the two metal shielding layers. In the laminated device, no (or very little) common mode capacitance is distributed within the dielectric isolation layer, and no (or very little) common mode or “leakage” current flows across the dielectric isolation layer. As a result, various adverse effects of the common mode capacitance and the leakage current during operation of the laminated device are avoided.

A proximity sensor for the inductive detection of objects, including a housing with a front cap, a processing and receiving unit, comprising a printed circuit board, which is configured to connect to an external control and evaluation unit, and a coil carrier, on which at least one primary coil and at least one first secondary coil are arranged circumferentially wound and spaced apart in an axial direction of an axis extending axially through the housing, wherein the first secondary coil lies closer, in the axial direction, to the end face than the primary coil, wherein a second secondary coil is arranged on the coil carrier, wherein the primary coil is arranged between the first and second secondary coils, wherein a metallic shielding element is arranged in an axial area surrounding the second secondary coil and is not arranged in an axial area surrounding the first secondary coil.

Charging devices according to embodiments of the present technology may include a housing including an input configured to receive power from a power source and provide power to internal components of the charging device. The charging devices may include a ferrite. The ferrite may be coupled with electrical ground. The charging devices may also include a conductive coil seated in the ferrite. The conductive coil may be configured to generate an electromagnetic field from an AC signal.

This application provides a dry-type transformer and a winding method thereof. The dry-type transformer includes a magnetic core, a first coil, a second coil, and a shielding component. The first coil is disposed around the exterior of the magnetic core, and the second coil is disposed around the exterior of the first coil. In a direction from the iron core to the second coil, the shielding component includes a first conducting layer, a second conducting layer, a third conducting layer, and a fourth conducting layer that are sequentially disposed at intervals, the first coil is disposed between the magnetic core and the first conducting layer, and the second coil is disposed between the second conducting layer and the third conducting layer.

A transformer includes a primary coil unit including a primary winding, a first insulating portion and a shielding layer, wherein the first insulating portion wraps the primary winding, the shielding layer covers an outer surface of the first insulating portion, the shielding layer includes an opening, and a part of the first insulating portion is exposed at the opening; an outgoing wire terminal in the opening and having a first portion and a second portion connected with each other, the first portion coupled to the primary winding and wrapped by the first insulating portion, the second portion being exposed out of the first insulating portion; a connecting wire having a first end connected to the second portion of the outgoing wire terminal; and an insulating sleeve partially wrapping the connecting wire, and a second end of the connecting wire being exposed out of the insulating sleeve, (FIG. 17).

The invention provides a two-sided auxiliary structure for induction cards, which comprises: a metal shield layer; and two high-conductivity magnetic layers, which are respectively set on two opposite sides of the metal shield layer, wherein the area of the metal shield layer is greater than those of the two high-conductivity magnetic layers. The two-sided auxiliary structure for induction cards of the invention improves the problem of poor induction success rate of plural induction cards.

An inductor built-in substrate includes a core substrate having openings, a magnetic resin filled in the openings and having through holes, and through-hole conductors formed in the through holes respectively such that each of the through-hole conductors includes a metal film. The magnetic resin is formed such that each of the through holes has an angle part having an obtuse angle formed by an upper surface of the magnetic resin and a side wall of a respective one of the through holes.

This invention presents a new packaging technique that allows for the use of a wider range of isolating materials for inductive conductivity sensors, thereby significantly reducing the cost of producing the sensors, improving their precision and accuracy, and increasing their sensitivity.