A magnetic assembly formed by a custom magnetic core and its bobbin with interconnection pins is presented. This magnetic assembly leads to a higher power density of magnetic assembly and a better utilization of the volume inside a power converter, allowing a higher power density of the power converter and a higher efficiency through the minimization of the parasitic inductances.

An electronic device package box includes a box unit having lower and upper end sections that are spaced apart in an up-down direction, and multiple first and second connecting pins that are aligned with each other and alternatingly arranged in a longitudinal direction perpendicular to the up-down direction. Each first connecting pin has a first embedded portion, a first wire-connecting portion extending from the lower end section, and a first extending portion extending from the box unit and proximate to the lower end section. Each second connecting pin has a second embedded portion, a second wire-connecting portion extending from the upper end section, and a second extending portion extending from the box unit and proximate to the lower end section.

An edge mount magnetic component includes a bobbin and two E-core halves. The bobbin is configured to receive the two E-core halves when body portions of the two E-core halves are positioned vertically. The bobbin includes a first outer flange, a second outer flange, and a passageway spanning therebetween. The bobbin further includes first, second, third, and fourth pin supports. The first and second pin supports are connected to an outer surface of the first end flange and are spaced apart by at least a width of the passageway. The third and fourth pin supports are connected to an outer surface of the second end flange and are spaced apart by at least the width of the passageway. The bobbin further includes slots for routing a winding to a pin and includes walls to ensure the winding is electrically separated from the E-core halves.

A inductor arrangement has a toroidal core with a central opening, a winding which is arranged around the core and has two winding ends, and an electrically insulating insert which is inserted into the central opening in a clamping manner. Here, the winding ends are inserted into the insert in a clamping manner.

The invention, which relates to a choke arrangement (1) for application in an EMC filter, has as its objective specifying a choke arrangement (1) that is mechanically robust and that enables improved insulation of the windings (4, 5). The objective is attained by disposing about the toroidal core (10) a two-part enclosure (15) and by disposing an insulation web (19) in the two-part enclosure (15).

least one contact element is covered at least in part by a first wall section of the cover cap. The coil body comprises a depression which is formed below the magnetic core and in which a second wall section of the cover cap extending perpendicularly to the side surface of the magnetic core extends between the coil body and the magnetic core received in the coil body. The cover cap comprises a third wall section which is disposed opposite the second wall section and covers at least in part a side surface of the magnetic core and covers the winding at least in part.

A contacting device for electrical contacting of a printed circuit board with a coil body for a solenoid valve for a brake device for a vehicle, including: a helical electrically conductive contact spring which is configured to be contacted or being contactable with the printed circuit board at a first spring end and configured to be contacted or being contactable with the coil body at a second spring end, situated opposite the first spring end, to enable a resilient electrical contacting of the printed circuit board with the coil body; and a pin which is receivable or has been received in an interior space of the contact spring, the pin being configured to support the contact spring from the interior space in a received state received in the interior space. Also described are a related solenoid valve, method, and computer readable storage medium.

A component having a winding carrier, at least one winding, a magnetic core and first and second connections. The winding carrier surrounds at least regions of the core in such a way that an insulation section between the connections along an underside of the component cannot be bypassed via the core. In particular, an underside of the winding carrier is designed to be closed.

An inductive component comprises a magnetic core, a winding, and a coil body. The coil body comprises a contact element attached to a contact strip of the coil body for electrical connection to the winding, a magnetic core receptacle in which the magnetic core is received in part, and an elongate recess formed in the contact strip and extending only in part below the magnetic core and above the contact element and extending in a longitudinally direction of the contact strip. A cover cap is attached to the contact strip and covers at least in part a side surface of the magnetic core facing the contact element. The cover cap comprises a first wall section covering at least in part the side surface of the magnetic core facing the contact element. A second wall section of the cover cap extending perpendicular to the first side surface of the magnetic core is inserted into the recess formed in the coil body, where the second wall section extends between the magnetic core and the contact element in the coil body.

In a high-frequency transformer element includes a primary coil including first coil conductors and a secondary coil including second coil conductors are disposed in a multilayer body that includes a plurality of insulating layers. A magnetic-field cancellation conductor pattern is disposed in the multilayer body, is adjacent to some conductors of the first coil conductors in a lamination direction of the insulating layers, is arranged along a surface of the insulating layers, and allows a high-frequency current to flow in a direction opposite a high-frequency current flowing in the first coil conductors.