The present disclosure relates to the field of power electronic technology, provides a magnetic unit, including: a magnetic core and a winding, the magnetic core includes Q magnetic legs arranged in a row, where Q is a natural number and Q≥2, and the winding includes a first winding and a second winding, where the first winding is magnetically coupled with the second winding, and the first winding is wound around the Q magnetic legs while the second winding is wound around the Q magnetic legs. The first winding between any two adjacent magnetic legs is generally symmetrically disposed at both sides of the symmetric plane between the any two adjacent magnetic legs, thereby the magnetomotive force (MMF) distribution between any two adjacent magnetic legs is uniform.

An electromagnetic device and a method for manufacturing the same are disclosed. The electromagnetic device includes a base plate, a magnetic core, multiple transmission units, and connection layers. The base plate includes a central part defining multiple inner via holes and a peripheral part defining multiple outer via holes. An annular accommodating groove is defined between the central part and the peripheral part. The magnetic core is received in the annular accommodating groove. Transmission units are located on both sides of the base plate. Each transmission unit includes a transmission wire layer including multiple conductive wire patterns, and each conductive wire pattern bridges one inner via hole and one outer via hole. Each of the connection layers is set on one side of the transmission wire layer close to the base plate. At least one connection layer has a dielectric loss no larger than 0.02.

An electronic device has a substrate, a signal wiring and a heat radiating wiring. The substrate has one surface and the other surface opposite to the one surface. The signal wiring is formed on an insulating layer of the substrate. The heat radiating wiring is formed on the insulating layer and thermally connected to the signal wiring on a same plane as the signal wiring.

Techniques for fabricating low-loss magnetic vias within a magnetic core are provided. According to some embodiments, vias with small, well-defined sizes may be fabricated without reliance on precise alignment of layers. According to some embodiments, a magnetic core including a low-loss magnetic via can be wrapped around conductive coils of an inductor. The low-loss magnetic vias can improve performance of an inductive component by improving the quality factor relative to higher loss magnetic vias.

A planar transformer includes a secondary coil layer, a shielding layer and a primary coil layer disposed in a PCB. The secondary coil layer includes at least part of a secondary coil. The secondary coil are provided with a secondary static electrical point. The shielding layer includes a shielding coil which includes a shielding coil segment of N1 turns and a second shielding coil segment of N2 turns. The first shielding coil segment includes a first shielding static electrical point and a first shielding free end. The second shielding coil segment includes a second shielding static electrical point and a second shielding free end. The winding direction of the first shielding coil segment is the same as the secondary coil, and the winding direction of the first shielding coil segment is opposite to the second shielding coil segment.

A planar transformer includes a primary coil layer, a secondary coil layer, and a shielding layer. The shielding layer is disposed between the primary coil layer and the secondary coil layer. A primary coil is disposed in the primary coil layer, and a secondary coil is disposed in the secondary coil layer. The shielding layer includes a shielding coil with one end connected to a first static electrical point and the other end suspended, and an auxiliary winding with one end connected to a second static electrical point. The auxiliary winding supplies power to a functional circuit of the planar transformer. The winding direction of the shielding coil is opposite to the winding direction of the secondary coil; the winding direction of the auxiliary winding is the same as the winding direction of the secondary coil.

A planar transformer includes: a primary side planar air core coil; a secondary side planar air core coil; a primary side planar core; and a secondary side planar core. The secondary side planar air core coil is arranged so as to be spaced from the primary side planar air core coil in the winding center axis direction of the primary side planar air core coil, the secondary side planar air core coil having a non-facing portion configured not to face the primary side planar air core coil in the winding center axis direction. The primary side planar core and the secondary side planar core are stacked on outer sides of the primary side planar air core coil and the secondary side planar air core coil in the directions of the winding center axes, respectively.

The present disclosure is related to a power module power structure and an assembling method thereof. The power module structure includes a first printed-circuit-board (PCB) assembly, a second PCB assembly, and a conductive connection component. The first PCB assembly includes a first circuit board, a power switch and a magnetic component. The first circuit board includes a first side, a second side and a through hole. The power switch is disposed on the first circuit board. The magnetic component includes a first magnetic core and a second magnetic core fastened on the first circuit board through the through hole. The second PCB assembly includes a second circuit board having a third side, a fourth side and at least one opening. The second magnetic core is exposed through the opening. The conductive connection component is disposed and electrically connected between the first PCB assembly and the second PCB assembly.

A spiral inductor includes a spiral trace and a plurality of first projections extending along a first edge of the spiral trace. The spiral inductor may further include a plurality of second projections extending along a second edge of the spiral trace, the second edge being opposite the first edge.

An inductor device includes a first wire, a second wire, a third wire, a fourth wire, and an eight-shaped inductor structure. The first wire includes at least two first sub-wires. The second wire includes at least two second sub-wires. The third wire includes at least two third sub-wires. The fourth wire includes at least two fourth sub-wires. The first wire is disposed in a first area. The second wire is disposed in a second area. The third wire is disposed in the first area and at least partially overlapped with the first wire in a vertical direction. The fourth wire is disposed in the second area and at least partially overlapped with the second wire in the vertical direction. The eight-shaped inductor structure is disposed on an outer side of the third wire and the fourth wire.