Power module includes transformer unit including primary and secondary windings and magnetic core; first and second capacitor units coupled to first terminal of primary winding of transformer unit through first node; first and second external pins respectively coupled to first terminal of first capacitor unit and second terminal of second capacitor unit; first and second switch units coupled to second terminal of primary winding of transformer unit thorough second node; third and fourth external pins respectively coupled to first terminal of first switch unit and second terminal of second switch unit; secondary-side circuit coupled to secondary winding; and fifth and sixth external pins electrically coupled to first and second output terminals of secondary-side circuit, respectively. First external pin is coupled to one of third and fourth external pins selectively.

A magnetic induction assembly includes a magnetic core, a primary winding, a secondary winding and a base. The primary winding is wound by a wire. The secondary winding is a conductive plate having an open loop and two contact ends. The base has a body having a through hollow. A surface of the body is formed with n partitions, where n is greater than or equal to 1. The partitions divide the body into n+1 winding areas for being selectively wound by the wire. Each of the partitions has a chamber, a through hole communicating with the through hollow and an opening allowing the secondary winding to enter the chamber. The magnetic core passes through the through hollow, the through holes and the loop of the conductive plate to magnetically couple with the primary winding and the secondary winding.

An output wire joining structure of a winding seat for a transformer or an inductor is disclosed. The winding seat includes a winding portion and a support portion. The winding portion is disposed on top of the support portion for winding a coil. Two sides of the support portion are provided with pin holders for insertion of output wires of the coil. At least one joining plate is disposed beneath the pin holders corresponding in position to the output wires. The output wires of the coil and metal pins of the pin holders are soldered to the joining plate respectively, so that the output wires and the metal pins are quickly soldered and fixed to form a connection, which has the advantages of increasing the rated current and facilitating the operation.

A pin structure of a transformer bobbin is provided. The transformer bobbin includes a winding part on which at least one winding is wound, and at least one wire outlet part arranged on a side of the winding part. The pin structure includes at least two accommodating slots arranged at the wire outlet part, and at least two conductive pins. Each of the accommodating slots has two first sections and a second section connected to the two first sections. Each of the conductive pins corresponds to one of the accommodating slots, and includes a connection section in the second section and two exposed sections connected to the connection section and extending to an outside of the winding part via the two first sections. One exposed section can perform socket welding, and the other one is bendable to define the end of the winding with the wire outlet part.

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 transformer includes: an upper primary substrate (110) which is formed by stacking a plurality of dielectric substrates, each substrate being provided with spiral conductive patterns; a lower secondary substrate (120) which is formed by stacking a plurality of dielectric substrates, each substrate being provided with spiral conductive patterns, in which the lower secondary substrate is positioned below the upper primary substrate (110) in such a way that the lower secondary substrate comes into contact with the upper primary substrate (110) or is spaced apart from the upper primary substrate (110); and a secondary coil element (200) of a planar shape to produce an induced current by a current applied to the upper primary substrate (110) and the lower primary substrate (120).

A transformer according to one embodiment of the present invention comprises: a core unit including an upper core and a lower core; a coil unit of which a portion is disposed in the core unit; and a bobbin unit disposed between the core unit and the coil unit, wherein the coil unit includes a first coil and a second coil of which at least a portion is disposed on the side surface of the first coil, the core unit includes a first outer foot part, a second outer foot part, and an intermediate foot part disposed between the first outer foot part and the second outer foot part, and the shortest distance between the first coil and the second coil can be 0.1 to 0.3 times the shortest distance between the outermost part of the first coil and an adjacent outer foot part from among the first outer foot part and the second outer foot part.

Power module includes transformer unit including primary and secondary windings and magnetic core; first and second capacitor units coupled to first terminal of primary winding of transformer unit through first node; first and second external pins respectively coupled to first terminal of first capacitor unit and second terminal of second capacitor unit; first and second switch units coupled to second terminal of primary winding of transformer unit thorough second node; third and fourth external pins respectively coupled to first terminal of first switch unit and second terminal of second switch unit; secondary-side circuit coupled to secondary winding; and fifth and sixth external pins electrically coupled to first and second output terminals of secondary-side circuit, respectively. First external pin is coupled to one of third and fourth external pins selectively.

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.

A coil component includes a body including a magnetic metal powder; an internal insulating layer buried in the body; an internal coil portion disposed on the internal insulating layer, and having turns of which cross-sectional areas increase towards the internal insulating layer from externally of the internal insulating layer; an external insulating layer covering the internal coil portion; an external coil portion disposed on the external insulating layer, and having a greater number of turns than a number of turns of the internal coil portion; a connection via penetrating through the external insulating layer and connecting the internal coil portion and the external coil portion; and an insulating film surrounding the internal insulating layer, the internal coil portion, the external insulating layer, and the external coil portion.