The system and method of converting high DC voltage input into low voltage output using DC/DC flyback converter using differential transformation technique. The said system comprises a primary winding of a transformer connected to the positive terminal of a DC supply. A primary power circuit including a MOSFET connected to the drain terminal of the MOSFET. Further, a pair of secondary winding of the transformer provided connected differentially to each other. The output voltage of the secondary side of the converter is based on the turn ratio of primary winding and the two secondary winding, wherein the two secondary windings are connected differentially with opposite polarity to each other.

A power control module and a method to create the power control module is provided. The power control module includes a plurality of transformers, wherein each transformer of the plurality of transformers includes a stack of ferrite cores comprising a plurality of ferrite cores and a continuous winding. The continuous winding has a plurality of turns through each ferrite core of the plurality of ferrite cores. The plurality of ferrite cores are oriented such that the plurality of ferrite cores are stacked together with legs of the plurality of ferrite cores oriented in opposite directions, and wherein the continuous winding comprises a folded section that extends between the plurality of ferrite cores of the stack of ferrite.

A high-voltage waveform generator comprising a power source, a transformer unit comprising a magnetic core, attached to the power source, a plurality of power switch cards, each having an aperture that allows said magnetic core to pass therethrough, one or more control switches located on each power card, and a control means for actuating the control switches, a power output; wherein the power switch cards are connected in series, wherein each of the apertures in the power switch cards is surrounded by conductive windings, whereby when the power source is activated, the magnetic core induces a current in each of the conductive windings, and wherein the control means activates the control switches simultaneously in under 100 nanoseconds to generate a pulse.

An electronic device includes a magnetic element, a first circuit module and a second circuit module. The magnetic component includes a magnetic core set and a winding, and the winding includes a first winding and a second winding, and the winding is assembled on the magnetic core set. The first circuit module is connected to the first winding of the magnetic element. The second circuit module is connected to the second winding of the magnetic element. The first circuit module or/and the second circuit module has/have an overlap portion with the winding on a vertical projection area of a first plane, and the first plane is the first plane is a horizontal plane at which the winding is located.

A magnetic device includes a magnetic core assembly and a winding assembly. The magnetic core assembly includes a first magnetic cover, a second magnetic cover and a plurality of magnetic legs. The second magnetic cover has a perforation. The plurality of magnetic legs are disposed between the first magnetic cover and the second magnetic cover. A middle region is defined by the plurality of magnetic legs, the first magnetic cover and the second magnetic cover. The middle region is in communication with the perforation. The middle region includes a plurality of communication portions. The winding assembly includes at least one coupled winding pair. In addition, two coupled windings of each coupled winding pair are respectively transferred through two different communication portions, and portions of the two coupled windings of each coupled winding pair are penetrated through the perforation of the second magnetic cover.

The present application provides a synchronous rectification assembly, a manufacturing method thereof and a power supply. The synchronous rectification assembly comprises a synchronous rectification board, a transformer and a main board; wherein the synchronous rectification board is disposed on the main board and is electrically connected to the main board, and the transformer is disposed on the synchronous rectification board and is electrically connected to the synchronous rectification board; the synchronous rectification board is provided with a conductive contact for being electrically connected to an external apparatus, and the synchronous rectification board is used for synchronously rectifying an output signal of the transformer and thereafter transmitting the output signal to the conductive contact. The present application can solve the problem that the output signal outputted by the transformer in the existing synchronous rectification assembly has a large loss during transmission.

The embodiments of the present disclosure provide a synchronous rectifier module, comprising: a transformer provided with a plurality of secondary windings, a first circuit board and a second circuit board disposed on opposite sides of the transformer, and a first connecting piece electrically connected to the first circuit board and a second connecting piece electrically connected to the second circuit board; the first connecting piece and the second connecting piece comprise current sharing portions connected to the first circuit board and the second circuit board respectively, and inductor portions which penetrate an inductance core side by side to form an output inductor, resistance values of the current sharing portions of the first connecting piece and the second connecting piece being equal or a resistance difference value therebetween being within a preset range. The present disclosure can quickly, accurately and conveniently improve the efficiency and the heat dissipation of the synchronous rectifier module, and achieve a better current sharing effect of the connecting pieces by adjusting the resistance value numerical range of the two connecting pieces.

The present application provides a synchronous rectification assembly, a manufacturing method thereof and a power supply. The synchronous rectification assembly comprises a first circuit board, a transformer, an electrical connection piece and a second circuit board; wherein the transformer is electrically connected to the first circuit board, and the second circuit board is provided with a conductive contact for being electrically connected to an external apparatus, and the electrical connection piece is electrically connected to the first circuit board and the second circuit board respectively; the first circuit board is configured to perform synchronous rectification on the output signal of the transformer and then transmit the output signal to the conductive contact of the second circuit board through the electrical connection piece. The present application can solve the problem that the output signal outputted by the transformer in the existing synchronous rectification assembly has a large loss during transmission.

A charge method, an adapter and a mobile terminal are provided. The adapter negotiates with the mobile terminal about the charging mode and the charging current of the battery. When determining to charge the battery in the quick charging mode, the adapter adopts the unidirectional pulse current to perform a quick charge on the battery using the negotiated charging current.

A switching power supply unit includes an N-number (N: an integer of 2 or greater) of transformers; an N-number of inverter circuits; a rectifying smoothing circuit including a {2×(N+1)}-number of rectifying devices, a choke coil, and a capacitor; an additional winding disposed to be interlinked with each of magnetic paths formed in the N-number of transformers; and a driver. In the rectifying smoothing circuit, a (N+1)-number of arms each have two of the rectifying devices, and are disposed in parallel to one another between the pair of output terminals, a secondary winding in each of the N-number of transformers is coupled between adjacent ones of the (N+1)-number of arms to individually form an H-bridge coupling, and the additional winding is coupled in series to one or more of the secondary windings in the N-number of transformers.