A transformer is provided, including a core, a primary conductor, a magnetic member, and a secondary conductor. The core includes a central pillar and at least one lateral pillar. An accommodating space is formed between the central pillar and the lateral pillar. The primary conductor, the magnetic member, and the secondary conductor are disposed in the accommodating space. The primary conductor surrounds the central pillar. The magnetic member surrounds the primary conductor, and the secondary conductor surrounds the magnetic member. The magnetic member is disposed between the primary conductor and the secondary conductor, and is flexible.

The present invention discloses a 220 KV transformer sleeve. The sleeve includes a sleeve assembly and a connecting assembly. The sleeve assembly includes a sleeve brace, an adjustable part coupled with the sleeve brace. The connecting assembly includes a rotating part and a mobile part. The sleeve is secured on the transformer core body through screws, and the adjustable part can be opened through the connecting assembly. When maintenance is required, there is no need to dismantle the entire sleeve. The work efficiency is greatly improved. This minimizes inductance leakage and prevents eddy currents from occurring.

A multi-coil inductor includes a plurality of stacked inductor units. Each of the inductor units comprises: a magnetic core in which a magnetic path is formed; and a plurality of coils which are wound around the magnetic core to form at least one winding pair. Wherein a part of the magnetic path between the adjacent inductor units is shared. In the present invention, the leakage inductance is controlled and the maybe magnetic saturation of magnetic core avoided by adjusting series and parallel connections among the coils.

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.

The power conversion device includes: a boost, converter which includes a magnetically-coupled reactor and a plurality of semiconductor switching elements connected to the magnetically-coupled reactor; an inverter; a cooler for cooling the magnetically-coupled reactor; a bus bar which is a conductive wiring member; and a current sensor for detecting a magnetic flux generated around the bus bar. The magnetically-coupled reactor includes a first winding, a second winding, and a core for magnetically coupling the first winding and the second winding. The core has a composite magnetic body containing soft magnetic powder and a binder, and at least parts of the first winding and the second winding are embedded in the composite magnetic body. The cooler is provided in contact with the magnetically-coupled reactor. The current sensor is provided on a side opposite to the magnetically-coupled reactor with the cooler therebetween.

A transformer includes a stacked structure in which a plurality of coils is stacked through insulation layers. The stacked structure includes: a primary coil stacked layer including a plurality of primary coil layers connected in parallel with one another; and a secondary coil stacked layer including a plurality of secondary coil layers connected in parallel with one another. One of the primary coil layers is disposed as an outermost layer in the stacked structure, and another is disposed between at least two layers of the plurality of secondary coil layers. The primary coil layer includes a plurality of primary coils connected in parallel with one another. The secondary coil layer includes one or more secondary coils thicker than the primary coil.

The present invention suppresses leakage magnetic field. A power transfer coil configured to transmit or receive power includes: an inner coil; a first outer coil formed so as to surround the inner coil such that a magnetic flux opposite in phase to a magnetic flux outside the inner coil is generated outside the first outer coil, the first outer coil having one end connected to a first terminal and the other end connected to one end of the inner coil; and a second outer coil formed so as to surround the inner coil such that a magnetic flux opposite in phase to the magnetic flux outside the inner coil is generated outside the second outer coil, the second outer coil having one end connected to a second terminal and the other end connected to the other end of the inner coil.

The magnetic core includes a middle core, a first end core, a second end core, a first side core, and a second side core. At least either the first side core or the second side core includes an inward recessed portion provided in an inward face that faces the first winding portion in a Y direction. In a plan view of the magnetic core from a Z direction, at least a portion of the inward recessed portion is overlapped with a range corresponding to the length of the first winding portion in an X direction. The X direction is a direction conforming to the axial direction of the middle core, the Y direction is a direction in which the middle core, the first side core, and the second side core are side-by-side, and the Z direction is a direction orthogonal to the X direction and the Y direction.

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.

Exemplary embodiments of the disclosure are related to inductors, e.g., at least a pair of planar inductors for a wireless apparatus, for example transceivers used in a wireless device. A device may include a first planar inductor configured on a first area of a substrate. The first planar inductor includes a first loop configured to produce a first magnetic field in a first direction and a second loop configured to produce a second magnetic field in a second direction. The device further includes a second planar inductor configured on a second area of the substrate. The second planar inductor includes a third loop configured to produce a third magnetic field in a third direction. The third loop may be configured to surround the first loop and divide the second loop into an enclosed area and an external area.