A self-clamping structure for solving a short-circuit resistance problem of amorphous alloy transformers comprises an A-phase coil, a B-phase coil and a C-phase coil which are horizontally arranged, the A-phase coil being in close contact with the B-phase coil, and the B-phase coil being in close contact with the C-phase coil. By using a solidified low-voltage coil as a fastening splint and binding with a high-strength binding strap, the low-voltage coils of the A-phase and the B-phase clamp and fix a weak portion between the A and B phases; and the low-voltage coil of the B-phase and the C-phase clamp and fix a weak portion between the B and C phases. Outer sides of the A- and C-phase coils are each provided with a high-strength insulation splint, so that the splint and the low-voltage coil of corresponding phase constitute the splint pair to clamp and fix the corresponding weak portion.

A magnetic field shielding structure includes a magnetic layer and a resonance reactive shielding circuit including a capacitor and a conductor connected to the capacitor and having a loop form. At least a portion of the magnetic layer overlaps an area surrounded by the conductor in a thickness direction of the magnetic layer.

An electronic component includes a first inductor, a second inductor, and a shield structure. Each of the first inductor and the second inductor includes a plurality of inductor conductor layers. The plurality of inductor conductor layers include a first conductor layer closest to a first surface of a stack and a second conductor layer closest to a second surface of the stack. The shield structure is arranged between the first inductor and the second inductor when viewed in a stacking direction, and is arranged between the second conductor layer of each of the first inductor and the second inductor and the first surface of the stack.

An induction charging coil device is provided, in particular an induction charging coil device for a hand-held power tool, including at least one coil unit having at least one shielding unit, at least one core unit and at least one electronics unit and/or one cell unit to be shielded. It is provided that a projection area of the core unit, in the case of a projection in the direction of a winding axis of the coil unit, covers at least essentially the electronics unit and/or the cell unit to be shielded.

Exemplary embodiments of the present disclosure are related to inductor shielding. A device may include an inductor and a plurality of conductive strips extending across the inductor. At least a first conductive strip of the plurality of conductive strips is physically isolated from at least a second conductive strip of the plurality of conductive strips in a region of overlay of the first and second conductive strips.

A wireless charging apparatus including a power emitting module and a power transmission module is provided. The power emitting module has a first coil for transmitting a charge power. The power transmission module is electrically coupled to the power emitting module. The power transmission module has second and third coils, where the second coil is coupled to the first coil for receiving the charge power, and the third coil is coupled to the second coil to receive the charge power. Wherein, the third coil is coupled to a portable electrical device, and provides the charge power to charge the portable electrical device.

A circuit includes a first digital controlled oscillator and a second digital controlled oscillator coupled to the first digital controlled oscillator. A skew detector is connected to determine a skew between outputs of the first digital controlled oscillator and the second digital controlled oscillator, and a decoder is utilized to output a control signal, based on the skew, to modify a frequency of the first digital controlled oscillator using a switched capacitor array to reduce or eliminate the skew. A differential pulse injection oscillator circuit and a pulse injection signal generator circuit are also provided,

A transformer includes: a core having a central arm and first and second outer arms on opposite sides of the of the central arm; a primary winding surrounding the central arm; a secondary winding surrounding the central arm; a primary winding shield surrounding the primary winding including a center tap connection connected to an output power connection; and a secondary winding shield surrounding the secondary winding including a center tap connection connected to an output power connection is disclosed. The transformer also includes a DC-to-AC converter connected to the primary winding that includes a primary bias power supply, a primary conversion element and a primary controller, an AC-to-DC converter connected to the secondary winding, a sensor connected to an output of the AC-to-DC converter and a secondary bias power supply that receives power from the secondary winding shield.

Methods of and systems for directing flux from a transmit coil to a receive coil within an inductive power transfer system are disclosed. For example, a transmit coil can be shielded with a contoured shield made from a ferromagnetic material. The contoured shield contours to several surfaces of the transmit coil so as to define a single plane through which magnetic flux is directed to a receive coil.

A coil unit includes a non-magnetic conductive plate which is disposed in an arrangement direction of first and second coils have reverse winding direction to each other, and a magnetic body. The magnetic body includes a first portion which is positioned in an outer side than an outline of one side of the conductive plate in the arrangement direction of the first and second coils, and a second portion which is positioned in an outer side than an outline of the other side of the conductive plate in the arrangement direction of the first and second coils. When viewing from the arrangement direction of the first and second coils, the first and second portions are positioned on a side of the conductive plate where is opposite to a side which faces the first and second coils.