Techniques for a magnetic-shielding-and-enhancement winding are disclosed. The magnetic-shielding-and-enhancement winding is a winding of a multi-turn coil that is on a separate layer from other windings of the coil (e.g., on a general winding layer). The magnetic-shielding-and-enhancement winding provides magnetic shielding to reduce localized multiplicative effects of aggregate fields generated by the windings of the coil on the general winding layer and simultaneously acts as one or more turns of the winding structure to enhance the field in a desirable manner.

An inductor comprises an excitation coil with an excitation coil axis and at least one shielding coil with a respective shielding coil axis. The excitation coil axis and the shielding coil axis define an angle , wherein applies: 60120, preferably 75105, and preferably 8595. The inductor is shielded and enables in an easy and flexible manner the attenuation of electric and magnetic fields.

An arrangement for compensating disturbance voltages induced in a transformer is disclosed. In an embodiment an arrangement includes a transformer component comprising a transformer winding and an ancillary apparatus, wherein the ancillary apparatus comprises an auxiliary winding, wherein the auxiliary winding is connected in series with the transformer winding, and wherein the ancillary apparatus is arranged and designed such that an interference voltage induced in the transformer component is reduced by a counter-voltage induced in the ancillary apparatus.

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.

A stationary induction electrical apparatus includes a disc winding having a structure in which a flow path for a cooling medium is provided between coils where a low voltage is generated between shield wires, an L-shaped insulation barrier is provided between coils where a high voltage is generated between the shield wires, a horizontal portion of the L-shaped insulation barrier is provided so as to closely contact an upper surface or a lower surface of the disc coil, a tip end portion in an axial direction of the L-shaped insulation barrier is provided so as to closely contact an inner surface of the disc coil which is adjacent to a pressboard insulation cylinder, and a height of the tip end portion in the axial direction is lower than a thickness of one coil.

A stationary induction apparatus includes a main body tank and a stationary induction apparatus main body. The main body is accommodated in the tank. An electrostatic shield ring is placed on the upper and lower end parts of a winding. An electrostatic shield ring has a magnetic ring and two insulating rings vertically fixing the magnetic ring for a spool. A conductive tape is laid on an insulating tape. These tapes are wound around the spool. An insulating tape is wound around the wound tapes. The width of the insulating tape is equal to or greater than the width of the conductive tape. One end of the conductive tape is connected to one end part of the winding and to the magnetic ring. A gap is provided at at least one place on the magnetic ring. The winding direction of the conductive tape is inverted at at least one place.

Shielded electrical transformers and power converters using those transformers are disclosed. In some implementations, a shielded electrical transformer includes a magnetic core, a primary winding, a first secondary winding, and a second secondary winding. The transformer includes a first shielding winding that has a same voltage potential direction as the primary winding and is connected in series with the primary winding to carry current that passes through the primary winding. The transformer also includes a second shielding winding that has a voltage potential direction opposite the primary winding and is connected from primary ground to a floating terminal. The first secondary winding, the second secondary winding, the first shielding winding, and the second shielding winding can each have an approximately equal number of turns.

A resonant high current density transformer with an improved structure includes a secondary insulating bobbin, a primary insulating bobbin and a core assembly. The secondary insulating bobbin includes a base. Two posts extend from a first side of the base, and a raised plate extends from a second side of the base, the second side is opposite to the first side. The two posts and the raised plate form a receiving space for receiving an insulating sheath having a plurality of sleeves. A secondary winding is provided on each of the sleeve. The primary insulating bobbin having a tunnel is provided at one side of the secondary insulating bobbin. The surface of the primary insulating bobbin is provided with a primary winding and covered by an insulating cover. A core assembly includes a first core and a second core. A first primary core column and a second primary core column opposite to each other extend from a side of the first and second cores, respectively, and a plurality of first secondary core columns and a plurality of second secondary core columns extend from another side of the first and second cores, respectively. The first primary core column and the second primary core column are inserted into the tunnel of the primary insulating bobbin, while each of the first secondary core columns and each of the second secondary core columns are inserted into a corresponding one of the sleeves. As a result, the secondary windings are capable of withstanding large current. Their overall length covers the air gap of the core assembly, thus achieving magnetic shielding. Meanwhile, production and assembly processes are simplified.

Active electromagnetic shielding for dynamic high power wireless charging and related electrified roadway systems, method, and wireless power transmitters is disclosed. A wireless power transmitter includes a first canceling coil offset from a power transmission coil, a second canceling coil offset from the power transmission coil, and circuitry electrically connected to the first canceling coil and the second canceling coil. The circuitry is configured to deliver canceling currents to the first canceling coil and the second canceling coil to destructively interfere with portions of electromagnetic fields generated by the power transmission coil.

A planar transformer includes: a first primary coil in a first layer of a printed circuit board (PCB); a first secondary coil in one or more second layers in the PCB; and a second secondary coil in the one or more second layers.