In at least some implementations, a lamination stack includes a plurality of plates coupled together, each plate including at least one leg that collectively define a leg of the stack, with the leg of the stack arranged so that a wire coil may be arranged on the leg of the stack, and wherein the leg of the stack includes a location feature arranged to facilitate location of the stack relative to an adjacent component. In at least some implementations, the location feature may be integrally formed with at least one of the plates, and may be defined by a projection extending from a free end of at least one leg of the stack.

A receiver for a wireless charging system, capable of receiving power energy using non-contact type magnetic induction, includes a coil capable of receiving the power energy and a part for generating a predetermined output power from the power energy received by the coil, a portable terminal, an NFC coil further provided outside of the coil, and a ferrite sheet further provided at the coil and the NFC coil.

A receiver for a wireless charging system, capable of receiving power energy using non-contact type magnetic induction, includes a coil capable of receiving the power energy and a part for generating a predetermined output power from the power energy received by the coil, a portable terminal, an NFC coil further provided outside of the coil, and a ferrite sheet further provided at the coil and the NFC coil.

A coil component includes a body and a coil conductor embedded in the body. The body includes a magnetic layer and a non-magnetic layer. The magnetic layer is formed of a composite material including a metal particle and a resin material, and the non-magnetic layer is arranged not to extend through a winding portion of the coil conductor or not to entirely extend through the body.

A coil component includes a body and a coil conductor embedded in the body. The body includes a magnetic layer and a non-magnetic layer. The magnetic layer is formed of a composite material including a metal particle and a resin material, and the non-magnetic layer is arranged not to extend through a winding portion of the coil conductor or not to entirely extend through the body.

A coil component includes: a coil embedded in a substrate body and having a winding part constituted by a wound conductor; wherein the substrate body has: a first region sandwiched between one end surface of the substrate body and a plane parallel with the one end surface and running through a portion of a first external electrode farthest away from the one end surface; a second region sandwiched between another end of the substrate body and a plane parallel with the another end surface and running through a portion of a second external electrode farthest away from the another end surface; and a third region between the first region and the second region; and the winding part is provided in the third region, and also in the first region where it is wound by one turn or more.

A magnetic core for a current sensor is provided. The magnetic core comprises a first and a second core part, each of which is formed from a stack made up of a plurality of sheet metal layers. The second core part has a first end piece structured such that some of the sheet metal layers are longer and protrude beyond the remaining, shorter sheet metal layers. The first core part has a second end piece which is structured inversely to the first end piece of the second core part. The first core part and the second core part are joined together at a connection point such that the longer sheet metal layers of the first end piece and the second end piece overlap at the connection point, wherein the overlap takes place at a number of interfaces that is at least two less than the number of sheet metal layers.

A magnetic core for a current sensor is provided. The magnetic core comprises a first and a second core part, each of which is formed from a stack made up of a plurality of sheet metal layers. The second core part has a first end piece structured such that some of the sheet metal layers are longer and protrude beyond the remaining, shorter sheet metal layers. The first core part has a second end piece which is structured inversely to the first end piece of the second core part. The first core part and the second core part are joined together at a connection point such that the longer sheet metal layers of the first end piece and the second end piece overlap at the connection point, wherein the overlap takes place at a number of interfaces that is at least two less than the number of sheet metal layers.

A modularized transformer includes an annular iron core, a first module encircling the annular iron core, a second module encircling the first module, a third module encircling the second module, a fourth module encircling the third module, and a primary-side power supply line mounted on the fourth module and encircling the annular iron core. Thus, the modularized transformer has a modularized structure and includes multiple modules that are extended and increased to amplify the voltage or current continuously and to regulate the voltage or current.

A modularized transformer includes an annular iron core, a first module encircling the annular iron core, a second module encircling the first module, a third module encircling the second module, a fourth module encircling the third module, and a primary-side power supply line mounted on the fourth module and encircling the annular iron core. Thus, the modularized transformer has a modularized structure and includes multiple modules that are extended and increased to amplify the voltage or current continuously and to regulate the voltage or current.