Disclosed herein is a differential mode filter that includes first and second terminal electrodes provided on a first flange part of a core, and first and second wires wound around a winding core part of the core in an opposite direction to each other and connected respectively to the first and second terminal electrodes. The first and second wires cross each other on the winding core part to form a plurality of crossing portions that include first, second, and third crossing portions that are first, second, and third occurrences counting from the one end of the first and second wires, respectively. A first crossing angle between the first and second wires at the first crossing portion is larger than at least one of second and third crossing angles between the first and second wires at the second and third portions, respectively.

A common mode filter is manufactured to include a coil part including an insulation layer and a conductor pattern formed in the insulation layer; and a magnetic substrate coupled to one surface or both surfaces of the coil part. The magnetic substrate includes: an electrostatic absorbing layer made of an electrostatic absorbing material; a magnetic layer provided on one surface or both surfaces of the electrostatic absorbing layer and made of a magnetic material; and an electrode provided between the magnetic layer and the electrostatic absorbing layer and made of a conductive material. Therefore, common mode filter may maintain high efficiency characteristics while preventing an electrostatic discharge phenomenon.

Fabricating composite monolithic structures to achieve optimal electrical, thermal, and mechanical properties through the elimination of air is discussed herein. A method of fabricating a composite structure includes coating an insulating layer with an uncured binding material and performing a first curing process on the uncured binding material to form a first stage cured binding material on the insulating layer without introduction of air pockets in a conventional manufacturing atmospheric environment. The method further includes disposing the insulating layer on an array of conductive structures. The first stage cured binding material is positioned between the insulating layer and the array of conductive structures. The method further includes performing a second curing process on the first stage cured binding material to form a cured binding material, and forming cured regions between adjacent conductive structures of the array of conductive structures.

Fabricating composite monolithic structures to achieve optimal electrical, thermal, and mechanical properties through the elimination of air is discussed herein. A method of fabricating a composite structure includes coating an insulating layer with an uncured binding material and performing a first curing process on the uncured binding material to form a first stage cured binding material on the insulating layer without introduction of air pockets in a conventional manufacturing atmospheric environment. The method further includes disposing the insulating layer on an array of conductive structures. The first stage cured binding material is positioned between the insulating layer and the array of conductive structures. The method further includes performing a second curing process on the first stage cured binding material to form a cured binding material, and forming cured regions between adjacent conductive structures of the array of conductive structures.

A conical inductor provided in the present invention includes: a housing, a conical coil located inside the housing, a first pin and a second pin respectively connected to two ends of the conical coil, where one end of the first pin is connected to one end of the conical coil, the other end of the first pin is connected to a hole in a first side wall of the housing in a fastened manner, one end of the second pin is connected to the other end of the conical inductor, and the other end of the second pin is connected to a hole in a second side wall of the housing in a fastened manner; and each of the first pin and the second pin includes one segment of waveform segment fluctuating in a direction perpendicular to a top wall of the housing.

A conical inductor provided in the present invention includes: a housing, a conical coil located inside the housing, a first pin and a second pin respectively connected to two ends of the conical coil, where one end of the first pin is connected to one end of the conical coil, the other end of the first pin is connected to a hole in a first side wall of the housing in a fastened manner, one end of the second pin is connected to the other end of the conical inductor, and the other end of the second pin is connected to a hole in a second side wall of the housing in a fastened manner; and each of the first pin and the second pin includes one segment of waveform segment fluctuating in a direction perpendicular to a top wall of the housing.

An I-shaped inductor and a transformer are provided. The I-shaped inductor includes an I-shaped iron core and two coils. The I-shaped iron core includes one winding part and two connecting parts, the two connecting parts are respectively positioned on both ends of the winding part, one side of the connecting part is a connecting side, both ends of the connecting side are respectively provided with two electroplating pins, the two coils are wound on the winding part, each connecting part is connected with both ends of a corresponding coil, and ends of different coils are respectively connected to the electroplating pins on different connecting parts. The transformer includes a cover plate and at least two I-shaped inductors.

An I-shaped inductor and a transformer are provided. The I-shaped inductor includes an I-shaped iron core and two coils. The I-shaped iron core includes one winding part and two connecting parts, the two connecting parts are respectively positioned on both ends of the winding part, one side of the connecting part is a connecting side, both ends of the connecting side are respectively provided with two electroplating pins, the two coils are wound on the winding part, each connecting part is connected with both ends of a corresponding coil, and ends of different coils are respectively connected to the electroplating pins on different connecting parts. The transformer includes a cover plate and at least two I-shaped inductors.

An inductor is disclosed, including a first wire, a non-conductive material, and a shell. The non-conductive material may cover the first wire, with a portion of each end of the first wire uncovered. The shell may include a top portion and a bottom portion and include at least one magnetized layer and at least one gap between the first portion and the second portion. The shell may also surround a portion of the non-conductive material.

An inductor is disclosed, including a first wire, a non-conductive material, and a shell. The non-conductive material may cover the first wire, with a portion of each end of the first wire uncovered. The shell may include a top portion and a bottom portion and include at least one magnetized layer and at least one gap between the first portion and the second portion. The shell may also surround a portion of the non-conductive material.