The present invention is an inductor element having a conductor wound in a coil form, and a core part surrounding the coil and including a magnetic powder and a resin. The core part includes a top board part and a bottom board part respectively covering both ends of the coil, and an outer circumference part positioned at an outer circumference side of the coil, and a resin content of the outer circumference part is larger than a resin content of the top board part and also larger than a resin content of the bottom board part.

An inductor includes an integrated preform having a coil installed thereinside. The coil includes extension portions extending from two stages of a spiral wound portion. The integrated preform is formed by bonding together first and second preforms. The first and/or second preform is shaped like a housing including a plate-shaped bottom, a wall provided around the periphery of the bottom portion, and two cut out portions provided in the wall. The extension portions extend to outside the integrated preform via the cut out portions. The difference between a first distance from a reference surface, which is the bottom surface of the bottom of the first or second preform, to a bottom surface of one cut out portion and a second distance from the reference surface to the bottom surface of the other cut out portion is substantially an integer multiple of the width of the flat wire.

An inductor includes an integrated preform having a coil installed thereinside. The coil includes extension portions extending from two stages of a spiral wound portion. The integrated preform is formed by bonding together first and second preforms. The first and/or second preform is shaped like a housing including a plate-shaped bottom, a wall provided around the periphery of the bottom portion, and two cut out portions provided in the wall. The extension portions extend to outside the integrated preform via the cut out portions. The difference between a first distance from a reference surface, which is the bottom surface of the bottom of the first or second preform, to a bottom surface of one cut out portion and a second distance from the reference surface to the bottom surface of the other cut out portion is substantially an integer multiple of the width of the flat wire.

Provided is an iron-based soft magnetic powder for dust cores that enables production of a dust core having high density and low iron loss. An iron-based soft magnetic powder for dust cores comprises: an iron-based soft magnetic powder; a condensed aluminum phosphate layer on particle surfaces of the iron-based soft magnetic powder; and a silicone resin layer on a surface of the condensed aluminum phosphate layer, wherein the condensed aluminum phosphate layer is a continuous coating, and a total mass of the condensed aluminum phosphate layer and the silicone resin layer is 0.60 mass % or less with respect to 100 mass % of a total mass of the iron-based soft magnetic powder, the condensed aluminum phosphate layer, and the silicone resin layer.

A coil component according to one aspect is provided with a core containing a plurality of soft magnetic metal particles, a winding wire wound on the core, and a sheathing body provided on the core so as to cover at least part of the winding wire and having a relative magnetic permeability smaller than that of the core.

A coil component according to one aspect is provided with a core containing a plurality of soft magnetic metal particles, a winding wire wound on the core, and a sheathing body provided on the core so as to cover at least part of the winding wire and having a relative magnetic permeability smaller than that of the core.

A magnetic particle includes a magnetic metal particle having a plurality of phases. The plurality of phases include an Fe-based phase and an Fe.sub.3O.sub.4 phase. An area ratio of the Fe.sub.3O.sub.4 phase in which the Fe.sub.3O.sub.4 phase occupies in the plurality of phases is less than 50%.

An embodiment provides a coil component including a base body, and a coil conductor provided in the base body. At least partial region of the base body contains (i) a plurality of first metal magnetic particles having a first aspect ratio greater than one and having a first average particle size and (ii) a plurality of second metal magnetic particles having a second aspect ratio greater than the first aspect ratio, having a second average particle size less than the first average particle size. The first and second metal magnetic particles are oriented in a reference direction in the base body.

A rod-shaped magnetic core element, having a first end with a spherical or cylindrical recess or a spherical or cylindrical connecting protrusion, and a second end with a spherical or cylindrical recess or a spherical or cylindrical connecting protrusion so that a bent connection of at least two magnetic core elements is variably adjustable. Magnetic core elements comprising spherical or cylindrical magnetic core ends of this type allow a nearly gap-free construction with little magnetic leakage due to slightly larger end surfaces in comparison with ferrite rods having beveled plane end section surfaces. The enlarged end surface of the spherical surface advantageously allows a more stable connection of individual magnetic core elements without adhesive bonding. This allows the construction of flexible, multiple-member and inexpensive rod core coils and antennae.

A rod-shaped magnetic core element, having a first end with a spherical or cylindrical recess or a spherical or cylindrical connecting protrusion, and a second end with a spherical or cylindrical recess or a spherical or cylindrical connecting protrusion so that a bent connection of at least two magnetic core elements is variably adjustable. Magnetic core elements comprising spherical or cylindrical magnetic core ends of this type allow a nearly gap-free construction with little magnetic leakage due to slightly larger end surfaces in comparison with ferrite rods having beveled plane end section surfaces. The enlarged end surface of the spherical surface advantageously allows a more stable connection of individual magnetic core elements without adhesive bonding. This allows the construction of flexible, multiple-member and inexpensive rod core coils and antennae.