Abstract: A coil component includes a winding part and a magnetic base body. The winding part is constituted by a wound conductor. The magnetic base body includes a first magnetic portion and a second magnetic portion. The first magnetic portion has first metallic particles bonded together. An average particle diameter of the first metallic particles is a first particle diameter. The second magnetic portion has second metallic particles bonded together. An average particle diameter of the second metallic particles is a second particle diameter. The magnetic base body encapsulates the winding part. The second particle diameter is larger than the first particle diameter. At least a portion of the first magnetic portion is present around the winding part.

Abstract: A coil component comprises a coil conductor including a circling portion extending around a coil axis, a base body covering the circling portion, a first external electrode, and a second external electrode. The base body has a first surface intersecting the coil axis, a second surface opposite to the first surface, and an outer surface including a connecting surface connecting the first surface with the second surface. The outer surface of the base body includes a main body portion and at least one high resistance portion. The high resistance portion occupies an area of the connecting surface between the first external electrode and the second external electrode, other than the part occupied by the main body portion. The area extends along an entire length of a circumference of the base body around the coil axis. The high resistance portion has a higher volume resistivity than the main body portion.

Abstract: A coil component according to one or more embodiments of the invention includes a base body containing a plurality of metal magnetic particles, a coil conductor, and an external electrode. In one or more embodiments, the coil conductor has a coil portion disposed inside the base body, and an end surface exposed from a first surface of the base body. The coil conductor is configured such that the ratio of the dimension of a section of the coil portion in a short axis direction to the dimension of the end surface in a short axis direction is 0.5 to 0.95, the section of the coil portion is orthogonal to the direction in which current flows through the coil portion. In one or more embodiments, the external electrode is provided on the first surface such that it is connected to the end surface of the lead-out portion.

Abstract: Disclosed is a laminated inductor that has good direct current superimposition characteristics, does not cause a variation in temperature characteristics, suppresses the occurrence of delamination, and can be stably manufactured. Also disclosed are a method for manufacturing the laminated inductor and a laminated choke coil. A laminated inductor (10) for use as a choke coil in a power supply circuit includes a rectangular parallelepiped-shaped laminated chip (1) and at least one pair of external electrodes (8) that are provided at the end of the laminated chip (1) and are conductively connected to the end of a coil. The laminated chip (1) includes a plurality of magnetic material layers (3) formed of an Ni—Zn—Cu ferrite, a plurality of conductive layers (2), which are laminated through the magnetic material layers (3) to constitute a coil, and at least one nonmagnetic layer (4) formed of a Ti—Ni—Cu—Mn—Zr—Ag-base dielectric material and formed in contact with a plurality of the magnetic material layers (3).

Abstract: Disclosed is a laminated inductor that has good direct current superimposition characteristics, does not cause a variation in temperature characteristics, suppresses the occurrence of delamination, and can be stably manufactured. Also disclosed are a method for manufacturing the laminated inductor and a laminated choke coil. A laminated inductor (10) for use as a choke coil in a power supply circuit includes a rectangular parallelepiped-shaped laminated chip (1) and at least one pair of external electrodes (8) that are provided at the end of the laminated chip (1) and are conductively connected to the end of a coil. The laminated chip (1) includes a plurality of magnetic material layers (3) formed of an Ni—Zn—Cu ferrite, a plurality of conductive layers (2), which are laminated through the magnetic material layers (3) to constitute a coil, and at least one nonmagnetic layer (4) formed of a Ti—Ni—Cu—Mn—Zr—Ag-base dielectric material and formed in contact with a plurality of the magnetic material layers (3).

Abstract: A multi layer inductor using an Ni—Zn—Cu ferrite, which has an improved temperature characteristic and is free from structural defects, is provided, and a method for manufacturing the multi layer inductor is also provided. The multi layer inductor is characterized by including a laminate 1 having a rectangular parallelepiped shape, which is provided with a plurality of magnetic layers 3,3 composed of an Ni—Zn—Cu ferrite, a plurality of conductor layers 2,2 forming a coil upon being laminated via the magnetic layers and at least one non-magnetic layer 4 formed so as to come into contact with the plurality of magnetic layers 3,3 and composed of a Ti—Ni—Cu—Mn—Zr-based dielectric substance; and at least a pair of external electrodes 7,7 provided on the ends of the laminate 1 and conductively connected to the ends of the coil.

Abstract: In a hybrid module which is mounted on a mother circuit board with a first surface of a substrate opposed to the mother circuit board, a cavity is formed on the first surface, and a heat-generating circuit component is facedown-bonded in the cavity. Heat generated in the circuit component is radiated to the mother circuit board through a heat radiation plate.