In an embodiment, a multilayer ceramic capacitor 10 includes external electrodes 12 on both of first-direction ends of a capacitor body 11. Also, groups of metal grains 13 are provided on one third-direction face and another third-direction face of the capacitor body 11. Both of the first-direction ends of the groups of metal grains 13 provided on the other third-direction face of the capacitor body 11 are covered by second parts 12c of the respective external electrodes 12, while both of the first-direction ends of the groups of metal grains 13 provided on the one third-direction face of the capacitor body 11 are covered by first parts 12b of the respective external electrodes 12. The multilayer ceramic electronic component can offer excellent heat dissipation property.

The utility model relates to an electric driver and an illumination device. The electric driver comprises: a carrier; a first electrical component and a second electrical component, wherein the first electrical component and the second electrical component are provided on the carrier; and a heat insulation structure, wherein the second electrical component comprises a first heat insulator surrounding the second electrical component and a second heat insulator surrounding the first heat insulator, wherein a gap is provided between the first heat insulator and a second heat insulator. The electric driver according to the present utility model improves the lifetime of capacitors, is low-cost, and has a compact structure.

An electronic component includes a first capacitor including a first dielectric material having a permittivity that is inversely proportional to temperature; and a second capacitor connected in parallel with the first capacitor and including a second dielectric material having a permittivity that is directly proportional to temperature.

An electronic component includes a first capacitor including a first dielectric material having a permittivity that is inversely proportional to temperature; and a second capacitor connected in parallel with the first capacitor and including a second dielectric material having a permittivity that is directly proportional to temperature.

A method for manufacturing a laminated ceramic capacitor having a laminated body including a plurality of stacked ceramic layers and internal electrodes located between the ceramic layers. The laminated body has a pair of mutually opposed principal surfaces extending in the direction in which the ceramic layers extend, a pair of mutually opposed side surfaces and a pair of mutually opposed end surfaces which respectively extend in directions orthogonal to the principal surfaces. The internal electrodes are 0.4 m or less in thickness, and are located in an area defined by a width-direction gap of 30 m or less interposed with respect to each of the pair of side surfaces and an outer layer thickness of 35 m or less interposed with respect to each of the pair of principal surfaces.

A method for manufacturing a laminated ceramic capacitor having a laminated body including a plurality of stacked ceramic layers and internal electrodes located between the ceramic layers. The laminated body has a pair of mutually opposed principal surfaces extending in the direction in which the ceramic layers extend, a pair of mutually opposed side surfaces and a pair of mutually opposed end surfaces which respectively extend in directions orthogonal to the principal surfaces. The internal electrodes are 0.4 m or less in thickness, and are located in an area defined by a width-direction gap of 30 m or less interposed with respect to each of the pair of side surfaces and an outer layer thickness of 35 m or less interposed with respect to each of the pair of principal surfaces.

A ceramic electronic component includes a multilayer body, an electronic component main body including first and second outer electrodes on the surface of multilayer body, a first substrate connection terminal bonded to at least one of the first outer electrode and the multilayer body by a bonding material that is electrically insulating, and a first metal terminal electrically connecting the first outer electrode and the first substrate connection terminal, in which, while the first metal terminal maintains an elastically deformed state, a first end portion thereof is bonded to the first outer electrode by an electrically conductive bonding material, and a second end portion thereof is bonded to the first substrate connection terminal by a bonding section with a different melting point from that of the bonding material.

A ceramic electronic component includes a multilayer body, an electronic component main body including first and second outer electrodes on the surface of multilayer body, a first substrate connection terminal bonded to at least one of the first outer electrode and the multilayer body by a bonding material that is electrically insulating, and a first metal terminal electrically connecting the first outer electrode and the first substrate connection terminal, in which, while the first metal terminal maintains an elastically deformed state, a first end portion thereof is bonded to the first outer electrode by an electrically conductive bonding material, and a second end portion thereof is bonded to the first substrate connection terminal by a bonding section with a different melting point from that of the bonding material.

In an embodiment, a multilayer ceramic capacitor 10 has a first metal layer 14 having many holes 14a, and a second metal layer 15 having many holes 15a, with a clearance CL provided in between in the length direction, on the other height-direction side face of the capacitor body; the first metal layer 14 is partially covered by a third part 12c of a first external electrode 12, while the remainder is exposed; and the second metal layer 15 is partially covered by a third part 13c of a second external electrode 13, while the remainder is exposed. The multilayer ceramic capacitor can have excellent heat dissipation property.

In an embodiment, a multilayer ceramic capacitor 10 has a first metal layer 14 having many holes 14a, and a second metal layer 15 having many holes 15a, with a clearance CL provided in between in the length direction, on the other height-direction side face of the capacitor body; the first metal layer 14 is partially covered by a third part 12c of a first external electrode 12, while the remainder is exposed; and the second metal layer 15 is partially covered by a third part 13c of a second external electrode 13, while the remainder is exposed. The multilayer ceramic capacitor can have excellent heat dissipation property.