Abstract: A coil component includes a core including a winding core portion and a pair of flange portions provided at both ends of the winding core portion, electrode portions provided in the flange portions, a wire wound around the winding core portion, and a magnetic plate fixed to the flange portions. The magnetic plate includes an annular first planar portion, a second planar portion that is located inside the inner circumference of the first planar portion and has a step between the first and the second planar portions, and a connection surface portion connecting the inner circumference of the first planar portion to the outer circumference of the second planar portion. The connection surface portion is configured by annularly disposing at least three slopes inclined with respect to the direction orthogonal to the first planar portion and has chamfered portions each being disposed between adjacent slopes.

Abstract: A coil component includes a core including a winding core portion and a pair of flange portions provided at both ends of the winding core portion, electrode portions provided in the flange portions, a wire wound around the winding core portion, and a magnetic plate fixed to the flange portions. The magnetic plate includes an annular first planar portion, a second planar portion that is located inside the inner circumference of the first planar portion and has a step between the first and the second planar portions, and a connection surface portion connecting the inner circumference of the first planar portion to the outer circumference of the second planar portion. The connection surface portion is configured by annularly disposing at least three slopes inclined with respect to the direction orthogonal to the first planar portion and has chamfered portions each being disposed between adjacent slopes.

Abstract: A coil component includes a core including a winding core portion and a pair of flange portions provided at both ends of the winding core portion, electrode portions provided in the flange portions, a wire wound around the winding core portion, and a magnetic plate fixed to the flange portions. The magnetic plate includes an annular first planar portion, a second planar portion that is located inside the inner circumference of the first planar portion and has a step between the first and the second planar portions, and a connection surface portion connecting the inner circumference of the first planar portion to the outer circumference of the second planar portion. The connection surface portion is configured by annularly disposing at least three slopes inclined with respect to the direction orthogonal to the first planar portion and has chamfered portions each being disposed between adjacent slopes.

Abstract: An arc welding method which suppresses sputtering and which makes it possible to obtain a smooth bead penetration surface shape as in MIG or MAG welding, without producing undercuts or bumping beads. A carbon dioxide gas welding method effecting welding at welding rates of about not less than 1.

Abstract: A welding voltage is determined based on an expression, P=k2×Vw2+k3×Vw, where, with a welding wire feed speed and a welding wire radius used as inputs, a power factor is P(kW), the a melting speed of a welding wire is Vw(g/sec), and k2 and k3 are constants(k2=0.898 and k3=4.625).

Abstract: The welding method according to the present invention is adapted to carry out a welding operation by feeding a welding wire to a material to be welded, and generating an arc between the material to be welded and welding wire, in which the welding is done with the welding wire feeding speed increased and reduced during the welding operation, the welding wire feeding speed being reduced after the occurrence of short-circuiting is detected, the welding wire feeding speed being increased after the cancellation of the short-circuiting and the transfer of the welding operation to the formation of the arc are detected.

Abstract: An arc welding method which suppresses sputtering and which makes it possible to obtain a smooth bead penetration surface shape as in MIG or MAG welding, without producing undercuts or bumping beads. A carbon dioxide gas welding method effecting welding at welding rates of about not less than 1.