An alloy composition, a Fe-based nano-crystalline alloy and a manufacturing method thereof, and a magnetic component are disclosed. The expression of the alloy composition is Fe.sub.aV.sub.αB.sub.bSi.sub.cP.sub.xC.sub.yCu.sub.z and 79≤a≤91 at %, 5≤b≤13 at %, 0≤c≤8 at %, 1≤x≤8 at %, 0≤y≤5 at %, 0.4≤z≤1.4 at %, 0<α<5 at % and 0.08≤z/x≤0.8(at % is atomic percent). The Fe-based nano-crystalline alloy is manufactured by subjecting the alloy composition to crystallization heat treatment. Even if the heating speed upon crystallization heat treatment is slow, or there is a deviation in the temperature reached, a Fe-based nano-crystalline alloy with high saturation magnetic induction intensity and excellent soft magnetic property can still be easily obtained from the alloy ingredients of the present invention. Moreover, the present invention provides a magnetic component manufactured using the Fe-based nano-crystalline alloy.

A motor includes: a stator that includes a laminated group of soft magnetic alloy strips that are laminated and is fastened to a base by a bolt that penetrates the laminated group in a direction of laminating the soft magnetic alloy strips; and a rotor that is rotatably installed on the base. A resin layer is provided at least on a laminated end surface closest to the bolt, in the laminated end surface of the stator.

A motor includes: a stator that includes a laminated group of soft magnetic alloy strips that are laminated and is fastened to a base by a bolt that penetrates the laminated group in a direction of laminating the soft magnetic alloy strips; and a rotor that is rotatably installed on the base. A resin layer is provided at least on a laminated end surface closest to the bolt, in the laminated end surface of the stator.

A laminated core that enables reducing an eddy-current loss while reducing a decrease in space factor is provided. The laminated core includes a plurality of laminated soft magnetic strips and at least one insulating layer arranged in part of each interface between the soft magnetic strips adjacent to one another. Each of the interfaces between the soft magnetic strips adjacent to one another includes at least one direct contact region and at least one indirect contact region. The soft magnetic strips adjacent to one another are in direct contact with one another in the at least one direct contact region. The soft magnetic strips adjacent to one another are in indirect contact with one another via the insulating layer in the at least one indirect contact region.

A laminated core that enables reducing an eddy-current loss while reducing a decrease in space factor. The laminated core includes laminated soft magnetic strips with at least one patterned soft magnetic strip having a first surface. The first surface includes at least one protruding portion having a top surface. The top surface of the at least one protruding portion contacts a surface opposed to the first surface. The surface opposed to the first surface is included in a surface of one of the soft magnetic strips, which is adjacent to the at least one patterned soft magnetic strip. A gap is present between the surface opposed to the first surface and a part of the first surface, the part being other than the top surface

[PROBLEM] To provide a wound magnetic core and a method for manufacturing a wound magnetic core permitting improvement of insulation between ribbon layers in a wound magnetic core at which soft magnetic metal ribbon has been wound to form an annular wound body.

[SOLUTION MEANS] A nonmagnetic insulating metal oxide powder is made to adhere to a surface of a soft magnetic metal ribbon having an amorphous structure; this is wound in annular fashion and made into a wound body at which the metal oxide powder intervenes between ribbon layers; the wound body is made to undergo heat treatment in a nonoxidizing atmosphere; the wound body is thereafter subjected to treatment for formation of an oxide film in an oxidizing atmosphere adjusted to be at a temperature lower than that at the heat treatment to cause oxidation of the surface of the soft magnetic metal ribbon; and spaces between ribbon layers at the wound body are moreover impregnated with resin and curing is carried out to fuse the metal oxide powder thereto.

An alloy ribbon that is an alloy ribbon containing a metal as a main component, and has a recess on at least one principal surface, in which a depth of the recess is 5% or more and 75% or less of an average thickness.

An alloy ribbon that is an alloy ribbon containing a metal as a main component, and has a recess on at least one principal surface, in which a depth of the recess is 5% or more and 75% or less of an average thickness.

The object of the present invention is to provide an alloy ribbon capable of having excellent adhesiveness between the alloy ribbons when a plurality of the alloy ribbons is stacked; and also, to provide a magnetic core using the alloy ribbon. The present invention is an alloy ribbon comprising metals scattered on at least one surface of the alloy ribbon, in which diameters of the scattered metals are 1 μm or more, and the scattered metals include Cu.

The object of the present invention is to provide an alloy ribbon capable of having excellent adhesiveness between the alloy ribbons when a plurality of the alloy ribbons is stacked; and also, to provide a magnetic core using the alloy ribbon. The present invention is an alloy ribbon comprising metals scattered on at least one surface of the alloy ribbon, in which diameters of the scattered metals are 1 μm or more, and the scattered metals include Cu.