A connector includes: a plurality of conductors; a magnetic core; a housing; and an insulator that locates a core assembling portion therein, the core assembling portion being composed of the respective intermediate portions of the plurality of conductors and the magnetic core, the housing chamber is at least partitioned into a first space in which the core assembling portion is housed and a second space in which the first electrical connection portion and the first counterpart conductor side are housed and are physically and electrically connected to each other, and the insulator is a solidified material of a liquid insulating potting agent filled in the vicinity of the core assembling portion in the first space in order to cover the core assembling portion.

A connector includes: a plurality of conductors; a magnetic core; a housing; and an insulator that locates a core assembling portion therein, the core assembling portion being composed of the respective intermediate portions of the plurality of conductors and the magnetic core, the housing chamber is at least partitioned into a first space in which the core assembling portion is housed and a second space in which the first electrical connection portion and the first counterpart conductor side are housed and are physically and electrically connected to each other, and the insulator is a solidified material of a liquid insulating potting agent filled in the vicinity of the core assembling portion in the first space in order to cover the core assembling portion.

An alloy having a formula Fe.sub.aCo.sub.bNi.sub.cCu.sub.dM.sub.eSi.sub.fB.sub.gX.sub.h is provided. M is at least one of V, Nb, Ta, Ti, Mo, W, Zr, Cr, Mn and Hf; a, b, c, d, e, f, g are in at. %; X denotes impurities and optional elements P, Ge and C; and a, b, c, d, e, f, g, h satisfy the following: 0b4, 0c<4, 0.5d2, 2.5e3.5, 14.5f16, 6g7, h<0.5, and 1(b+c)4.5, where a+b+c+d+e+f+g=100.
The alloy has a nanocrystalline microstructure, a saturation magnetostriction of |s|1 ppm, a hysteresis loop with a central linear part, and a permeability () of 10,000 to 15,000.

A radial-gap-type rotary electric machine, a production method therefore, a production device for a rotary electric machine teeth piece, and a production method therefore can achieve a high efficiency and have excellent productivity. A radial-gap-type rotary electric machine includes a rotation shaft, a rotator including an inner-peripheral-side rotator iron core rotatable around the rotation shaft and an outer-peripheral-side rotator iron core arranged on an outer peripheral side of the inner-peripheral-side rotator iron core and rotatable around the rotation shaft, and a stator disposed between the inner-peripheral-side rotator iron core and the outer-peripheral-side rotator iron core. A permanent magnet is provided on at least one of an outer-peripheral-side surface of the inner-peripheral-side rotator iron core and an inner-peripheral-side surface of the outer-peripheral-side rotator iron core. The stator includes a stator iron core including teeth formed of laminated bodies where amorphous metal foil strip pieces are held with mutual friction.

Provided is a method of manufacturing a laminated core for stably fixing a thin core piece while suppressing reduction in production efficiency, and an inner core and an outer core with core pieces stably fixed. A method of manufacturing a laminated core for manufacturing an inner core 10 includes: a step A of laminating a plurality of core pieces 11 and temporarily fixing each of the core pieces to another core piece 11 to obtain a core piece group 16; a step B of fitting the core piece group 16 to a holder 17; a step C of applying an uncured curable resin P to an outer peripheral region of the core piece group 16; and a step D of curing the curable resin P applied to the core piece group 16 and fully fixing each of the core pieces 11 to another core piece 11.

Provided is a method of manufacturing a laminated core for stably fixing a thin core piece while suppressing reduction in production efficiency, and an inner core and an outer core with core pieces stably fixed. A method of manufacturing a laminated core for manufacturing an inner core 10 includes: a step A of laminating a plurality of core pieces 11 and temporarily fixing each of the core pieces to another core piece 11 to obtain a core piece group 16; a step B of fitting the core piece group 16 to a holder 17; a step C of applying an uncured curable resin P to an outer peripheral region of the core piece group 16; and a step D of curing the curable resin P applied to the core piece group 16 and fully fixing each of the core pieces 11 to another core piece 11.

A magnet core for low-frequency applications and method for producing a magnet core for low-frequency applications is provided. The magnet core is made of a spiral-wound, soft-magnetic, nanocrystalline strip. The strip essentially has the alloy composition Fe.sub.RestCo.sub.aCu.sub.bNb.sub.cSi.sub.dB.sub.eC.sub.f, wherein a, b, c, d, e and f are stated in atomic percent and 0a1; 0.7b1.4; 2.5c3.5; 14.5d16.5; 5.5e8 and 0f1, and cobalt may wholly or partially be replaced by nickel. The magnet core has a saturation magnetostriction .sub.s of .sub.s<2 ppm, a starting permeability .sub.1 of .sub.1>100 000 and a maximum permeability .sub.max of .sub.max>400 000. In addition, a sealing metal oxide coating is provided on the surfaces of the strip.

A sensor may include a core and a coil. The core may include a rectangular substrate, a layer of magnetically-permeable material disposed on the substrate, and an adhesive rigidly coupling two ends of the substrate so as to form a tube with the rectangular substrate. The coil may be wound on the tube. The core may further include a layer of radiopaque material. The core may further include a flex pad for electrically coupling the coil with an external system.

A sensor may include a core and a coil. The core may include a rectangular substrate, a layer of magnetically-permeable material disposed on the substrate, and an adhesive rigidly coupling two ends of the substrate so as to form a tube with the rectangular substrate. The coil may be wound on the tube. The core may further include a layer of radiopaque material. The core may further include a flex pad for electrically coupling the coil with an external system.

After an first heat treatment step, an ambient temperature of a stack is held so that the stack is kept in a temperature range that allows the stack to be crystallized by heating the end of the stack to a second temperature range in the second heat treatment step; and a following expression (1) is satisfied, where Q1 represents an amount of heat required to heat the stack to the first temperature range in the first heat treatment step, Q2 represents an amount of heat that is applied to the stack when heating the end of the stack to the second temperature range in the second heat treatment step, Q3 represents an amount of heat that is released during crystallization of the stack, and Q4 represents an amount of heat required to heat the entire stack to the crystallization start temperature

Q1+Q2+Q3Q4(1).