US 12,283,411 B2
Method for crystallization heat treating a stack of amorphous alloy ribbons
Yu Takanezawa, Nissin (JP); Tomohiro Takao, Toyota (JP); Hideki Manabe, Toyota (JP); Shinichi Hiramatsu, Okazaki (JP); and Kensuke Komori, Toyota (JP)
Assigned to TOYOTA JIDOSHA KABUSHIKI KAISHA, Toyota (JP)
Filed by TOYOTA JIDOSHA KABUSHIKI KAISHA, Toyota (JP)
Filed on Dec. 23, 2019, as Appl. No. 16/725,028.
Claims priority of application No. 2019-002952 (JP), filed on Jan. 10, 2019.
Prior Publication US 2020/0224286 A1, Jul. 16, 2020
This patent is subject to a terminal disclaimer.
Int. Cl. H01F 41/02 (2006.01); C22C 45/02 (2006.01); H01F 1/153 (2006.01); H01F 27/25 (2006.01)
CPC H01F 27/25 (2013.01) [C22C 45/02 (2013.01); H01F 1/15333 (2013.01); H01F 41/0226 (2013.01); C21D 2201/03 (2013.01)] 5 Claims
OG exemplary drawing
 
1. A method for crystallizing a stack of a plurality of alloy ribbons, comprising:
a preparation step of preparing a stack of a plurality of amorphous alloy ribbons;
a first heat treatment step of heating the stack to a first temperature range lower than a crystallization start temperature of the amorphous alloy ribbons; and
a second heat treatment step of heating an end of the stack in a stacking direction by a heat source to a second temperature range equal to or higher than the crystallization start temperature after the first heat treatment step, wherein:
after the first heat treatment step, an ambient temperature of the 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 the second temperature range in the second heat treatment step;
in the second heat treatment step, a first amorphous alloy ribbon at the end of the stack is heated to the second temperature range while the stack other than the first amorphous alloy ribbon is kept in a temperature range lower than the crystallization start temperature, and heat released due to crystallization repeatedly occurs so as to propagate from the first amorphous alloy ribbon at the end of the stack to an amorphous alloy ribbon located at an opposite end of the stack from the first amorphous alloy ribbon, and
the heat released due to crystallization is dissipated from an outer surface of the opposite end of the stack by a heat dissipating member.