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MnZn FERRITE CORE AND MANUFACTURING METHOD THEREFOR
A Mn-Zn ferrite core includes a basic component, sub-components, and unavoidable impurities, wherein, as the sub-components, silicon oxide (in terms of SiO 2 ): 50 to 400 mass ppm and calcium oxide (in terms of CaO): 50 to 4000 mass ppm are added to the basic component consisting of iron oxide (in terms of Fe 2 O 3 ): 51.0 to 54.5 mol%, zinc oxide (in terms of ZnO): 8.0 to 12.0 mol%, and manganese oxide (in terms of MnO): balance; amounts of phosphorus, boron, sulfur, and chlorine in the unavoidable impurities are reduced as follows, phosphorus: less than 3 mass ppm, boron: less than 3 mass ppm, sulfur: less than 5 mass ppm, and chlorine: less than 10 mass ppm; and a ratio of a measured specific surface of the Mn-Zn ferrite core to an ideal specific surface of the Mn-Zn ferrite core satisfies formula (1) below Measured specific surface / ideal specific surface < 1500 where the measured specific surface represents a specific surface (m 2 /g) determined by a BET method (multipoint method) in JIS Z 8830 (2001); and the ideal specific surface represents a specific surface (m 2 /g) calculated from size and mass of the core on an assumption that the core is in an ideal state of having no cavities. This Mn-Zn ferrite core has a higher incremental permeability µ at a high temperature and in a high magnetic field than existing Mn-Zn ferrite cores. The Mn-Zn ferrite core has excellent characteristics in which, under the application of a direct-current magnetic field of 80 A/m, the incremental permeability µ is continuously 400 or more in a wide temperature range of 0 to 85°C and the incremental permeability µ at 65°C is 700 or more.
MnZn FERRITE CORE AND MANUFACTURING METHOD THEREFOR
A Mn-Zn ferrite core includes a basic component, sub-components, and unavoidable impurities, wherein, as the sub-components, silicon oxide (in terms of SiO 2 ): 50 to 400 mass ppm and calcium oxide (in terms of CaO): 50 to 4000 mass ppm are added to the basic component consisting of iron oxide (in terms of Fe 2 O 3 ): 51.0 to 54.5 mol%, zinc oxide (in terms of ZnO): 8.0 to 12.0 mol%, and manganese oxide (in terms of MnO): balance; amounts of phosphorus, boron, sulfur, and chlorine in the unavoidable impurities are reduced as follows, phosphorus: less than 3 mass ppm, boron: less than 3 mass ppm, sulfur: less than 5 mass ppm, and chlorine: less than 10 mass ppm; and a ratio of a measured specific surface of the Mn-Zn ferrite core to an ideal specific surface of the Mn-Zn ferrite core satisfies formula (1) below Measured specific surface / ideal specific surface < 1500 where the measured specific surface represents a specific surface (m 2 /g) determined by a BET method (multipoint method) in JIS Z 8830 (2001); and the ideal specific surface represents a specific surface (m 2 /g) calculated from size and mass of the core on an assumption that the core is in an ideal state of having no cavities. This Mn-Zn ferrite core has a higher incremental permeability µ at a high temperature and in a high magnetic field than existing Mn-Zn ferrite cores. The Mn-Zn ferrite core has excellent characteristics in which, under the application of a direct-current magnetic field of 80 A/m, the incremental permeability µ is continuously 400 or more in a wide temperature range of 0 to 85°C and the incremental permeability µ at 65°C is 700 or more.
MnZn FERRITE CORE AND MANUFACTURING METHOD THEREFOR
MnZn-FERRITKERN UND VERFAHREN ZU SEINER HERSTELLUNG
NOYAU DE FERRITE DE MnZn ET SON PROCÉDÉ DE FABRICATION
YOSHIDA HIROFUMI (author) / NAKAMURA YUKIKO (author) / GOTO SATOSHI (author)
2017-10-25
Patent
Electronic Resource
English
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