Claims
- 1. A magnetic marker comprising a magnetically switchable wire formed of a magnetic material and adapted to undergo a sharp magnetic inversion, or major Barkhausen discontinuity or generation of pulses when an alternating field of an intensity higher than the coercive force thereof is applied thereto,
said magnetically switchable wire having a diameter of ø70 μm to 110 μm and a length of 40 mm or less and being formed of at least one magnetic material selected from alloys including an alloy consisting mainly of Fe and containing 3 to 5% of Si and 1 to 3% of Ni, an alloy consisting mainly of Fe and containing 3 to 6% of Si and 1 to 4% of Mo, and an alloy consisting mainly of Fe and containing 3 to 5% of Si and 1 to 3% of Co.
- 2. A magnetic marker according to claim 1, wherein said magnetically switchable wire has a structure such that primary arms of a dendrite are oriented at an angle of 10° or less to the axis of said wire.
- 3. A manufacturing method for a magnetic marker, comprising:
forming a magnetically switchable wire having a diameter of ø70 μm to 110 μm by an in-gas melt spinning method such that at least one magnetic material, selected from alloys including an alloy consisting mainly of Fe and containing 3 to 5% of Si and 1 to 3% of Ni, an alloy consisting mainly of Fe and containing 3 to 6% of Si and 1 to 4% of Mo, and an alloy consisting mainly of Fe and containing 3 to 5% of Si and 1 to 3% of Co, is melted, and the resulting molten alloy is cooled and coagulated in a cooling gas while being ejected from a nozzle; and cutting said wire to a length of 40 mm or less, thereby obtaining a magnetic marker adapted to undergo occurrence of magnetic inversion or major Barkhausen discontinuity or generation of pulses when an alternating field of intensity higher than the coercive force of said wire is applied thereto.
- 4. A manufacturing method for a magnetic marker, which manufactures a magnetically switchable wire for the magnetic marker by using:
alloy melting mechanism for melting at least one magnetic material selected from alloys including an alloy consisting mainly of Fe and containing 3 to 5% of Si and 1 to 3% of Ni, an alloy consisting mainly of Fe and containing 3 to 6% of Si and 1 to 4% of Mo, and an alloy consisting mainly of Fe and containing 3 to 5% of Si and 1 to 3% of Co; a spinning nozzle capable of forming a molten metal jet by downwardly ejecting said molten alloy in a manner such that the molten alloy falls; a gas flow cylinder located so as to surround a fall path for said molten metal jet; cooling gas introducing mechanism for introducing a cooling gas for coagulating said molten metal jet into said gas flow cylinder; and a discharge portion through which the wire obtained as said molten metal jet is coagulated is discharged from said gas flow cylinder to the outside.
- 5. A manufacturing method for a magnetic marker according to claim 4, wherein said cooling gas is an oxygen-containing gas.
- 6. A manufacturing method for a magnetic marker according to claim 4, wherein said cooling gas contains a first gas component, formed of an inert gas to be introduced into said gas flow cylinder in a first position nearer to said spinning nozzle with respect to the falling direction of said molten metal jet in said gas flow cylinder, and a second gas component, formed of an oxidative gas to be introduced into said gas flow cylinder in a second position remoter from said spinning nozzle with respect to the falling direction of said molten metal jet.
- 7. A manufacturing method for a magnetic marker according to claim 6, wherein said first gas component is argon or helium, and said second gas component is oxygen or carbon dioxide.
- 8. A magnetic marker comprising:
a magnetically switchable wire formed of a magnetic material and adapted to undergo occurrence of sharp magnetic inversion when an alternating field of intensity higher than the coercive force thereof is applied thereto; and a magnetic casing formed of a magnetically hard or semihard magnetic material, covering said magnetically switchable wire, and capable of generating a bias magnetic field to prevent magnetic inversion of said magnetically switchable wire, said magnetic casing having heat-treated portions partially differentiated in magnetic properties by heat treatment in the longitudinal direction thereof.
- 9. A magnetic marker according to claim 8, wherein said magnetically switchable wire is formed of any selected one of alloys including Fe—Si, Fe—Si—Ni, Fe—Si—Mo, and Fe—Si—Co.
- 10. A magnetic marker according to claim 8, wherein said magnetically switchable wire is formed of an alloy consisting mainly of Fe and containing 3 to 5% of Si.
- 11. A magnetic marker according to claim 8, wherein said magnetically switchable wire is formed of an alloy consisting mainly of Fe and containing 3 to 5% of Si and 1 to 3% of Ni.
- 12. A magnetic marker according to claim 8, wherein said magnetically switchable wire is formed of an alloy consisting mainly of Fe and containing 3 to 6% of Si and 1 to 4% of Mo.
- 13. A magnetic marker according to claim 8, wherein said magnetically switchable wire is formed of an alloy consisting mainly of Fe and containing 3 to 5% of Si and 1 to 3% of Co.
- 14. A magnetic marker according to claim 8, wherein said magnetically switchable wire has a diameter of ø70 μm to 110 μm and a length of 40 mm or less and is formed of a magnetic material subject to said sharp magnetic inversion.
- 15. A magnetic marker according to claim 9, wherein said magnetically switchable wire has a diameter of ø70 μm to 110 μm and a length of 40 mm or less and is formed of a magnetic material subject to said sharp magnetic inversion.
- 16. A magnetic marker according to claim 8, wherein said magnetic casing is formed of a magnetic material obtained by subjecting to aging heat treatment an alloy consisting mainly of Fe and containing 25 to 35% of Cr and 5 to 15% of Co.
- 17. A magnetic marker according to claim 9, wherein said magnetic casing is formed of a magnetic material obtained by subjecting to aging heat treatment an alloy consisting mainly of Fe and containing 25 to 35% of Cr and 5 to 15% of Co.
- 18. A magnetic marker according to claim 8, wherein said magnetically switchable wire has a structure such that primary arms of a dendrite are oriented at an angle of 10° or less to the axis of said magnetically switchable wire.
- 19. A magnetic marker according to claim 9, wherein said magnetically switchable wire has a structure such that primary arms of a dendrite are oriented at an angle of 10° or less to the axis of said magnetically switchable wire.
- 20. A magnetic marker according to claim 8, which comprises a plurality of magnetically switchable wires and said magnetic casing enveloping the magnetically switchable wires.
- 21. A magnetic marker according to claim 9, which comprises a plurality of magnetically switchable wires and said magnetic casing enveloping the magnetically switchable wires.
- 22. A magnetic marker according to claim 20, wherein the respective coercive forces of said plurality of magnetically switchable wires are different from one another.
- 23. A magnetic marker according to claim 21, wherein the respective coercive forces of said plurality of magnetically switchable wires are different from one another.
- 24. A manufacturing method for a magnetic marker, which comprises a magnetically switchable wire formed of a magnetic material and adapted to undergo a sharp magnetic inversion when an alternating field of intensity higher than the coercive force thereof is applied thereto, and a magnetic casing formed of a magnetically hard or semihard magnetic material, covering said magnetically switchable wire, and capable of generating a bias magnetic field to prevent magnetic inversion of said magnetically switchable wire, said magnetic casing having heat-treated portions partially differentiated in magnetic properties by heat treatment in the longitudinal direction thereof,
said magnetically switchable wire being manufactured by the in-gas melt spinning method.
- 25. A manufacturing method for a magnetic marker according to claim 24, wherein a cooling gas used in said in-gas melt spinning method contains helium and oxygen.
Priority Claims (2)
Number |
Date |
Country |
Kind |
2000-216089 |
Jul 2000 |
JP |
|
2000-216090 |
Jul 2000 |
JP |
|
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This is a Continuation Application of PCT Application No. PCT/JP01/06167, filed Jul. 17, 2001, which wash not published under PCT Article 21(2) in English.
Continuations (1)
|
Number |
Date |
Country |
Parent |
PCT/JP01/06167 |
Jul 2001 |
US |
Child |
10097882 |
Mar 2002 |
US |