A fluid pipe magnetization unit includes a ferromagnetism casing, a plurality of magnetic rods, and at least one flow limiting element. The magnetic rods include at least one first magnetic rod and at least one second magnetic rod. Inner elements of the first magnetic rod and the second magnetic rod are alternately positioned with opposite magnetic poles in the ferromagnetism casing. The at least one flow limiting element is arranged in at least one weak magnetic area in the ferromagnetism casing to prevent fluid from flowing through the at least one weak magnetic area. In addition, a fluid pipe magnetization device with the same is also disclosed herein.

A fluid pipe magnetization unit includes a ferromagnetism casing, a plurality of magnetic rods, and at least one flow limiting element. The magnetic rods include at least one first magnetic rod and at least one second magnetic rod. Inner elements of the first magnetic rod and the second magnetic rod are alternately positioned with opposite magnetic poles in the ferromagnetism casing. The at least one flow limiting element is arranged in at least one weak magnetic area in the ferromagnetism casing to prevent fluid from flowing through the at least one weak magnetic area. In addition, a fluid pipe magnetization device with the same is also disclosed herein.

A superconductor bulk magnet magnetizing method providing a more homogenous trapped magnetic field includes: placing the bulk magnet inside a charger bore of an electrical charger magnet; placing a field correction unit inside a superconductor bore of the bulk magnet; applying an electrical current (I.sub.0) to the charger magnet, to generate an externally applied magnetic field, wherein a temperature T.sub.bulk of the bulk magnet exceeds a bulk magnet critical temperature T.sub.c; applying an auxiliary electrical current (I.sub.1, . . . ) to the field correction unit, thus generating an auxiliary magnetic field applied to the bulk magnet from within the superconductor bore, wherein T.sub.bulk>T.sub.c; lowering T.sub.bulk below T.sub.c; turning off the electrical current at the charger magnet, wherein T.sub.bulk<T.sub.c, and turning off the auxiliary electrical current at the field correction unit, wherein T.sub.bulk<T.sub.c; and removing the bulk magnet from the charger bore while T.sub.bulk<T.sub.c.

A superconductor bulk magnet magnetizing method providing a more homogenous trapped magnetic field includes: placing the bulk magnet inside a charger bore of an electrical charger magnet; placing a field correction unit inside a superconductor bore of the bulk magnet; applying an electrical current (I.sub.0) to the charger magnet, to generate an externally applied magnetic field, wherein a temperature T.sub.bulk of the bulk magnet exceeds a bulk magnet critical temperature T.sub.c; applying an auxiliary electrical current (I.sub.1, . . . ) to the field correction unit, thus generating an auxiliary magnetic field applied to the bulk magnet from within the superconductor bore, wherein T.sub.bulk>T.sub.c; lowering T.sub.bulk below T.sub.c; turning off the electrical current at the charger magnet, wherein T.sub.bulk<T.sub.c, and turning off the auxiliary electrical current at the field correction unit, wherein T.sub.bulk<T.sub.c; and removing the bulk magnet from the charger bore while T.sub.bulk<T.sub.c.

The present disclosure discloses a method for the magnetism stabilizing treatment of a permanent magnet material. The method can include the following steps: providing a permanent magnet material having a positive temperature coefficient of coercivity; magnetizing the permanent magnet material at a temperature T.sub.3 with a range of −200 degree centigrades to 200 degree centigrades; and performing a magnetism stabilizing treatment towards the permanent magnet material with temperature decreased in a range of the temperature T.sub.3 to a temperature T.sub.4, or at the temperature T.sub.3.

The present disclosure discloses a method for the magnetism stabilizing treatment of a permanent magnet material. The method can include the following steps: providing a permanent magnet material having a positive temperature coefficient of coercivity; magnetizing the permanent magnet material at a temperature T.sub.3 with a range of −200 degree centigrades to 200 degree centigrades; and performing a magnetism stabilizing treatment towards the permanent magnet material with temperature decreased in a range of the temperature T.sub.3 to a temperature T.sub.4, or at the temperature T.sub.3.

A magnetizer system for use with a medical device including ferrous elements. The magnetizer can include a magnetizer body defining a cavity, the magnetizer body having a body opening in communication with the cavity, the magnetizer body including one or more magnets configured to generate a magnetic field configured to imprint a magnetic signature on ferrous elements within the cavity. The magnetizer can include one or more mechanisms configured to detect the presence of the medical device.

A magnetizer system for use with a medical device including ferrous elements. The magnetizer can include a magnetizer body defining a cavity, the magnetizer body having a body opening in communication with the cavity, the magnetizer body including one or more magnets configured to generate a magnetic field configured to imprint a magnetic signature on ferrous elements within the cavity. The magnetizer can include one or more mechanisms configured to detect the presence of the medical device.

An apparatus for magnetic annealing one or more workpieces, and a method of operating the apparatus, are described. The apparatus includes: a workpiece holder configured to support one or more workpieces, wherein the one or more workpieces having at least one substantially planar surface; an optional workpiece heating system configured to elevate the one or more workpieces to an anneal temperature; and a magnet assembly having a first magnet and a second magnet, the first and second magnets defining a gap between opposing poles of each magnet, wherein the magnet assembly is arranged to generate a magnetic field substantially perpendicular to the planar surface of the one or more workpieces.

An apparatus for magnetic annealing one or more workpieces, and a method of operating the apparatus, are described. The apparatus includes: a workpiece holder configured to support one or more workpieces, wherein the one or more workpieces having at least one substantially planar surface; an optional workpiece heating system configured to elevate the one or more workpieces to an anneal temperature; and a magnet assembly having a first magnet and a second magnet, the first and second magnets defining a gap between opposing poles of each magnet, wherein the magnet assembly is arranged to generate a magnetic field substantially perpendicular to the planar surface of the one or more workpieces.