KR101152060B1 - Method for generating partly opposite pole in two poles of permanent magnet - Google Patents

Abstract

According to the present invention, when the center hole is formed by the anode midline in the cylindrical permanent magnet, and the inner bottom surface of the center hole is heated to Curie temperature, the conduction heat is rapidly separated by conduction into the upper N pole region and the lower S pole region. As the upper and lower conduction passages and the upper and lower conduction passages, the upper end of the upper pole and the lower end of the lower pole, the ferromagnetics are lost due to the conduction heat of Curie temperature. Being

A central hole is formed at the periphery of the N pole region on the upper side and the S pole region on the lower side, based on the anode midline of the cylindrical permanent magnet, and the inner bottom of the central hole is heated to Curie temperature. The conduction heat of the N pole area is the upper N pole, and the conduction heat of the lower S pole area is rapidly conducted to the lower S pole, respectively, and the upper end of the upper N pole, the end of the upper and lower conduction paths, and the upper and lower conduction paths, respectively. The ends of the lower and lower S-poles lose their ferromagnetic properties by the Curie's conduction heat, creating a counter-pole at the missing portion.

If vertical holes are formed in the upper N pole surface and the lower S pole surface of both ends of the cylindrical permanent magnet, and the inner bottom surface of the vertical hole is heated to Curie temperature, the conductive heat of the vertical hole formed in the upper N pole surface is the inner bottom surface. The conduction heat of the vertical holes formed in the upper N pole surface and formed at the lower S pole surface from the outer side to the outer periphery of the vertical hole is rapidly conducted to the lower S pole surface at the inner bottom edge of the vertical hole. The conduction passage formed by the outer periphery of the bottom surface and the peripheral periphery of the vertical hole, and the end portions of the upper and lower ends of the conducting passage, the north pole and the south pole of the south pole, are lost due to the heat of Curie. Apparatus for generating partial counter-pole at the anode of permanent magnet to produce counter-electrode at the missing part

Description

Method for generating partly opposite pole in two poles of permanent magnet}

The present invention relates to a method of producing a partial counter electrode at an anode of a permanent magnet which can be used industrially by partially forming a counter electrode at a north pole and a south pole of a cathode of a permanent magnet.

In Patent Application No. 10-2008-31528 filed by the applicant, the magnetic force is weakest at the N-pole and S-pole, which are the center line and the anode of the anode connecting the center of the north pole and the south pole of both ends where the magnetic lines of the cylindrical permanent magnet are concentrated. Using the midline of the anode, which is the midpoint of the anode, use the center line of the cylindrical permanent magnet to form a central hole passing through the anode center line at 360 ° on the outer peripheral middle line of the north pole and the south pole of the pole. The inner bottom surface is heated to Curie temperature to dissipate the magnetic force of the inner bottom surface, so that the upper and lower ends of the inner periphery of the central hole have both upper and lower ends of the cylindrical permanent magnets, The opposite poles S poles and N poles have the upper and lower ends of the inner periphery of the inner circumference of the central hole opposed thereto, the opposite pole N poles, and the S poles have the upper and lower ends of the cylindrical permanent magnets opposite to each other. On the S pole S pole, which is partially opposite. There was a tendency for partial counters to be lost over time as partial counters were weakened due to the interaction between the S poles or the original magnetic forces of the cylindrical permanent magnets.

In the cylindrical permanent magnet, there was a need for a method of generating a counter electrode partially on the entire surface of the north pole and the south pole of both ends, and preventing the partial counter pole from weakening or disappearing to the maximum.

When heat is applied to the permanent magnet, the conduction heat is rapidly conducted in the magnetic direction, and vertical holes are formed in the upper N pole surface and the lower S pole surface of both ends of the permanent magnet, and the bottom surface of the vertical hole is heated to Curie temperature. The conduction heat is rapidly conducted in the direction of the magnetic force, and as the ferromagnetics of the bottom and peripheral edges of the vertical hole are lost by the conduction heat, the opposite pole is generated in the portion lost by the intrinsic self-permanence of the permanent magnet. The results were found.

In the present invention, if the central permanent hole is formed from the cylindrical permanent magnet to the anode midline, and the inner bottom surface of the central hole is heated to Curie temperature, the conductive heat is the upper N pole region and the lower S pole region. It is rapidly conducted by conduction, and the upper and lower conduction passages and the upper and lower conduction passages, the upper end of the N pole and the lower end of the S pole, the ferromagnetics are lost by the conduction heat of Curie temperature. The opposite pole is created at

A central hole is formed at the periphery of the N pole region on the upper side and the S pole region on the lower side, based on the anode midline of the cylindrical permanent magnet, and the inner bottom of the central hole is heated to Curie temperature. The conduction heat of the N pole area is the upper N pole, and the conduction heat of the lower S pole area is rapidly conducted to the lower S pole, respectively, and the upper end of the upper N pole, the end of the upper and lower conduction paths, and the upper and lower conduction paths, respectively. The ends of the lower and lower S-poles lose their ferromagnetic properties by the Curie's conduction heat, creating a counter-pole at the missing portion.

If vertical holes are formed in the upper N pole surface and the lower S pole surface of both ends of the cylindrical permanent magnet, and the inner bottom surface of the vertical hole is heated to Curie temperature, the conductive heat of the vertical hole formed in the upper N pole surface is the inner bottom surface. The conduction heat of the vertical holes formed in the upper N pole surface and formed at the lower S pole surface from the outer side to the outer periphery of the vertical hole is rapidly conducted to the lower S pole surface at the inner bottom edge of the vertical hole. The conduction passage formed by the outer periphery of the bottom surface and the peripheral periphery of the vertical hole, and the end portions of the upper and lower ends of the conducting passage, the north pole and the south pole of the south pole, are lost due to the heat of Curie. The opposite pole is created in the disappearance part.

The present invention is to form a central hole and a vertical hole in the cylindrical permanent magnet and then to heat the inner bottom surface of the central hole and the vertical hole to the Curie temperature, the heating temperature is rapidly conducted in the magnetic direction while the heat conduction path is Curie temperature As a result, ferromagneticity is lost, and partial opposite poles can be generated at the upper N pole and the lower S pole, which are the ends of the heat conduction path and the heat conduction path.

As shown in the cross-sectional view of the embodiment of FIG. 1, the central hole is perpendicular to the center line 1 of the inner anode at the middle line 2 of the anode, which is the midpoint of the anode and the pole of the cylindrical permanent magnet. After forming (10) and heating the inner bottom surface 11 of the central hole 10 to the Curie temperature according to the material of the permanent magnet, the heat of conduction is the upper N pole region based on the midline 2 of the anode. The upper and lower conduction passages 12 and 12a and the upper and lower conduction passages, which are separated into the S-pole regions of the lower and lower portions, are rapidly conducted to the upper N-pole and the lower S-pole, which are both ends thereof, and are thermally conductive to the upper and lower portions thereof. The end face portion 13 of the upper N pole and the end face portion 13a of the lower S pole, which are the ends of the ferromagnetic material are lost due to the conduction heat of Curie temperature, and the opposite pole is formed at the end of the cylindrical permanent magnet. On the upper N-pole surface of which is the opposite pole, and on the lower S-pole surface, the north pole is simultaneously It will not be created.

In addition, center holes 20 and 20a are perpendicular to the anode center line 1 at the periphery of the N pole region at the upper side and the S pole region at the lower side with respect to the anode midline 2 of the cylindrical permanent magnet, respectively. After forming, if the inner bottom surfaces 21 and 21a of the central holes 20 and 20a are heated to Curie temperature, the conduction heat of the upper N pole region is not directed to the lower side, but to the upper N pole and the lower S side. The conduction heat of the pole area is not directed upward, and is rapidly conducted to the lower S pole, respectively, so that the upper and lower conduction passages 22 and 22a and the upper and lower end end portions 23 and the lower end of the upper and lower conduction passages, respectively. The end portion 23a of the S pole is demagnetized by the conduction heat of Curie temperature, and the opposite pole is generated at the missing portion, so that the S pole is the opposite pole to the upper N pole face of the cylindrical permanent magnet, and N is the opposite pole to the bottom S pole face. Each part can be partially created.

And vertical holes 30 and 30a parallel to the anode center line 1 are formed on the upper N pole surface and the lower S pole surface of both ends of the cylindrical permanent magnet, and then the inner bottom surfaces 31 and 31 a of the vertical hole. When heated to the Curie temperature, the conduction heat of the vertical hole 30 formed on the upper N pole surface is not directed downward by the magnetic force of the upper N pole, and from the outside of the inner bottom surface 31 to the peripheral edge of the vertical hole 30. The conduction heat of the vertical hole 30a formed at the upper N pole surface and at the lower S pole surface is not directed upward by the magnetic force of the lower S pole, and from the outside of the inner bottom surface 31a to the peripheral edge of the vertical hole 30a. The conductive passages 32, 32a and the ends of the conductive passages are formed as the outer periphery of the inner bottom surface 31, 31a and the peripheral periphery of the vertical holes 30, 30a while being rapidly conducted to the lower S-pole surface. N pole, end of lower pole As the surface portions 33 and 33a lose ferromagneticity by the conduction heat of Curie temperature, an opposite pole is formed in the missing portion, and the north pole of the upper pole N of the cylindrical permanent magnet is the opposite pole, and the north pole of the opposite pole of the lower pole S pole. Can be partially generated.

1 is a cross-sectional view showing an embodiment of the present invention

2 is a plan view of the embodiment of FIG.

3 is a bottom view of the embodiment of FIG.

Explanation of symbols for important parts of the drawings

1: center line of anode 2: middle line of anode

10,20,20a: Center hole 11,21,21a: Interior bottom

12,12a, 22,22a: Conducting passage 13,13a, 23,23a: End section of the conducting passage

30,30a: Vertical hole 31,31a: Interior bottom

32,32a: conduction passage 33,33a: end section of the conduction passage

Claims (3)

delete Center holes 20 and 20a are formed in the vertical direction with the anode center line 1 at the periphery of the N pole region at the upper side and the S pole region at the lower side, respectively, based on the anode middle line 2 of the cylindrical permanent magnet. Heat the inner bottom surfaces 21 and 21a of the central hole 20 and 20a to Curie temperature to obtain the upper and lower conductive poles of the upper and lower conductive passages 22 and 22a and the upper and lower conductive passages. A method of producing a partial counter electrode at the anode of the permanent magnet in which the end portion portion 23 and the end portion portion 23a of the lower S pole are demagnetized by conduction heat of Curie temperature, thereby producing the missing portion as the opposite pole. Vertical holes 30 and 30a are formed in the upper N pole surface and the lower S pole surface of both ends of the cylindrical permanent magnet, and the inner bottom surfaces 31 and 31 a of the vertical holes are heated to a Curie temperature to form an inner bottom surface ( 31) (31a) and the conductive passages (32) and (32a) formed in the outer periphery of the vertical holes (30) and (30a), and the N and S poles of the upper and lower ends of the conductive passages. A method of producing a partial counter electrode at the anode of the permanent magnet in which the end portions (33) and (33a) are dissipated by the heat of Curie's conduction to produce ferromagnetic properties.

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