JP2012050329A - Permanent magnet for motor and manufacturing method of permanent magnet for motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a permanent magnet for a motor having an eddy current generated in the permanent magnet be small even in the case where a permanent magnet motor with the permanent magnet embedded is made to be rotated in a high-speed.SOLUTION: A magnet material which is made up of Nd 27 to 30% - Fe 60 to 70% - B 1 to 2% at wt.% is wet-pulverized in an organic solvent. The magnet material which is wet-pulverized in the organic solvent and a resin binder are mixed in the organic solvent, and thereby, slurry 41 is produced. A permanent magnet 1 is manufactured by sintering a green sheet 42 with the produced slurry 41 formed in a sheet shape and a ceramic green sheet which will become an insulating layer in a state where a plurality of layers are laminated alternately.

Description

  The present invention relates to a permanent magnet for a motor embedded in a permanent magnet motor and a method for manufacturing the permanent magnet for a motor.

In recent years, permanent magnet motors used in hybrid cars, hard disk drives, and the like have been required to be smaller, lighter, higher in output, and more efficient. Such a permanent magnet motor has a structure in which a permanent magnet is embedded in the outer peripheral surface of a rotor and a coil is disposed on the inner peripheral surface of a stator, as shown in, for example, Japanese Patent Application Laid-Open No. 2007-306735.
In order to realize a reduction in size, weight, output, and efficiency in the permanent magnet motor, the permanent magnet embedded in the permanent magnet motor is required to further improve the magnetic characteristics. Permanent magnets include ferrite magnets, Sm—Co magnets, Nd—Fe—B magnets, Sm ₂ Fe ₁₇ N _x magnets, etc., but Nd—Fe—B magnets with particularly high coercive force are permanent. Used as a permanent magnet for a magnet motor.

  Here, as a manufacturing method of the permanent magnet used for the permanent magnet motor, a powder sintering method is generally used. Here, in the powder sintering method, as shown in FIG. 9, first, a magnetic powder obtained by pulverizing raw materials by a jet mill (dry pulverization) is manufactured. Thereafter, the magnet powder is put into a mold and press-molded into a desired shape while applying a magnetic field from the outside. And it manufactures by sintering the solid-shaped magnet powder shape | molded by the desired shape at predetermined temperature (for example, 1100 degreeC in a Nd-Fe-B type magnet).

Here, in recent years, there is an increasing demand for smaller and lighter permanent magnet motors. However, when the permanent magnet motor is downsized, the rotor rotates at a high speed in order to maintain the same torque as before the downsizing. It is necessary to let When high-speed rotation is performed, an eddy current is generated in the permanent magnet embedded in the motor. When a permanent magnet integrally formed by the powder sintering method described above is used for a permanent magnet motor, this eddy current is generated over the entire permanent magnet.
And when an eddy current generate | occur | produces in a permanent magnet, the temperature of a permanent magnet will rise. In addition, since the coercive force of the permanent magnet decreases as the temperature rises, the torque of the motor also decreases.

  Japanese Patent Application Laid-Open No. 2001-25189 describes a permanent magnet that is integrally formed so that a highly insulating ferrite magnet is disposed between a plurality of Nd magnets. In the permanent magnet having such a configuration, even when an eddy current is generated, the eddy current stays in each Nd magnet divided by the ferrite magnet, so that the eddy current can be reduced.

JP 2007-306735 A (pages 4 to 6, FIG. 1) JP 2001-25189 A (page 3 to page 4, FIG. 2)

  Here, although the permanent magnet described in Patent Document 2 is different in that two types of magnet powders, Nd magnet powder and ferrite magnet powder, are used, the powder sintering method shown in FIG. 9 has been used as before. . And when it was supposed to manufacture a permanent magnet by this powder sintering method, there existed the following problems. That is, in the powder sintering method, it is necessary to ensure a certain porosity in the press-molded magnet powder for magnetic field orientation. When magnet powder having a certain porosity is sintered, it is difficult to uniformly contract during the sintering, and deformation such as warpage and dent occurs after sintering. In addition, since pressure unevenness occurs when the magnet powder is pressed, the sintered magnet can be dense and dense, and distortion occurs on the magnet surface. Therefore, conventionally, it was necessary to compress the magnet powder in a size larger than the desired shape, assuming that the magnet surface can be distorted in advance. Then, after sintering, a diamond cutting and polishing operation is performed to correct the shape into a desired shape. As a result, the number of manufacturing steps increases, and the quality of the manufactured permanent magnet may decrease.

  The present invention has been made in order to solve the problems in the prior art, the shrinkage by sintering becomes uniform, deformation such as warping and dent after sintering is difficult to occur, and a permanent magnet is embedded. Even when the permanent magnet motor is rotated at a high speed, the eddy current generated in the permanent magnet can be reduced. An object of the present invention is to provide a permanent magnet for a motor that can be provided and a method for manufacturing the permanent magnet for a motor.

  In order to achieve the object, a permanent magnet for a motor according to claim 1 of the present application is a permanent magnet embedded in a permanent magnet motor, and includes a plurality of sheet-like magnets stacked and a plurality of the sheet-like magnets stacked. An insulating layer disposed therebetween, wherein the sheet-shaped magnet is a step of producing a slurry by mixing a magnet raw material wet crushed in an organic solvent and a resin binder in the organic solvent; The method comprises producing a green sheet of magnet powder obtained by forming the slurry into a sheet, and a step of sintering the green sheet of magnet powder.

  A permanent magnet for motor according to claim 2 is the permanent magnet for motor according to claim 1, wherein the green sheet of magnet powder and the insulating layer are sintered in the step of sintering the green sheet of magnet powder. A plurality of layers are alternately stacked and sintered.

  The motor permanent magnet according to claim 3 is the motor permanent magnet according to claim 2, wherein the insulating layer is made of a ceramic green sheet.

  A permanent magnet for a motor according to claim 4 is the permanent magnet for motor according to claim 1, wherein the sheet-like magnet manufactured by sintering a green sheet of the magnet powder and the insulating layer. It is manufactured by alternately laminating a plurality of layers.

  The motor permanent magnet according to claim 5 is the motor permanent magnet according to claim 4, wherein the insulating layer is made of a resin that joins the plurality of sheet magnets together.

  A permanent magnet for a motor according to a sixth aspect is the permanent magnet for a motor according to any one of the first to fifth aspects, wherein the sheet-like magnet is made of an Nd-based magnet.

  According to a seventh aspect of the present invention, there is provided a method for producing a permanent magnet for a motor, the method for producing a permanent magnet for a motor embedded in a permanent magnet motor, comprising: A step of producing a slurry by mixing in a solvent, a step of producing a green sheet of magnetic powder obtained by forming the slurry into a sheet, and a plurality of green sheets and insulating layers of the magnetic powder are alternately stacked. And a step of sintering.

  A method for manufacturing a permanent magnet for a motor according to claim 8 is the method for manufacturing a permanent magnet for a motor according to claim 7, wherein the insulating layer is made of a ceramic green sheet.

  A method for producing a permanent magnet for a motor according to claim 9 is the method for producing a permanent magnet for a motor embedded in a permanent magnet motor, wherein the magnet raw material wet-ground in an organic solvent and a resin binder Producing a slurry by mixing in a solvent, producing a green sheet of magnet powder obtained by forming the slurry into a sheet, and producing a sheet magnet by sintering the green sheet of the magnet powder And a step of alternately stacking a plurality of the sheet-like magnets and insulating layers.

  The method for manufacturing a permanent magnet for a motor according to claim 10 is the method for manufacturing a permanent magnet for a motor according to claim 9, wherein the insulating layer is made of a resin that joins the plurality of sheet-like magnets to each other. Features.

  Furthermore, the manufacturing method of the permanent magnet for motors which concerns on Claim 11 is a manufacturing method of the permanent magnet for motors in any one of Claim 7 thru | or 10. Said magnet powder consists of Nd type | system | group magnet powder. Features.

According to the motor permanent magnet of claim 1 having the above configuration, the motor permanent magnet is configured by laminating a plurality of sheet magnets with insulating layers disposed therebetween, and therefore the permanent magnet is embedded. Even when the permanent magnet motor is rotated at a high speed, the eddy current generated in the permanent magnet can be reduced. Accordingly, it is possible to prevent a temperature increase and a decrease in coercive force of the permanent magnet and to provide a high-power small motor.
Moreover, since a permanent magnet is formed by laminating a plurality of sheet-like magnets obtained by sintering green sheets, shrinkage due to sintering is reduced, and deformation such as warpage and dent after sintering is unlikely to occur. In addition, since pressure unevenness during pressing is eliminated, it is not necessary to perform post-sintering correction processing that has been conventionally performed, and the manufacturing process can be simplified. Thereby, a permanent magnet can be formed with high dimensional accuracy.

  Moreover, according to the permanent magnet for a motor according to claim 2, a permanent magnet in which a plurality of sheet magnets are laminated is formed by sintering together with the insulating layer when the green sheet of magnet powder is sintered. Therefore, it is possible to manufacture a permanent magnet in which a plurality of sheet-like magnets are laminated in a simplified process without the need to join the sheet-like magnet and the insulating layer after sintering.

  According to the permanent magnet for a motor according to claim 3, a plurality of sheet-like magnets are laminated by sintering together with a ceramic green sheet that becomes an insulating layer when the green sheet of magnet powder is sintered. Since the permanent magnet is formed, it is possible to manufacture a permanent magnet in which a plurality of sheet magnets are laminated by a simplified process without the need to join the sheet magnet and the insulating layer after sintering.

  According to the permanent magnet for a motor according to claim 4, after the sheet-like magnet is sintered, the plurality of sheet-like magnets are laminated by alternately laminating a plurality of sheet-like magnets and insulating layers. Since the permanent magnet is formed, an eddy current generated in the magnet can be reduced by a simple structure using a permanent magnet produced by using conventional sintering conditions as it is.

  According to the permanent magnet for a motor according to claim 5, after the sheet-like magnet is sintered, the plurality of sheet-like magnets are laminated by joining each sheet-like magnet with a resin that is an insulating layer. Since the permanent magnet is formed, an eddy current generated in the magnet can be reduced by a simple structure using a permanent magnet and a resin produced using the conventional sintering conditions as they are.

  Further, according to the permanent magnet for a motor according to claim 6, even if the permanent magnet motor is rotated at a high speed with respect to the Nd-based magnet capable of securing a particularly high coercive force, the permanent magnet is generated in the magnet. Eddy current can be reduced. Therefore, a small and high output motor can be provided.

According to the method for producing a permanent magnet for a motor according to claim 7, a magnet powder green sheet is produced by producing a magnet powder slurry, and forming the produced slurry into a sheet shape. Since the permanent magnet for a motor is manufactured by alternately laminating and sintering a plurality of insulating layers, a plurality of sheet magnets can be formed in a simplified process without the need to join the sheet magnet and the insulating layer after sintering. Laminated permanent magnets can be manufactured.
And even if it is a case where the permanent magnet motor with which the manufactured permanent magnet was embed | buried is rotated at high speed, the eddy current which generate | occur | produces in a permanent magnet can be made small. Accordingly, it is possible to prevent a temperature increase and a decrease in coercive force of the permanent magnet and to provide a high-power small motor.
In addition, since the permanent magnet shrinks uniformly during sintering, deformation such as warping and dents after sintering does not occur, and pressure unevenness during pressing is eliminated. There is no need for processing, and the manufacturing process can be simplified. Thereby, a permanent magnet can be formed with high dimensional accuracy.

  According to the method for manufacturing a permanent magnet for a motor according to claim 8, a plurality of sheet-like magnets are also obtained by sintering together with a ceramic green sheet that becomes an insulating layer when the green sheet of magnet powder is sintered. Is formed, so that it is possible to manufacture a permanent magnet in which a plurality of sheet magnets are laminated in a simplified process without the need to join the sheet magnet and the insulating layer after sintering. Become.

In addition, according to the method for manufacturing a permanent magnet for a motor according to claim 9, a magnet powder green sheet is produced by producing a magnet powder slurry, and the produced slurry is formed into a sheet shape. A sheet-like magnet is manufactured by sintering, and a permanent magnet for a motor is manufactured by alternately laminating a plurality of sheet-like magnets and insulating layers, so that the conventional sintering conditions are used as they are. An eddy current generated in the magnet can be reduced by a simple structure using a permanent magnet and an insulating layer.
And even if it is a case where the permanent magnet motor with which the manufactured permanent magnet was embed | buried is rotated at high speed, the eddy current which generate | occur | produces in a permanent magnet can be made small. Accordingly, it is possible to prevent a temperature increase and a decrease in coercive force of the permanent magnet and to provide a high-power small motor.
In addition, since the permanent magnet shrinks uniformly during sintering, deformation such as warping and dents after sintering does not occur, and pressure unevenness during pressing is eliminated. There is no need for processing, and the manufacturing process can be simplified. Thereby, a permanent magnet can be formed with high dimensional accuracy.

  In addition, according to the method for manufacturing a permanent magnet for a motor according to claim 10, since each sheet magnet is joined by a resin which is an insulating layer after the sheet magnet is molded, the conventional sintering conditions are used as they are. It becomes possible to manufacture a permanent magnet in which a plurality of sheet-like magnets are laminated by a simple manufacturing process using the manufactured permanent magnet and resin.

  Furthermore, according to the method for manufacturing a permanent magnet for a motor according to claim 11, even when an Nd-based magnet capable of securing a particularly high coercive force is manufactured, even when the permanent magnet motor is rotated at a high speed, the magnet It becomes possible to manufacture an Nd-based magnet with a reduced eddy current generated therein.

It is the figure which showed the internal structure of the permanent magnet motor which concerns on this embodiment. It is the whole view which showed the permanent magnet which concerns on this embodiment. It is the schematic diagram which expanded and showed a part of permanent magnet which concerns on this embodiment. It is the figure which compared the eddy current which generate | occur | produces in the conventional permanent magnet and the permanent magnet which concerns on this invention. It is the figure which expanded and showed the Nd magnet particle which comprises a permanent magnet. It is the figure which showed the hysteresis curve of the ferromagnetic material. It is the schematic diagram which showed the magnetic domain structure of the ferromagnetic material. It is explanatory drawing which showed the manufacturing process of the permanent magnet which concerns on this embodiment. It is explanatory drawing which showed the manufacturing process of the conventional permanent magnet.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, an embodiment embodying a motor permanent magnet and a method for manufacturing a motor permanent magnet according to the present invention will be described in detail with reference to the drawings. First, the structure of the permanent magnet motor 2 in which the permanent magnet 1 according to the present embodiment is embedded will be described with reference to FIG. FIG. 1 is a diagram showing an internal configuration of a permanent magnet motor 2 according to the present embodiment.

  As shown in FIG. 1, the permanent magnet motor 2 is basically composed of a stator 3 and a rotor 4 that is rotatably disposed inside the stator 3.

  First, the stator 3 will be described. The stator 3 includes a stator core 11 and a plurality of stator windings 12 wound around the stator core 11. A predetermined number of stator windings 12 are arranged at equal intervals on the inner peripheral surface of the stator 3, and when the stator windings 12 are energized, a rotating magnetic field for rotating the rotor 4 is generated.

  On the other hand, the rotor 4 will be described. The rotor 4 is substantially V-shaped inside the rotor body 15 and outside the shaft 16 inside the rotor body 15 and the shaft 16 connected to the rotor body 15. And a plurality of (16 in FIG. 1) permanent magnets 1 arranged in this manner. The permanent magnets 1 are arranged so that their polarities are alternately different in the circumferential direction, and generate an attractive force and a repulsive force based on the rotating magnetic field generated by the stator winding 12. The rotor 4 (that is, the shaft 16) rotates based on the generated suction force and repulsive force.

[Configuration of permanent magnet]
Next, the structure of the permanent magnet 1 embedded in the permanent magnet motor 2 will be described with reference to FIGS. The plurality of permanent magnets 1 embedded in the permanent magnet motor 2 basically have the same structure. Therefore, in the following, only one permanent magnet 1 among the plurality of embedded permanent magnets 1 will be described as an example.

  The permanent magnet 1 according to this embodiment is an Nd—Fe—B based magnet. Further, Dy (dysprosium) for increasing the coercive force of the permanent magnet 1 is added. In addition, content of each component shall be Nd: 27-30 wt%, Dy (or Tb): 0.01-8 wt%, B: 1-2 wt%, Fe (electrolytic iron): 60-70 wt%. Moreover, the permanent magnet 1 is comprised by laminating | stacking the some sheet-like magnet 21 as shown in FIG. FIG. 2 is an overall view showing the permanent magnet 1 according to the present embodiment.

  Here, the sheet-like magnet 21 constituting the permanent magnet 1 will be described. The sheet-like magnet 21 is a sheet-like permanent magnet having a thickness of 0.1 mm to 3 mm (2 mm in FIG. 2). And it produces by sintering the green sheet shape | molded from the Nd magnet powder made into the slurry state so that it may mention later. The permanent magnet 1 formed by laminating a plurality of sheet magnets 21 has a rectangular parallelepiped shape of 10 mm × 5 mm × 50 mm.

Next, the lamination | stacking aspect of the sheet-like magnet 21 which comprises the permanent magnet 1 is demonstrated in detail using FIG. FIG. 3 is an enlarged schematic view showing a part of the permanent magnet 1 according to the present embodiment.
As shown in FIG. 3, a ceramic insulating layer 22 obtained by sintering a thin ceramic green sheet as an insulating layer is disposed between the sheet magnets 21 stacked in the permanent magnet 1. The ceramic insulating layer 22 is formed by sandwiching a green sheet of ceramic powder and a plurality of ceramic green sheets alternately before the green sheet formed from Nd magnet powder is sintered. It is molded by sintering together with the green sheet. Thereby, after sintering, the permanent magnet 1 is integrally formed in a state where each sheet-like magnet 21 and the ceramic insulating layer 22 are joined.

  As the insulating layer, a heat-resistant adhesive resin such as an epoxy resin may be used instead of the ceramic insulating layer 22. In the case of using an epoxy resin, first, a green sheet formed from Nd magnet powder is sintered to form a plurality of sheet-like magnets 21, and then an epoxy resin is applied between the sheet-like magnets 21. The permanent magnet 1 is formed by joining the magnets 21.

  And if the permanent magnet 1 is formed from the several sheet-like magnet 21 which pinches | interposes an insulating layer as mentioned above, it will become possible to make small the eddy current which generate | occur | produces in the sheet-like magnet 21. FIG. FIG. 4 is a diagram comparing eddy currents generated in a conventional permanent magnet and a permanent magnet according to the present invention.

  Here, when the integrally formed permanent magnet 31 manufactured by compressing and sintering the magnet powder in a rectangular parallelepiped shape in advance as shown in FIG. 9 as the prior art is used for the permanent magnet motor 2, As shown in FIG. 4, an eddy current is generated throughout the permanent magnet 31. Here, in recent years, there is an increasing demand for reducing the size and weight of the permanent magnet motor 2, but when the permanent magnet motor 2 is reduced in size, in order to maintain the same torque as before the size reduction, the shaft 16 is required. Need to rotate at high speed. And if it rotates at high speed, an eddy current will generate | occur | produce in the permanent magnet embedded at the motor, and the temperature of a permanent magnet will rise. Since the coercive force of the permanent magnet decreases as the temperature rises, it has been desired to prevent the generation of eddy currents.

  Here, the permanent magnet 1 which concerns on this embodiment is formed from the some sheet-like magnet 21 which pinches | interposes an insulating layer as mentioned above. Therefore, even when an eddy current is generated by using the permanent magnet 1 for the permanent magnet motor 2, the eddy current path is blocked by the ceramic insulating layer 22 as an insulating layer as shown in FIG. Therefore, the scale of the eddy current generated inside the permanent magnet 1 can be reduced, and even when the permanent magnet motor 2 is rotated at a high speed, it is possible to suppress an increase in the temperature of the permanent magnet.

  Furthermore, the permanent magnet 1 according to the present embodiment improves the coercive force of the permanent magnet 1 by coding the Dy layer 36 on the surface of the Nd magnet particles 35 constituting the permanent magnet 1 as shown in FIG. Yes. FIG. 5 is an enlarged view showing Nd magnet particles constituting the permanent magnet 1.

Hereinafter, a mechanism for improving the coercive force of the permanent magnet 1 by the Dy layer 36 will be described with reference to FIGS. 6 and 7. FIG. 6 is a diagram showing a hysteresis curve of a ferromagnetic material, and FIG. 7 is a schematic diagram showing a magnetic domain structure of the ferromagnetic material.
As shown in FIG. 6, the coercive force of the permanent magnet is that of the magnetic field necessary for setting the magnetic polarization to 0 (ie, reversing the magnetization) when a magnetic field is applied in the reverse direction from the magnetized state. It is strength. Therefore, if the magnetization reversal can be suppressed, a high coercive force can be obtained. In the magnetization process of the magnetic material, there are rotational magnetization based on the rotation of the magnetic moment, and domain wall movement in which the domain wall that is the boundary between the magnetic domains (90 ° domain wall and 180 ° domain wall) moves.

Here, in this embodiment, when the magnet powder is finely pulverized by wet pulverization as described later, a small amount (for example, 0.01 to 8 wt% with respect to the magnet powder (the amount of Dy added to Nd, particularly Dy In the case of adding a compound, the Dy compound of D) distribution and the dispersant is added. Accordingly, when the magnet powder to which the Dy compound is added is subsequently sintered, the Dy compound is uniformly adhered to the particle surface of the Nd magnet particle 35 by wet dispersion, and the Dy layer 36 shown in FIG. 5 is formed. As a result, as shown in FIG. 7, Dy is unevenly distributed at the interface of the magnet particles, and the coercive force of the permanent magnet 1 can be improved.
In this embodiment, if a green sheet obtained by wet mixing a Dy compound with a magnet raw material in a solvent is fired under appropriate firing conditions, Dy can be prevented from diffusing and penetrating (solid solution) into the magnet particles 35. Here, it is known that when Dy diffuses and penetrates into the magnet particle 35, the residual magnetization of the magnet (magnetization when the strength of the magnetic field is reduced to 0) is reduced. Therefore, in this embodiment, it can prevent that the residual magnetization of the permanent magnet 1 falls.
The Dy layer 36 does not need to be a layer composed only of a Dy compound, and may be a layer composed of a mixture of Dy and Nd. In addition, the coercive force of the permanent magnet 1 can be similarly improved by adding a Tb (terbium) compound instead of the Dy compound. When Tb is added, a Tb compound layer is similarly formed on the surface of the Nd magnet particle 35. And the coercive force of the permanent magnet 1 can be further improved by forming the Tb layer.

[Permanent magnet manufacturing method]
Next, a method for manufacturing the permanent magnet 1 according to the present embodiment will be described with reference to FIG. FIG. 8 is an explanatory view showing a manufacturing process of the permanent magnet 1 according to the present embodiment.

First, an ingot consisting of Nd 27-30% -Fe 60-70% -B 1-2% in wt% is produced. Thereafter, the ingot is roughly pulverized to a size of about 200 μm by a stamp mill or a crusher. Next, the coarsely pulverized magnet powder is finely pulverized to a size of about 0.3 to 5 μm by a wet method using a bead mill, and the magnet powder is dispersed in the solution to produce a slip. In the wet pulverization, 4 kg of toluene is used as a solvent with respect to 5 kg of the magnet powder, and 0.05 kg of a phosphate ester dispersant is added as a dispersant. Moreover, 0.01-8 wt% Dy compound is added with respect to magnet powder during wet grinding. Thereby, the Dy compound is dispersed in the solvent together with the magnet powder. Detailed dispersion conditions are as follows.
・ Dispersion equipment: Bead mill ・ Dispersion media: Zirconia beads

Here, as the Dy compound to be added, a substance soluble in the solvent of the slurry is preferably used. For example, Dy-containing organic substances, more specifically, dysprosium cation-containing organic acid salts (aliphatic carboxylates, aromatic carboxylates, alicyclic carboxylates, alkylaromatic carboxylates, etc.), dysprosium cation-containing organic complexes (Acetylacetonate, phthalocyanine complex, merocyanine complex, etc.) and organometallic compounds other than the above.
Even if it is insoluble in a solvent, Dy or Dy compound pulverized into fine particles can be added during wet dispersion and uniformly dispersed on the surface of the Nd magnet particles by uniform dispersion.

  In addition, the solvent used for pulverization is not particularly limited, and alcohols such as isopropyl alcohol, ethanol and methanol, lower hydrocarbons such as pentane and hexane, aromatics such as benzene, toluene and xylene, ketones, and the like. Although a mixture etc. can be used, isopropyl alcohol etc. are especially preferable.

  After dispersion of the magnet powder, the resin binder is added and mixed into the produced slip. Subsequently, the magnet powder and the resin binder are kneaded to generate the slurry 41. The material used as the resin binder is not particularly limited, and may be various thermoplastic resins alone or a mixture, or various thermosetting resins alone or a mixture, and desired physical properties and properties can be obtained. Anything within the range is acceptable. For example, there is a methacrylic resin.

Subsequently, a green sheet 42 is formed from the generated slurry 41. As a method for forming the green sheet 42, for example, the produced slurry 41 can be applied by an appropriate method on a support substrate such as a separator and dried as necessary. The coating method is preferably a method excellent in layer thickness controllability such as a doctor blade method. Further, it is preferable to sufficiently defoam the mixture so that bubbles do not remain in the spreading layer by using an antifoaming agent in combination. Detailed coating conditions are as follows.
・ Coating method: Doctor blade ・ Gap: 1mm
Support substrate: Silicone-treated polyester film Drying conditions: 90 ° C x 10 minutes, then 130 ° C x 30 minutes

  Further, a pulsed magnetic field is applied to the green sheet 42 coated on the support substrate in a direction crossing the transport direction. Thereby orienting the magnetic field in the desired direction. Note that the direction in which the magnetic field is oriented needs to be determined in consideration of the magnetic field direction required for the permanent magnet 1 formed from the green sheet 42.

  Next, the green sheet 42 formed from the slurry 41 is divided into a flat plate shape of 10 mm × 5 mm × 2 mm. Thereafter, a ceramic green sheet made of ceramic powder is separately disposed between the divided green sheets, and a plurality of magnet powder green sheets and ceramic green sheets are alternately stacked (see FIG. 3). Sinter for hours. In addition, sintering is performed in Ar or a vacuum atmosphere. And as a result of sintering, the permanent magnet 1 which consists of the several sheet-like magnet 21 laminated | stacked is manufactured.

  When an epoxy resin is used as the insulating layer instead of the ceramic insulating layer 22, first, a green sheet formed from the slurry is sintered to produce the sheet magnet 21. After that, by applying an epoxy resin between the sheet-like magnets 21 and joining the sheet-like magnets 21, the permanent magnet 1 in which the sheet-like magnets 21 and the insulating layers are alternately laminated is manufactured.

As described above, in the permanent magnet 1 and the method for manufacturing the permanent magnet 1 according to the present embodiment, the magnet raw material composed of Nd27-30% -Fe60-70% -B1-2% in wt% is wet-ground in a solvent. Then, a resin binder is added to the pulverized magnet powder, and the magnet powder and the resin binder are kneaded to generate a slurry 41. The generated slurry is formed into a sheet shape, and a ceramic insulation that becomes an insulating layer. Since the permanent magnet 1 is manufactured by sintering in a state where a plurality of layers 22 are alternately stacked (see FIG. 3), even when the permanent magnet motor 2 in which the permanent magnet 1 is embedded is rotated at a high speed. The eddy current generated in the permanent magnet 1 can be reduced. Therefore, it is possible to prevent a temperature increase and a decrease in coercive force of the permanent magnet 1 and provide a high-power small motor.
In addition, the eddy current generated in the magnet can be reduced even when the permanent magnet motor is rotated at a high speed with respect to the Nd-based magnet that can ensure a particularly high coercive force.
Moreover, since the ceramic green sheet which becomes an insulating layer at the time of sintering the green sheet 42 of the magnet powder is also sintered, the permanent magnet 1 in which the plurality of sheet-like magnets 21 are laminated is formed. There is no need to join the sheet magnet 21 and the insulating layer, and the permanent magnet 1 in which the plurality of sheet magnets 21 are laminated can be manufactured by a simplified process.
Further, if the permanent magnet 1 is manufactured by bonding the sheet magnets with an epoxy resin that is an insulating layer after the molding of the sheet magnets, An eddy current generated in the magnet can be reduced by a simple structure using an epoxy resin.
Further, since the permanent magnet 1 is manufactured by sintering the green sheet 42, deformation such as warpage and dent after sintering does not occur due to uniform shrinkage due to sintering, and pressure unevenness during pressing Therefore, it is not necessary to perform correction processing after sintering, which has been conventionally performed, and the manufacturing process can be simplified. Thereby, the permanent magnet 1 can be molded with high dimensional accuracy.

In addition, this invention is not limited to the said Example, Of course, various improvement and deformation | transformation are possible within the range which does not deviate from the summary of this invention.
For example, in this embodiment, as a method of dispersing magnet powder and Dy compound in a solvent, as shown in FIG. 5, the coarsely pulverized magnet powder is dispersed in the solvent by wet grinding in the solvent together with the Dy compound. However, it can also be performed by the following method.
(1) First, the coarsely pulverized magnet powder is finely pulverized to a size of about 0.3 to 5 μm by dry pulverization using a ball mill or jet mill.
(2) Next, the finely pulverized magnet powder is added to a solvent and uniformly dispersed in the solvent. At that time, a dispersant and a Dy compound are also added to the solvent.
(3) The magnetic powder dispersed in the solvent and the resin binder are kneaded to generate the slurry 41.
Thereafter, by performing the same processing as in the present embodiment, it becomes possible to manufacture a permanent magnet having the same configuration as in the present embodiment.

  In this embodiment, first, an ingot made of Nd—Fe—B is pulverized, and then a Dy compound is added and dispersed in a solvent to produce a green sheet. However, Nd—Fe containing Dy in advance is prepared. A green sheet may be produced by pulverizing an ingot composed of -Dy-B and dispersing it in a solvent. However, in that case, the amount of Dy included in the ingot needs to be 20 to 30 wt% with respect to Nd.

  In this embodiment, the permanent magnet embedded in the permanent magnet motor 2 mounted on the hybrid car is described as an example. However, the vibration motor mounted on the mobile phone and the voice driving the head of the hard disk drive are described. Of course, the present invention can also be applied to a permanent magnet embedded in a permanent magnet motor such as a coil motor or a spindle motor that rotates a disk of a hard disk drive.

  Moreover, the pulverization conditions, kneading conditions, sintering conditions, etc. of the magnet powder are not limited to the conditions described in the above examples.

DESCRIPTION OF SYMBOLS 1 Permanent magnet 2 Permanent magnet motor 21 Sheet magnet 22 Ceramic insulating layer 41 Slurry 42 Green sheet

Claims (11)

In the permanent magnet embedded in the permanent magnet motor,
A plurality of laminated sheet magnets;
An insulating layer disposed between the plurality of laminated sheet magnets,
The sheet magnet is
A step of producing a slurry by mixing a magnet raw material wet-ground in an organic solvent and a resin binder in the organic solvent;
Producing a green sheet of magnet powder obtained by forming the slurry into a sheet;
A permanent magnet for a motor produced by sintering a green sheet of the magnet powder.   The permanent magnet for a motor according to claim 1, wherein in the step of sintering the green sheet of magnet powder, a plurality of the green sheets of magnet powder and the insulating layer are alternately stacked and sintered.   The permanent magnet for a motor according to claim 2, wherein the insulating layer is made of a ceramic green sheet.   2. The permanent magnet for a motor according to claim 1, wherein the permanent magnet is manufactured by alternately laminating a plurality of the sheet-like magnets and the insulating layers that are manufactured by sintering the green sheets of the magnet powder. 3. .   The permanent magnet for a motor according to claim 4, wherein the insulating layer is made of a resin that joins the plurality of sheet-like magnets to each other.   The permanent magnet for a motor according to any one of claims 1 to 5, wherein the sheet-like magnet is made of an Nd-based magnet. In the method for manufacturing a permanent magnet for a motor embedded in a permanent magnet motor,
A step of producing a slurry by mixing a magnet raw material wet-ground in an organic solvent and a resin binder in the organic solvent;
Producing a green sheet of magnet powder obtained by forming the slurry into a sheet;
A method of manufacturing a permanent magnet for a motor, comprising: a step of alternately stacking and sintering a plurality of green sheets of magnetic powder and insulating layers.   The method for manufacturing a permanent magnet for a motor according to claim 7, wherein the insulating layer is made of a ceramic green sheet. In the method for manufacturing a permanent magnet for a motor embedded in a permanent magnet motor,
A step of producing a slurry by mixing a magnet raw material wet-ground in an organic solvent and a resin binder in the organic solvent;
Producing a green sheet of magnet powder obtained by forming the slurry into a sheet;
A step of producing a sheet magnet by sintering a green sheet of the magnet powder;
And a step of alternately laminating a plurality of the sheet-like magnets and insulating layers. A method for producing a permanent magnet for a motor.   The method for manufacturing a permanent magnet for a motor according to claim 9, wherein the insulating layer is made of a resin that joins the plurality of sheet-like magnets to each other.   The method of manufacturing a permanent magnet for a motor according to any one of claims 7 to 10, wherein the magnet powder is made of an Nd-based magnet powder.

Images