WO2014002983A1 - 希土類系焼結磁石の製造方法 - Google Patents
希土類系焼結磁石の製造方法 Download PDFInfo
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- WO2014002983A1 WO2014002983A1 PCT/JP2013/067335 JP2013067335W WO2014002983A1 WO 2014002983 A1 WO2014002983 A1 WO 2014002983A1 JP 2013067335 W JP2013067335 W JP 2013067335W WO 2014002983 A1 WO2014002983 A1 WO 2014002983A1
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C38/00—Ferrous alloys, e.g. steel alloys
- C22C38/002—Ferrous alloys, e.g. steel alloys containing In, Mg, or other elements not provided for in one single group C22C38/001 - C22C38/60
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F41/00—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties
- H01F41/02—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets
- H01F41/0253—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets for manufacturing permanent magnets
- H01F41/0266—Moulding; Pressing
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F3/00—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces
- B22F3/12—Both compacting and sintering
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B30—PRESSES
- B30B—PRESSES IN GENERAL
- B30B11/00—Presses specially adapted for forming shaped articles from material in particulate or plastic state, e.g. briquetting presses, tabletting presses
- B30B11/008—Applying a magnetic field to the material
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B30—PRESSES
- B30B—PRESSES IN GENERAL
- B30B11/00—Presses specially adapted for forming shaped articles from material in particulate or plastic state, e.g. briquetting presses, tabletting presses
- B30B11/02—Presses specially adapted for forming shaped articles from material in particulate or plastic state, e.g. briquetting presses, tabletting presses using a ram exerting pressure on the material in a moulding space
- B30B11/027—Particular press methods or systems
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C38/00—Ferrous alloys, e.g. steel alloys
- C22C38/005—Ferrous alloys, e.g. steel alloys containing rare earths, i.e. Sc, Y, Lanthanides
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C38/00—Ferrous alloys, e.g. steel alloys
- C22C38/06—Ferrous alloys, e.g. steel alloys containing aluminium
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C38/00—Ferrous alloys, e.g. steel alloys
- C22C38/10—Ferrous alloys, e.g. steel alloys containing cobalt
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C38/00—Ferrous alloys, e.g. steel alloys
- C22C38/16—Ferrous alloys, e.g. steel alloys containing copper
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F41/00—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties
- H01F41/02—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets
- H01F41/0253—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets for manufacturing permanent magnets
- H01F41/0273—Imparting anisotropy
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F2998/00—Supplementary information concerning processes or compositions relating to powder metallurgy
- B22F2998/10—Processes characterised by the sequence of their steps
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F2999/00—Aspects linked to processes or compositions used in powder metallurgy
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F3/00—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces
- B22F3/02—Compacting only
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C2202/00—Physical properties
- C22C2202/02—Magnetic
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F1/00—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties
- H01F1/01—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials
- H01F1/03—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity
- H01F1/032—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of hard-magnetic materials
- H01F1/04—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of hard-magnetic materials metals or alloys
- H01F1/047—Alloys characterised by their composition
- H01F1/053—Alloys characterised by their composition containing rare earth metals
- H01F1/055—Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5
- H01F1/057—Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B
- H01F1/0571—Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B in the form of particles, e.g. rapid quenched powders or ribbon flakes
- H01F1/0575—Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B in the form of particles, e.g. rapid quenched powders or ribbon flakes pressed, sintered or bonded together
- H01F1/0577—Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B in the form of particles, e.g. rapid quenched powders or ribbon flakes pressed, sintered or bonded together sintered
Definitions
- the present invention relates to a method for producing a rare earth sintered magnet, and more particularly to a method for producing a rare earth sintered magnet using a wet molding method.
- RTB-based sintered magnet R is at least one rare earth element (concept including yttrium (Y)), T is iron (Fe) or iron and cobalt (Co), B is boron) and Rare earth-based sintered magnets such as samarium / cobalt-based sintered magnets have, for example, residual magnetic flux density B r (hereinafter sometimes simply referred to as “B r ”), coercive force H cJ (hereinafter simply referred to as “H cJ ”). Is widely used because of its excellent magnetic properties.
- the RTB-based sintered magnet exhibits the highest magnetic energy product among various known magnets and is relatively inexpensive, so that it is a voice coil motor for a hard disk drive and a hybrid vehicle. It is used for various applications such as various motors such as motors for motors and motors for electric vehicles, and home appliances.
- various motors such as motors for motors and motors for electric vehicles, and home appliances.
- RTB based sintered magnets there has been a demand for further improvement in magnetic properties of rare earth sintered magnets such as RTB based sintered magnets in order to reduce the size, weight, and increase the efficiency in various applications.
- rare earth sintered magnets including RTB based sintered magnets
- an ingot obtained by melting (melting) a raw material such as metal and casting the molten metal into a mold, or a strip cast method
- An alloy powder having a predetermined particle diameter obtained by pulverizing a raw material alloy casting material having a desired composition such as a strip obtained by the above is used.
- Many rare earth-based materials including RTB-based sintered magnets are obtained by press-molding the alloy powder (press-molding in a magnetic field) to obtain a compact (compact), and further sintering the compact.
- a sintered magnet is manufactured.
- Two grinding steps are used.
- the method of press molding press molding in a magnetic field
- One is a dry forming method in which the obtained alloy powder is pressed while being dried.
- the other is, for example, a wet forming method described in Patent Document 1, in which an alloy powder is dispersed in a dispersion medium such as oil to form a slurry, and the alloy powder is supplied in the state of the slurry into a mold cavity and pressed. Perform molding.
- the dry molding method and the wet molding method can be roughly divided into two types depending on the relationship between the pressing direction during magnetic field pressing and the magnetic field direction.
- One is a perpendicular magnetic field forming method (also referred to as “transverse magnetic field forming method”) in which the direction compressed by the press (press direction) and the direction of the magnetic field applied to the alloy powder are orthogonal, and the other is the press direction and the alloy powder.
- a parallel magnetic field forming method also referred to as “longitudinal magnetic field forming method” in which the directions of the magnetic fields applied to are parallel.
- the dry molding method is widely used because the structure of the molding machine is relatively simple and there is no need for steps such as dedispersing medium (removing the dispersing medium) during press molding and dedispersing medium from the molded product. Has been.
- the perpendicular magnetic field forming method since the press direction and the magnetic field application direction are orthogonal to each other, it is possible to perform press forming without significantly disturbing the orientation of the alloy powder oriented in the magnetic field application direction, and R 2 T 14 A molded body having a high degree of orientation of the B phase can be produced.
- the perpendicular magnetic field molding method since the pressing direction and the magnetic field applying method are parallel, the orientation of the alloy powder is easily disturbed during press forming, and the orientation degree of the R 2 T 14 B phase is low as compared with the perpendicular magnetic field forming method. Accordingly, in the dry molding method, the perpendicular magnetic field molding method is mainly used, and the parallel magnetic field molding method is manufactured only for shapes such as a disk shape, a ring shape, and a thin plate shape, which are difficult to be molded by the perpendicular magnetic field molding method. .
- the wet forming method requires the supply of slurry and the dedispersion medium, so that the structure of the molding machine is relatively complicated, but the dispersion medium suppresses oxidation of the alloy powder and the molded body, The amount of oxygen in the molded body can be reduced.
- the dispersion medium is interposed between the alloy powders during press forming in a magnetic field, the alloy powder can be easily rotated in the magnetic field application direction because the constraint due to frictional force is weak. For this reason, a higher degree of orientation can be obtained. Therefore, there is an advantage that it is possible to obtain a rare earth sintered magnet having a magnetic property superior to that of the dry molding method.
- the wet molding method when used, it is possible to obtain a higher degree of orientation and an excellent oxidation suppression effect than the dry molding method, and the resulting RTB-based sintered magnet tends to have higher magnetic properties. There is.
- the high degree of orientation and excellent oxidation suppression effect by using the wet molding method can be obtained not only in the RTB-based sintered magnet but also in other rare-earth sintered magnets. it can.
- the wet molding method has the following problems.
- it is necessary to discharge most of the dispersion medium (oil, etc.) in the slurry outside the cavity when the slurry is put into the cavity and press forming in a magnetic field.
- a dispersion medium discharge hole is provided on one side, and the volume of the cavity is reduced by the movement of the upper punch and / or the lower punch.
- the dispersion medium is discharged from the dispersion medium discharge hole.
- the concentration of the alloy powder is high in the portion near the dispersion medium discharge hole in the initial stage of press molding. Forms a layer called “cake layer” (high density).
- the upper punch and / or the lower punch moves and press molding proceeds, and more dispersion medium is filtered out and the cake layer area in the cavity is expanded.
- the entire region in the cavity layer becomes a cake layer in which the density of the alloy powder is high (the dispersion medium concentration is low), and the alloy powders are bonded (combined relatively weakly) to obtain a compact.
- the magnetic field is applied in a direction parallel to the pressing direction, that is, in a direction parallel to the direction from the upper punch to the lower punch. Even if the cake layer is formed near the exit, the magnetic field is not bent and proceeds straight from the portion without the cake layer into the cake layer. For this reason, there is no restriction on the size of the cavity in the magnetic field application direction unlike the perpendicular magnetic field forming method.
- the distance between the coils serving as the magnetic field generation source is increased, so that the strength of the magnetic field applied in the cavity is reduced and the degree of orientation of the alloy powder is reduced. . Therefore, when the dimension in the magnetic field application direction is increased, the magnetic field strength must be increased. Further, since the pressing direction and the magnetic field application method are parallel, it is effective to increase the magnetic field strength in order to solve the problem that the orientation of the alloy powder is easily disturbed during press forming.
- the parallel magnetic field forming method by the wet forming method is known in the literature from Patent Document 1 and the like, but the actual manufacturing site has a cavity dimension (cavity depth dimension) in the magnetic field application direction.
- the parallel magnetic field forming method has not been used for the production of long shaped bodies or large shaped bodies having a value greater than 10 mm. That is, until now, a rare earth sintered magnet having a uniform and high magnetic property obtained from a molded body having a cavity dimension (cavity depth dimension) exceeding 10 mm in the direction of applying a magnetic field has been manufactured by a wet molding method. It wasn't.
- a molded body having a large dimension in the direction of applying a magnetic field has been manufactured mainly by a perpendicular magnetic field forming method by a dry forming method.
- a cross-sectional shape having a substantially arc-shaped outer periphery, a substantially arc-shaped inner periphery, and a pair of side edges connecting the outer periphery and the inner periphery (hereinafter referred to as “substantially arcuate”). )) was molded by pressing, and after sintering, slicing was performed in a direction perpendicular to the direction of magnetic field application, a voice coil motor magnet for a hard disk drive was manufactured.
- An object of the present invention is to provide a method for producing a long or large rare earth-based sintered magnet having a uniform magnetic property in each part of a single magnet and a high magnetic property and a large size in the magnetic field application direction.
- Another object of the present invention is to provide a method for manufacturing a rare earth sintered magnet having a large dimension in the magnetic field application direction and a complicated cross section in a direction orthogonal to the magnetic field application direction.
- Aspect 1 of the present invention includes: 1) a step of preparing a slurry containing a rare earth element, iron and boron, and a dispersion medium in a predetermined ratio; and 2) at least one of the mold moves.
- a step, 5) a step of sintering the shaped body is a method for producing a rare earth metal-based sintered magnet, which comprises a.
- Aspect 2 of the present invention is the method for producing a rare earth sintered magnet according to aspect 1, wherein the flow rate of the slurry is 20 to 400 cm 3 / sec.
- Aspect 3 of the present invention is the method for producing a rare earth sintered magnet according to aspect 1, wherein the flow rate of the slurry is 20 to 200 cm 3 / sec.
- Aspect 5 of the present invention is the method for producing a rare earth sintered magnet according to any one of Aspects 1 to 4, wherein the concentration of the alloy powder in the slurry is 70 to 90% by mass.
- Aspect 6 of the present invention is the method for producing a rare earth sintered magnet according to Aspect 5, wherein the concentration of the alloy powder in the slurry is 84% by mass or more.
- the present invention it is possible to provide a method for producing a long or large rare earth sintered magnet having a large magnetic field application direction and uniform magnetic characteristics in each part of a single magnet.
- the present inventors have a result of intensive studies, the magnetic field parallel molding, while applying a magnetic field of more than 1.5T in the cavity, the slurry flow rate 20 cm 3 / sec ⁇ 600 cm 3 / sec into the cavity ranges As a result, there is almost no density variation in each part of the molded body, and as a result, the magnetic characteristics in each part of the rare earth sintered magnet obtained from the molded body are uniform (the part of the magnet).
- the present invention has been found out that there is little variation in the magnetic characteristics due to the difference between the two) and high magnetic characteristics.
- a molded body in which the dimension of the cavity in the magnetic field application direction (depth dimension of the cavity) exceeds 10 mm has not been manufactured by the wet molding method. Therefore, there was no necessity for applying a magnetic field of 1.5 T or more. Further, in the conventional wet molding method, it has been important to supply the slurry as soon as possible (increase the slurry flow rate) in order to improve the production efficiency, so that the supply amount of the slurry is, for example, 600 cm 3 / sec or less. There has never been a technical idea of adjusting to a relatively small value.
- the upper punch surface and the lower punch surface are magnetic poles in the cavity, so that the slurry supplied from the vicinity of the lower punch (especially in the slurry) It is assumed that (alloy powder) is oriented in the direction of the magnetic field and is attracted to the lower punch surface and accumulates in a mountain shape.
- the newly supplied slurry especially the alloy powder in the slurry
- the cavity is filled with the slurry.
- the reason for the large variation in density in each part of the compact is that when the slurry accumulates in a mountain shape, the alloy powder in the slurry Is attracted to the lower punch surface, so that the solid alloy powder and the liquid dispersion medium are separated (solid-liquid separation), and the separated dispersion medium is collected around the cavity (at the bottom of the mountain). It is thought to be caused.
- the supply amount of the slurry is 20 cm 3 / second to 600 cm 3 / second, which is a small amount compared to the conventional one, it is considered that solid-liquid separation is suppressed. For this reason, there is almost no density variation in each part of the compact, and as a result, the magnetic characteristics in each part of the magnet itself are uniform and have high magnetic characteristics. It is thought that a magnetized magnet is obtained.
- the slurry supply port In the vicinity, the present inventors have newly found that the alloy powder oriented in the direction parallel to the magnetic field is displaced (excluded), and the orientation of the alloy powder tends to be disturbed. Since the disordered portion in the vicinity of the slurry supply port remains as it is (the orientation is disturbed), and becomes a rare earth sintered magnet through processes such as press molding, deoiling treatment, sintering and heat treatment.
- the inventors have also found that the magnetic properties of the part are lower than those of the other parts.
- the deterioration of the magnetic characteristics due to the disorder of the orientation in the vicinity of the slurry supply port becomes more conspicuous when a long or large molded body having a large cavity depth is press-molded.
- the supply amount of the slurry is 20 cm 3 / second to 600 cm 3 / second, which is a small amount compared with the conventional case, the influence on the alloy powder oriented in the direction of the magnetic field is limited. It is considered that the disorder of orientation in the vicinity of is very small.
- the magnetic characteristics of the portion corresponding to the vicinity of the slurry supply port are hardly deteriorated, the magnetic properties of each portion of the single magnet are uniform and have high magnetic properties, and the dimension in the magnetic field application direction is large. Long and large rare earth sintered magnets can be obtained.
- the reason that the present inventors presume that the magnetic properties of the obtained sintered magnet can be improved by setting the slurry supply rate to 20 cm 3 / second to 600 cm 3 / second is as described above (1
- the density of the compact is uniform, and (2) the disorder of the orientation of the alloy powder in the vicinity of the slurry supply port can be suppressed, and at least one of these two reasons contributes. Estimated.
- FIG. 1 (a) to FIG. 1 (d) are schematic cross-sectional views showing a method for producing a rare earth sintered magnet according to the present invention.
- FIG. 1A to FIG. 1D may be collectively referred to as “FIG. 1”.
- Fig.1 (a) is a schematic sectional drawing of the shaping
- the molding apparatus 100 has a cavity 9 surrounded by the through hole of the mold 5, the upper punch 1 and the lower punch 3.
- the cavity 9 has a length L0 along the molding direction.
- the forming direction means a direction in which at least one of the upper punch and the lower punch moves to approach the other (that is, the pressing direction).
- the lower punch 3 is fixed as will be described later, and the upper punch 1 and the mold 5 move integrally. Therefore, the direction from the top to the bottom in FIG. 1 (the direction of the arrow P in FIGS. 1C and 1D) is the molding direction.
- the electromagnet 7 is disposed on the side surface of the upper punch 1 and the lower side surface of the mold 3.
- a broken line B schematically shows a magnetic field formed by the electromagnet 7.
- a magnetic field is applied from the bottom to the top in FIG. 1, that is, in a direction parallel to the molding direction.
- the magnetic field strength is 1.5T or more. This is because when the slurry is supplied into the cavity 9, the magnetization direction of the alloy powder in the slurry is more reliably aligned in the direction of the magnetic field, and a high degree of orientation is obtained. If it is less than 1.5T, the degree of orientation of the alloy powder decreases, or the orientation of the alloy powder tends to be disturbed during press forming.
- the strength of the magnetic field inside the cavity 9 can be obtained by measurement with a gauss meter or magnetic field analysis.
- the electromagnet 7 is preferably disposed so as to surround the side surface of the upper punch 1 and the lower side surface of the mold 5 as shown in FIG. This is because a uniform magnetic field parallel to the molding direction can be formed in the cavity 9.
- “parallel to the forming method” is not only the case where the direction of the magnetic field is the direction from the lower punch 3 to the upper punch 1 (from the bottom to the top in the figure), but also in the reverse direction, that is, This includes the case of the direction from the upper punch 1 to the lower punch 3 (from the top to the bottom in the figure).
- the cavity 9 is connected to a supply port 15 for inserting slurry therein.
- a through hole penetrating the inside of the mold 5 functions as the supply port 15.
- the supply port 15 is connected to a slurry supply device (hydraulic device having a hydraulic cylinder) (not shown), and the slurry 25 pressurized by the hydraulic cylinder or the like is supplied to the cavity 9 through the supply port 15.
- the upper punch 1 preferably has a dispersion medium discharge hole 11 for filtering and discharging the dispersion medium in the slurry to the outside of the cavity 9.
- the upper punch 1 has a plurality of dispersion medium discharge holes 11 as shown in FIG.
- the upper punch 1 preferably has a filter 13 such as a filter cloth, a filter paper, a porous filter, or a metal filter so as to cover the dispersion medium discharge hole 11. .
- the alloy powder can be more reliably prevented from entering the dispersion medium discharge hole 11 (that is, only the dispersion medium is filtered), and the dispersion medium in the slurry can be filtered out to the outside of the cavity 9.
- the dispersion medium discharge hole 11 may be provided in the lower punch 3.
- the filter 13 it is preferable to arrange the filter 13 so as to cover the dispersion medium discharge hole 11.
- the slurry 25 is supplied into the cavity 9 at a flow rate (slurry supply amount) of 20 to 600 cm 3 / sec. This is because if the flow rate is less than 20 cm 3 / sec, it is difficult to adjust the flow rate, and the slurry may not be supplied into the cavity due to pipe resistance.
- the flow rate exceeds 600 cm 3 / sec, as described above, the density in each part of the molded body varies, and the molded body is cracked when the molded body is taken out after press molding, or at the time of sintering. This is because cracking may occur due to shrinkage. Further, the disorder of orientation may occur in the vicinity of the slurry supply port.
- the flow rate of the slurry is preferably 20 to 400 cm 3 / sec, more preferably 20 to 200 cm 3 / sec.
- the density variation in each part of a molded object can be further reduced by making it into the said preferable range and also the said more preferable range.
- the flow rate of the slurry can be controlled by changing the flow rate of the oil fed into the hydraulic cylinder by changing the flow rate adjustment valve of the hydraulic device having the hydraulic cylinder serving as the slurry supply device, and changing the speed of the hydraulic cylinder. it can.
- FIG. 1B is a schematic cross-sectional view showing a state where the cavity 9 is filled with the supplied slurry 25.
- the slurry 25 includes an alloy powder 21 containing a rare earth element and a dispersion medium 23 such as oil.
- the upper punch 1 and the lower punch 3 are in a stationary state, and therefore the length of the cavity 9 in the molding direction (that is, the distance between the upper punch 1 and the lower punch 3) is It remains constant at L0.
- the same magnetic field as that in FIG. 1A is applied to the inside of the cavity 9.
- the supply pressure of the slurry is preferably 1.96 MPa to 14.71 MPa (20 kgf / cm 2 to 150 kgf / cm 2 ).
- the supply port 15 preferably has a diameter of 2 mm to 30 mm.
- the alloy powder 21 of the slurry 25 supplied into the cavity 9 has a magnetization direction parallel to the direction of the magnetic field, that is, parallel to the forming direction due to a magnetic field of 1.5 T or more applied in the cavity.
- the arrows shown in the alloy powder 21 schematically indicate the magnetization direction of the alloy powder 21.
- FIG.1 (c) and FIG.1 (d) are schematic sectional drawings which show a press molding typically.
- FIG. 1C shows a state where the cavity 9 is compressed until the length in the molding direction becomes L1 (L0> L1)
- FIG. 1D shows that the length of the cavity 9 in the molding direction is obtained. It is in the state compressed until it became LF (L1> LF) which is the length of the forming object to perform.
- the press molding is performed by moving at least one of the upper punch 1 and the lower punch 3 and causing the upper punch 1 and the lower punch 3 to approach each other to reduce the volume of the cavity 9.
- the lower punch 3 is fixed, and the upper punch 1 and the mold 5 are integrated, and the direction of the arrow P in the drawing (in the drawing) Press molding is performed by moving from the upper direction to the lower direction.
- the “cake layer” refers to a layer in which the concentration of the alloy powder is increased by filtering out the dispersion medium in the slurry to the outside of the cavity 9 (in many cases, the so-called “cake layer”). In a cake-like state).
- the ratio (L0 / LF) of the length (L0) in the molding direction of the cavity 9 before press molding to the length (LF) in the molding direction of the obtained molded body is 1. It is preferably 1 to 1.4.
- the alloy powder 21 in which the magnetization method is oriented in the direction of the magnetic field rotates due to the stress applied during press forming, and the magnetization direction is parallel to the magnetic field. The risk of deviating from any direction can be reduced, and the magnetic properties can be further improved.
- a method of increasing the concentration of the slurry for example, 84% or more
- FIG. 2 is a schematic cross-sectional view illustrating another embodiment of a magnetic field press.
- FIG. 2 shows a state where the slurry supply is completed and press molding is started in the molding apparatus 200.
- the upper punch 1 ⁇ / b> A can move up and down, and the lower portion of the upper punch 1 ⁇ / b> A is located in the through hole of the mold 5.
- the die 5 is fixed, and the press in the magnetic field is performed in the directions of arrows P indicating the upper punch 1A and the lower punch 3 respectively (that is, the upper punch 1A is downward and the lower punch 3 is upward).
- the mold 5 and the upper punch 1 may be fixed, and the lower punch 3 may be moved in the direction of the arrow P (upward) to perform pressing in the magnetic field. .
- pressing in the magnetic field may be performed by fixing the upper punch 1 and moving the die 5 and the lower punch 3 integrally upward.
- the composition of the alloy powder is an RTB-based sintered magnet (R is at least one rare earth element (concept including yttrium (Y)), and T is iron (Fe ) Or iron and cobalt (Co), B means boron) and known rare earth sintered magnet compositions including samarium-cobalt sintered magnets.
- RTB-based sintered magnet is preferable. This is because it exhibits the highest magnetic energy product among various magnets and is relatively inexpensive.
- R is selected from at least one of Nd, Pr, Dy, and Tb. However, it is preferable that R contains either one of Nd and Pr. More preferably, a combination of rare earth elements represented by Nd—Dy, Nd—Tb, Nd—Pr—Dy or Nd—Pr—Tb is used.
- Dy and Tb are particularly effective in improving HcJ .
- a small amount of other rare earth elements such as Ce or La may be contained, and misch metal or didymium can also be used.
- R may not be a pure element, and may contain impurities that are unavoidable in the production within the industrially available range.
- a conventionally known content can be adopted as the content, and for example, a range of 25% by mass to 35% by mass is a preferable range.
- High magnetic properties is less than 25 wt%, may not particularly high H cJ is obtained, there are cases where B r is reduced when it exceeds 35 mass%.
- T contains iron (including the case where T is substantially composed of iron), and may be substituted by 50% or less by weight of cobalt (Co) (T is substantially composed of iron and cobalt). Including cases). Co is effective for improving temperature characteristics and corrosion resistance, and the alloy powder may contain 10% by mass or less of Co. The content of T may occupy the remainder of R and B or R and B and M described later.
- the content of B may be a known content, and for example, 0.9 mass% to 1.2 mass% is a preferable range. Is less than 0.9 wt% may high H cJ can not be obtained in some cases B r decreases when exceeding 1.2 mass%.
- a part of B can be substituted with C (carbon). Substitution with C may be able to improve the corrosion resistance of the magnet.
- the total content of B + C (when both B and C are included) is preferably set within the above B concentration range by converting the number of C substitution atoms by the number of B atoms.
- an M element can be added to improve HcJ .
- the element M is at least one selected from the group consisting of Al, Si, Ti, V, Cr, Mn, Ni, Cu, Zn, Ga, Zr, Nb, Mo, In, Sn, Hf, Ta, and W.
- the amount of M element added is preferably 2.0% by mass or less. This is because if it exceeds 5.0% by mass, Br may decrease. Inevitable impurities can also be tolerated.
- Alloy powder manufacturing method For example, an alloy powder is prepared by ingot or flakes of a raw material alloy for rare earth magnets having a desired composition by a melting method, and hydrogen is absorbed (occluded) in the alloy ingots and flakes to be hydrogen pulverized. To obtain coarsely pulverized powder. The coarsely pulverized powder can be further pulverized by a jet mill or the like to obtain a fine powder (alloy powder).
- An alloy ingot can be obtained by an ingot casting method in which a metal prepared in advance so as to have a finally required composition is melted and placed in a mold.
- the molten metal is brought into contact with a single roll, twin roll, rotating disk or rotating cylindrical mold, and rapidly cooled to produce a solidified alloy that is thinner than an alloy made by the ingot method. Alloy flakes can be produced by a rapid cooling method.
- the thickness of the rare earth magnet raw material alloy (quenched alloy) produced by the quenching method is usually in the range of 0.03 mm to 10 mm and has a flake shape.
- the molten alloy begins to solidify from the contact surface (roll contact surface) of the cooling roll, and crystals grow in a columnar shape from the roll contact surface in the thickness direction.
- the quenched alloy is cooled in a short time as compared with an alloy (ingot alloy) produced by a conventional ingot casting method (die casting method), so that the structure is refined and the crystal grain size is small. Moreover, the area of a grain boundary is wide.
- the rapid cooling method is excellent in the dispersibility of the R-rich phase. For this reason, it is easy to break at the grain boundary by the hydrogen pulverization method.
- the size of the hydrogen pulverized powder can be set to 1.0 mm or less, for example.
- an alloy powder having a D50 particle size of 3 to 7 ⁇ m can be obtained by an air flow dispersion type laser analysis method.
- the jet mill has (a) an atmosphere composed of nitrogen gas and / or argon gas (Ar gas) with an oxygen content of substantially 0% by mass, or (b) an oxygen content of 0.005 to 0.5 mass. It is preferable to perform in an atmosphere composed of% nitrogen gas and / or Ar gas. In order to control the amount of nitrogen in the obtained sintered body, it is more preferable to adjust the concentration of the nitrogen gas in the Ar gas by setting the atmosphere in the jet mill to Ar gas and introducing a small amount of nitrogen gas therein. .
- a dispersion medium is a liquid which can obtain a slurry by disperse
- a preferable dispersion medium used in the present invention mention may be made of mineral oil or synthetic oil.
- the type of mineral oil or synthetic oil is not specified.
- the kinematic viscosity at room temperature of mineral oil or synthetic oil is preferably 10 cst or less.
- the fractional distillation point of mineral oil or synthetic oil exceeds 400 ° C., deoiling after obtaining a molded body becomes difficult, and the amount of residual carbon in the sintered body increases and the magnetic properties may be lowered. Therefore, the fractional distillation point of mineral oil or synthetic oil is preferably 400 ° C. or lower.
- vegetable oil may be used as a dispersion medium.
- Plant oil refers to oil extracted from plants, and the types of plants are not limited to specific plants. For example, soybean oil, rapeseed oil, corn oil, safflower oil or sunflower oil can be used.
- a slurry can be obtained by mixing the obtained alloy powder and a dispersion medium.
- the mixing ratio of the alloy powder and the dispersion medium is not particularly limited, but the concentration of the alloy powder in the slurry is preferably 70% or more (that is, 70% or more) by mass ratio. This is because the alloy powder can be efficiently supplied into the cavity at a flow rate of 20 to 600 cm 3 / sec, and excellent magnetic properties can be obtained.
- the concentration of the alloy powder in the slurry is preferably 90% or less in terms of mass ratio. This is to ensure the fluidity of the slurry. More preferably, the concentration of the alloy powder in the slurry is 75% to 88% by mass ratio.
- the alloy powder can be supplied more efficiently and the fluidity of the slurry can be ensured more reliably. Even more preferably, the concentration of the alloy powder in the slurry is 84% or more by mass ratio. As described above, the ratio (L0 / LF) of the cavity 9 in the molding direction length (L0) to the molding direction length (LF) of the obtained molded body can be as low as 1.1 to 1.4. As a result, the magnetic characteristics can be further improved.
- the mixing method of the alloy powder and the dispersion medium is not particularly limited.
- the alloy powder and the dispersion medium may be prepared separately, and a predetermined amount may be weighed and mixed together.
- a container containing a dispersion medium is placed in the alloy powder outlet of a pulverizer such as a jet mill and the alloy powder obtained by pulverization
- the slurry may be collected directly in the dispersion medium in the container to obtain a slurry.
- the atmosphere in the container is also made of nitrogen gas and / or argon gas, and the obtained alloy powder is directly collected in the dispersion medium without being exposed to the atmosphere to form a slurry.
- a slurry comprising an alloy powder and a dispersion medium by wet pulverization using a vibration mill, a ball mill, an attritor or the like while the coarsely pulverized powder is held in the dispersion medium.
- a dispersion medium such as mineral oil or synthetic oil remains in the molded body obtained by the wet molding method (longitudinal magnetic field molding method) described above.
- a sintering temperature of, for example, 950 to 1150 ° C.
- the internal temperature of the molded body increases rapidly, and the dispersion medium remaining in the molded body reacts with the rare earth elements of the molded body.
- rare earth carbide may be produced.
- the rare earth carbide is thus formed, the generation of a sufficient amount of liquid phase for sintering is hindered, and a sintered body having a sufficient density cannot be obtained and the magnetic properties may be deteriorated.
- the deoiling treatment is preferably performed at 50 to 500 ° C., more preferably 50 to 250 ° C. and a pressure of 13.3 Pa (10 ⁇ 1 Torr) or less for 30 minutes or more. This is because the dispersion medium remaining in the molded body can be sufficiently removed.
- the heating and holding temperature in the deoiling treatment is not necessarily one temperature as long as it is in the temperature range of 50 to 500 ° C., and may be two or more temperatures. Further, by performing a deoiling treatment in which the temperature rising rate from room temperature to 500 ° C. is 10 ° C./min, preferably 5 ° C./min, under a pressure condition of 13.3 Pa (10 ⁇ 1 Torr) or less, The same effects as those of the preferred deoiling treatment can be obtained.
- the compact is preferably sintered under a pressure of 0.13 Pa (10 ⁇ 3 Torr) or less, more preferably 0.07 Pa (5.0 ⁇ 10 ⁇ 4 Torr) or less at a temperature of 1000 It is preferably carried out in the range of 1 ° C to 1150 ° C.
- the residual gas in the atmosphere is preferably replaced with an inert gas such as helium or argon.
- the obtained sintered body is preferably subjected to a heat treatment.
- the heat treatment can improve the magnetic properties.
- Known conditions can be adopted as the heat treatment conditions such as heat treatment temperature and heat treatment time.
- Example 1 The molten alloy was melted by a high-frequency melting furnace so that the composition was Nd 20.7 Pr 5.5 Dy 5.5 B 1.0 Co 2.0 Al 0.1 Cu 0.1 balance Fe (mass%). Quenching was performed by a strip casting method to obtain a flaky alloy having a thickness of 0.5 mm. The alloy was coarsely pulverized by a hydrogen pulverization method, and further finely pulverized by a jet mill with nitrogen gas having an oxygen content of 10 ppm (0.001% by mass, ie substantially 0% by mass). The obtained alloy powder had a particle size D50 of 4.7 ⁇ m.
- the alloy powder was immersed in a mineral oil (product name: MC OIL P-02, manufactured by Idemitsu Kosan Co., Ltd.) having a fractional distillation point of 250 ° C. and a kinematic viscosity at room temperature of 2 cst in a nitrogen atmosphere. %) Slurry was prepared.
- a mineral oil product name: MC OIL P-02, manufactured by Idemitsu Kosan Co., Ltd.
- a parallel magnetic field forming apparatus shown in FIG. 1 was used for press forming.
- a mold having a cavity size of 145 mm in length and 145 mm in width was used.
- the cavity depth (the length in the magnetic field application direction) was 85 mm.
- the cavity is supplied from the supply port 15 with the slurry concentration, slurry flow rate and slurry supply pressure shown in Table 1 from a slurry supply device (not shown). 9 was supplied with the slurry.
- the molding pressure is 98 MPa so that the ratio (L0 / LF) of the cavity length (L0) to the molded body length (LF) after molding becomes the value shown in Table 1.
- Press molding was performed at (1 ton / cm 2 ).
- Sample No. 4 shows that the slurry flow rate was Sample No. Same as 3, 5 and 9, but the slurry supply pressure is different. This is a sample No. For No. 4, by adjusting the pressure control valve of the hydraulic device, changing the slurry supply pressure, and adjusting the slurry flow rate adjustment valve, The same slurry flow rate was obtained at a slurry supply pressure different from 3, 5, and 9.
- the slurry flow rate was 15 cm 2 / sec (sample No. 1)
- the slurry could not be supplied to the cavity due to the pipe resistance, and press molding could not be performed.
- the slurry flow rate was 700 cm 2 / sec (sample No. 8)
- the molded body was cracked when the molded body was taken out after press molding, and thus could not be sintered.
- Obtained sample No. The molded bodies of 2 to 7 and 9 were heated from room temperature to 150 ° C. at 1.5 ° C./min in vacuum, held at that temperature for 1 hour, and then heated to 500 ° C. at 1.5 ° C./min. Mineral oil in the molded body was removed, and the temperature was further increased from 500 ° C. to 1100 ° C. at 20 ° C./min, and the temperature was maintained for 2 hours for sintering. The obtained sintered body was heat-treated at 900 ° C. for 1 hour, and further heat-treated at 600 ° C. for 1 hour.
- FIG. 3 a cube shape having a side of 7 mm from 12 portions shown in FIG. 3 (one side of the cube is parallel to the magnetic field application direction as shown in FIG. 3).
- the magnet samples were cut out, and the magnetic properties (B r , H cJ ) of each magnet sample after cutting out were measured with a BH tracer.
- An arrow B in FIG. 3 indicates the direction of the magnetic field applied during press molding.
- 1U, 2U, 3U, and 4U correspond to the vicinity of the four corners of the upper surface of the molded body that was in contact with the upper punch 1 during press molding
- 5U represents the center of the upper surface. It corresponds to the vicinity of the part.
- 5M corresponds to the vicinity of the center of the molded body
- 6S corresponds to the vicinity of the supply port 15.
- 1L, 2L, 3L, and 4L correspond to the vicinity of the four corners of the lower surface of the molded body that was in contact with the lower punch 3 during press molding
- 5L corresponds to the vicinity of the center portion of the lower surface.
- Table 2 shows the value of the residual magnetic flux density Br .
- the coercive force HcJ of each magnet was in the range of 1710 to 1790 kA / m.
- the sintered magnet of the present invention (Sample No.) based on a compact formed by pressing a slurry by supplying a slurry at a flow rate of 20 to 600 cm 3 / sec into a cavity to which a magnetic field of 1.5 T or more is applied. .2 to 7), B r is high and B r at the respective portions of the magnet itself is almost uniform.
- Sample No. 3 and sample no. As evident from comparison of 4, the slurry flow rate does not change at all the uniformity of the B r at the respective portions of the magnet itself be varied slurry supply pressure when the same. Furthermore, sample no. 3 and sample no. As is apparent from the comparison of FIG. 5, sample Nos. With L0 / LF in the range of 1.1 to 1.4. In the case of No. 3, uniform Br was obtained in each part of the magnet alone.
- Example 2 As the mold, a mold 5 having a cavity having a substantially arcuate cross section with an R width of 35 mm, an R height of 15 mm, and a wall thickness of 8 mm is used, and the cavity depth (length in the magnetic field application direction) is set to 80 mm.
- Sample No. 1 of Example 1. Using the same slurry as No. 3, press molding was performed under the same conditions. The obtained molded body was sintered under the same conditions as in Example 1 to obtain a long sintered magnet having a substantially arcuate cross section.
- a magnet sample having a cubic shape with a side of 3 mm is cut from 12 portions shown in FIG. 4 and one side of the cube is parallel to the magnetic field application direction (direction of arrow B in FIG. 4).
- the magnetic properties (B r , H cJ ) of each magnet sample after cutting were measured with a BH tracer.
- An arrow B in FIG. 4 indicates the direction of the magnetic field applied during press molding.
- 1U, 2U, 3U, 4U, and 5U correspond to the vicinity of the upper surface of the molded body that was in contact with the upper punch 1 during press molding, and 1U and 4U are substantially arc-shaped.
- 2U and 3U correspond to the vicinity of the end of the substantially arc-shaped inner peripheral surface
- 5U corresponds to the vicinity of the center portion of the upper surface
- 1L, 2L, 3L, 4L, and 5L correspond to the vicinity of the lower surface of the molded body that was in contact with the lower punch 3 during press molding
- 1L and 4L correspond to the vicinity of the end of the substantially arc-shaped outer peripheral surface
- 3L corresponds to the vicinity of the end portion of the substantially arc-shaped inner peripheral surface
- 5L corresponds to the vicinity of the center portion of the lower surface
- 5M corresponds to the vicinity of the center of the molded body
- 6S corresponds to the vicinity of the supply port 15.
- the HcJ of each magnet was in the range of 1710 to 1790 kA / m.
- the slurry of the present invention based on a long shaped body having a substantially arcuate cross section obtained by supplying slurry at a flow rate of 200 cm 3 / sec into a cavity to which a magnetic field of 1.5 T or more is applied.
- sintered magnet (sample No.10) is, B r is high and B r at the respective portions of the magnet itself is almost uniform.
- the cross section used as a magnet for a voice coil motor of a hard disk drive is In the direction of applying a magnetic field, such as a substantially arcuate shape with an outer R surface (substantially arc-shaped outer peripheral surface), an inner R surface (substantially arc-shaped inner peripheral surface), and a convex portion formed on at least part of the arc end surface.
- a magnetic field such as a substantially arcuate shape with an outer R surface (substantially arc-shaped outer peripheral surface), an inner R surface (substantially arc-shaped inner peripheral surface), and a convex portion formed on at least part of the arc end surface.
- a sintered magnet having a large size and a complicated cross-sectional shape in a direction perpendicular to the magnetic field application direction can be easily manufactured.
- Comparative Example 1 Using the same alloy powder as in Example 1, press molding was performed in the air by a parallel magnetic field molding method using a dry molding method. A mold having a cavity size of 55 mm in length and 40 mm in width was used. The depth of the cavity (the length in the magnetic field application direction) was 8 mm.
- press molding the cavity is filled with alloy powder, the upper punch is lowered to seal the cavity, a static magnetic field with a magnetic field strength of 1.0 T is applied in the depth direction of the cavity, and then the upper punch is further lowered. Then, press molding was performed at a molding pressure of 98 MPa (1 ton / cm 2 ) so that the ratio (L0 / LF) of the cavity length (L0) to the molded body length (LF) after molding was 1.7.
- Example No. 11 The obtained compact was sintered under the same conditions as in Example 1 to obtain a sintered magnet (Sample No. 11).
- a cube sample with a 3 mm piece one side of the cube is parallel to the magnetic field application direction) is cut out from the central portion of the obtained sintered magnet, and the magnetic properties (B r , H cJ ) of the cut magnet sample are measured with a BH tracer. ) results of measurement of, B r is 1.23T, H cJ was 1750kA / m.
- a sintered magnet obtained by the parallel magnetic field molding by a dry molding method compared to the sintered magnet of the present invention, B r is decreased. This is because the alloy powder and the molded body are oxidized when the alloy powder is supplied to the cavity or when the molded body is taken out after the press molding, and the amount of oxygen in the molded body is increased. This is because the degree of orientation of the alloy powder is not high.
- Comparative Example 2 Using the same alloy powder as in Example 1, press molding was performed in the atmosphere by a perpendicular magnetic field molding method using a dry molding method. A mold having a cavity size of 64 mm in length and 5 mm in width was used. The cavity depth was 54 mm. The 5 mm direction is the magnetic field application direction.
- press molding In press molding, the cavity is filled with alloy powder, the upper punch is lowered to seal the cavity, a static magnetic field with a magnetic field strength of 1.0 T is applied in the depth direction of the cavity, and then the upper punch is further lowered. Then, press molding was performed at a molding pressure of 98 MPa (1 ton / cm 2 ) such that the ratio (L0 / LF) of the cavity length (L0) to the length (LF) of the molded body after molding was 2.2.
- Example No. 12 The obtained molded body was sintered under the same conditions as in Example 1 to obtain a sintered magnet (Sample No. 12).
- a cube sample with a 3 mm piece (one side of the cube is parallel to the magnetic field application direction) is cut out from the central portion of the obtained sintered magnet, and the magnetic properties (B r , H cJ ) of the cut magnet sample are measured with a BH tracer. ) results of measurement of, B r is 1.30 T, H cJ was 1750kA / m.
- a sintered magnet obtained by the perpendicular magnetic field molding by a dry molding method compared to the sintered magnet of the present invention, B r is decreased slightly.
- B r is improved. This is because the perpendicular magnetic field forming method can be formed without disturbing the orientation of the alloy powder oriented in the magnetic field application direction than the parallel magnetic field forming method.
- Comparative Example 3 Sample No. 1 of Example 1 Using the same slurry as No. 3, press molding was performed by a perpendicular magnetic field molding method using a wet molding method. A mold having a cavity size of 60 mm in length and 40 mm in width was used. The cavity depth was 55 mm. The horizontal 40 mm direction is the magnetic field application direction.
- a cavity is formed by lowering an upper punch, and a static magnetic field having a magnetic field strength of 1 T is applied in the cavity lateral direction (40 mm direction) in the cavity, and then a slurry flow rate of 400 cm 3 / second is supplied from a slurry supply device.
- the slurry was supplied from the supply port to the cavity at a slurry supply pressure of 5.88 MPa (60 kgf / cm 2 ).
- the molding pressure of 39 MPa (0. 0) is set so that the ratio (L0 / LF) of the cavity length (L0) to the molded body length (LF) after molding is 1.45. 4 ton / cm 2 ).
- the obtained compact was sintered under the same conditions as in Example 1 to obtain a sintered magnet (Sample No. 13).
- a magnet sample having a cube shape with a side of 7 mm (as shown in FIG. 5, one side of the cube is parallel to the magnetic field application direction) is cut out from 10 portions I to X shown in FIG.
- the magnetic properties (B r , H cJ ) of each magnet sample after cutting were measured with a BH tracer.
- An arrow B in FIG. 5 indicates the direction of the magnetic field applied during press molding.
- I, II, III, IV, and V correspond to the vicinity of the upper surface of the molded body that was in contact with the upper punch during press molding. As can be seen from FIG.
- I to V are arranged in a straight line
- III corresponds to the vicinity of the central portion
- I and V correspond to the vicinity of the end portion
- VI, VII, VIII, IX, and X correspond to the vicinity of the lower surface of the molded body that was in contact with the lower punch during press molding.
- VI to X are arranged in a straight line
- VIII corresponds to the vicinity of the central portion
- VI and X correspond to the vicinity of the end portion.
- the HcJ of the magnets I to X was in the range of 1710 to 1790 kA / m.
- the magnetic characteristics of each part of the magnet alone are uniform and have high magnetic characteristics.
- Rare earth sintered magnets can be easily manufactured.
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Abstract
Description
また、プレス成形(磁界中プレス成形)の方法は2つに大別される。一方は、得られた合金粉末を乾燥した状態のままプレス成形する乾式成形法である。他方は、例えば、特許文献1に記載される湿式成形法であり、合金粉末を油等の分散媒に分散させてスラリーとし、合金粉末をこのスラリーの状態で金型のキャビティ内に供給しプレス成形を行う。
湿式成形法ではキャビティ内にスラリーを入れて磁界中プレス成形を行う際に、スラリー中の分散媒(油等)の多くをキャビティ外に排出する必要があり、通常、上パンチまたは下パンチの少なくとも一方に分散媒排出孔を設け、上パンチおよび/または下パンチの移動によりキャビティの体積が減少し、スラリーが加圧されると分散媒排出孔から分散媒が排出される。この際、分散媒排出孔に近い部分からスラリー中の分散媒が濾過排出(濾過および排出)されるため、プレス成形の初期段階では分散媒排出孔に近い部分に合金粉末の濃度が高くなった(密度が高い)「ケーキ層」と呼ばれる層を形成する。
ケーキ層は合金粉末の密度が高い(単位体積当たりの合金粉末量が多い)ため、スラリーのケーキ層以外の部分(単位体積当たりの合金粉末量が少ない部分)と比較して透磁率が高くなっている。このため、磁界は、ケーキ層に集束することとなる。これは、喩え、キャビティの外側では磁界がキャビティ側面に概ね垂直に印加されても、キャビティ内部では磁界がケーキ層の方に曲げられることを意味する。従って、この曲がった磁界に沿って合金粉末が配向するため、プレス成形後の成形体において、配向が曲がった部分が存在することとなり、成形体単体における配向度が低下し、焼結磁石において十分な磁気特性が得られない場合がある。
このため、前記方法では直方体などの比較的単純な形状は製造可能であるが、断面が略弓形などの複雑形状の場合は、形成するのが困難であり、また喩え特許文献2に記載の方法等により形成できても十分な磁気特性を得ることができない場合が多かった。
さらに、近年、ハードディスクドライブのボイスコイルモータ用磁石として用いられている、断面が略弓形で外R面(略円弧状の外周面)、内R面(略円弧状の内周面)および円弧端面の少なくとも一部に凸部が形成されたような形状など、磁界印加方向に寸法が大きく、且つ磁界印加方向と直交する方向の断面形状が複雑な形状の長尺成形品を乾式成形法により製造することは不可能であった。
また、本発明は、磁界印加方向に寸法が大きく、磁界印加方向と直交する方向の断面が複雑な形状の希土類系焼結磁石の製造方法を提供することを目的とする。
また、本発明により、磁界印加方向に寸法が大きく、磁界印加方向と直交する方向の断面が複雑な形状の希土類系焼結磁石の製造方法を提供できる。
そこで、本発明者らは鋭意検討した結果、平行磁界成形法において、キャビティ内に1.5T以上の磁界を印加した状態で、キャビティ内にスラリーを流量20cm3/秒~600cm3/秒の範囲で供給して成形体を製造することにより成形体の各部分における密度ばらつきがほとんど無くなり、この結果、当該成形体より得た希土類系焼結磁石の各部分における磁気特性が均一で(磁石の部位の差による磁気特性のバラツキが少なく)かつ高い磁気特性を有することを見出し本発明に至ったものである。
ただし、この理由は、現時点で得られている知見から推定したものであり、本発明の技術的範囲を制限することを意図したものではないことに留意すべきである。
すなわち、このような状態でスラリーを供給し(前記の山を押し上げるように)キャビティ内をスラリーで満たした後プレス成形することは、合金粉末の密度(単体積あたりに存在する合金粉末の量)が、キャビティの中心部および底部に比べてキャビティの上部および周囲の方が低い状態でプレス成形することとなり、従って、得られた成形体の中心部や底部に比べ上部や周囲の密度が低くなると考えられる。成形体の各部分において密度が異なると、成形体を焼結して得られる焼結磁石の磁気特性の低下および場所によるバラツキを生ずることとなる。
さらに、このような密度のバラツキがあると、プレス成形後の成形体取出し時に成形体に割れが生じる場合があり、また、成形体で割れが無くても、焼結時の収縮により割れが生じる場合がある。
すなわち、1.5T以上の磁界を印加した状態でキャビティ内にスラリーを供給する場合は、磁界の強さが1.5T未満である従来の成形方法と同様に比較的大きい流量でスラリーをキャビティ内に供給すると、固液分離が顕著となり、成形体の各部分における密度にばらつきが多く発生するものと考えられる。
以下に、本発明の希土類系焼結磁石の製造方法に係る成形工程の詳細を示す。
図1(a)~図1(d)は、本発明の希土類系焼結磁石の製造方法を示す概略断面図である。以降、図1(a)~図1(d)を纏めて「図1」という場合がある。
図1(a)は、スラリーを供給する前の成形装置100の概略断面図である。成形装置100は、金型5の貫通孔と上パンチ1と下パンチ3とに取り囲まれたキャビティ9を有している。
キャビティ9は、成形方向に沿った長さL0を有している。ここで、成形方向とは、上パンチと下パンチの少なくとも一方が他方に接近するために移動する方向(すなわちプレス方向)を意味する。
図1に示す実施形態では、後述するように下パンチ3が固定され、上パンチ1と金型5とが、一体的に移動する。従って、図1において上から下に向かう方向(図1(c)および図1(d)の矢印Pの方向)が成形方向である。
上パンチ1が分散媒排出孔11を有する場合、上パンチ1は、分散媒排出孔11を覆うように、例えば濾布、濾紙、多孔質フィルターまたは金属フィルターのようなフィルター13を有することが好ましい。これにより、合金粉末が分散媒排出孔11内に侵入するのをより確実に防止(すなわち、分散媒のみを濾過)し、スラリー中の分散媒をキャビティ9の外側に濾過排出できる。
次に、キャビティ9内に20~600cm3/秒の流量(スラリー供給量)でスラリー25を供給する。流量が20cm3/秒未満では、流量を調整することが困難であり、また、配管抵抗によってキャビティ内にスラリーを供給できない場合があるからである。一方、流量が600cm3/秒を超えると、上述のように、成形体の各部分における密度にばらつきが発生し、プレス成形後の成形体取出し時に成形体に割れが生じる、または焼結時の収縮により割れが生じる場合があるからである。また、スラリー供給口近傍に配向の乱れが生じ得るからである。
スラリーの流量は、好ましくは20~400cm3/秒であり、より好ましくは20~200cm3/秒である。前記好ましい範囲さらには前記より好ましい範囲にすることにより、成形体の各部分における密度ばらつきをより一層低減することができる。
スラリーの流量は、スラリー供給装置となる油圧シリンダを有する油圧装置の流量調整弁を調整することによって、油圧シリンダへ送り込む油の流量を変化させ、油圧シリンダの速度を変化させることによって制御することができる。
このように、キャビティ9が供給されたスラリー25により満たされた後、プレス成形を行う。
図1(c)および図1(d)は、プレス成形を模式的に示す概略断面図である。
図1(c)は、キャビティ9の成形方向の長さがL1(L0>L1)となるまで圧縮した状態を示し、図1(d)は、キャビティ9の成形方向の長さが得ようとする成形体の長さであるLF(L1>LF)となるまで圧縮した状態である。
図2は、磁界中プレスの別の実施形態を例示する概略断面図である。図2は、成形装置200において、スラリー供給が完了し、プレス成形を開始する状態を示している。
金型5は固定されており、磁界中プレスは、上パンチ1Aと下パンチ3とをそれぞれに示した矢印Pの向き(すなわち、上パンチ1Aを下方向に、下パンチ3を上方向)に移動させて実施する。
また、この図2の実施形態の変形例として、金型5と上パンチ1とを固定し、下パンチ3を矢印Pの方向(上方向)に移動させて磁界中プレスを実施してもよい。
さらに、上パンチ1を固定し、金型5と下パンチ3とを一体的に上方向に移動させて磁界中プレスを実施してもよい。
以下に、成形工程以外の工程について説明する。
(1)スラリーの作製
・合金粉末の組成
合金粉末の組成は、R-T-B系焼結磁石(Rは希土類元素(イットリウム(Y)を含む概念)の少なくとも1種、Tは鉄(Fe)または鉄とコバルト(Co)、Bは硼素を意味する)およびサマリウム・コバルト系焼結磁石を含む既知の希土類系焼結磁石の組成を有してよい。
好ましいのは、R-T―B系焼結磁石である。各種磁石の中でも最も高い磁気エネルギー積を示し、かつ比較的安価であるからである。
Rは、Nd、Pr、Dy、Tbのうち少なくとも一種から選択される。ただし、Rは、NdおよびPrのいずれか一方を含むことが好ましい。更に好ましくは、Nd-Dy、Nd-Tb、Nd-Pr-DyまたはNd-Pr-Tbで示される希土類元素の組合せを用いる。
合金粉末は例えば、溶解法により、所望の組成を有する希土類系磁石用原料合金のインゴットまたはフレークを作製し、この合金インゴットおよびフレークに水素を吸収(吸蔵)させて水素粉砕を行い、粗粉砕粉を得る。
そして、粗粉砕粉をジェットミル等により更に粉砕して微細粉(合金粉末)を得ることができる。
最終的に必要な組成となるように事前に調整した金属を溶解し、鋳型に入れるインゴット鋳造法により合金インゴットを得ることができる。
また、溶湯を単ロール、双ロール、回転ディスクまたは回転円筒鋳型等に接触させて急冷し、インゴット法で作られた合金よりも薄い凝固合金を作製するストリップキャスト法または遠心鋳造法に代表される急冷法により合金フレークを製造することができる。
急冷法によって作製した希土類系磁石用原料合金(急冷合金)の厚さは、通常0.03mm~10mmの範囲にあり、フレーク形状である。合金溶湯は冷却ロールの接触した面(ロール接触面)から凝固し始め、ロール接触面から厚さ方向に結晶が柱状に成長してゆく。急冷合金は、従来のインゴット鋳造法(金型鋳造法)によって作製された合金(インゴット合金)と比較して、短時間で冷却されているため、組織が微細化され、結晶粒径が小さい。また粒界の面積が広い。Rリッチ相は粒界内に大きく広がるため、急冷法はRリッチ相の分散性に優れる。
このため水素粉砕法により粒界で破断し易い。急冷合金を水素粉砕することで、水素粉砕粉(粗粉砕粉)のサイズを例えば1.0mm以下とすることができる。
ジェットミルは、(a)酸素含有量が実質的に0質量%の窒素ガスおよび/またはアルゴンガス(Arガス)からなる雰囲気中、または(b)酸素含有量が0.005~0.5質量%の窒素ガスおよび/またはArガスからなる雰囲気中で行うのが好ましい。
得られる焼結体中の窒素量制御するために、ジェットミル内の雰囲気をArガスとし、その中に窒素ガスを微量導入して、Arガス中の窒素ガスの濃度を調整することがより好ましい。
分散媒は、その内部に合金粉末を分散させることによりスラリーを得ることができる液体である。
本発明に用いる好ましい分散媒として鉱物油または合成油を挙げることができる。
鉱物油または合成油はその種類が特定されるものではないが、常温での動粘度が10cstを超えると粘性の増大によって合金粉末相互の結合力が強まり磁界中湿式成形時の合金粉末の配向性に悪影響を与える場合がある。
このため鉱物油または合成油の常温での動粘度は10cst以下が好ましい。また鉱物油または合成油の分留点が400℃を超えると成形体を得た後の脱油が困難となり、焼結体内の残留炭素量が多くなって磁気特性が低下する場合がある。
したがって、鉱物油または合成油の分留点は400℃以下が好ましい。
得られた合金粉末と分散媒とを混合することでスラリーを得ることができる。
合金粉末と分散媒との混合率は特に限定されないが、スラリー中の合金粉末の濃度は、質量比で、好ましくは70%以上(すなわち、70質量%以上)である。20~600cm3/秒の流量において、キャビティ内部に効率的に合金粉末を供給できると共に、優れた磁気特性が得られるからである。
また、スラリー中の合金粉末の濃度は、質量比で、好ましくは90%以下である。スラリーの流動性を確実に確保するためである。
より好ましくは、スラリー中の合金粉末の濃度は、質量比で、75%~88%である。より効率的に合金粉末を供給でき、かつより確実にスラリーの流動性を確保できるからである。
更により好ましくは、スラリー中の合金粉末の濃度は、質量比で、84%以上である。上述のように、キャビティ9の成形方向の長さ(L0)の得られる成形体の成形方向の長さ(LF)に対する比(L0/LF)を1.1~1.4と低い値にでき、その結果、磁気特性をより一層向上できるからである。
合金粉末と分散媒とを別々に用意し、両者を所定量秤量して混ぜ合わせることによって製造してよい。
あるいは粗粉砕粉をジェットミル等で乾式粉砕して合金粉末を得る際にジェットミル等の粉砕装置の合金粉末排出口に分散媒を入れた容器を配置し、粉砕して得られた合金粉末を容器内の分散媒中に直接回収しスラリーを得てもよい。この場合、容器内も窒素ガスおよび/またはアルゴンガスからなる雰囲気とし、得られた合金粉末を大気に触れさせることなく直接分散媒中に回収して、スラリーとすることが好ましい。
上述した湿式成形法(縦磁界成形法)により得た成形体には鉱物油または合成油等の分散媒が残留している。
この状態の成形体を常温から例えば950~1150℃の焼結温度まで急激に昇温すると成形体の内部温度が急激に上昇し、成形体内に残留した分散媒と成形体の希土類元素とが反応して希土類炭化物を生成する場合がある。このように希土類炭化物が形成されると、焼結に充分な量の液相の発生が妨げられ、充分な密度の焼結体が得られず磁気特性が低下する場合がある。
脱油処理の加熱保持温度は50~500℃の温度範囲であれば1つの温度である必要はなく、2つ以上の温度であってもよい。また、13.3Pa(10-1Torr)以下の圧力条件で室温から500℃までの昇温速度を10℃/分以下、好ましくは5℃/分以下とする脱油処理を施すことによっても、前記の好ましい脱油処理と同様の効果を得ることができる。
成形体の焼結は、好ましくは、0.13Pa(10-3Torr)以下、より好ましくは0.07Pa(5.0×10-4Torr)以下の圧力下で、温度1000℃~1150℃の範囲で行なうのが好ましい。なお、焼結による酸化を防止するために、雰囲気の残留ガスは、ヘリウム、アルゴンなどの不活性ガスにより置換しておくことが好ましい。
得られた、焼結体は、熱処理を行うのが好ましい。熱処理により、磁気特性を向上させることができる。熱処理温度、熱処理時間などの熱処理条件は、公知の条件を採用することができる。
組成がNd20.7Pr5.5Dy5.5B1.0Co2.0Al0.1Cu0.1残部Fe(質量%)となるように高周波溶解炉によって溶解し、合金溶湯をストリップキャスト法によって急冷し、厚み0.5mmのフレーク状の合金を得た。前記合金を、水素粉砕法によって粗粉砕し、さらに、ジェットミルにより酸素含有量が10ppm(0.001質量%、すなわち実質的には0質量%)の窒素ガスで微粉砕した。得られた合金粉末の粒径D50は4.7μmであった。前記合金粉末を窒素雰囲気中で分留点が250℃、室温での動粘度が2cstの鉱物油(出光興産製、商品名:MC OIL P-02)に浸漬して表1に示す濃度(質量%)のスラリーを準備した。
表1において、試料No.4は、スラリー流量が試料No.3、5および9と同じであるが、スラリー供給圧力は異なる。これは、試料No.4については、油圧装置の圧力制御弁を調整し、スラリー供給圧力を変更し、またスラリー流量調整弁を調整することにより、試料No.3、5および9と異なるスラリー供給圧力で、同じスラリー流量を得たものである。
図3の矢印Bは、プレス成形時に印加した磁界の方向を示す。
図3に示す12か所の部分のうち、1U、2U、3U、4Uは、プレス成形時に上パンチ1と接していた成形体の上面のそれぞれの四隅の近傍に相当し、5Uは上面の中央部近傍に相当する。5Mは成形体の中央部近傍に相当し、6Sは供給口15の近傍に相当する。1L、2L、3L、4Lは、プレス成形時に下パンチ3と接していた成形体の下面のそれぞれの四隅近傍に相当し、5Lは下面の中央部近傍に相当する。
残留磁束密度Brの値を表2に示す。なお、それぞれの磁石の保磁力HcJは1710~1790kA/mの範囲にあった。
金型として、R幅35mm、R高さ15mm、肉厚8mmの略弓形の断面を有するキャビティを有する金型5を用い、キャビティの深さ(磁界印加方向の長さ)を80mmとする以外は、実施例1の試料No.3と同じスラリーを用い、同じ条件でプレス成形した。得られた成形体を実施例1と同じ条件で焼結し、断面が略弓形の長尺焼結磁石を得た。
図4の矢印Bは、プレス成形時に印加した磁界の方向を示す。
図4に示す12か所の部分のうち、1U、2U、3U、4U、5Uは、プレス成形時に上パンチ1と接していた成形体の上面の近傍に相当し、1Uと4Uは略円弧状の外周面の端部近傍に相当し、2Uと3Uは略円弧状の内周面の端部近傍に相当し、5Uは上面の中央部近傍に相当する。1L、2L、3L、4L、5Lは、プレス成形時に下パンチ3と接していた成形体の下面の近傍に相当し、1Lと4Lは略円弧状の外周面の端部近傍に相当し、2Lと3Lは略円弧状の内周面の端部近傍に相当し、5Lは下面の中央部近傍に相当する。5Mは成形体の中央部近傍に相当し、6Sは供給口15の近傍に相当する。
Brの値を表3に示す。なお、それぞれの磁石のHcJは1710~1790kA/mの範囲にあった。
実施例1と同じ合金粉末を使用して、乾式成形法による平行磁界成形法にて大気中でプレス成形を行った。金型にはキャビティ寸法が縦55mm、横40mmのものを使用した。キャビティの深さ(磁界印加方向の長さ)は8mmとした。
得られた焼結磁石の中央部から一片が3mmの立方体形状(立方体の一辺が磁界印加方向に平行)の磁石サンプルを切り出し、切り出し後の磁石サンプルについてBHトレーサによって磁気特性(Br、HcJ)を測定した結果、Brは1.23T、HcJは1750kA/mであった。
実施例1と同じ合金粉末を使用して、乾式成形法による直角磁界成形法にて大気中でプレス成形を行った。金型にはキャビティ寸法が縦64mm、横5mmのものを使用した。キャビティの深さは54mmとした。5mm方向が磁界印加方向である。
実施例1の試料No.3と同じスラリーを用い、湿式成形法による直角磁界成形法にてプレス成形を行った。金型にはキャビティ寸法が縦60mm、横40mmのものを使用した。キャビティの深さは55mmとした。横40mm方向が磁界印加方向である。
図5の矢印Bは、プレス成形時に印加した磁界の方向を示す。
図5に示す10か所の部分のうち、I、II、III、IV、Vは、プレス成形時に上パンチと接していた成形体の上面の近傍に相当する。図5から判るように、I~Vは直線状に並んでおり、IIIが中央部近傍に相当し、IとVが端部近傍に相当する。VI、VII、VIII、IX、Xは、プレス成形時に下パンチと接していた成形体の下面の近傍に相当する。図5から判るように、VI~Xは直線状に並んでおり、VIIIが中央部近傍に相当し、VIとXが端部近傍に相当する。
Brの値を表4に示す。なお、I~Xの磁石のHcJは1710~1790kA/mの範囲にあった。
3 下パンチ
5 金型
7 電磁石
9 キャビティ
11 分散媒排出孔
13 フィルター
15 供給口
21 合金粉末
23 分散媒
25 スラリー
27 ケーキ層
Claims (6)
- 1)希土類元素と鉄とホウ素とを含む合金粉末と、分散媒と、を所定の比率で含むスラリーを準備する工程と、
2)金型と、少なくとも一方が移動して該金型内で互いに接近離間可能でかつ、少なくとも一方が前記スラリーの前記分散媒を排出するための排出孔を有する上パンチと下パンチと、に取り囲まれたキャビティを準備する工程と、
3)前記キャビティの内部に、前記上パンチと前記下パンチの少なくとも一方が移動可能な方向と平行な方向に1.5T以上の磁界を印加し、前記スラリーを20~600cm3/秒の流量で供給し、該キャビティを前記スラリーで満たす工程と、
4)前記磁界を印加したままで、前記上パンチと前記下パンチとを接近させる磁界中プレス成形により、前記合金粉末の成形体を得る工程と、
5)前記成形体を焼結する工程と、
を含むことを特徴とする希土類系焼結磁石の製造方法。 - 前記スラリーの前記流量が20~400cm3/秒であることを特徴とする請求項1に記載の希土類系焼結磁石の製造方法。
- 前記スラリーの前記流量が20~200cm3/秒であることを特徴とする請求項1に記載の希土類系焼結磁石の製造方法。
- 前記上パンチと前記下パンチの少なくとも一方が移動可能な前記方向において、前記磁界中プレス成形前のキャビティの長さ(L0)の前記成形体の長さ(LF)に対する比(L0/LF)が1.1~1.4であることを特徴とする請求項1~3の何れか1項に記載の希土類系焼結磁石の製造方法。
- スラリー中の合金粉末の濃度が70~90質量%であることを特徴とする請求項1~4の何れか1項に記載の希土類系焼結磁石の製造方法。
- スラリー中の合金粉末の濃度が84質量%以上であることを特徴とする請求項5に記載の希土類系焼結磁石の製造方法。
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EP13810728.9A EP2869319B1 (en) | 2012-06-29 | 2013-06-25 | Method for producing rare earth sintered magnets |
CN201380033804.5A CN104428854B (zh) | 2012-06-29 | 2013-06-25 | 稀土类烧结磁体的制造方法 |
US14/411,266 US10020113B2 (en) | 2012-06-29 | 2013-06-25 | Method for producing rare earth sintered magnet |
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EP2869319B1 (en) | 2018-08-08 |
US10020113B2 (en) | 2018-07-10 |
JP6060971B2 (ja) | 2017-01-18 |
JPWO2014002983A1 (ja) | 2016-06-02 |
CN104428854A (zh) | 2015-03-18 |
EP2869319A4 (en) | 2016-04-06 |
US20150206655A1 (en) | 2015-07-23 |
EP2869319A1 (en) | 2015-05-06 |
CN104428854B (zh) | 2017-03-08 |
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