Permanent magnet and a manufacturing method thereof

BACKGROUND OF THE INVENTION
This invention generally relates to a permanent magnet having magnetic anisotropy by means of mechanical orientation, and a manufacturing method thereof. More particularly, the present invention relates to a permanent magnet comprising R (R being at least one element selected from the group consisting of rare earth elements including Yttrium (Y)), M (M being at least one element selected from the group consisting of transition elements such as Fe, Cu, Au and Zr) and X (X being at least one element selected from the group consisting of B, Al and Ga).
Permanent magnets are important electric-electronic materials which are used in a wide range of fields such as in domestic appliances and in peripheral equipment for computers. In pursuit of the present users' desire for miniaturization and the improved of efficiency of permanent magnets, higher performance permanent magnets have been required.
Permanent magnets are made of a material which can produce magnetic fields without applying electric power, has a high coercive force, and has a high residual magnetic flux density. These requirements are quite different from high permeability magnetic material, which is currently used in magnets of the Alnico series, barium-ferrite and the rare-earth transition metal series.
In particular, permanent magnets of the rare-earth transition metal series, such as R-Co or R-Fe-B magnets, have high magnetic properties having very high coercive forces, and energy-product values, therefore, much research and development has been carried out on them.
Described below are several references concerning high performance anisotropic permanent magnets of the rare-earth-iron (transition metal) series and their manufacturing method:
(1) Japanese patent application disclosure No. 59-46008 (equivalent to EP 101552A and U.S. Pat. No. 4,770,723), and in the reference by M. Sagawa, S. Fujimura, N. Togawa, H. Yamamoto and Y. Matsuura (J. Appl. Phys. Vol. 55(6), 15 Mar. 1984, p. 2083), disclose permanent magnets which are characterized by a magnetically anisotropic sintered substance comprising 8-30 atomic % of R (R being at least one element selected from the group consisting of rare-earth elements including Y) and residual of iron(Fe). This substance is manufactured by means of a sintering method of powder metallurgy.
In this sintering method, the manufacturing process comprises preparing an alloy ingot by means of melting and casting, providing magnetic powder of suitable grain size by means of grinding, blending said powder with an additive binder for forming and forming a green body by press-forming in a magnetic field. After pressing, the green body is sintered in an argon atmosphere at a temperature of 1100 degree centigrade for about one hour, and after that, the product is rapidly cooled to room temperature. After sintering, the product is heat-treated at 600 degree centigrade to improve its coercive force.
(2) Japanese patent application disclosure No. 59-211549 (equivalent to EP125752), and the reference by R. W. Lee (Appl. Phys. Lett. vol. 46(8), 15 Apr. 1985, p790) disclose a resin-bonded rare-earth-iron magnet which is formed from fine particles of alloy ribbon prepared by means of the melt-spinning method, having a fine crystalline magnetic phase and comprising at least one rare earth element selected from the group consisting of neodymium, praseodymium and mesh metal, transition metal elements, and iron and boron. The fine particles are formed in the desired shape of a magnet by a binder mixed with the particles, the fine particle being magnetically isotropic and the formed magnet being magnetized to any desired direction in a proper magnetic field. The magnet has a density of at least 80% of the alloy density and an energy product of at least 9 megagauss-oersted.
The permanent magnet is manufactured by means of the resin-bonding method using rapidly quenched thin ribbon prepared by the melt spinning method having a process comprising rapidly quenching thin ribbon of about 30 micrometer thickness by means of a melt spinning apparatus used to provide an amorphous alloy.
In the resin bonding method, using a rapidly-quenched ribbon prepared by the melt-spinning method, a first rapidly-quenched thin ribbon of R-Fe-B alloy is prepared by means of a melt spinning apparatus. The obtained ribbon of 30 micrometer thickness is an aggregate of crystal having a diameter of less than 1000 micrometers, and is brittle, and easily breakable, and the crystals are distributed homogeneously so that it has an isotropic magnetic property. It is able to obtain a magnet of density of more than 85% by means of press forming pulverized particles obtained by pulverizing the thin ribbon to a desired grain size with a resin under a pressure of about 7 tons/cm.sup.2.
(3) Japanese patent application disclosure No. 60-100402 (equivalent to EP 133758A), and in the reference of R. W. Lee; (Appl. Phys. Letter. Vol. 46(8), 15 Apr. 1985, p790.). These references describe:
(a) Isotropic permanent magnets comprised of fully densified fine particles characterized in that the magnet being provided by hot pressing amorphous or fine particle material comprises iron, neodimium and/or praseodimium and boron.
(b) Anisotropic permanent magnets consisting of fine particles characterized by providing a magnet by hot pressing and hot die upsetting a material comprising iron, neodimium and/or praseodymium and boron, the desirable magnetizing direction of the magnet being parallel to the upset compression direction.
(c) Permanent magnets characterized by a magnet formed by high temperature plastic deforming of an amorphous or fine particle alloy comprising substantially 50.about.90 atomic % of iron, 10.about.50 atomic % of neodymium and/or praseodymium and 1.about.10 atomic % of boron in which the desirable magnetizing direction is perpendicular to the plastic flow in the deformation.
These references also disclose a method of manufacturing a permanent magnet, wherein the permanent magnet is anisotropic and characterized by being composed of iron-rare-earth metals. The manufacturing method comprising heat treating amorphous or fine grained solid particles, including iron, neodymium and/or praseodymium and boron, to prepare a plastically deformed body of fine grained microstructure, and cooling the body.
The manufacturing method of these magnets is a method to manufacture R-Fe-B magnet having anisotropic properties and having a high density by means of a 2-step hot-pressing method in a vacuum or in an inert-gas atmosphere from a ribbon-like rapidly-quenched thin ribbon or plate.
In this pressing process, one-axial pressure is applied to align the magnetization direction parallel to the pressing axis to prepare an anisotropically magnetizable alloy.
Also, it is preferable that the particle grain size of the ribbon-like thin plate be preliminarily manufactured by the melt-spinning method and may be prepared smaller than the grain size showing maximum coercive force to give optimum grain size after the grain-growth in the hot-press process.
(4) Finally, Japanese patent application disclosure No. 62-276803 (equivalent to DE3626406A or U.S. patent application No. 06/895,653) discloses a permanent magnet of a rare-earth-iron system which is characterized by melting an alloy comprising 8.about.30 atomic % of R (at least one element selected from the group consisting of rare-earth elements including Y), 2.about.28 atomic % of boron, less than 50 atomic % of cobalt, less than 15 atomic % of aluminum and rest iron and impurities. The alloy is casted and hot-worked at a temperature above 500.degree. C. so as to refine the crystal grain and orient crystal axis to a specific direction to make a magnetic anisotropic cast alloy.
The permanent magnet of R-Fe-B system described above in sections (1) to (4) have drawbacks described below.
The manufacturing method described in the references of section (1), it is indispensable to pulverize the alloy, and because of that, the R-Fe-B alloy is very active to oxygen, and when it is pulverized, the power becomes highly oxidized.
Also, in the process of the forming the powder, it is necessary to add forming additive such as zinc stearate, although this additive may be removed preliminarily before the sintering process, some part of the additive remains in the magnet body in the form of carbon, and it is not desirable because this residual carbon deteriorates the magnetic properties of the R-Fe-B magnet.
The formed body, which is called a green body, is very difficult to handle because it is easy to break. Thus, the handling is very troublesome when the formed bodies are arranged in the sintering furnace.
As a result of these drawbacks, the manufacturing cost of a magnet of a R-Fe-B series, is expensive because it is not only necessary to provide expensive equipment, but in addition the manufacturing method thereof does not have good productivity. Thus, it is not able to effectively utilize of an advantage of a R-Fe-B series magnet, i.e., cheap raw materials.
The permanent magnets described in sections (2) and (3) are manufactured by means of vacuum-melt spinning machine. This machine is not only very expensive, but also has very low productivity.
The permanent magnet describe in section (2) is also disadvantaged in that the temperature characteristic and the application thereof because it has homogeneous magnetic properties so that it is a low energy product and also has bad squareness of the hysteresis loop.
The manufacturing method described in section (3) is a unique one which utilizes hot-pressing in two-steps, but when used for mass-production, it is inefficient.
Furthermore, coasening of the crystal grains is remarkable if the temperature rises above 800.degree. C. Because of which, the intrinsic coercive force iHc becomes extremely low so that it is not able to provide a practical permanent magnet.
With respect to the manufacturing method described in section (4), it has the drawback that the manufactured magnet has somewhat inferior magnetic properties compared with that of the magnets manufactured in accordance with references described in sections (2) or (3), although it does not include a pulverizing process and has only one hot-press process thus reducing the manufacturing process to its maximum extent.
SUMMARY OF THE INVENTION
The object of the present invention is to overcome the disadvantages in the traditional techniques hereinabove described, in particular, the characteristics of the permanent magnet manufactured in accordance with the reference described in section (4). Another object of the present invention is to provide an inexpensive permanent magnet having excellent characteristics and the manufacturing method thereof.
The present invention relates to a permanent magnet of the type which comprises, R(rare-earth elements) M(transition elements, and X(Group IIIb elements, such as B, Al or Ga) and the manufacturing method thereof. More particularly, the present invention relates to a permanent magnet which is characterized by raw material to make an alloy ingot, the raw material being basically comprised by R (at least one rare-earth element selected from the group consisting of Pr, Nd, Dy, Ce, La, Y and Tb), M (at least one transition element selected from the group consisting of Fe, Co, Cu, Ag, Au, Ni and Zr), X (at least one of the IIIb elements of the periodic table of B, Ga and Al), in which said R-rich liquid phase of non-magnetic substance is eliminated to condense the magnetic phase and to give magnetic anisotropy by means of mechanical alignment.
The present invention also relates to the method of manufacturing a permanent magnet characterized by melting and casting the alloy of the basic raw material, hot-working the cast ingot at the temperature above 500.degree. C. to eliminate a non-magnetic R-rich liquid phase, concentrate the magnetic phase and give magnetic anisotropy by means of mechanical alignments.
More particularly, the permanent magnet is characterized by a basic component comprised by from 12 to 25 atomic % of R, from 65 to 85 atomic % of M and 3 to 10 atomic % of X, and by eliminating the non-magnetic R-rich liquid phase to concentrate the magnetic phase of from 10 to 18 atomic % of R, from 72 to 87 atomic % of M and from 3 to 10 atomic % of X and giving magnetic anisotropy by means of mechanical alignment.
Also the manufacturing method of aforesaid permanent magnet is characterized by melting and casting an alloy of the basic component, then hot-working at a temperature above 500.degree. C. to reduce or eliminate the non-magnetic R-rich liquid phase and to concentrate the magnetic phase comprising from 10 to 18 atomic % of R, from 72 to 87 atomic % of M and from 3 to 10 atomic % of X and giving magnetic anisotropy by means of mechanical alignment.
It is also the object of the present invention to provide a permanent magnet having a crystal grain size of 0.3.about.50 .mu.l and having a concentration of less than 10% (not including 0%) of the R-rich phase.
Furthermore, the present invention relates to a permanent magnet characterized by the low material of the basic component thereof being comprised of from 12 to 25 atomic % of Pr, from 65 to 85 atomic % of Fe and 3 to 10 atomic % of B, in which the magnetic phase is comprised of 10 to 18 atomic % of Pr, 72 to 87 atomic % of Fe and 3.about.10 atomic % being concentrated, and providing a magnetic anisotropic permanent magnet having a crystal grain size of from 0.3 to 50 .mu.m and have less than 10% (not including 0%) of the R-rich phase by means of mechanical alignment.
In addition, the manufacturing method thereof is characterized by melting and casting the basic low materials, hot working the cast ingot at a temperature above 500.degree. C. to reduce or eliminate the non-magnetic R-rich phase and to concentrate the magnetic phase comprising from 10 to 18 atomic % of Pr, from 72 to 87 atomic % of Fe and from 3 to 10 atomic % of B, to provide an anisotropic permanent magnet by means of mechanical alignment and having a grain size of from 0.3 to 150 .mu.m and the ratio of the R-rich phase of less than 10% (not including 0%).
Furthermore, the present invention is directed to a method of manufacturing the permanent magnet described above, in which after the hot working of the case ingot, the material is heat-treated and also, one of the hot working being selected from the group consisting hot-press, hot-rolling and extrusion is performed.
The permanent magnet and manufacturing method thereof, according to the present invention is effective as described below:
(1) It is able to raise crystal alignment along the C-axis to substantially improve the residual magnetic flux density Br, and also by refining the particle size of the crystal coercive force and the maximum energy product (BH) max can be substantially raised.
(2) Manufacturing cost is inexpensive because of a simple manufacturing process.
(3) It is able to improve corrosion resistance because the magnet is less active to the oxygen owing to the low concentration of oxygen in the magnet body.
(4) Manufacturing cost can be reduced because of a good machinability thereof.
(5) The number of working steps and amount of investment can be substantially reduced compared with the conventional sintering manufacturing method.
(6) A low-cost magnet with excellent performance can be provided compared with the manufacturing method of the magnet using the conventional melt-spinning method.

BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 is a manufacturing process chart of the magnet of R-Fe-B series according to the invention,
FIG. 2 is a schematic illustration showing an effect of this invention,
FIG. 3 is a graph showing relation between contention of R-rich phase and 4.pi.Is and iHc,
FIG. 4 is a diagram showing two 4.pi.I-H curve of the magnet according to the invention and each curve showing respectively a curve of two orientation one of which is parallel to the compression direction and the other perpendicular thereto after the hot-pressing process,
FIG. 5 shows demagnetizing curves of the cast ingot before and after annealing,
FIG. 6 and FIG. 7 show, respectively, the relation between Pr content and magnetic characteristics and that of B content and magnetic properties of respective magnets,
FIG. 8 is a diagrammatic view of a roll working process,
FIG. 9 is a schematic view of an extrusion process, and
FIG. 10 shows weight variations of a magnet according to the invention and a traditional magnet.

DESCRIPTION OF THE PREFERRED EMBODIMENT
The inventors achieved this invention after the evaluation of many kinds of cast alloys of R-Fe-B series and acquired the knowledge that when an appropriate heat treatment is applied to an alloy of Pr-Fe-B series, a high coercive force can be obtained, and further, improvements of the magnetic characteristics of the alloy can be obtained by means of hot-pressing.
Thus, in accordance with the invention, a permanent magnet is provided in which the magnet comprises an alloy of R-M-X series, R being at least one element selected from the group consisting of Pr, Nd, Dy, Ce, La, Y and Tb, M being at least one element selected from the group consisting of Fe, Co, Cu, Ag, Au, Ni and Zr, and X being at least one element selected from the group consisting of B, Al and Ga. The process of manufacturing the magnet is characterized by melting and casting the alloy, and hot-working the cast alloy at a temperature above 500.degree. C. to concentrate the magnetic phase by removing or eliminating the non-magnetic R-rich phase and providing magnetic anisotropy by mechanical alignment. In accordance with this process, which comprises casting, hot-working, and heat-treatment, and does not include powder process, it is possible to provide an excellent magnet comparable to that obtained by the traditional manufacturing method.
In accordance with the invention, a permanent magnet is provided by the process (a).about.(c) shown in FIGS. 2(a)-(c), which are more fully described later.
As a result of squeezing outside the nonmagnetic R-rich liquid phase from the initial R-M-X basic material by hot-working such as hot-pressing, carried out at a temperature above 500.degree. C., and preferably at 750.degree..about.1050.degree. C., ferromagnetic particles are concentrated, and only the particle phase is refined and aligned. This enforces the magnetic properties.
In the manufacture of the magnet, a composition adjustment is made to embody stoichiometric R.sub.2 Fe.sub.14 B (in atomic percentage) or R.sub.11.7 Fe.sub.82.4 B.sub.5.9 (in atomic percentage), but when R is rich, the R-rich phase comprises a non-magnetic phase, and also, when B is rich, the B-rich phase acts as a non-magnetic phase.
In this invention, the R content is prepared a little greater than the stoichiometric content so the R-rich phase can be considered as a non-magnetic phase, but when the B content is a little greater than the stoichiometric content, obviously the B-rich phase can be considered as a non-magnetic phase.
Following are the reasons for the composition limit of the basic components R, M and X of the raw material:
R:12.about.25%
When R is below 12%, the quantity of the R-rich phase becomes too small and makes hot-working difficult. Also, when R exceeds 25%, the quantity of the non-magnetic phase becomes too high and results in poor concentration of the magnetic phase, thereby adversely affecting the magnetic properties.
M:65.about.85%
When M exceeds 85%, the R-rich phase is smaller and causes hot-working difficulties. Also, when M is below 65%, the quantity of the non-magnetic phase becomes too high and results in a poor concentration of the magnetic phase.
X-3-10%
When X is below 3%, the quantity of the magnetic phase becomes too small and cannot provide high performance. Also, when X exceeds 10%, the non-magnetic phase becomes too high and also hot working becomes difficult.
The basic composition of raw materials as specified above gives a product composition after hot working of R: 10.about.18%, M: 72.about.87%, X: 3.about.10%, which are the composition ranges which provide excellent magnetic properties in accordance with the invention.
Further, in accordance with the invention, the crystal grain size is limited in the range between 0.3.about.150 .mu.m, the reason of which is as described below:
A crystal grain size of 0.3 micrometer is the critical radius of a single magnetic domain particle, and when the particle size is smaller than 0.3 .mu.m, the initial magnetizing curve is equal to that of the permanent magnet made by the traditional manufacturing method described hereinbefore in section (3).
Also, when the crystal grain size exceeds 150 .mu.m, the resulting magnet, after hot-working, has a coercive force lower than 4KOe, and is practically useless.
Further, as will be shown later, 4.pi.Is (solid line of FIG. 3) increases when the non-magnetic R-rich phase content is lowered. Also, when the R-rich phase content increases, 4.pi.Is decreases, so that the R-rich phase must be kept below 10% for practical applications. But if the R-rich phase is 0%, it loses coercive force, therefore, it should be limited between 0% and 10%.
Several embodiments of the invention are now described.
EMBODIMENTS
Embodiment 1
A process chart of the manufacturing method according to the invention is shown in FIG. 1.
In this embodiment, for the hot working process, mainly hot-pressing was carried out at a temperature of 1000.degree. C. to align the crystal grains of the alloy. The hot-pressing is controlled to minimize the strain rate. Also, the C-axes of the crystal grains are aligned parallel to the compression direction of the alloy.
At first, following the manufacturing process shown in FIG. 1, an alloy comprising Pr.sub.17 Fe.sub.76 0.5B.sub.5 Cul..sub.5 was melted in an induction furnace having an argon atmosphere and then cast as an ingot.
The purity of each of the rare-earth, iron and copper, was over 99.9%, and for the boron, ferroboron is used.
Then, the cast ingot is hot-pressed, as shown in FIG. 2(b), an open die in an argon atmosphere at a temperature of 1000.degree. C. to obtain a thickness reduction of 80%. Compressing pressure in this process had a value between 0.2 and 0.8 ton/cm.sup.2 and the strain rate was between 10.sup.-3 and 10.sup.-4 /sec.
Then, annealing for 24 hours was done at a temperature of 1000.degree. C. and the workpiece was polished to measure its magnetic properties.
The magnetic and other properties of the magnet are shown in table 1 with some reference data showing values obtained from a traditional sintered permanent magnet (Nd.sub.15 Fe.sub.77 B.sub.8) made as described in section (1) and (Nd.sub.13 Fe.sub.82.6 B4.4) of section (3).
Further, magnetic properties were measured by a B-H tracer of maximum applied magnetic field of 25kOe.
TABLE 1______________________________________invented magnet conventional conventional(embodiment 1) magnet (1) magnet (3)______________________________________raw mat'l Pr.sub.17 FE.sub.76.5 B.sub.5 Cu.sub.1.5 Nd.sub.15 Fe.sub.77 B.sub.8 Nd.sub.13 Fe.sub.82.6 B.sub.4.4magnet Pr.sub.13.5 Fe.sub.79.6 B.sub.6.3 Cu.sub.0.9 same above same abovecomposi-tionBr(KG) 12.5 12.5 11.75iHc(kOe) 9.9 13.8 13.0BHmax 36.2 37.7 32.0(MGOe)Avg. 22 20 .sup..about. 0.02grainsize02(ppm) 210 2900 900C(ppm) 200 .820 1000porosity 0.2 2.7 0.2R-rich 5.2 8.1 3.8phaseratio (%)magneti- good good badzation______________________________________
As shown in table 1, it is obvious that the magnet produced by using the invention is not inferior to the conventional permanent magnet described in sections (1) and (3) in magnetic properties and is superior in the magnetizing property.
Further, adding copper to the cast magnet is very effective to improve the coercive force and it is also effective for the improvement of magnetic alignment.
The permanent magnet according to the invention differs from the sintered permanent magnets described in section (1) in Oxygen and Carbon content and in porosity, and differs from the permanent magnet section (2) in the grain size of the crystals, and is superior in its magnetization.
Structure aspects of the magnet according to this invention are now described in connection with FIGS. 2(a)-(c) which show a magnet including Pr.sub.2 Fe.sub.14 B phase particles 11, an .alpha.-Fe phase 12, an R-rich phase 13, and an R-rich liquid phase 14.
FIG. 2(a) shows the condition of the main phases after melting and casting an alloy comprising Pr.sub.17 Fe.sub.76.5 B.sub.5 Cu1.5, and as shown in the figure, a small amount of .alpha.-Fe phase 12 is included within the Pr.sub.2 Fe.sub.14 B phase grain 11.
Also, among the Pr.sub.2 Fe.sub.14 B phase grain 11, a non-magnetic R-rich phase 13 is present.
FIG. 2(b) shows the condition during the hot-pressing process in an open die, during which, at the temperature of 800.degree..about.1050.degree. C., the R-rich phase 13 is melted and changed into the R-rich liquid phase 14, and the R-rich liquid phase 14 is removed by the pressure applied through the hot-working, such as hot-pressing, and squeezed to the ouside of the ingot.
Also, the .alpha.-Fe phase 12 is diffused and disappears, the Pr.sub.2 Fe.sub.14 B phase grain 11 is pulverized during the hot-press working, and the crystal alignment along the C-axis is aligned with the direction of compression.
FIG. 2(c) shows the magnet, in which the squeezed out R-rich phase 13 portion is cut away and the central portion containing the fine Pr.sub.2 Fe.sub.14 B phase particle 11 comprises the magnet.
The space between each Pr.sub.2 Fe.sub.14 B phase grain is filled with an R-rich phase 13, iron and copper. It is obvious that the quantity of the filling material is much reduced compared with that of the cast ingot, and that the magnetic Pr.sub.2 Fe.sub.14 B phase grain is much concentrated compared with that of the initial ingot.
In FIG. 3, the relation between the content of the R-rich phase of the magnet and 4.pi.Is and iHc are shown. Also, in FIG. 4, 4.pi.I-H curves of a magnet comprised of Pr.sub.17 Fe.sub.76.5 B.sub.5 Cu.sub.1.5 are shown for directions parallel and perpendicular to the pressing direction.
FIG. 3 shows that 4.pi.Is (solid line) increases when the quantity of the non-magnetic R-rich phase decreases. Because 4.pi.Is decreases when the quantity of the R-rich phase increases, it is desirable that the quantity thereof be below 10%.
FIG. 4 shows two kinds of demagnetizing curves of the hot-pressed Pr-Fe-B-Cu magnet measured in easy and hard magnetization directions.
From FIG. 4, it can be seen that the easy magnetization direction is parallel to the compression direction, i.e. c axis. From the initial magnetizing curve, it may be determined that this magnet has a nucleation type coercive force mechanism.
This magnet has the same direction of anisotropy as, but a different coercive force mechanism than the conventional magnet described in section (3).
Embodiment 2
An alloy comprising Pr.sub.17 Fe.sub.79 B.sub.4 was melted by means of an induction furnace in an argon atmosphere in accordance with the process shown in FIG. 1 and cast as an ingot.
The purity of the iron and rare-earth used was over 99.9% and for the boron, ferroboron was used.
Then, the cast ingot was hot pressed, as shown in FIG. 2(b), in an argon atmosphere to make an 80% thickness reduction. Compression pressure in this work has 0.2.about.0.8 ton/cm.sup.2 and the strain rate was 10.sup.-3 -10.sup.-4 /sec.
After these treatments, the magnetic properties were measured and, after annealing at 1000.degree. C. for 24 hours, the magnetic properties were measured again.
Table 2 shows the magnetic properties measured before and after the annealing, and in table 3 several magnetic properties after the annealing are shown.
Further, in FIG. 5, a demagnetizing curve (1) of the cast ingot and that (2) of the magnet after annealing are shown.
TABLE 2______________________________________ Br (KG) iHc(KOe) (BH)max(KOe)______________________________________before anneal 10.6 3.6 14.3after anneal 10.8 7.3 22.2______________________________________
TABLE 3______________________________________low material composition Pr.sub.17 Fe.sub.79 B.sub.4magnet composition Pr.sub.14.8 Fe.sub.80.3 B.sub.4.9avg. particle size 20oxygen O (ppm) 250carbon C (ppm) 180porosity (%) 0.2R-rich phase ratio (%) 7.9magnetization good______________________________________
As shown in Table 3, the magnetic phase is concentrated as shown in the difference between the raw-material composition of Pr.sub.17 Fe.sub.79 B.sub.4 and the magnet composition of Pr.sub.14.8 Fe.sub.80.3 B.sub.4.9. Also, the magnetic properties show excellent values and more particularly, as shown in table 2 and FIG. 5, it is obvious that the magnetic properties can be enhanced by means of annealing.
Further, when the cast ingot is prepared with the same manufacturing condition but with changed quantities of Pr and/or B, properties of the magnet thus produced are changed as shown in FIG. 6 and FIG. 7.
FIG. 6 and FIG. 7 show the composition dependency of the hot-pressed magnet, in which all the measurements are made in the orientation which is parallel to that of the pressing. Also, it is easily understandable that the magnet is anisotropic because the value (BH) max (MGo) is greatly enhanced.
Embodiment 3
An alloy having a composition of Pr.sub.2 Nd.sub.5 Fe.sub.79 B.sub.5.5 Cu.sub.1.5 was melted and cast to provide a cast ingot by means of the process described in Embodiments (1) and (2).
After that, the cast ingot was hot-pressed at a temperature of 1000.degree. C. at the strain rate of 10.sup.-3 -10.sup.-4 /sec. with a thickness reduction of 80%.
After 1000.degree. C., 24 hours annealing, the alloy was cut and polished and the magnetic properties of the magnet of a composition of Pr.sub.9.5 Nd.sub.4 Fe.sub.80.1 B.sub.6.1 Cu.sub.0.8 were measured.
The magnetic and other properties of the magnet are tabulated in Table 4.
As shown in Table 4, it is obvious that the magnetic properties thereof are excellent.
TABLE 4______________________________________Composition of raw material Pr.sub.12 Nd.sub.5 Fe.sub.79 B.sub.5.5 Cu.sub.1.5Composition of magnet Pr.sub.9.5 Nd.sub.4 Fe.sub.80.1 B.sub.6.1 Cu.sub.0.3Br (KG) 12.5iHc (KOe) 8.8(BH) max (KGOe) 33.1Oxygen O (ppm) 230Carbon C (ppm) 190Porosity (%) 0.2R-rich phase ratio (%) 5.1avg. particle size (.mu.m) 24magnetizing good______________________________________
Embodiment 4
Alloys as shown in Table 5 were melted and cast in the same way as in Embodiments 1-3.
Then, these cast ingots were hot-pressed in an open die in an argon atmosphere and annealed. After cutting and polishing, magnetic properties of the materials were measured. Compositions of the magnets are shown in Table 6, and several magnetic properties are shown in Table 7.
TABLE 5______________________________________Alloy CompositionNo.______________________________________1 Pr.sub.15 Fe.sub.80 B.sub.52 Pr.sub.10 Fe.sub.75.5 B.sub.5.53 Pr.sub.22 Fe.sub.72 B.sub.64 Pr.sub.10 Nd.sub.7 Fe.sub.75 Co.sub.4 B.sub.45 Pr.sub.5 Nd.sub.14 Fe.sub.67 Co.sub.8 B.sub.5 Cu.sub.16 Pr.sub.8 Nd.sub.8 Fe.sub.71 Co.sub.5 B.sub.5.5 Cu.sub.5 Ga.sub.17 Pr.sub.10 Nd.sub.5 Dy.sub.3 Fe.sub.75 B.sub.5 Cu.sub.28 Ce.sub.2 Pr.sub.15 Nd.sub.2 Fe.sub.50 Co.sub.25 B.sub.4 Cu.sub.1 Ga.sub.19 Pr.sub.16 Nd.sub.2 Fe.sub.74 B.sub.5 Cu.sub.1 Ga.sub.1 Al.sub.110 Pr.sub.15 Nd.sub.5 Fe.sub.61 CO.sub.10 B.sub.7 Ag.sub.211 Ce.sub.3 Pr.sub.10 Nd.sub.4 Fe.sub.77 B.sub.4 Ni.sub.1 Zr.sub.112 La.sub.1 Pr.sub.17 Fe.sub.70 Co.sub.3 B.sub.6 Cu.sub.313 Dy.sub.5 Nd.sub.11 Fe.sub.77 B.sub.5.5 Cu.sub.214 Pr.sub.14 Tb.sub.3.5 Fe.sub.71 CO.sub.5 B.sub.5.5 Au.sub.1 215 Nd.sub.17 Fe.sub.75.5 B.sub.5 Ag.sub.1.5 Ga.sub.______________________________________ 1
TABLE 6______________________________________Composition of MagnetNo.______________________________________1 Pr.sub.13.5 Fe.sub.80.2 B.sub.5.82 Pr.sub.14 Fe.sub.80.2 B.sub.5.83 Pr.sub.14.3 Fe.sub.79.5 B.sub.6.24 Pr.sub.7.6 Nd.sub.5.5 Fe.sub.76.9 Co.sub.5 B.sub.55 Pr.sub.3.6 Nd.sub.10.5 Fe.sub.71 Co.sub.9 B.sub.5.7 Cu.sub.0.26 Pr.sub.6 Nd.sub.6.7 Fe.sub.74.9 Co.sub.6 B.sub.6 Cu.sub.0.3 Ga.sub.0.17 Pr.sub.7 Nd.sub.3.5 Dy.sub.2 Fe.sub.81.4 B.sub.5.8 Cu.sub.0.38 Ce.sub.1.5 Pr.sub.10.1 Nd.sub.1.4 Fe.sub.55.1 Co.sub.26.5 B.sub.5.1 Cu.sub.0.2 Ga.sub.0.19 Pr.sub.11.2 Nd.sub.1.4 Fe.sub.80.8 B.sub.5.9 Cu.sub.0.2 Ga.sub.0.1 A.sub.10.410 Pr.sub.10.5 Nd.sub.3.4 Fe.sub.67 Co.sub.11.5 B.sub.7.2 Ag.sub.0.411 Ce.sub.2.1 Pr.sub.8/2 Nd.sub.3.3 Fe.sub.80.3 B.sub.5.2 Ni.sub.0.4 Zr.sub.0.612 La.sub.0.7 Pr.sub.11.7 Fe.sub.77.4 Co.sub.3.5 B.sub.6.3 Cu.sub.0.413 Dy.sub.4.2 Nd.sub.9.2 Fe.sub.80.8 B.sub.5.5 Cu.sub.0.314 Pr.sub.9.8 Tb.sub.3 Fe.sub.75.5 Co.sub.5.5 B.sub.6 Au.sub.0.215 Nd.sub.13.2 Fe.sub.80.6 B.sub.5.7 Ag.sub.0.3______________________________________ Ga.sub.0.2
TABLE 7______________________________________ (BH)max avg.gr. R-richBr(KG) iHc(KOe) (MGOe) size(.mu.m) phase(%)______________________________________1 12.0 7.9 29.2 25 4.12 12.3 9.6 32.7 27 5.73 11.2 12.2 28.3 20 6.54 10.8 11.8 26.3 23 3.75 13.0 10.5 38.1 24 6.16 13.6 15.0 41.7 18 3.07 13.4 13.6 40.5 20 2.88 11.9 12.5 31.9 20 3.89 12.9 14.3 37.5 21 3.710 12.7 6.6 29.1 30 5.911 12.6 12.2 35.8 20 5.812 13.3 10.8 39.9 17 2.813 13.5 14.6 42.0 15 4.614 13.9 16.6 42.5 20 2.715 14.0 8.8 37.7 25 4.5______________________________________
Embodiment 5
An alloy having a composition of Pr.sub.15 Nd.sub.2 Fe.sub.76.5 B.sub.5 Cu.sub.1.5 was melted and cast employing the same raw materials described in the embodiments 1-4.
Then, the cast ingot was worked by methods such as hot-pressing, rolling, or extruding at a temperature of between 900.degree. and 1000.degree. C. as shown in Table 8.
FIG. 8 and FIG. 9 show illustrations of the hot-rolling and extrusion. In FIG. 8, rolls 5 are shown, and in FIG. 9, an hydraulic press 6 and dies are shown.
In the hot-pressing and hot rolling, respectively, the press 3 and the rolls 5 are adjusted to give a low strain rate. Also, each process is controlled to arrange that the easy magnetization axis of the crystal grains is aligned parallel to the compression direction of the alloy in the high temperature region of the working apparatus as shown by the arrows in FIGS. 2(b), 8 and 9.
Then, annealing at 1000.degree. C. for 24 hours is carried out and the material is then cut and polished to measure its magnetic properties.
In table 9 the composition of the magnets, and in table 10 the magnetic property of these magnets, are shown respectively.
As shown in Tables 8-10, the magnetic properties are enhanced by all working processes including hot-pressing, rolling and extrusion.
TABLE 8______________________________________ degree of thick- ness strainSample Working reduc- rate temp.No. method tion (%) (/sec.) (.degree.C.)______________________________________workingmethod1 16 hot press- 80 10.sup.-4 .about.10.sup.-5 950 ing2 17 hot press- 80 10.sup.-2 .about.10.sup.-3 1000 ing3 18 rolling 60 1.about.10 9004 19 rolling 45 10.about.100 9505 20 extrusion 80 10.sup.-1 .about. 950______________________________________
TABLE 9______________________________________Magnet composition16 Pr.sub.11.2 Nd.sub.1.3 Fe.sub.81.4 B.sub.6 Cu.sub.0.117 Pr.sub.12.2 Nd.sub.1.6 Fe.sub.80 B.sub.5.8 Cu.sub.0.418 Pr.sub.13.8 Nd.sub.1.8 Fe.sub.78.4 B.sub.5.3 Cu.sub.0.719 Pr.sub.14.9 Nd.sub.2.0 Fe.sub.76.7 B.sub.5.0 Cu.sub.0.920 Pr.sub.11.0 Nd.sub.1.2 Fe.sub.81.7 B.sub.6.1 Cu.sub.0.0______________________________________
TABLE 10______________________________________Several Properties of Magnet(s) Avg. R-richBr iHc (BH) particle phase(KG) (KOe) (MGOe) size (.mu.m) (%)______________________________________16 13.9 12.2 43.6 21 2.417 11.4 12.7 29.3 22 5.018 10.9 14.7 26.8 17 6.519 9.8 16.6 21.2 13 10.120 11.9 8.8 28.6 27 5.6______________________________________
Embodiment 6
A magnet made by the method described in embodiment 1 in accordance with the invention and a conventional sintered magnet are provided of the same composition (Nd.sub.15 Fe.sub.77 B.sub.5) and of the same form and are introduced into a thermo-hygrostat kept at 40.degree. C. and 95% relative humidity and checked for weight change. The results are shown in FIG. 10.
As shown in FIG. 10, relative to the conventional magnet (sintered magnet), the magnet in accordance with the invention has a lower weight change which indicates that it has a lower oxygen concentration. This is a great difference between the two kinds of magnets.
From these embodiments, it is obvious that the inventive permanent magnets have a high coercive force and can be provided with anisotropic properties by means of hot working such as hot-pressing, and the maximum (BH) max value of the magnets reaches the value of 43.6 MGOe.

Number	Date	Country	Kind
63-150039	Jun 1988	JPX
63-150040	Jun 1988	JPX

Number	Name	Date
4770723	Sagawa	Sep 1988
4859254	Mizoguchi	Aug 1989
4921551	Vernia	May 1990
5125988	Akioka et al.	Jun 1992

Number	Date	Country
0125752	Nov 1984	EPX
0133758	Mar 1985	EPX
0197712	Oct 1986	EPX
231620A2	Aug 1987	EPX
2586323	Feb 1987	FRX
63213323	Sep 1986	JPX
62-23959	Jan 1987	JPX
62-198103	Sep 1987	JPX
62-265705	Nov 1987	JPX
62-276803	Dec 1987	JPX
63-114106	May 1988	JPX
63-312915	Dec 1988	JPX
2206241	Dec 1988	GBX

	Number	Date	Country
Parent	993450	Dec 1992
Parent	429167	Oct 1989

Permanent magnet and a manufacturing method thereof

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