EP0447567A1

EP0447567A1 - Corrosion-resistant tm-b-re type magnet and method of production thereof

Info

Publication number: EP0447567A1
Application number: EP90914967A
Authority: EP
Inventors: Yukiko Kawasaki Steel Corporation Technical Ozaki; Michio Kawasaki Steel Corp. Shimotomai; Yasutaka Kawasaki Steel Corporation Fukuda; Akira Kawasaki Steel Corporation Fujita; Yoko Kawasaki Steel Corporation Kitano; Junichi Kawasaki Steel Corporation Shimomura
Original assignee: Kawasaki Steel Corp
Current assignee: JFE Steel Corp
Priority date: 1989-10-12
Filing date: 1990-10-11
Publication date: 1991-09-25
Anticipated expiration: 2010-10-11
Also published as: JPH03250607A; DE69027201D1; KR960013029B1; EP0447567B1; CA2044171A1; KR920701999A; DE69027201T2; WO1991006107A1; CA2044171C; EP0447567A4; JP2675430B2

Abstract

A two-phase permanent magnet which has not only excellent magnetic characteristics but also significantly high corrosion resistance. It is manufactured by use of two magnetically useful phases as the starting materials. One is an RE₂TM₁₄B phase having a high residual flux density; the other is a low-melting RE-TM phase and/or RE-TM-B phase which contributes to the improvement of sinterability and has a function of cleaning the main phase grain boundary and a property of causing the resultant material to be an electrochemically noble composition.

Description

TECHNICAL FIELD

This invention relates to rare earth metal-transition metal series magnets having not only excellent magnetic properties but also improved corrosion resistance and temperature-dependent properties and a method of producing the same.

BACKGROUND ART

As a typical permanent magnet manufactured at the present, there are mentioned Alnico magnets, ferrite magnets, rare earth metal magnets and the like. The Alnico magnets are manufactured from the old time, but their demand is lowering in accordance with the development of cheap ferrite magnets and rare earth metal magnets having higher magnetic properties. On the other hand, the ferrite magnets are chemically stable and low in the cost because oxides are used as a main starting material, so that they are the main current as a magnet material even at the present, but they have a drawback that maximum energy product is small.
Recently, Sm-Co series magnets having a combination of magnetic isotropy inherent to rare earth metal ion and magnetic moment inherent to transition metal element have been developed, whereby the conventional value of maximum energy product is largely increased. However, the Sm-Co series magnet is mainly composed of resourceless Sm and Co, so that it is obliged to become expensive.
Now, it has been attempted to develop cheap magnet alloys containing no expensive Sm and Co and having high magnetic properties, and consequently Egawa et al developed stable ternary alloys by sintering process (Japanese Patent Application Publication No. 61-34242 and Japanese Patent laid open No. 59-132104) and J. J. Groat et al developed alloys having a high coercive force by liquid quenching process (Japanese Patent laid open No. 59-64739). These magnets are composed of Nd, Fe and B, and their maximum energy product exceeds that of Sm-Co series magnet.
However, Nd-Fe-B series magnets contain greater amounts of a light rare earth element such as ND having very high activity or the like and a corrosive Fe as a main component, so that the corrosion resistance is poor and hence the magnetic properties are degraded to damage the reliability as an industrial material.
Therefore, in order to improve the corrosion resistance, there are taken countermeasures such as surface plating (Japanese Patent laid open No. 63-77103), coating treatment (Japanese Patent laid open No. 60-63901) and the like on the sintered magnets, and surface treatment on resin bonded type magnets before kneading magnet powder with a resin and the like, but they can not be said to be an effective rustproof treatment over a long period of time, and the cost becomes higher due to such a treatment and further there are caused problems such as magnetic flux loss due to the presence of protective film and the like.
As a solution on the above problems, the inventors have previously proposed rare earth metal-transition metal-boron series magnet alloys in which Fe in the Nd-Fe-B series magnet is replaced with high concentrations of Co and Ni (Japanese Patent laid open No. 2-4939).
Such magnets are excellent in the corrosion resistance and high in the Curie point, so that the reliability as a magnet material is largely increased.
The invention is concerned with rare earth metal-transition metal series magnets of two phase structure further developed from the above magnet.
Moreover, magnets having excellent magnetic properties through two alloying process in which rare earth rich phase and rare earth poor phase are mixed and sintered at liquid phase state have previously been proposed as Nd series magnet of two phase structure (Japanese Patent laid open No. 63-93841 and No. 63-164403). In this case, the magnetic properties are improved, but there is still remained a problem on the corrosion resistance.

DISCLOSURE OF INVENTION

The invention is to advantageously solve the aforementioned problems and to propose rare earth metal-transition metal series magnets of two phase structure being excellent in not only the magnetic properties but also the corrosion resistance and a method of advantageously producing the same.
At first, details of elucidating the invention will be described.
The inventors have made various metallographical studies on the above magnet using high resolution electron microscope or the like, and confirmed that this magnet contains Nd₂(Fe, Co, Ni)₁₄B phase having a large saturated magnetic flux density, and intergranular phases surrounding crystal grains of the above phase and developing a strong coercive force such as Nd₂(Fe, Co, Ni)₁₇, Nd(Fe, Co, Ni)₅, Nd₂(Fe, Co, Ni)₇, Nd(Fe, Co, Ni)₄B and Nd(Fe, Co, Ni)₁₂B₆ and further Nd_1-xTM_x of CrB structure (TM is mainly Ni) and the like.
Furthermore, it has been found that better corrosion resistance is exhibited as the amount of Nd phase being a point of causing corrosion is less and the concentration of Ni or Co in the above intergranular phase becomes high.
Now, the inventors have made further studies with respect to this point and found that the above intergranular phase hardly appears in a range of Nd-Fe-B ternary phase diagram other than Nd₂(Fe, Co, Ni)₁₇ and is rather a phase appearing only in the range of Nd-Co-B system.
For the reference, Nd-Fe-B ternary phase diagram is shown in Fig. 1 (N. F. Chaban, Yu. B. Kuzma, N. S. Bilonizhko, O. O. Kachmar and N. U. Petrov, Akad Nauk, SSSR, SetA, Fiz.-Mat. Tekh, Nauki No. 10 (1979) 873), and Nd-Co-B ternary phase diagram is shown in Fig. 2 (N. S. Bilonizhko and Yu. B. Kuzma, Izv. Akad. Nauk SSSR Neorg. Mater, 19 (1983) 487) (In the original report, Nd₂Fe₁₄B phase and Nd₂Co₁₄B phase are misinterpreted as Nd₂Fe₉B phase and Nd₂Co₉B phase, so that they are corrected in Figs. 1 and 2).
In Fig. 1, a phase of number 1 is Nd₂Fe₁₄B phase, and NdFe₄B₄ phase (phase of number 2), Nd phase, Nd₂Fe₁₇ phase and Fe phase appear as a composition near thereto. In Fig. 2, however, Nd₂Co₁₇ phase, NdCo₅ phase, Nd₂Co₇ phase, NdCo₄B phase (phase of number 2) and NdCo₁₂B₆ phase (phase of number 7) appear in a magnet prepare from a composition near to Nd₂Co₁₄B phase of number 1, and Nd phase does not naturally appear at an equilibrium state.
As previously mentioned, Nd phase is not only a point of causing rust but also a magnetically useless phase, so that it should be eliminated.
It is, therefore, an object of the invention to provide permanent magnets having excellent magnetic properties and corrosion resistance by using magnetically useful two phases, i.e. RE₂TM₁₄B phase having a high residual magnetic flux density and a low melting point RE-TM phase or RE-TM-B phase enhancing the sinterability and possessing a cleaning action against grain boundary of main phase and further forming an electrochemically noble composition as a starting material to prepare a two phase magnet.
That is, the invention lies in a corrosion-resistant rare earth metal-transition metal series permanent magnet consisting essentially of RE: not less than 10 at% but not more than 25 at% (where RE: one or more of Y, Sc and lanthanoid, B: not less than 2 at% but not more than 20 at% and the reminder being substantially TM (TM is one or more of Fe, Co and Ni), whose texture being comprised of a phase of RE₂TM₁₄B (TM is the same as mentioned above) having Nd₂Fe₁₄B structure, RE-TM series intermetallic compound phase (TM is Ni or a mixture of Ni and Fe or Co) or RE-TM series eutectic structure (TM is the same as mentioned above) and/or RE-TM-B series intermetallic compound phase (TM is the same as mentioned above) having a melting point lower than that of the above phase.
Furthermore, the invention lies in a method of producing a corrosion-resistant rare earth metal-transition metal series magnet, which comprises subjecting a mixture of powder composed mainly of RE₂TM₁₄B series intermetallic compound phase (TM is one or more of Fe, Co and Ni) and powder having a melting point lower than that of the above powder and composed of mainly of RE-TM series intermetallic compound phase (TM is Ni or a mixture of Ni and Fe or Co) or RE-TM series eutectic structure (TM is the same as mentioned above) and/or RE-TM-B series intermetallic compound phase (TM is the same as mentioned above) to a compression molding and then sintering it.
In the invention, in order to more improve the corrosion resistance, it is effective to make the intergranular phase electrochemically more noble than the main phase, so that it is preferable that a ratio of Ni and/or Co in TM of the low melting point RE-TM and RE-TM-B series phases is higher than that in RE₂TM₁₄B phase. Particularly, the increase of Ni ratio is effective to the improvement of corrosion resistance and the reduction of cost.
In the invention, it favorable that a ratio of RE₂TM₁₄B intermetallic compound phase to RE-TM, RE-TM-B series intermetallic compound phase is about 95:5 to 40:60 as a formula unit. Because, when this ratio is outside the above range, there is caused a disadvantage of bringing about considerable degradation of coercive force and saturated magnetic flux density. The term "formula unit" used herein corresponds to a case that Nd₂Fe₁₄B is considered as one molecule (this is called as formula in case of solid). The particle size of each of the above powders to be mixed is desirable to be about 0.5-5 µm for handling easiness and homogeneous mixing.
A typical composition of RE-TM series intermetallic compound phase (inclusive of eutectic structure, same as above) and RE-TM-B series intermetallic compound phase having a melting point lower than that of RE₂TM₁₄B intermetallic compound phase is as follows.
·RE-TM series
RE₂TM₁₇, RETM₅, RE₂TM₇, RETM₃, RETM₂, RE₁TM_1-x, RE₇TM₃, RE₃TM and RE-TM eutectic structure
·RE-TM-B series
RETM₄B, RE₃TM₁₁B₄, RE₂TM₅B₂, RE₂TM₇B₃, RE₂TM₅B₃, RETM₁₂B₆, RETM₂B₂, RETM₉B₄, RE₂TMB₃
Moreover, powder composed mainly of the above RE₂TM₁₄B, RE-TM series and RE-TM-B series intermetallic compound phases can be obtained as follows.
That is, constitutional elements are weighed so as to have a given composition and shaped into an ingot by arc melting or high frequency melting under vacuum or in an inert gas atmosphere. Then, the ingot is held at a temperature of 600-1000°C under vacuum or in an inert gas atmosphere for 1-30 days to form a single phase of intermetallic compound. In general, the intermetallic compound phase has frequently a solid solution range to a certain extent (∼20%), so that the starting composition is allowed to have a composition width in accordance therewith.
The single phase of the intermetallic compound is roughly ground by means of a hammer mill and then finely divided into a particle size of 0.5-5 µm by using a jet mill or an attritor . Moreover, when the hardness is low and the pulverization is difficult in the low melting point RE-TM and RE-TM-B phases, hydrogen brittleness is previously carried out within a temperature range of room temperature to about 350°C for several hours before the grinding with a hammer mill, whereby the subsequent pulverization is made easy.
According to the invention, powder composed mainly of the previously prepared intermetallic compound having a composition of RE₂TM₁₄B is mixed with at least one powder composed mainly of the previously prepared RE-TM series intermetallic compound and RE-TM-B series intermetallic compound phases having a melting point lower than that of the above powder, pressed and sintered, whereby high magnetic properties and high corrosion resistance can simultaneously be provided.
This is considered to be due to the fact that the powder having a melting point lower than that of the powder composed mainly of RE₂TM₁₄B intermetallic compound phase promotes the sintering and forms an intergranular phase between crystal grains of RE₂TM₁₄B to improve coercive force.
In RE₂TM₁₄B phase, Nd and Pr are desirable as RE from viewpoints of magnitude of magnetic moment and magnetic coupling with TM atm as well as the cost, but it is needless to say that the other RE or a combination of Nd, Pr therewith may be used.
As to TM, one or more of Fe, Co and Ni is sufficient, and particularly it is preferable to increase the ratio of Ni from a viewpoint of high corrosion resistance of the magnet. Further, RE₂TM₁₄B phase bears the saturated magnetic flux density of the magnet, so that the ratios of Fe, Co and Ni in TM are desirable to be not less than 10 at% but less than 73 at% in Fe, not less than 7 at% but not more than 50 at% in Co and not less than 5 at% but not more than 30 at% in Ni. Even when the main phase is RE₂TM₁₄B phase in which Fe as TM is 100%, the corrosion resistance of the permanent magnet according to the invention is superior to that of the conventional RE-TM-B magnet, so that the above phase can naturally be used as a main phase in accordance with the use purpose of the magnet.
As RE in the low melting point phase of RE-TM system and RE-TM-B system, light rare earth element such as La, Ce, Pr, Nd or the like is advantageously adaptable importantly considering the cost, and middle to heavy rare earth elements from Sm to Lu and Y, Sc and the like are adaptable for more enhancing the corrosion resistance.
As to TM, the presence of Ni and/or Co, particularly Ni is effective to improve the corrosion resistance, so that according to the invention Ni is necessarily contained as TM. In this case, the content in TM is preferable to be not less than about 8%.
The addition effect of Ni is as follows.

i) The melting point of RE-TM system and RE-TM-B system is lowered, and the wetting of liquid phase in the liquid phase sintering is promoted to increase the sintering density and enhance the residual magnetic flux density.
ii) The effect of cleaning grain boundary in liquid phase is enhanced in the liquid phase sintering to more increase the coercive force by the same reason as in the above item i).
iii) It is effective to the improvement of corrosion resistance and cheap as compared with Co.

Furthermore, when the ratio of Ni and/or Co in the low melting point phase is made higher than that of RE₂TM₁₄B phase, the corrosion resistance can be more improved because the phases of these powders tend to preferentially corrode in the grain boundary as compared with RE₂TM₁₄B phase in the sintered body if the structure of TM is same and is advantageously acted by previously making electrochemically noble. Furthermore, the magnetically useless Nd phase can be eliminated, so that the residual magnetic flux density increases and hence the maximum energy product (BH)_max also increases.
In this connection, even when an alloy having an average composition as a whole magnet is melted from the first as in the conventional technique, pulverized, pressed and sintered so as to approach to an equilibrium state, the Nd phase is not obtained. For this purpose, it is necessary to conduct the heating at a high temperature for long time, during which abnormal growth of crystal grain is undesirably caused to considerably degrade the coercive force.
Moreover, it is not necessary that the same element is used in RE of the main phase and RE of the low melting point phase. And also, in the magnet consisting of the above two phases, the effect of the invention is not lost even when a part of RE and TM is replaced with at least one of Mg, Al, Si, Ti, V, Cr, Mn, Cu, Ag, Au, Cd, Rh, Pd, Ir, Pt, Zn, Ga, Ge, Zr, Nb, Mo, In, Sn, Hf, Ta and W in an amount up to 8 at% of a full magnet.
As to the production method, there may be carried out a method wherein a mixture of powder of RE₂TM₁₄B composition and powder composed mainly of low melting point RE-TM series and/or RE-TM-B series intermetallic compound phases is placed in an iron pipe under vacuum and then sintered while hot rolling as a method of producing large size magnets in addition to the method in which the above powder mixture is subjected to compression molding and then sintered.

BRIEF DISCLOSURE OF DRAWINGS

Fig. 1 is a Nd-Fe-B three component phase diagram; and
Fig. 2 is a Nd-Co-B three component phase diagram.

BEST MODE FOR CARRYING OUT THE INVENTION

Example 1

An alloy button was prepared by arc melting neodymium, transition metal and boron at an atomic ratio of 2:14:1, which was subjected to a normalizing treatment in a vacuum furnace at 950°C for 7 days and further to rough grinding and fine pulverization, whereby fine powder having a particle size of few microns was obtained. In this case, the ratios of Fe, Co, Ni in the transition metal were varied to produce a plurality of alloy powders.
Similarly, powder having a ratio of neodymium or (neodymium + dysprosium) to nickel of 1:1 was prepared. In this case, the normalizing treatment conditions were 680°C and 5 days.
Then, powders selected from the above two groups were mixed at a mixing ratio shown in Table 1, pressed while applying a magnetic field of 15 kOe, sintered at 1000°C under vacuum for 2 hours and then quenched to room temperature.
The magnetic properties and corrosion property of the thus obtained samples were measured to obtain results shown in Table 1. Moreover, the corrosion property was evaluated by exposing the sample to an environment at a temperature of 70°C and a humidity of 95% for 48 hours and measuring a rusted area ratio on the surface of the sample.
For the comparison, the measured results of a sample produced by the conventional method in which a full composition for the sintered magnet was melted at once and subjected to rough grinding - fine pulverization - pressing in magnetic field - sintering steps are also shown in Table 1.
As seen from the above table, the rare earth metal-transition metal series magnets of two phase structure according to the invention considerably improve not only the magnetic properties but also corrosion resistance as compared with those obtained by melting the full composition from the first as in the conventional technique.

Example 2

An alloy button was prepared by arc melting neodymium, transition metal and boron at an atomic ratio of 2:14:1, which was subjected to a normalizing treatment in a vacuum furnace at 950°C for 7 days and further to rough grinding and fine pulverization, whereby fine powder having a particle size of few microns was obtained. In this case, the ratios of Fe, Co, Ni in the transition metal were varied to produce a plurality of alloy powders.
Similarly, powder having a ratio of neodymium and/or dysprosium or praseodymium to nickel or (nickel + cobalt) of 3:1 was prepared. In this case, the normalizing treatment conditions were 485°C and 5 days.
The magnetic properties and corrosion property of the thus obtained samples were measured to obtain results shown in Table 2.
For the comparison, the measured results on the properties of a magnet produced by the technique disclosed in Japanese Patent laid open NO. 63-164403 are also shown in Table 2.
As seen from the above table, the rare earth metal-transition metal series magnets of two phase structure according to the invention are excellent in the magnetic properties and corrosion resistance. Furthermore, when Acceptable Example 8 is compared with Acceptable Example 13, it is apparent that the corrosion resistance is improved as the Ni ratio in RE₃(Ni, Co)₁ becomes particularly higher. Moreover, in the conventional example, the magnetic properties are good, but the corrosion resistance is poor because Ni is not contained.

Example 3

A fine alloy powder of RE₂TM₁₄B composition was prepared by the same manner as in Example 1, while a fine alloy powder in which ratios of Ni and Co in TM were made higher than those of RE₂TM₁₄B powder was prepared as a starting powder. After these powders were mixed, a sintered magnet was produced by the same manner as in Example 1.
The properties of the thus obtained sintered magnet are shown in Table 3 together with those of the sintered magnet produced by the conventional method.
As seen from the above table, when using the fine alloy powder in which the ratios of Ni and Co in TM are higher than those of RE₂TM₁₄B powder as a powder to be mixed, the more improvement of the corrosion resistance is attained.

INDUSTRIAL APPLICABILITY

According to the invention, the rare earth metal-transition metal series magnets having improved corrosion resistance and magnetic properties can be produced as compared with the conventional production method. Particularly, the corrosion resistance is improved, so that the considerable improvement of reliability as an industrial material is realized.

Claims

A corrosion-resistant rare earth metal-transition metal series permanent magnet consisting essentially of RE: not less than 10 at% but not more than 25 at% (where RE: one or more of Y, Sc and lanthanoid, B: not less than 2 at% but not more than 20 at% and the remainder being substantially TM (TM is one or more of Fe, Co and Ni), whose texture being comprised of a phase of RE₂TM₁₄B (TM is the same as mentioned above) having Nd₂Fe₁₄B structure, RE-TM series intermetallic compound phase (TM is Ni or a mixture of Ni and Fe or Co) or RE-TM series eutectic structure (TM is the same as mentioned above) and/or RE-TM-B series intermetallic compound phase (TM is the same as mentioned above) having a melting point lower than that of the above phase.
The corrosion-resistant rare earth metal-transition metal series permanent magnet according to claim 1, wherein a ratio of Ni and/or Co in TM in said low melting point RE-TM series and RE-TM-B series phases is made higher than that of said RE₂TM₁₄B phase.
A method of producing a corrosion-resistant rare earth metal-transition metal series magnet as claimed in claim 1, which comprises subjecting a mixture of powder composed mainly of RE₂TM₁₄B series intermetallic compound phase (TM is one or more of Fe, Co and Ni) and powder having a melting point lower than that of the above powder and composed of mainly of RE-TM series intermetallic compound phase (TM is Ni or a mixture of Ni and Fe or Co) or RE-TM series eutectic structure (TM is the same as mentioned above) and/or RE-TM-B series intermetallic compound phase (TM is the same as mentioned above) to a compression molding and then sintering it.
A method of producing a corrosion-resistant rare earth metal-transition metal series magnet as claimed in claim 2, which comprises subjecting a mixture of powder composed mainly of RE₂TM₁₄B series intermetallic compound phase (TM is one or more of Fe, Co and Ni) and powder having a melting point lower than that of the above powder and composed of mainly of RE-TM series intermetallic compound phase (TM is Ni or a mixture of Ni and Fe or Co) or RE-TM series eutectic structure (TM is the same as mentioned above) and/or RE-TM-B series intermetallic compound phase (TM is the same as mentioned above) to a compression molding and then sintering it.