WO1992000595A1

WO1992000595A1 - Method for processing powdered magnetic materials and products thereby obtained

Info

Publication number: WO1992000595A1
Application number: PCT/FR1991/000517
Authority: WO
Inventors: Daniel Fruchart; Salvatore Miraglia; Paul Mollar; René Perrier De la Bathie; Robert Fruchart
Original assignee: Centre National De La Recherche Scientifique - Cnrs
Priority date: 1990-07-02
Filing date: 1991-06-28
Publication date: 1992-01-09
Also published as: ATE106600T1; DE69102277D1; FR2664086A1; FR2664086B1; JPH06501135A; EP0538320B1; DE69102277T2; EP0538320A1

Abstract

A method for improving the magnetic properties of a polyphase product having permanent-magnet-like properties at room temperature, acting as a precursor and having been processed by hydridizing crackling at a low pressure and a low temperature to obtain an intermediate hydride in powdered form. According to the method, the intermediate hydride in powdered form undergoes, after hydridizing, a first partially dehydridizing heat treatment in a vacuum and at a low temperature below its segregation temperature, and the non-segregated product thereby obtained undergoes a second, subsequent intense dehydridizing heat treatment in a vacuum and at a temperature of around 600 °C.

Description

PROCESSING OF POWDER MAGNETIC MATERIALS AND PRODUCTS THUS OBTAINED

The invention relates to an improved process intended to optimize the magnetic properties of a material endowed with permanent magnet properties, with a view to obtaining a product with high magnetic performance and presenting itself in finely divided form. More specifically, it relates to a process capable of increasing the internal magnetic energy of such a material, of the rare earth / iron / boron alloy type, obtained after decrepitation by hydriding-dehydriding procedure. Finally, it also relates to the products obtained by this process.

The need for materials with high magnetic properties, in powder form is growing every day, especially in the context of their use for the production of sintered or bonded magnets (injected or pressed).

The production of bonded magnets is carried out fundamentally by the introduction of a large amount of magnetic material in the most divided form possible, in an organic continuous matrix, generally made of a synthetic polymer. This step is carried out in a traditional manner using a twin screw, at the polymer melting temperature. In this way, in order to obtain high performance bonded magnets, it is sought to introduce into the matrix the greatest possible quantity of magnetic material. In the context of optimizing such magnets, the aim is to minimize the size of the "particles" constituting the magnetic material, while increasing the magnetic properties, and in particular the coercivity of said "particles". In addition, it is important that the size distribution of these "particles" be as tight as possible, in particular in order to optimize the magnetic properties (coercivity, induction) of the bonded magnet. This property is particularly important in the context of the production of magnets linked to strong anisotropy. Indeed, this small distribution, and the effective size of the "particles" obtained, depend on the one hand, on the dispersibility of the powders, namely, their ability to disperse homogeneously, for example in the matrix or coating resin, and on the other hand their orientability, namely, their ability to orient themselves under magnetic field, and more precisely to align their direction of easy magnetization with the direction of the applied magnetic field, and this by rotation mechanical.

The advantage of obtaining powders with high magnetic properties of small homogeneous particle size thus appears clearly. Bonded anisotropic magnets produced from these powders are likely to have a much higher residual induction than those produced to date with the powders available today, and this, from the same "absolute" quantity of magnetic material. One of the aims of the present invention is to propose a process capable of manufacturing such powders, having a high coercivity.

With regard to obtaining magnetic materials in powder form, in European patent EP-A-0 173 588, a process known as "decrepitation" has been described, comprising at least one hydriding-dehydrating cycle. of a compound corresponding to the general formula R_ »M _X4 B, where B denotes boron, R denotes an element belonging to the Rare Earth family or Yttrium, M denoting essentially iron, and which can be partially substituted by d 'other metallic elements, making it possible to end up with a product of low grain size, and endowed with magnetic properties which are interesting in terms of its magnetization, but which generally have an insufficient level of coercivity. We have indeed been able to show that the magnetic properties of a material were inter alia linked to the definition of its microstructure (domain, grain, textur, etc.). In this way, we sought to obtain materials finely divided into particles of small sizes, typically about ten micrometers and less, by a process easy to implement, inexpensive and in a safe manner for the experimental manufacturers . This process consists in obtaining the pulverization of the base material by hydriding. This process, called decrepitation, consists succinctly in absorbing hydrogen by a metal alloy under certain conditions of pressure and temperature. This absorption, whose chemical reaction of atomic hydrogen bonding on particular sites of the material causes a release of heat, induces an increase in the volume of the alloy, consecutive to the dilation of the crystalline mesh, leading in fact to a dis location of the massive material. This takes place at levels, namely at an inter-granular level, that is to say between the entities of the same phase, and at an intra-granular level, corresponding to the "bursting" of entities d 'the same phase. An agglomerated eta powder is obtained, which it is possible to disperse by simple stirring.

It has been found that, although the products obtained have a particle size entirely in keeping with the desired objective, on the other hand, the magnetic properties obtained had to be optimized for certain particular applications, in particular for permanent magnets, or for bonded magnets . Indeed, the powder obtained certainly has a particle size close to ten micrometers, or even less, in revenge the internal magnetic energy (HB) max developed by the latter remains moderate, and in any case insufficient to be used as such in the production of high capacity permanent-polymer magnets. The object of the invention consists, starting from materials having qualities of permanent magnets - intrinsically self, or potentially (example amorphous product) - to obtain powders having the same magnetic properties as their precursors by applying heat treatments meeting particular conditions. The invention also aims to obtain powder of small homogeneous particle size, endowed with these magnetic properties. After decrepitation obtained by hydrura tion, then partial dehydriding carried out under primary vid and at a temperature below the demixing temperature of the hydride obtained, temperature typically around 520 ° C, possibly followed by thermal plateau, a second thermal treatment is applied at a temperature close to 600 ° C., that is to say a temperature higher than the hydride desorption temperature of the main phase of the material.

It has been found that this thermal post-treatment makes it possible to obtain a dehydriding of the set of phases constituting the base alloy. Indeed, as we know, whatever the method of obtaining the latter, we must go through a step of melting the base material in order to obtain an alloy in mas sive form. This fusion not being congruent, there exists between the preponderant entities, constitutive of the "magnetic" phase proper, one or more secondary phases with eutectic behavior, richer in rare earth elements. In fact, the subsequent heat treatments aim to dehydrate this or these secondary phases. Finally, by a third heat treatment, the aim is to reshape the envelope with a concentration rich in rare earth elements. By "primary vacuum" is meant in the sense of the invention a vacuum preferably less than 10 ^-2 to 10 ^~ * millimeters of mercury (or about 1 to lu ^-2 Pa). This primary vacuum is intended to allow the evacuation of hydrogen gas as it is formed. The duration of the thermal dehydration treatments is moreover linked to the restoration of the initial primary vacuum.

The duration of the dehydriding treatment depends on the base material used. It is followed by cooling at constant speed, speed also depending on the starting material.

In other applications, this first post-treatment can be followed by a thermal plateau, then by subsequent thermal treatments, the purpose of which is similar to the first.

The second advanced dehydriding treatment, as well as that of high temperature annealing (third treatment) cannot be carried out directly on bonded magnets, given the low melting temperature of their matrix. In this way, in order to increase the magnetic properties of the bonded magnets, it was important to increase the magnetic performance of the powders obtained by decrepitation, according to the method described in the document EP-A-0 173 588 already cited.

In the publication TAKESHITA et al (N ° 18P0216 of lOth International or shop on Rare-Earth Magnets and Their Applications, Kyoto, Japan, May 16-19, 1989), it has certainly been shown that by submitting an ingot of an alloy Nd-Fe-B to a stream of hydrogen gas at a temperature between 750 and 900 ° C for a period of time between one and three hours, followed by a phase of about one hour under vacuum, at the same temperature, and finally by quenching to room temperature, powders of relatively good magnetic properties could be obtained. On the other hand, such a process leads to the demixing of the main phase of the basic multiphase material, and can only lead to the production of magnetically isotropic products, whatever the precursor.

In fact, only powders with anisotropic magnetic characteristics make it possible to obtain, by orientation under a magnetic field, sintered or bound materials, the persistence of which increases by effect of the orientation in a parallel direction of the particles. On the contrary, the use of magnetically iso¬ tropic powders does not make it possible to increase the magnetization (reman¬ence) of sintered or bonded materials produced from these, when they are oriented under magnetic field. .

To date, it is not known how to prepare fine and homogeneous powders of rare earth / iron / boron alloys, having a very strong anisotropy and high magnetic properties, allowing for example an increase of more than 60 to 80 % of their magnetization by orien¬ tation under field, and adapted to the production of magnets linked to very strong magnetization and coercivity.

Various methods have however been proposed for preparing powders having a certain degree of anisotropy. One of them, described for example in document EP-A-0 302 947, consists in mechanically grinding a solid anisotropic alloy having previously undergone an appropriate mechanical treatment. If certainly the products obtained have a certain magnetic anisotropy, inherent in the starting product, and not or only slightly altered by the treatment which it undergoes, on the other hand, the coercivity they develop after treatment is relatively low, this being greatly altered by the particle size reduction treatments, in particular mechanical . As a result, mechanical grinding turns out to be particularly ill-suited to obtaining homogenous fine powders, given the considerable degradation of magnetic properties of the precursor it generates.

Another approach, described in particular in document EP - A - 0 304 054, consists on the contrary of starting from an isotropic powder of fine and uniform particle size obtained for example by decrepitation with hydrogen at very high temperature (600 to 900 ° C), then to subject this powder to a treatment of plastic deformation type that hot (analogous to that carried out in the previous case at the level of the precursor) intended to induce in the said powder a certain degree of anisotropy without risk of cause it to sinter. There are certainly powders of small particle size, but whose magnetic properties, in particular the possible anisotropy of the precursor, are considerably reduced or even canceled, due to the separation of the magnetic phases constituting the basic magnetic structure, this separation being inherent to treatment under high temperature hydrogen.

On the contrary, within the framework of the present invention, a mode of treatment has been aimed at associated with a suitable precursor composition making it possible to induce a maximum rate of magnetic anisotropy at the level of this precursor. A technique of particle size reduction has been used, such as decrepitation with hydrogen practiced under moderate temperature conditions, followed by an appropriate post-treatment of dehydrogenation, capable of fully preserving the very strong anisotropy. of the precursor used for this purpose. The starting product therefore plays a fundamental role both in terms of its composition and its isotropic or anisotropic character, the latter being preserved through successive stages of decrepitation and post-treatments. In fact, this product is advantageously a rare earth / iron / boron alloy, the fe being able to be partially substituted by cobalt or by other transition elements (3d, 4d, 5d). Advantageously, and when it is desired to obtain optimum magnetic properties, part of this iron or cobalt element can be substituted by other elements such as copper or aluminum.

For the subsequent production of oriented sintered or bonded magnets, it is essential to start with a pre-cursor with anisotropic magnetic properties, in order to obtain a highly anisotropic decrepit powder whose particles are liable to orient under the effect of 'an external magnetic field. In this case, this orientation will indeed contribute to considerably increasing the remanent induction of the sintered or bonded magnet thus produced, while in the case of a product with isotropic magnetic properties, the treatment of orientation under field magnetic would have no effect.

A highly anisotropic precursor is obtained (in terms of its magnetic characteristics) if the o uses materials derived from "powder metallurgy", a technique described in more detail in document EP-A-0 101 552, or if we start from massive magnet falls. The precursors resulting from a hot-working treatment of the hammering or pressing type, described in document WO 87/07425, also exhibit these characteristics of strong magnetic anisotropy. There are also such magnetic anisotropic precursors, resulting from a specific hyper-tempering treatment. Massive precursors or in ribbons having contrary isotropic magnetic properties are obtained in the framework of the process of hot-working made by spinning, also described in the document 87/07425, or in the hyper-quenching process on roll described in particular in the document EP-A-0 108 474.

The invention also relates to the product obtained. It is a product having good magnetic properties, typically an internal energy (HB) m greater than or equal to 80 kJ / m ³ for isotropic powders and 240 kJ / m ³ for anisotropic powders, with a small homogeneous particle size, typically close to ten micrometers, or less, and in any event less than fifteen (15) micrometers. Advantageously, these products have a remanent magnetization typically of at least 40 Am ² / kg for isotropic powders and 80 Am ² / kg for oriented anisotropic powders and a high coercivity of at least 700 kA / m. in addition, when the precursor is produced by hot working, the grains of the products obtained have characteristic facies in the form of broken crystallites typical of the morphology resulting from this process of re-reading.

It was certainly known to obtain materials with significant magnetic properties, such as an internal magnetic energy greater than or equal to 200 kJ / m ³ . This type of material is for example described in the publication SHIMODA et al (J. APPL. PHYS 64 10) in which it has been proposed to produce permanent magnets based on a praseodymium / iron / boron / copper mixture and this with a low reduction rate, especially below 90%. This production process is carried out by hot pressing, at a temperature of around 1000 ^Q C The magnets obtained certainly have high magnetic properties, however their size is small. In addition, taking into account their production process, in particular by sheathing under sheath, we certainly obtain a refinement of the grains (however insufficient with a reduction rate of less than 90%), and above all a heterogeneous particle size and microstructure. Finally, the good magnetic properties can only be obtained by using praseodymium. In fact, it is clearly indicated that by replacing praseodymium with neodymium, the magnetic properties tend to drop drastically. However, the drawback of using praseodym lies in its high cost, given its low proportion in nature compared to neodymium.

Products with magnetic properties are also known, having a homogeneous and small particle size, the limit of which can be less than 0.1 μm. These products are for example obtained by means of the procedure described in the document already cited EP-A-0 173 588. As already said, the decrepitation of the products by hydriding dehydrating certainly allows to obtain products of small particle size but with a significant loss magnetic properties.

It was then thought to apply mechanical treatments in order to reduce the particle size on products obtained by quenching and having good magnetic properties. These products are presented, for example, in the form of pre-oriented platelets, leading to a certain anisotropy. However, it turns out in use that the application of mechanical grinding that also alters the magnetic qualities, in particular because of mechanical shocks. Consequently, to date there are no powdery products having simul temporarily a small homogeneous particle size, of the order of ten micrometers, or even less, and high magnetic properties, in particular for highly anisotropic powders, which develop a remanent induction in oriented form Br _βJ - _{± β} „ _{t * β} such as the report:

is greater than or equal to 80%.

The starting material is a material having the massive state already of high magnetic properties. The method according to the invention aims, following a decrepification having reduced its magnetic properties, to restore them to result in magnetic properties, in particular in coercivity, and residual induction, close to those of the starting crude product.

According to the process, the starting product is an isotropic or anisotropic polyphase alloy depending on the destination of the final product, of rare earth / iron / boron composition. In known manner, the iron can be substituted with cobalt, in particular with a view to increasing the Curie point of the final product or with other 3d transition metals, such as copper, or 4d and 5d. In addition, iron can also be partially substituted by other metallic elements such as aluminum, and this cumulatively with the transition elements. One can advantageously replace some of the rare earth atoms with others, such as dysprosium, depending on the qualities of the magnetic properties required.

This alloy is, as already said, in polyphase form, respectively a magnetic phase with high anisotropy, corresponding to the general formula R _^ -M _i4 -B, and one or more other phases with a concentration mainly in rare earth elements, consecutive to the embodiment of the basic material. The method of obtaining these starting materials will not be described in detail. As already said, they can be obtained according to the so-called "rapid quenching" technique, mechanical hot grinding or corroying, or even by the powder metallurgy technique, ie sintered powders previously oriented under field magnetic.

Once this basic material has been obtained, it is firstly hydrided by absorption of hydrogen under pressure (1 to 5 MPa) for example in an autoclave made of special steel, and generally at room temperature. However, in some cases, thermal activation is necessary. Anyway, one or a few thermal cycling during the hydrogenation phase ensure better chemical and particle size homogeneity of the material. This hydriding results in the frag¬ mentation of the material, which thus becomes very easily dispersible. The revelation of the pulverulent form of the material can be obtained by simple mechanical agitation, or by simple grinding.

According to the process of the invention, the hydrogenated pulverulent material undergoes three treatment phases:

During a first phase, a partial dehydrogenation is carried out, which concerns phase principa¬ the hydrided R ₂ -M _i4 -BH _x (where x is between 1 and 5), the latter being transformed into R ₂ -M _r4 -B.

Indeed, the hydrides formed being of the meta-stable type, the dehydriding must be carried out under primary vacuum at a temperature below their demixing temperature, otherwise, the formation of rare earth hydrides, of iron and a poorly defined iron-boron phase, the magnetic properties of the material then being definitively and unacceptably altered. The temperature of this partial dehydriding which can start under primary vacuum around 150 ° C, and q increases around 300 ° C, must not exceed 520 ° demixing temperature of hydrides R ^ -M ^ -BH ,,.

During a second phase of the treatment, q is carried out at a temperature of the order of 600 ° C., complete dehydration of the decrepit material can be carried out, in particular at the level of the eute tick rich in rare earths , which constitutes the film envelope of the magnetic domains This second phase is also carried out under primary vacuum.

Finally, the dehydrated powder thus obtained can be subjected in a third phase to an annealing treatment between 450 and 1000 ° C., aimed at completely restoring the magnetic properties, in particular the coer civity.

It can be seen that by treating the materials under this temperature scale, any risk of sintering of the residual material is avoided, a result which would run counter to the desired morphology.

The treatment can advantageously be supplemented with an in-situ passivation by introducing argon under normal pressure, before bringing the product to normal temperature.

The final heat treatments (thermal bearings) aim at optimizing at the level of the elementary particles the cohesion of the granular material, namely the phase of type R ₂ -M _i4 -B and its eutectic intergranular envelope. The different parameters of these heat treatments, respectively temperature, duration, cycle, are a function of the composition of the base material and their metallurgical synthesis process. We choose different types of starting materials (in the sense of the metallurgy of their preparation), depending on whether we want to favor the magnetization properties or coercivity properties. Likewise, and as already said, the choice of the starting material also depends on the desired anisotropy of the final product. This choice comes both in its composition and in its synthesis process.

There is shown in Figure 1, a block diagram that the different stages involved in the production of a bonded magnet. In addition to the steps mentioned above, the powders obtained after the various heat treatments are dispersed before being coated in a resin, then oriented in the field.

In order to illustrate the process according to the invention, various embodiments of products with the resulting magnetic properties have been described below.

Example 1: Phase a

An isotropic compound corresponding to the following chemical formula is used as precursor material:

obtained by hyper-quenching at the speed of 50 m / s. Sintered in massive form, such a material is known to present good magnetic properties, such as: remanent induction: 85 Am ² / kg. Coercive field: 1,250 kA / m

This material undergoes a decrepitation treatment by hydriding, and the desorption is carried out by a thermal treatment above 180 ° C. This treatment, aimed at desorbing the hydrogen from the main phase, is carried out at a speed of 300 ° C / hour. It constitutes the so-called dehydriding phase, carried out under primary vacuum. It is followed by a thermal plateau for 1 hour at 520 ^β C and finally by cooling at the speed of 150 ^β C / hour. For this finely divided isotro¬ pe material, a residual induction of 42 Am ² / kg is obtained, but a very reduced coercive field of 120 kA / m, which makes this material not usable for shaping in the state of bound magnet.

Example 1: Phase b

The same treatment is repeated as phase a, from the same material, then the latter is subjected to a second heating phase at 600 ° C., temperature obtained at the speed of 300 ° C./hour. This treatment is followed by heating to 640 ° C, temperature obtained at the speed of 50 ^β C / hour, the thermal plateau at 640 ° C being maintained for 30 minutes. This phase is followed by rapid cooling down to 600 ° C, at a speed of 1000 ° C / hour, followed by a temperature decrease of 150 ^β C / hour.

The results obtained are respectively:. a residual induction of 56 Am ^≈ / kg on a non-oriented sample of compaction 0.4; and a coercive field of 1,100 kA / m.

It can be noted that the influence of the second treatment on the material makes it possible to restore the initial magnetic properties in a way.

Example 2: Phase a

We start from an isotropic precursor material corresponding to the formula:

Nd _x6 Fe ₇₇ AlB ₆ obtained by hot working by spinning, with a working rate of 12. This material has the following magnetic characteristics in a solid state:. Residual induction: 75 Am ² / kg. Coercive field: 950 kA / m This material is decrepit and then heat treated, in the same manner as that described in the Example.

I phase a. The residual induction of the non-oriented compaction sample 0.4 is 43 AπrVkg, the field

5 coercive being only 320 kA / m.

Example 2: Phase b

The same precursor material which has undergone the treatment of Example 1 (phase a), then undergoes heating at 10,600 ° C., temperature obtained at the speed of 300 ° C./h

It is then treated according to the same process as that indicated in example 1 phase b.

The residual induction measured on a sample

15 non-oriented compaction 0.4 is 43 Am ² / kg, and the coercive field of 880 kA / m. As in the previous case, the isotropic magnetic characteristics of the solid material are therefore largely restored.

20 Example 3

We start from an anisotropic precursor material corresponding to the crude formula:

Nd _X5 DyFe _τβ B6 obtained by spinning and forging by hot working (working rate 25: 10). The initial magnetic characteristics of the material in massive form are respectively:

. remanent induction: 75 Am ² / kg. Coercive force: 1,430 kA / m 30

The material is decrepit by hydriding, then heated to 520 ^G C under primary vacuum, temperature obtained at the speed of 300 ° C / hour. It undergoes a thermal plateau lasting one hour at this temperature then is

35 heated to 600 ^β C, temperature obtained at the speed of 300 ° C / hour. It is then heated to 680 ° C, obtained at the speed of 100 "C / hour. It then undergoes a thermal plateau for 20 minutes at 680" C, then is rapidly cooled to 600 ° C at the speed of 600 ° C / hour, followed by a temperature drop to 150 ° C / hour.

The sample, in the form of a non-oriented anisotropic powder of compaction 0.4, exhibits a residual induction of 40 Am ² / kg for a coercive field of 1,200 kA / m.

The original magnetic characteristics of the material are once again restored.

Example 4 We start from an anisotropic precusor material corresponding to the crude formula:

Nd _i6 Cu_.Fe ₇₆ B ₆ obtained by forging by hot working, with a working rate of 10. The initial magnetic characteristics of this material in massive form are respec¬ tively:

. Residual induction: 116 Am ² / kg. Coercive force: 1.030 kA / m

This material is then treated as indicated in Example 3. The powder thus obtained is obtained as magnetic properties, in the non-oriented state, with a compaction of 0.4:

. Persistent induction: 53 Am ² / kg. Coercive field: 720 kA / m.

This powder is then heat treated at 1000 ° C and then at 500 ° C and is then coated in a resi¬ ne under magnetic field. The characteristics of the oriented powder thus introduced become:. Residual induction: 96 Am ² / kg. Coercive field: 720 kA / m. Thus, it appears from the above examples that the products obtained from typical size adjacent to ten micrometers, have properties ^• Magnetic quite interesting, once an appropriate heat treatment is applied to them. We note in particular the very good values obtained for coercivity, values which approach the values obtained for this quantity with the massive precursor products. It therefore appears clearly the fundamental role played by the precursor material, in particular when it is desired to favor coercivity.

All of these materials have a large residual induction, which has been characterized on a non-oriented pulverulent sample, with a relative compactness close to 0.4.

The powders thus obtained, taking into account their small homogeneous particle size on the one hand, and their high magnetic properties on the other hand, enabled the production of anisotropic bonded magnets, for which the measured remanent induction is increased by 30 at 40% compared to the anisotropic bonded magnets available today, and this for substantially the same charge of magnetic material.

Claims

1 / Method for optimizing the magnetic properties of a multiphase product endowed with permanent magnet properties at ambient temperature, acting as a pre-cursor, having undergone a decrepitation treatment by hydriding under low pressure at low temperature in order to '' obtaining an intermediate hydride in pulverulent form, characterized: - in that the powdery intermediate hydride undergoes consecutively upon hydriding a first heat treatment under partial dehydration vacuum at a temperature below its demixing temperature, - and, in that the non-deixed product then obtained undergoes a second thermal post-treatment under vacuum for dehydration at a temperature close to 600 ° C.

2 / Process for optimizing the magnetic properties of an isotropic multiphase product according to claim 1, characterized in that the precursor is an isotropic material obtained by the process chosen from the group consisting of hyper-quenching such as wheel quenching and hot working (with a working rate of at least 10).

3 / A method for optimizing the magnetic properties of an anisotropic multiphase product according to claim 1, characterized in that the precursor is an anisotropic material obtained by orientation under magnetic field and sintering of powders, or by forging a solid material or resulting from a fall in the manufacture of magnets. 4 / Method according to one of claims 1 to 3, characterized in that the dehydrated product obtained undergoes a third thermal post-treatment under a neutral atmosphere or under vacuum, at a temperature between 450 and 1,000 "C, the two post -treatments can be separated or not a thermal bearing.

5 / Method according to one of claims 1 to 4, characterized in that the precursor mainly responds to the quadratic phase R ₂ -M ₁₄ -B, the demixing temperature of which is close to 520 ° C, in which: - B denotes boron;

R denotes an element of the rare earth family or Yttrium, - and M denotes iron, optionally partially substituted by a transition element, such as cobalt, and / or by other metallic elements, such as especially aluminum and copper.

6 / Magnetic compounds obtained according to the process defined in claim 5, of homogeneous morphology of majority quadratic phase R ₂ -M ₁₄ -B, in which:

B denotes boron; - R denotes an element of the rare earth family or Yttrium, and M denotes iron, optionally partially substituted by a transition element, such as cobalt and / or other metallic elements, characterized in that '' they are in the form of a homogeneous particle size powder of average size less than or equal to fifteen micrometers, and in that they develop a coercive field of at least 700 kA / m and a remanent induction of at least 40 Am ² / kg.

7 / magnetic compounds according to claim 6, characterized in that they are magnetically isotropic.

8 / New magnetic compounds as claimed in claim 6, characterized in that they are magnetically anisotropic in that they develop a persistent induction in oriented Br _ojriβ „ _{tasβ form,} such as the ratio:

Br _oriβntώ . is greater than or equal to 80%.

9 / Magnetic compounds according to one of claims 6 to 8, characterized in that the grains which constitute them mainly contain crystallites of phase R ₂ -M ₁₄ -B, the morphology of which is identical to that of the grains of the precursor.