NL8800739A - HARDMAGNETIC MATERIAL. - Google Patents

Description

)% t PHN f2481 1 N.V. Philips "Incandescent light factories in Eindhoven Hard magnetic material.

The invention relates to a hard magnetic material containing a rare earth metal, iron and carbon. The invention also relates to a magnet based on hard-etnic material.

Hard magnetic material of the type mentioned in the opening paragraph is known, inter alia, from J. Appl. Phys. 61 3574-3576 (1987). The compound Nd2Fe ^ C described herein is described as unstable by the authors of the article. Therefore, this material cannot be used as the starting material for a permanent magnet.

The object of the invention is to provide a hard magnetic material which contains a rare earth metal (RE), iron and carbon, and which is stable. According to the invention, this object is met with a hard magnetic material, which is further characterized in that the material contains a hard magnetic phase, the composition of which corresponds to the formula wherein RE is at least one element, selected from the set 20 consisting of Nd ( Neodynium), Pr (Praseodynium), Ce (Cerium) and La (Lanthanum), and where 0.2 (x 4 <2. It has been established that the value of x cannot be chosen arbitrarily. The materials where x is less than 0.2 appear to be insufficiently stable The Curie temperature of the materials where x is greater than 2 will be around or below the room temperature, which is difficult for magnetic application of these materials The Curie temperature can in principle be increased by a to replace part of the iron present in the material with cobalt The absence of B in the compounds according to the invention is an advantage, because in the preparation thereof no toxic, volatile boron compounds can be formed.

It has further been experimentally established that the hard magnetic phase of the compounds according to the invention has a tetragonal crystal structure of the ThMn® type, as is the case with the known NdjFe®B. As can be seen from the table below, the Curie temperature (Tc) of the compounds of the invention is between 300 and 550 K. The Curie temperature of compounds of the invention having an identical rare earth metal is lower as the Μη content is higher.

TABLE:

Connection Curie temperature (K) 10 Nd2Fe ^ ^ Mn ^ jC 505

Nd2Fe.j3 ^ HnQ gC 492

Nd2Fe13MnC 452

NdFe ^ ςΗη ^ gC 400

Nd2Fe12Mn2C 355 15 P ^ Fe ^ ^ HiIq jC 481 P ^ Fe ^ gHnQ gC 460

Pr2Fe13MnC 412

Pr2Fe- (2Mn2c 306 20) The hard magnetic materials of the invention can be conventionally obtained by fusing appropriate starting materials in the proportions corresponding to the gross formula, followed by a recrystallizing annealing treatment in a temperature range of 800 ° C-950 ° C in 25 protective gas or vacuum.

It should be noted that in experiments that led to the present invention, the applicant has become aware that the manufacture of a stable material with a hard magnetic phase, the composition of which conforms to the formula Nd2Fe ^ C, is possible in principle. On the one hand, this was found to be possible by having a casting with gross composition Nd 2 Fe 2 C undergo a long-term recrystallizing annealing treatment within a small temperature range, preferably between 850 and 880 ° C. The applicant has indications that for the preparation of the material according to the invention a shorter recrystallizing annealing treatment is required to obtain the desired tetragonal structure than the known method. The annealing treatment of the materials according to the invention can also take place in a wider temperature range.

On the other hand, this stable material can also be prepared by ribbon spraying a melt of gross composition Nd2Fe14C, followed by a recrystallizing annealing treatment of the formed ribbon.

Both known methods have the drawback that they are less attractive from a production economic point of view.

The hard magnetic properties of the compounds according to the invention are comparable to those of Nd2Fe ^ B based materials. For example, the magnetization measured on Nd2Fe13 -jMtiq 3C powder at room temperature is approximately 100 Am / kg. This value is comparable to the saturation magnetization measured on Nd2Fe ^ B powder at room temperature. It should be noted that since these are magnetically very anisotropic material in these cases, these values cannot be considered as the saturation magnetization.

After pulverization, magnets in the form of shaped bodies can be made from the materials obtained in the usual manner.

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Claims (2)

Hard magnetic material containing rare earth metal, iron and carbon, characterized in that the material contains a hard magnetic phase, the composition of which corresponds to the formula RE2Fe14-xMnx ^ where RE is at least one element selected from the collection consisting of Nd (Neodyniuo), Pr (Praseodynium), Ce (Cerium) and La 10 (Lanthanum), where 0.2 N <x N <2. 2. Permanent magnet on the basis of a hard magnetic material according to claim 1., SS 0 07 3 9