Permanent magnet alloy

Abstract

A permanent magnet alloy characterized by increased Curie temperature which is achieved by including nickel and cobalt in combination with at least one rare earth element neodymium and mischmetal in combination with iron and boron. Specifically, the alloy contains, in atomic percent, 10 to 20 mischmetal and/or neodymium, 2 to 30 nickel and/or cobalt, 2 to 14 boron and balance iron.

Description

Permanent magnets when used in applications such as electrical motors require relatively high Curie temperatures (Tc) to permit the magnets to function in high temperature applications. For this purpose Curie temperatures of at least about 310.degree. C. are necessary. Permanent magnet alloys containing a rare earth element such as neodymium or mischmetal in combination with iron are known but these cannot achieve the required Curie temperature necessary for use of the magnets in conventional high-temperature applications. If boron is added for this purpose, the Curie temperature is increased but not to the required level.

It is accrordingly a primary object of the present invention to provide a magnet alloy containing at least one rare-earth element and a Curie temperature above 310.degree. C.

This and other objects of the invention, as well as a more complete undestanding thereof, may be obtained from the following description, specific examples and drawing:

The single FIGURE is a graph showing the effect of nickel and cobalt additions on the Curie temperature of neodymium-iron-boron permanent magent alloys.

Broadly, in accordance with the invention the permanent magnet alloy consists essentially of, in atomic percent, neodymium and mischemetal within the range of 10 to 20. If neodymium or mischmetal are used alone they may be within the range of 12 to 18%. Nickel and cobalt may be present within the range of 2 to 30. If nickel is used alone it is within the range of 2 to 15 and if cobalt is used alone it is present within the range of 2 to 30. Boron is present within the range of 2 to 14. The major alloying constituent constituting the balance of the alloy is iron.

To demonstrate the inventon from the standpoint of Curie temperatures achieved in accordance with the practice of the invention the alloys, all of which contain neodymium and iron, set forth in Table I were melted and premanent magnets were produced for testing to determine the Curie temperature. The magnets were produced by melting the elements in their stoichiometric proportions and casing in copper molds. The cast alloys were crushed to 5 to 10 micron size, oriented in a magnetic field, pressed and sintered at 1000.degree.-1100.degree. C.

TABLE I______________________________________AlloyMolecular Formula Atomic Percent T.sub.c (.degree.C.)______________________________________NdFe.sub.7 Nd = 12.5 Fe = 87.5 57NdFe.sub.7 B.sub.0.33 Nd = 12 Fe = 84 B = 4 2991*NdFe.sub.6 NiB.sub.0.33 Nd = 12 Fe = 72 Ni = 12 358 B = 4NdFe.sub.6.4 B Nd = 12 Fe = 76 B = 12 2952*NdFe.sub.6 Ni.sub.0.4 B Nd = 11.9 Fe = 71.4 Ni = 4.8 345 B = 11.9NdFe.sub.5.13 B.sub.0.53 Nd = 15 Fe = 77 B = 8 3043*NdFe.sub.4.46 Co.sub.0.66 B.sub.0.53 Nd = 15 Fe = 67 Co = 10 424 B = 84*NdFe.sub.3.8 Co.sub.1.33 B.sub.0.53 Nd = 15 Fe = 57 Co = 20 518 B = 85*NdFe.sub.3.13 Co.sub.2 B.sub.0.53 Nd = 15 Fe = 47 Co = 30 582 B = 8______________________________________

As may be seen from Table I only the magnets containing either cobalt or nickel in combination with neodymium, iron and boron exhibit Curie temperature above the required value of 310.degree. C. In addition, it may be seen from Table I that the Curie temperature increased with increased additions of nickel and cobalt. The Curie temperature test results of Table I for both nickel and cobalt containing alloys are graphically presented in the Figure.

The meschmetal containing alloys of Table II were melted and prepared in the manner similar to the magnets of Table I.

TABLE II__________________________________________________________________________AlloyMolecular Formula Atomic Percent Curie Temperature__________________________________________________________________________MM*Fe.sub.5.26 B.sub.0.4 MM = 15 Fe = 79 B = 6 242.degree. C.MM Fe.sub.5.26 B.sub.0.4 MM = 15 Fe = 79 B = 6 228.degree. C.MM*Fe.sub.4.6 Co.sub..66 B.sub.0.4 MM = 15 Fe = 69 Co = 10 B = 6 352.degree. C.MM Fe.sub.4.6 Co.sub..66 B.sub.0.4 MM = 15 Fe = 69 Co = 10 B = 6 326.degree. C.__________________________________________________________________________ *La/Ce ratio in MM = 1.41; MM = 0.5

These alloys were also tested to determine Curie temperature. Like the neodymium containing alloys of Table I only the mischmetal-iron-boron alloys containing cobalt exhibited adequate Curie temperature.

The beneficial effect of additions of cobalt and nickel were also demonstrated for these magnets, as shown in Table III, when tested for anisotropy or magnetic alignment. The results of these tests are set forth in Table III.

TABLE III__________________________________________________________________________ AnisotropyAlloy Field,Molecular Formula Atomic Percent H.sub.A__________________________________________________________________________NdFe.sub.6.4 B Nd = 12 Fe = 76 B = 12 52,000 Oe6*NdFe.sub.6.4 NiB Nd = 10.6 Fe = 68 Ni = 10.6 B = 10.6 60,000 OeNdFe.sub.5.13 B.sub.0.53 Nd = 15 Fe = 77 B = 8 45,000 Oe7*NdFe.sub.4.46 Co.sub.0.66 B.sub.0.53 Nd = 15 Fe = 67 Co = 10 B = 8 64,000 Oe8*NdFe.sub.3.8 Co.sub.1.33 B.sub.0.53 Nd = 15 Fe = 57 Co = 20 B = 8 49,000 Oe__________________________________________________________________________

With these alloys of Table III the magnetic alignment was improved by the addition of either nickel or cobalt to the neodymium-iron-boron alloy.

Claims

1. A permanent magnet alloy consisting essentially of, in atomic percent, a rare earth element selected from the group consisting of neodymium and mischmetal 10 to 20, nickel 2 to 15, boron 2 to 14 and balance iron.