JPS62167842A - Production of rare earth magnet - Google Patents

Abstract

PURPOSE:To obtain additionally higher magnet characteristics by executing heat treatments in >=3 stages under specific conditions after sintering in the stage of producing permanent magnets consisting of a rare earth metal, transition metal and more particularly Nd, Fe and B by powder metallurgy. CONSTITUTION:Raw materials are melted, ground and molded in a magnetic field to form an R2T14B magnet essentially consisting of Nd.Fe.B (R is Y and rare earth metal, T is a transition metal). The molding is sintered by holding the same for about 1hr in a vacuum at, for example, about 1,080 deg.C sintering temp. holding for about 1hr in Ar and is then quickly cooled. The sintered body is subjected to >=3 stages of the aging treatments to start the treatment in a 1,000 deg.C temp. range from the sintering temp. in the first stage and to make the treatment in a 400-650 deg.C temp. range in the final stage. For example, the sintered body is held for 1hr in the above-mentioned first stage and while the temp. is lowered by about 100 deg.C each, the sintered body is held at each temp. for 1hr each and is subjected to the multi-stage aging treatment down to 500 deg.C.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides R2T14B made of rare earth metal (R) and transition metal (T), typified by Nd-Fef permanent magnets.
In particular, Nd-Fe-
The present invention relates to improvement of magnetic properties when a permanent magnet containing B as a main component is manufactured by a powder metallurgy method.

[Conventional technology]

Methods for manufacturing R-Fe-B magnets are roughly divided into two methods. One is the liquid quenching method, which uses a thin ribbon of super-quenched molten alloy. On the other hand,
This is a sintered magnet manufactured by pulverizing an ingot of a magnetic alloy obtained by melting, molding it in a magnetic field, and then sintering it.

Documents related to sintered magnets manufactured by the R-Fai magnetic surface magnet powder metallurgy method include Japanese Patent Application Laid-open No. 59-46008 and Japanese Society of Applied Magnetics 35th Research Meeting Materials “Nd-F
e-B section magnet" (May 1981).

The former only states that the molded body is left to cool after sintering, but does not specify the conditions for heat treatment after sintering. The latter also describes that after sintering a molded body, heat treatment at around 600° C. increases IHC. On the other hand, 1 Summary of General Lectures at the Spring Conference of the Japan Institute of Metals (1985, April,
P, 346) Regarding heat treatment of P-Fe-B permanent magnet alloy, heat treatment at 1000°C or lower is described. However, these heat treatments relate to one or two stages of aging treatment and are completely different from the present invention.

[Problem that the invention seeks to solve]

As a result of two different experiments, the inventor found that Nd-Fe-B
It has been discovered that even higher magnetic properties can be obtained by subjecting an R2T14B magnet sintered body containing R2T14B as a main component to multi-stage aging.

Generally, the manufacturing process of single magnets using powder metallurgy includes melting, crushing, orientation in a magnetic field, compression molding, and sintering.

They proceed in the order of the statute of limitations. Melting is usually carried out in a vacuum or inert atmosphere, such as with a high frequency arc.

Grinding is divided into coarse grinding and fine grinding, and coarse grinding is performed using a show crusher, iron mortar, disk mill, roll mill, etc. Fine grinding is done using a goal mill.

This is done using a vibration mill, jet mill, etc. Magnetic field orientation and compression molding are usually performed simultaneously in a magnetic field using a mold. Sintering is in the range of 1000 to 1150°C,
It is carried out in an inert atmosphere.

Aging is performed at a temperature around 600°C.

The present inventors have discovered that high magnetic properties can be obtained by appropriately controlling the aging conditions of the magnet sintered body.

[Means for solving problems]

In the present invention, raw materials are melted in an R2T14B magnet whose main component is Nd-Fe-B (where R is yttrium and a rare earth element, and T is a transition metal), and then pulverized using a pulverizer.

This is then subjected to a multi-stage aging treatment in which aging treatment is performed in at least three stages after forming in a magnetic field, with the starting temperature of the first stage of aging treatment being 1000°C or higher (below the sintering temperature) and the final stage being 400°C. The holding power IHC was 9 KO.
e or more, energy product (OH) max is 37 MGau
Obtained ss Oe or higher.

〔Example〕

1. Uses 98% pure Nd and high purity Fe4''e.

An ingot was produced by high-frequency heating in an Ar atmosphere so that Nd was 34 wt%, B was 1.1 wj%, and the balance was Fe.

Next, this alloy was coarsely ground, and then ground to an average particle size of about 3 μm using a ball mill. This powder was compacted at a pressure of 1 ton/J in a magnetic field of 10 KOe. After holding this molded body in vacuum at a sintering temperature of 1080°C for 1 hour.

It was held in Ar for 1 hour, sintered, and quenched.

Next, this sintered body was heated at 900°C and 950°C.

℃, 1050℃, and 1080℃ as aging starting temperatures for 1 hour, and then decreasing the temperature by about 100℃ and holding each temperature for 1 hour to perform multi-stage aging treatment up to 500℃. . The results are shown in FIG. Further, FIG. 3 shows the heating, cooling and drying of the multi-stage aging treatment at an aging start temperature of 1080° C. in this example. For comparison, a sintered body produced by the same method was aged for 1 hour at 600°C, which is considered to be good. As shown in Figure 1, the properties were Br 12.8KG, IHC7 ,OKO
e, (BH)max.

35, 0 M-G・Oe and h.

By setting the multi-stage aging start temperature in the range from 1000° C. to the sintering temperature, the magnetic properties are significantly improved.

2. Using the sintered body produced in Example 1, start multi-stage aging from the sintering temperature of 1080°C, lower the temperature by approximately 100°C, hold each temperature for 1 hour, and complete the final multi-stage aging. Multi-stage aging was performed by changing the aging treatment temperature in the range from 400°C to 800°C. The relationship between the final multi-stage aging treatment temperature and the magnet properties is shown in FIG. 2.

When the final multi-stage aging temperature ranges from 400°C to 600°C, the magnetic properties are significantly improved.

The above examples describe the effects of the Nd-Fe-B system and multi-stage aging, but these results do not apply to Nd-Fe4
It can be easily inferred that an R2T14B alloy containing as a main component is highly promising.

In addition, regarding the holding temperature interval and holding time of multi-stage aging, in this example, it was carried out at about 100°C for 1 hour, but other temperature intervals and holding times may be used. It can be easily inferred that even if the temperature is raised or lowered in the process-1, the effects of the present invention can be fully expected as long as the treatment temperature is within the range of the present invention described above.

Further, in this example, the temperature was lowered stepwise, but the same effect was obtained even if rapid heating and cooling were repeated for each aging. Also, the number of multi-stage aging is preferably 3.
Levels above were effective.

〔Effect of the invention〕

The present invention has been described in detail above.

When manufacturing R2T14B magnets containing Nd-Fe-B as the main component by powder metallurgy, the sintered body is aged at a temperature range of 1000°C from the sintering temperature and then heated to 1400°C.

[Brief explanation of drawings]

FIG. 1 shows the relationship between the multi-stage aging start temperature and magnetic properties of the Nd-Fe4 magnet sintered body in Example 1. Figure 2 shows the relationship between the final multi-stage aging treatment temperature and magnet properties of the Nd-Fe-B magnet sintered body in Example 2. Figure 3 shows the relationship between the starting temperature in Example 1 and 1080°C. Showing heating/cooling/lean in multi-stage aging treatment. Figure 1: 9j'J starting temperature (・C) Figure 3

Claims (1)

[Claims] R_2T_1_4B containing 1, Nd, Fe, and B as main components
In the method of manufacturing magnet alloys by powder metallurgy, aging treatment is performed in at least three stages, with the first stage starting the sintered body at a temperature range of 1000°C from the sintering temperature, and the final stage at 40°C.
A method for producing a rare earth magnet, characterized in that it is carried out at a temperature range of 0°C to 650°C (wherein R in R_2T_1_4B represents yttrium and a rare earth element, and T represents a transition metal).