US2161926A

US2161926A - Method of manufacturing permanent magnets

Info

Publication number: US2161926A
Application number: US63237A
Authority: US
Inventors: Jonas Gottfried Bruno
Original assignee: Philips Gloeilampenfabrieken NV
Current assignee: Koninklijke Philips NV
Priority date: 1935-03-04
Filing date: 1936-02-10
Publication date: 1939-06-13
Anticipated expiration: 1956-06-13

Description

Patented June "13, 1939 UNITED STATES PATENT oi-"rics METHOD OF MANUFACTURING PERMANENT MAGNETS Y Gottfried Bruno Jonas, Eindhoven, Netherlands, assignor to N. V. Philips Gloellampenfabrieken, Eindhoven, Netherlands No Drawing. Application February 10. 1936, Serial No. 63,237. In Germany March 4, 1935 .1 Claim.

- Per cent 15 Nickel 3 to50 Cobalt i 0.01 to 50 Titanium 1 to 50 Although suitable permanent magnets can be made from such steel without the use of special 'heat treatment, this is only true to a limited extent and in some specific-cases in which the steel has a special composition and in which the dimensions of the castings fall within certain limits and, even then, special provisions are need- 25 ed for carrying the heat away from the mold. On the other hand, it is generally recognized that to obtain a hardening effect with precipitation hardening alloys, a thermal treatment consisting of several steps is necessary. This is the case, for instance, with Duralumin whose properties have been subjected to many years of thorough investigations.

In heat-treating magnet steel alloys based on precipitation hardening the following is the 35 usual procedure. Bodies of such steel alloys are quenched to room temperature from high temperatures at which an increased dissolving capacity of the main phase for a heterogeneous phase occurs. The alloys are then aged for a 40 longer or shorter time at temperatures which are considerably below the hardening temperature. In practice this method of heat treatment is often carried out by immersing the hot magnet body in an oil or a water bath and subsequently heating the body for some time at a higher temperature. Such heat treatment is fundamentally necessary and is generally used for this type of magnet steels. However, the exact quenching and aging temperatures, the aging time, and the quenching speed vary and depend upon the properties of the special alloy being used; the quenching speed being controlled by the selection of the cooling medium. 55 This commonly-used heat treatment has been found unsuitable for magnet steels of the above referred to type. Although it gives good magnetic results the difficulties are due to mechanical reasons which arise in the manufacture of the magnets because the high natural brittleness of this type of material, which are accentuated by such rough heat treatment. As a result, alloys of this type which are most promising because of the excellence of their magnetic properties, can not be used in the commercial manufacture of magnets at all, or involve so muchwaste as to make the cost prohibitive.

The object of my invention is to overcome such difficulties in the heat treatment of such alloy steels. According to my invention I quench the alloy, instead of to substantially room temperature, to a temperature which is substantially in I the range of the usual aging temperatures, and

may be even slightly higher. After the steel has completely acquired such a quenching temperature,.it is permitted to gradually cool to room temperature; after this it is reheated to the aging temperature at which it is then. allowed to age for a definite time.

If the quenching temperature used is higher 7 than the required aging temperature, the above to the aging temperature at which it is kept for a definite time interval, after which the steel is cooled down to room temperature.

Also when the quenching takes place at a temperature which is lower than the aging temperature-which is preferable-in certain casesthe temperature of the steel may be raised from the quenching temperature to the aging temperature, or may first ,be cooled from the quenching temperature to room temperature and then heated to the aging temperature as has been previously stated.

The simplest heat treatment is obtained when temperatures are equal the magnet body may remain in this bath during the n aging time, which may vary from e. g. one minute to several hours dependent upon the temperature of the bath and the size. of the magnet bodies. This with a separate heating operation.

I found that the magnetic properties of the alloy steels heat-treated in accordance with the invention are at least equal to and in many cases for which the product BH is maximum.

' cultiesand with small waste. K

very much better than those of the same alloy 1' steels which have been quenched to room temperature.

For a better understanding I may refer to experiments I have made with a composition obtained by pouring an alloy from 16% nickel, 28%

cobalt, 12% titanium, f aluminum, the remainder being iron. Test pieces of 10 a 28 x32 mm. were used.

a. On quenching these pieces from about 1225" C. in oil down to room temperature and after aging for some-hours at temperatures increasing up to 500 to 700 C. the following magnetic values were found; in which Brem is the remanence, Hcoerc is the coercive force, and BHmax is the product of the values for B and corresponding H rem 6900 Hcoerc 7 20 BHmu 1,730,000

12. Furthermore similanpieces were quenched from abouti1175 C. in water down to room temperature'and subsequently aged for a comparatively long time (about 20 hours) at temperatures increasing up to 500 to 700 C.

The following magnetic values were found:

Bram 4800 Hcoerc 970 13mm 1,710,000

The samejsteel having the same dimensions was subsequently treated according to the present invention, viz: e. the pieces were quenched from about 1175 C. in a tinbath of about 700 C. and were allowed to remain for about one minute therein, whereupon they were cooled down in the air. After aging for some hours at temperatures increasing up to 800-650 C. the following magnetic values were found:

BI s.

HM" BHmsx 2,700,000

d. The pieces were quenched from about 1175 C. in a tinbath at a temperature of about 575 C. and left therein for about 2 minutes followed by cooling down in the air. After agin for a long time (about 20 hours) at temperatures increasing up to 575-680 C. the following magnetic values were found:

Bram 6200 Honor: 1000 311mm 2,600,000

The important advantageof my invention is that at the same time when heat-treating magnets of the usual dimensions by the method of the invention, the danger of fissures, cracks and breakage occurring is minimized and the magnets can be manufactured without mechanical diflioneness As has been stated with previously used heat treatments this could not be achieved, and even in making small plain test magnets for measuring the magnetic properties of the alloy, there have been considerable diillculties due to brittleness. Only the heat-treating method of the invention made it possible to commercially manufacture such steel magnets.

According to the invention, quenching of the body is preferably effected from a temperature lying within the range of about 1300 C. to 1100" C. and takes place at a quenching temperature lying between 550 C. and 750 C. The quenching as stated takes place in a suitable metal or salt bath whose temperature lies within the latter range. The body may then be allowed to remain in this bath so as to be aged, or it may be subjected to a separate aging operation at a temperature of 650 C. to 680 C. after having being cooled to room temperature as above described. In some cases a quenching bath may be used having a considerably lower temperature, iior instance 100? C. to 200 C. The magnet body is then allowed to remain in this bath only until its temperature has been reduced from the initial temperature (of 1100-1300 C.) to the required quenching temperature of, for instance, 700 C.

As an example from loudspeaker practice it is remarked that an annular magnet of the size used in present-day moving-coil loudspeakers and having a composition obtained by pouring an alloy of 16% Ni, 28% Co, 46% ferrotitanium (=26% Ti, 10% Al) the remainder. being substantially iron, gave the following magnetic values which, however, should not be considered to be the maximum obtainable: l

Bren; 6200 Hcoerc 800 The magnet had the following dimensions:

. I mm. External diameter 74 Internal diameter 49 Height 35 Quenching was efiected from about 1200 C. in a tin bath of 600 to 750 C. and it was left therein for about one minute, followed by cooling down in the air. After that it was aged at a temperature increasing up to about 670 C. and subsequently magnetised in the usual way.

While I have described my invention in connection with specific examples and application, I do not wish to be limited thereto but desire the appended claims to be construed as broadly as permissible in view of the prior art.

What I claim is:

In the manufacture of permanent magnet bodies from an alloy steel containing 10. to 30% Ni, 3 to Ti, 2 to 13 Al, 4 to 30% Co, and the remainder substantially iron, the steps of drastically quenching the magnet body in a suitable bath from a temperature between 1,000" C. and 1,300 C. only to a temperature between 550 C. and 750 C., slowly cooling the body from the temperature of the bath to' room temperature, aging the body at a temperature between 650 C. to 680 C., and cooling the body to room temperature. GO'IIFRIED BRUNO JONAS.