DE826977C - Use of cobalt-chromium-iron alloys for springs - Google Patents

Description

Use of cobalt-chromium-iron alloys for springs The ternary The diagram of the three-component system iron-cobalt-clirom is known in broad outline.

It is also known that, for. B. Alloys with 56% cobalt, 8% Chromium, remainder iron after special heat and rolling treatment. Permanent magnet properties own.

It is also known that in alloys with 20 to 40% cobalt, 5 to 10% chromium, the remainder iron, the Brinell hardness can be increased from about 280 to 38o to about 35o to 450 by tempering at about 45 °.

Finally, the use of alloys with more than to% cobalt, more than 10% iron, up to 4o0 / 0 chromium and up to 2% beryllium for the production of Springs of technical arrangements have been proposed without further details made about the appropriate composition within this wide range of alloys would have been. According to the invention, alloys are made of 52 to 59% cobalt, 6 to 10% Chromium, the rest iron for the manufacture of balance springs for watches or for springs used, which should have similar properties as balance springs. The alloys can also add beryllium and titanium, individually or together, in amounts up to each i o / o included. From balance springs it is required that they are in addition to sufficient Hardness or strength and a sufficiently high modulus of elasticity as low as possible Temperature dependence of the modulus of elasticity over the widest possible temperature range exhibit. For example, this is used for balance springs for the temperature range of -2o to + 40 ° required. For springs of technical arrangements it may be desirable a temperature-independent modulus of elasticity in a different temperature range to have. Based on what about the properties of some of the alloys in the system Cobalt chrome fins was known, it could not be deduced or determined that alloys with the composition to be used according to the invention has the properties in particular would combine in a useful way for balance springs. To generate the desired Properties, it is useful to the alloys after their annealing at temperatures between iooo ° and the melting point to cool quickly or to quench them and they then to anneal at temperatures of 400 to 700 °, preferably 50 to 65o °.

After annealing and quenching, cold working, e.g. B. cold rolling are switched on. The alloys used can contain, in the usual way, small amounts of deoxidation and processing additives, e.g. 13. Manganese or silicon in: \ Zengen, which are usually not Tiber 10, / o.

Claims (5)

PATL: N CLAIM: i. Use of alloys with 52 to 59% cobalt, 6 to 12% chromium, the remainder iron, optionally in addition to the usual deoxidizing and processing additives as a material for springs with sufficient hardness and sufficient modulus of elasticity in as large a temperature range as possible, do not agree with the temperature or have a modulus of elasticity that changes slightly, especially for balance springs of clocks. 2. Use of alloys in addition to those mentioned in claim i Components still beryllium and titanium, individually or together, in amounts up to each contain i%, for the purpose stated in claim i. 3. Use of I, egie-ungen, those in addition to the ingredients mentioned in claim 1 or 2 also 1> 1s i% manganese or contain silicon, for the purpose stated in: ynspruch i. 4. Use \ -oii alloys of the composition mentioned in claims 1, 2 or 3 im quenched from temperatures above 100 ° and at 400 to 700 °, preferably at 500 to 65o ° tempered condition for the purpose of claim i. 5. Use of alloys according to claim 2, which are cold worked before tempering, for the Purpose according to: 1nsl> ruch i. Related publications: H o u d r e m o n t, Handbuch der Spezialstahlkunde, 1943, pp. 747, 756 1111d 359.