CH704233A1 - Outer part of a casing for a watch, where outer part is made of quasi-beta titanium alloy that is subjected to a hardening treatment comprising heating the alloy at a specified value, quenching and then tempering to obtain a hardness - Google Patents

Abstract

The outer part of a casing for watch, is claimed. The outer part is made of quasi-beta titanium alloy, which is subjected to a hardening treatment comprising heating the titanium alloy at a temperature of 760[deg] C+- 5[deg] C below beta -transus for 30 minutes, quenching and then tempering at a temperature of 5000[deg] C+- 5[deg] C for a period of 8 hours so to obtain a hardness of greater than 490 HV.

Description

Technical area

The present invention relates to an article based on titanium, including a decorative portable article such as a dressing part for the watch industry, having a high hardness.

State of the art

In general, the cladding parts for watches such as boxes, cases, bracelet links, or the like, with high hardness and gloss are made from austenitic stainless steels. One of the main reasons for this choice is that this type of steel can be easily stamped or stamped.

In order to lighten the trim parts, the manufacturers are interested in titanium and its alloys for the manufacture of watch cases, bracelets, etc. These titanium-based articles do not contain any allergenic elements, and when properly treated, exhibit aesthetic brilliance. For this purpose, titanium alloy Ti6Al4V, also known as grade 5 titanium, is most often used. Indeed grade 5 titanium alloy is used extensively in applications in the field of aeronautics, medical, marine and chemical engineering. Its mechanical properties are similar to the properties of type 316 stainless steels.

However, titanium and its alloys, including grade 5 titanium alloy, are susceptible to scratching because of their rather low surface hardness (the hardness of titanium in its raw state is about twice as high as that of unhardened 316L steel) and the surface appearance of articles made from these materials tend to degrade after a certain period of use.

[0005] A number of titanium surface treatments have been proposed in the past in order to improve its surface hardness. These treatments include coating the surface of titanium or a titanium alloy with a hard coating, for example, by a physical deposition method such as CVD or others. This approach, however, faces the problem of adhesion between the coating and the metal substrate.

EP 672 489 discloses a titanium-based article comprising a mixture comprising a titanium matrix and addition elements selected from nitrides, carbides, carbonitrides, silicides, and borides. The article has a high hardness which varies, depending on the choice of addition elements and their amount in the mixture, typically between 300 and 1200 HV. The surface of the article can however lose its metallic luster and change color.

[0007] It is also known that titanium can be cured on the surface by treatments consisting of heating it in the presence of oxygen or nitrogen. Document CH 539 128 describes such a process for the manufacture of a titanium part in which, after having been shaped, the part is exposed at high temperature and under low pressure to the diffusion of oxygen, nitrogen, hydrogen or a mixture of these gases, then cooled rapidly.

Typically, these known methods use relatively mild temperatures below 1000 ° C, and the duration of treatment reaches several hours or even several hundred hours in some cases. The appearance of the piece thus treated may also be affected by the fact that the surface of the titanium or titanium alloy becomes coarse because of the growth of the grains at the surface during the treatment.

Brief summary of the invention

An object of the present invention is to provide the use of a titanium alloy for the manufacture of watchmaking parts free of limitations of the prior art known.

According to the invention, these objects are attained in particular by means of an outer piece of cladding for a watch being formed at least partly in a titanium alloy, characterized in that the titanium alloy is of quasi-type. -Beta, and in that said titanium alloy is subjected to a curing treatment comprising dissolving the titanium alloy at a temperature of about 30 ° C to 60 ° C below the β-transus; a quench; and a tempering treatment at a temperature between about 450 ° C and 590 ° C, for a period of between 4 and 10 hours; so as to obtain a hardness of at least greater than 450 HV.

In a preferred embodiment, the quasi-Beta type alloy is a Ti-10V-2Fe-3Al alloy. The solution step can be carried out at a temperature of about 760 ° C +/- 5 ° C for a period of at least 30 minutes. Preferably, the tempering step is carried out at a temperature of about 500 ° C +/- 5 ° C, for a period of about 8 hours.

The invention also relates to a watch comprising the dressing part formed at least partly in the titanium alloy described here.

This solution has the advantage over the prior art of trim parts that are less sensitive to scratches than conventional parts manufactured, for example, grade 5 titanium.

Example (s) of embodiment of the invention

In a preferred embodiment, a dressing part of a watch is made of a titanium alloy type Ti-10V-2Fe-3AI. Here, the trim piece may comprise one or more of the pieces forming the watch case, for example, a middle part, a crown, a bezel and a bottom, but also links of bracelets, or others.

The alloy of Ti-10V-2Fe-3AI type, also called Ti-10-2-3, is a titanium alloy of quasi-Beta type which has at room temperature two alpha phases (hereinafter "α"). ) And Beta (hereinafter "β"), which has a β transition (hereinafter "β-transus") between a domain where the α and β phases coexist and the pure β phase domain. The temperature at which the β-transus is encountered is about 800 ° C and may vary depending on the composition of the alloy. The Ti-10-2-3 alloy contains sufficient β stabilizing element (here Fe) to suppress the martensitic transformation during quenching at room temperature.

The Ti-10-2-3 alloy is an alloy having both low density and high mechanical strength. This is why it is very popular in applications in the field of aeronautics, for example to produce parts of landing gear and structural parts. However, this alloy is very sensitive to microstructural defects. The Ti-10-2-3 parts are generally obtained after thermomechanical transformation steps followed by heat treatment steps. The Ti-10-2-3 alloy typically has a hardness of about 310 HV in the raw state, i.e., in the absence of heat treatment. Therefore, it will be susceptible to scratches and the surface appearance of articles made in this alloy will tend to degrade after a certain period of use.

In one embodiment, a trim piece is made of a Ti-10-2-3 alloy having a composition comprising between 9.0% and 11.0% by weight of vanadium, between 1.6% and 2.2% by weight of between 2.6% and 3.4% by weight of aluminum, up to 0.13% of oxygen, up to 0.05% of carbon, up to 0.05% of nitrogen, up to 0.015% of hydrogen, the percentage residual being titanium and impurities resulting from the elaboration.

After being shaped, the trim piece Ti-10-2-3 is subjected to a curing treatment comprising a solution step, followed by a quenching step to maintain the supersaturated structure at room temperature. The curing treatment also includes a tempering step for uniformly distributing the precipitated phase during the first step. The hardening mechanism of titanium alloys is substantially different from that of steels. Tempering and tempering steps are found, but for Ti 10-2-3 the gain in hardness is mainly acquired after an income stage.

More particularly, a hardening treatment comprises the steps of: heat treating solution of the titanium alloy piece at a temperature of about 30 ° C to 60 ° C below the β-transus, for a period of at least 30 min .; quenching, i.e. cooling the room, for example, to room temperature; heat treatment of tempering the room at a temperature typically between about 450 ° C and 590 ° C for a period between 4 and 10 hours.

Preferably, the dissolution step is carried out at a temperature of about 760 ° C +/- 5 ° C. The cooling step is typically carried out with the blown air but can also be done with a quenching with water. After the cooling step, the measured hardness is about 380 HV. The tempering step is carried out at a temperature of about 500 ° C +/- 5 ° C for a duration of about 8 hours. The gain in hardness is then achieved. After this tempering step the hardness obtained is at least greater than about 450 HV, and preferably about 490 HV.

The dissolution and tempering steps are preferably carried out in a neutral atmosphere furnace so as to avoid oxidation of the parts.

The microstructure of the Ti-10-2-3 alloy after thermomechanical transformations during a shaping step (forging or rolling, for example) is heterogeneous. The dissolution step makes it possible to homogenize the microstructure of the alloy which has been marked by the thermomechanical transformations which preceded. The dissolution temperature makes it possible to put in solution a maximum of phase a without eliminating this phase which remains necessary to avoid an excessive increase of the size of the grain. Preferably, the temperature and the duration of the dissolution stage are determined to obtain at the end of the first stage a quantity of phase a between 2 and 5%. A minimum content of 2% makes it possible to prevent p-phase grains from growing in an uncontrolled manner, which would have the consequence of considerably reducing the mechanical characteristics of the alloy, especially the tensile mechanical properties. And a phase content of less than 5% is preferable to allow a good homogenization of the microstructure of the alloy, and in particular to break the boundaries of a phase that have formed following thermomechanical treatments.

The cooling step is carried out to room temperature at a rate preferably between 5 ° C and 150 ° C per minute. This is for example an air cooling performed after removing the piece of the solution treatment furnace. It is preferable that the cooling rate be less than 150 ° C per minute to avoid too heterogeneous hardening between the surface and the core of the room and avoid the risk of cracks (superficial cracks) during cooling. A rate of at least 5 ° C per minute is preferable to anticipate a homogeneous response to the subsequent income treatment during which hardening precipitation occurs.

The manufacture of the trim piece is not limited to the Ti-10-2-3 alloy, but may also include other alloys of quasi-Beta type, such as Ti-13V-11Cr- 3Al (also Ti-13-11-3), Ti-15V-3Cr-3Al-3Sn Ti-15-3 (also), and Ti-5Al-5V-5Mo-3Cr (also Ti-5-5-5- 3). Titanium alloys of quasi-Beta type contain a small amount of β stabilizers, such as Mo, V, Fe, Cr, Nb, etc., which allow the retention of a certain amount of the β phase in the alloy. . Titanium alloys of the quasi-Beta type are defined in the reference: P. Bania: Beta Titanium Alloys and Their Role in the Titanium Industry, in: Beta Titanium Alloys in the 1990 s, D. Eylon et al. (eds.), TMS, Warrendale, PA, USA (1993) 6.

In this case, the temperatures at which the solution and solution steps are performed during the curing treatment may be different from those used in the case of the Ti-10-2-3 alloy. For example, in the case of the Ti-5-5-5-3 alloy, the dissolution step is advantageously carried out at a temperature of between about 790 ° C. +/- 5 ° C., ie say at a temperature of about 50 ° C below the temperature of the p-transus (which is about 840 ° C for this alloy). The tempering step is preferably performed at a temperature of about 600 ° C ± 5 ° C.

A cladding part of a watch manufactured in titanium alloy Ti-10-2-3, or other quasi-beta titanium alloy, and subjected to the curing treatment as described. above, can produce watch cases less sensitive to scratches than conventional boxes manufactured, for example, grade 5 titanium.

The use of a thermally hardened quasi-Beta titanium alloy is not necessarily limited to a cladding part of a watch or a part of the cladding of a watch, but can also be used for the manufacture of all or part of parts of the movement of the watch, such as axes, the pendulum, platinum, bridges, or others.

Claims (8)

An outer cladding part for a watch being formed at least in part of a titanium alloy, characterized in that the titanium alloy is of quasi-Beta type, and in that said titanium alloy is subjected to a treatment. curing method comprising dissolving the titanium alloy at a temperature of about 30 ° C to 60 ° C below the β-transus; a quench; and a tempering treatment at a temperature between about 450 ° C and 590 ° C, for a period of between 4 and 10 hours; so as to obtain a hardness of at least greater than 450 HV. 2. The dressing part according to claim 1, wherein the quasi-Beta type alloy is a Ti-10V-2Fe-3Al alloy. 3. Skin part according to claim 2, wherein the Ti-10V-2Fe-3Al alloy comprises between 9.0% and 11.0% by weight of V, between 1.6% and 2.2% by weight of Fe, and between 2.6%. and 3.4% by weight of Al. The cladding part according to claim 2 or 3, wherein the dissolving step is carried out at a temperature of about 760 ° C +/- 5 ° C for a period of at least 30 min. 5. Dressing part according to one of claims 2 to 4, wherein the tempering step is carried out at a temperature of about 500 ° C +/- 5 ° C, for a period of about 8 hours. 6. A trim piece according to one of claims 2 to 5, wherein the alloy a hardness of about 490 HV. 7. Use of a titanium alloy according to one of claims 1 to 6 for the manufacture of at least a portion of an outer piece of dressing for a watch. 8. Watch comprising the dressing part according to one of claims 1 to 6.