CH720707A2 - PLATINUM LEAGUE - Google Patents

Abstract

This disclosure relates to a Platinum alloy for jewellery applications, comprising: – Platinum, between 920 ‰ by weight and 980 ‰ by weight; – Tin, between 5 ‰ by weight and 35 ‰ by weight; – Ruthenium, between 8 ‰ by weight and 45 ‰ by weight or Copper, between 2 ‰ by weight and 45 ‰ by weight.

Description

Technical field

[0001] This disclosure relates to the field of metallurgy, in particular to the field of Platinum alloys. In particular, this disclosure concerns a Platinum alloy for jewelry applications.

[0002] This disclosure also relates to a jewelry item made from the Platinum alloy described herein.

Field of technique

[0003] Platinum alloys are metal alloys that can be used for jewelry applications. In particular, Platinum alloys can be favorably employed for the production of watch mechanisms, thanks to their mechanical and functional properties.

[0004] Such mechanisms can be hidden by the case back or, alternatively, they can be visible, completing the aesthetics of the object itself. In this particular case, the case back typically features a transparent element, for example made of sapphire glass or plastic material, which allows the user - when the watch is not being worn - to observe the internal mechanisms.

[0005] Platinum alloys can also be used to make jewellery items such as watch components or bracelets, intended for example to come into direct contact with human skin.

[0006] In jewelry applications, the brightness or brilliance of the alloy plays an important role; the higher it is, the greater the aesthetic quality of the object and consequently the alloy is more appreciated. In the CIELAB system this property is defined by the L* coordinate.

[0007] Platinum alloys for jewellery applications must have optimal workability characteristics; in particular, Platinum alloys must be able to be subjected to all mechanical processes typically used for the production of jewellery or watch parts. In particular, they must not present defects such as cracks or fractures when subjected to deformation by plastic deformation (rolling, wire drawing, etc.) and/or mechanical processes by chip removal.

[0008] In the field of application considered, alloys of Platinum and Ruthenium for mechanical processing are known; in particular, a binary alloy is known, which consists of Platinum at 950 ‰ by weight and Ruthenium 50 ‰ by weight. Such alloys, in addition to being characterized by a high melting temperature, above 1700 °C, actually present limitations in workability, in particular during the chip removal phases. For example, the diamond-polishing process, widely used for other families of precious alloys - in particular for gold alloys of different carats - can hardly be used for the production of components in binary alloys of Platinum and Ruthenium.

[0009] The purpose of this disclosure is to describe a Platinum alloy that allows for improved workability.

Summary

[0010] In order to solve the above-described drawbacks and in particular to obtain an alloy with optimal workability properties, the Applicant has conceived a Platinum alloy in accordance with the aspects described herein. These aspects may be combined with each other or with portions of the detailed description or the claims.

[0011] In accordance with the present disclosure, a Platinum alloy for jewelry applications is described, comprising: – Platinum, between 920 ‰ by weight and 980 ‰ by weight; – Tin, between 5 ‰ by weight and 35 ‰ by weight; – Ruthenium, between 8 ‰ by weight and 45 ‰ by weight or Copper, between 2 ‰ by weight and 45 ‰ by weight.

[0012] According to a further non-limiting aspect, Tin is present between 10 ‰ by weight and 30 ‰ by weight, preferably between 12 ‰ by weight and 28 ‰ by weight.

[0013] According to a further non-limiting aspect, Copper is present between 4 ‰ by weight and 41 ‰ by weight, preferably between 8 ‰ by weight and 39 ‰ by weight, more preferably between 8 ‰ by weight and 34 ‰ by weight.

[0014] According to a further non-limiting aspect, Ruthenium is present between 10 ‰ by weight and 43 ‰ by weight, preferably between 15 ‰ by weight and 38 ‰ by weight, more preferably between 15 ‰ by weight and 35 ‰ by weight.

[0015] According to a further non-limiting aspect, Platinum is present between 930 ‰ by weight and 970 ‰ by weight, preferably between 940 ‰ by weight and 960 ‰ by weight.

[0016] According to a further non-limiting aspect, the alloy comprises: – Tantalum, between 2 ‰ by weight and 30 ‰ by weight, preferably between 4 ‰ by weight and 25 ‰ by weight, more preferably between 8 ‰ by weight and 20 ‰ by weight, and/or – Niobium, between 2 ‰ by weight and 20 ‰ by weight, preferably between 4 ‰ by weight and 15 ‰ by weight, more preferably between 5 ‰ by weight and 10 ‰ by weight.

[0017] According to a further non-limiting aspect, the sum by weight of Platinum, Tin, Ruthenium, Tantalum and/or Niobium, or the sum by weight of Platinum, Tin, Copper, Tantalum and/or Niobium is such as to determine the achievement of 1000 ‰ by weight of the alloy.

[0018] According to a further non-limiting aspect, the alloy comprises: – Chromium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight; and/or – Molybdenum, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight.

[0019] According to a further non-limiting aspect, the sum by weight of Platinum, Tin, Ruthenium, Chromium and/or Molybdenum, or the sum by weight of Platinum, Tin, Copper, Chromium and/or Molybdenum is such as to determine the achievement of 1000 ‰ by weight of the alloy.

[0020] According to a further non-limiting aspect, the alloy comprises: – Gallium, between 5 ‰ by weight and 23 ‰ by weight, preferably between 8 ‰ by weight and 20 ‰ by weight, more preferably between 10 ‰ by weight and 18 ‰ by weight; or – Gold, between 2 ‰ by weight and 14 ‰ by weight, preferably between 4 ‰ by weight and 12 ‰ by weight, more preferably between 6 ‰ by weight and 8 ‰ by weight; or – Palladium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 4 ‰ by weight and 16 ‰ by weight, more preferably between 6 ‰ by weight and 14 ‰ by weight.

[0021] According to a further non-limiting aspect, the sum by weight of Platinum, Tin, Copper, Gallium or Gold or Palladium is such as to determine the achievement of 1000 ‰ by weight of the alloy.

[0022] According to a further non-limiting aspect, the sum by weight of Platinum, Tin, Ruthenium, or Platinum Tin, Copper reaches 970 ‰ by weight of the alloy, preferably 975 ‰ by weight of the alloy and more preferably 980 ‰ by weight of the alloy.

[0023] According to a further non-limiting aspect, the Platinum alloy comprises at least one of Iridium, Rhenium, Vanadium, Indium, Hafnium, in an overall amount not exceeding 30 ‰ by weight, preferably not exceeding 25 ‰ by weight and more preferably not exceeding 20 ‰ by weight.

[0024] According to a further non-limiting aspect, the alloy described here is characterised by the fact that it is ternary or quaternary.

[0025] According to a further non-limiting aspect, the alloy described here is characterised by the fact that it has a colour which in the CIELAB 1976 colour space, and in accordance with the colour measurement conditions according to CIE D65, has an L* coordinate at least equal to 85.

[0026] According to a further non-limiting aspect, the alloy described herein is characterised by having a hardness of at least 150 Vickers points, optionally wherein when comprising Copper, said Platinum alloy is characterised by having a hardness of at least 155 Vickers points or wherein when comprising Ruthenium, said Platinum alloy is characterised by having a hardness of at least 160 on the Vickers scale, preferably at least 170 Vickers scale.

[0027] According to a further non-limiting aspect, the alloy consists of Platinum between 930 ‰ by weight and 970 ‰ by weight, preferably between 940 ‰ by weight and 960 ‰ by weight, and Ruthenium, between 18 ‰ by weight and 35 ‰ by weight, preferably between 22 ‰ by weight and 34 ‰ by weight.

[0028] In accordance with the present disclosure, a Platinum alloy is also described consisting of: – Platinum, between 920 ‰ by weight and 980 ‰ by weight, preferably between 930 ‰ by weight and 970 ‰ by weight, more preferably between 940 ‰ by weight and 960 ‰ by weight; – Tin, between 5 ‰ by weight and 35 ‰ by weight, preferably between 10 ‰ by weight and 30 ‰ by weight, more preferably between 12 ‰ by weight and 28 ‰ by weight; – alternatively: – Ruthenium, between 8 ‰ by weight and 45 ‰ by weight, – Copper, between 2 ‰ by weight and 45 ‰ by weight, – at least one of: – Tantalum, between 2 ‰ by weight and 30 ‰ by weight, preferably between 4 ‰ by weight and 25 ‰ by weight, more preferably between 8 ‰ by weight and 20 ‰ by weight, and/or – Niobium, between 2 ‰ by weight and 20 ‰ by weight, preferably between 4 ‰ by weight and 15 ‰ by weight, more preferably between 5 ‰ by weight and 10 ‰ by weight, – or, alternatively to Tantalum and/or Niobium, at least one of: – Chromium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight; and/or – Molybdenum, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight, – or, alternatively to Tantalum and/or Niobium and/or Chromium and/or Molybdenum, at least one of: – Gallium, between 5 ‰ by weight and 23 ‰ by weight, preferably between 8 ‰ by weight and 20 ‰ by weight, more preferably between 10 ‰ by weight and 18 ‰ by weight; or – Gold, between 2 ‰ by weight and 14 ‰ by weight, preferably between 4 ‰ by weight and 12 ‰ by weight, more preferably between 6 ‰ by weight and 8 ‰ by weight; o – Palladium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 4 ‰ by weight and 16 ‰ by weight, more preferably between 6 ‰ by weight and 14 ‰ by weight.

[0029] In accordance with the present disclosure, there is described a jewelry article comprising a Platinum alloy according to one or more of the present aspects.

[0030] According to a further non-limiting aspect, the object of jewellery includes a jewel or a watch or a watch bracelet or a mechanical watch movement or part of a mechanical watch movement.

[0031] In a further non-limiting aspect, the watch bracelet is configured to be worn on the wrist and/or the mechanical watch movement or movement part is configured to be installed in a wristwatch.

Figure

[0032] Some embodiments of the Platinum alloy which is the subject of this disclosure will be described below with reference to the attached figure, a brief description of which is given below.

[0033] Figure 1 shows a Cartesian diagram in which the abscissa contains data relating to the grain quality of the Platinum alloy; the ordinate contains data relating to the alloy's brightness, expressed as the L* coordinate referred to CIELAB 1976.

Detailed description

[0034] This disclosure describes a Platinum alloy for jewelry applications with high machinability, in particular during chip removal and/or diamond cutting operations.

[0035] The Applicant has verified that the workability of Platinum alloys is associated with the characteristics of the microstructure, and has carried out several studies on grain refining elements which, when introduced into an alloy, have the task of improving the workability characteristics of the alloy.

[0036] The Applicant has carried out several studies of specific compositions in which, in general, Platinum is contained in amounts ranging from 920 ‰ by weight to 980 ‰ by weight. Due to the high amount of Platinum, and taking into account the considerable cost of Platinum, it appears clear that the main application of the Platinum alloy described here is that of high-end jewellery/watchmaking. This does not exclude that other applications of the Platinum alloy described here may be present. The application for jewellery/watchmaking should not, for this reason, be understood in a limiting manner.

[0037] The Platinum alloys which form the subject of this disclosure have been studied in depth by the Applicant, and in particular have been subjected to optical microscopic examination showing a microstructure characterised by a very fine grain, and have a particularly high reflectance.

[0038] The Applicant has focused in particular on the quality of the Platinum alloy, in terms of average grain size and, secondarily, in terms of grain homogeneity. The Applicant has also found that known Platinum and Ruthenium alloys have significantly high melting temperatures. The melting temperatures of Platinum and Ruthenium alloys may in fact be such that the melting crucible may partially collapse, contaminating the molten alloy with elements other than those of the desired composition.

[0039] For this reason, the Applicant has conceived a Platinum alloy that includes Tin, between 5 ‰ by weight and 35 ‰ by weight. The inclusion of Tin in the Platinum alloy has allowed to reduce the melting temperature of the alloy, with consequent reduction of the inclusion of pollutants and with the consequent greater flexibility in the selection of melting crucibles. The inclusion of Tin, the Applicant has observed, contributes to improving the workability of the alloy. The Applicant has also observed that the improvement of the workability of the alloy can also be given by the presence of Niobium in addition to the Tin, or in partial replacement of the same.

[0040] In order to ensure suitable mechanical properties for jewellery processing, the Applicant has mainly focused on two families of Platinum - Tin alloys, in which, in addition to the aforementioned Platinum and Tin, Ruthenium or Copper are also present.

[0041] The Applicant has observed that Copper, in general, contributes to lowering the melting temperature compared to Ruthenium. For this reason, the specific formulations that are characterized by the presence of Copper instead of Ruthenium, while presenting improved mechanical workability compared to known Platinum alloys, are less subject to the introduction of pollutants released from the melting crucible.

[0042] Platinum alloys according to this disclosure have also been studied in terms of performance not only with variations in their chemical composition, but also as a function of diversified production processes.

[0043] The following table illustrates some specific compositions for the Platinum alloy studied by the Applicant. 309 952 28 20 318 952 18 20 10 319 952 18 10 20 320 952 33 15 322 952 23 10 15 325 952 28 15 5 326 952 23 15 10 327 952 23 15 10 528 952 20 14 14 530 952 30 18 531 952 30 8 10 561 953 29 10 8 567 953 12 25 10 569 953 14 25

Table 1

[0044] The compositions indicated in Table 1 are specific compositions that the Applicant has obtained from research carried out on a general family of Platinum alloys for jewellery applications, comprising: – Platinum, between 920 ‰ by weight and 980 ‰ by weight; – Tin, between 5 ‰ by weight and 35 ‰ by weight; – Ruthenium, between 8 ‰ by weight and 45 ‰ by weight, or Copper, between 2 ‰ by weight and 45 ‰ by weight.

[0045] Platinum - Ruthenium alloys are traditionally used for jewelry applications, while Platinum - Copper alloys include compositions in which Copper is present as an alternative to Ruthenium, and represent more economical production solutions due to the lower cost of Copper compared to Ruthenium.

[0046] Copper and Ruthenium help provide platinum alloys with sufficient hardness and workability for jewelry applications.

[0047] From the previous general family, the Applicant has concentrated the studies on a first general subfamily in which Tin is present between 10 ‰ by weight and 30 ‰ by weight, preferably between 12 ‰ by weight and 28 ‰ by weight.

[0048] By selecting from the general family the alloys which present Copper instead of Ruthenium, the Applicant has focused in particular on a second subfamily of alloys in which Copper is present between 4 ‰ by weight and 41 ‰ by weight, preferably between 8 ‰ by weight and 39 ‰ by weight, more preferably between 8 ‰ by weight and 34 ‰ by weight.

[0049] Alternatively, by selecting from the general family the alloys which present Ruthenium in place of Copper, the Applicant has focused in particular on a third subfamily of alloys in which Ruthenium is present between 10 ‰ by weight and 43 ‰ by weight, preferably between 15 ‰ by weight and 38 ‰ by weight, more preferably between 15 ‰ by weight and 35 ‰ by weight.

[0050] Further in-depth studies have been carried out on alloys in which Platinum is present between 930 ‰ by weight and 970 ‰ by weight, preferably between 940 ‰ by weight and 960 ‰ by weight. The quantities of Platinum introduced here have in particular been studied both in relation to compositions according to the first subfamily and to compositions according to the second and third subfamily.

[0051] The Applicant has conceived some embodiments of the alloy according to the present disclosure which present a non-negligible quantity of Tantalum. From an analysis carried out by the Applicant, the presence of Tantalum, in some cases in partial substitution of Ruthenium, has determined a further reduction in the grain size of the alloy, and the alloys thus obtained are characterized by a greater brightness compared to Platinum alloy compositions in which Tantalum is absent. The Applicant has also conceived a family of Platinum alloys in which Niobium and/or Chromium are present.

[0052] In particular, the Applicant focused on Platinum alloys in which the following are present: – Tantalum, between 2 ‰ by weight and 30 ‰ by weight, preferably between 4 ‰ by weight and 25 ‰ by weight, more preferably between 8 ‰ by weight and 20 ‰ by weight, and/or – Niobium, between 2 ‰ by weight and 20 ‰ by weight, preferably between 4 ‰ by weight and 15 ‰ by weight, more preferably between 5 ‰ by weight and 10 ‰ by weight.

[0053] Some alloys of the subfamily including Tantalum and/or Niobium in the quantities indicated in the previous paragraph are quaternary alloys, in which the sum by weight of Platinum, Tin, Ruthenium, Tantalum and/or Niobium, or - for alloys containing Copper instead of Ruthenium - the sum by weight of Platinum, Tin, Copper, Tantalum and/or Niobium is such as to determine the achievement of 1000 ‰ by weight of the alloy.

[0054] These last families are those that led to the creation of the final compositions according to table 1 for example with the codes 318, 319, 322, 531, 561.

[0055] As previously mentioned, the Applicant has studied further families of Platinum alloys in which the following are present: – Chromium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight; and/or – Molybdenum, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight.

[0056] Some alloys of the subfamily including Chromium and/or Molybdenum in the quantities indicated in the previous paragraph are quaternary alloys, in which the sum by weight of Platinum, Tin, Ruthenium, Chromium and/or Molybdenum, or - for alloys containing Copper instead of Ruthenium - the sum by weight of Platinum, Tin, Copper, Chromium and/or Molybdenum is such as to determine the achievement of 1000%0 by weight of the alloy.

[0057] These last families are those that led to the creation of the final compositions according to table 1 for example with the codes 326 and 327.

[0058] Starting from the general family of compositions previously mentioned, and including the limitations of the first, second and third sub-family, and with further analyses carried out on compositions in which Platinum is present between 930 ‰ by weight and 970 ‰ by weight, preferably between 940 ‰ by weight and 960 ‰ by weight, the Applicant has conceived a plurality of families of Platinum alloys which, in addition to Platinum, Copper or Ruthenium in the quantities previously described, includes: – Gallium, between 5 ‰ by weight and 23 ‰ by weight, preferably between 8 ‰ by weight and 20 ‰ by weight, more preferably between 10 ‰ by weight and 18 ‰ by weight; o – Gold, between 2 ‰ by weight and 14 ‰ by weight, preferably between 4 ‰ by weight and 12 ‰ by weight, more preferably between 6 ‰ by weight and 8 ‰ by weight; o – Palladium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 4 ‰ by weight and 16 ‰ by weight, more preferably between 6 ‰ by weight and 14 ‰ by weight.

[0059] The Applicant has focused in particular on quaternary platinum alloys, i.e. those in which the sum by weight of platinum, tin, copper, and one of gallium or gold or palladium is such as to determine the achievement of 1000 ‰ by weight of the alloy.

[0060] Further families of Platinum alloys studied by the Applicant are those in which the sum by weight of Platinum, Tin, Ruthenium, or Platinum Tin, Copper reaches 970 ‰ by weight of the alloy, preferably 975 ‰ by weight of the alloy and more preferably 980 ‰ by weight of the alloy; this family of Platinum alloys is characterised by the presence of at least one of Iridium, Rhenium, Vanadium, Indium, Hafnium, in an overall amount not exceeding 30 ‰ by weight, preferably not exceeding 25 ‰ by weight and more preferably not exceeding 20 ‰ by weight.

[0061] A particular subfamily of Platinum alloys carefully studied by the Applicant is the family of ternary alloys which, starting from the general family, and with the limitations of at least one between the first subfamily and the third subfamily of Platinum alloys, and with particular reference to Platinum contents in an amount between 930 ‰ by weight and 970 ‰ by weight, preferably between 940 ‰ by weight and 960 ‰ by weight, contain only Ruthenium, between 18 ‰ by weight and 35 ‰ by weight, preferably between 22 ‰ by weight and 34 ‰ by weight.

[0062] In light of the above considerations, it is therefore clear that the present disclosure illustrates a Platinum alloy consisting of: – Platinum, between 920 ‰ by weight and 980 ‰ by weight, preferably between 930 ‰ by weight and 970 ‰ by weight, more preferably between 940 ‰ by weight and 960 ‰ by weight; – Tin, between 5 ‰ by weight and 35 ‰ by weight, preferably between 10 ‰ by weight and 30 ‰ by weight, more preferably between 12 ‰ by weight and 28 ‰ by weight; – alternatively: – Ruthenium, between 8 ‰ by weight and 45 ‰ by weight, – Copper, between 2 ‰ by weight and 45 ‰ by weight, – at least one of: – Tantalum, between 2 ‰ by weight and 30 ‰ by weight, preferably between 4 ‰ by weight and 25 ‰ by weight, more preferably between 8 ‰ by weight and 20 ‰ by weight, and/or – Niobium, between 2 ‰ by weight and 20 ‰ by weight, preferably between 4 ‰ by weight and 15 ‰ by weight, more preferably between 5 ‰ by weight and 10 ‰ by weight, – or, alternatively to Tantalum and/or Niobium, at least one of: – Chromium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight; and/or – Molybdenum, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight, – or, alternatively to Tantalum and/or Niobium and/or Chromium and/or Molybdenum, at least one of: – Gallium, between 5 ‰ by weight and 23 ‰ by weight, preferably between 8 ‰ by weight and 20 ‰ by weight, more preferably between 10 ‰ by weight and 18 ‰ by weight; or – Gold, between 2 ‰ by weight and 14 ‰ by weight, preferably between 4 ‰ by weight and 12 ‰ by weight, more preferably between 6 ‰ by weight and 8 ‰ by weight; o – Palladium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 4 ‰ by weight and 16 ‰ by weight, more preferably between 6 ‰ by weight and 14 ‰ by weight.

[0063] The compositions in Table 1 were obtained as specific embodiments of particular subfamilies of Platinum alloys based on the studies described above and obtained as preferred compositions for the following subfamilies.

[0064] Composition 309 is part of a subfamily of Platinum alloys consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 15 ‰ by weight and 25 ‰ by weight, Ruthenium, between 23 ‰ by weight and 33 ‰ by weight.

[0065] Composition 318 is part of a subfamily of Platinum alloys consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 15 ‰ by weight and 25 ‰ by weight, Ruthenium between 13 ‰ by weight and 23 ‰ by weight, Niobium, between 5 ‰ by weight and 15 ‰ by weight.

[0066] Composition 319 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin between 15 ‰ by weight and 25 ‰ by weight, Ruthenium between 13 ‰ by weight and 23 ‰ by weight, Tantalum, between 5 ‰ by weight and 15 ‰ by weight.

[0067] The Applicant notes in particular that compositions 309, 318 and 319 may be included in a specific subfamily of Platinum alloys consisting of: – Platinum, between 942 ‰ by weight and 963 ‰ by weight, preferably between 947 ‰ by weight and 957 ‰ by weight, – Tin, between 10 ‰ by weight and 30 ‰ by weight, preferably between 15 ‰ by weight and 25 ‰ by weight, – Ruthenium, between 21 ‰ by weight and 35 ‰ by weight, preferably between 23 ‰ by weight and 33 ‰ by weight, – optionally at least one of, preferably one of, Niobium, between 2 ‰ by weight and 17 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight, and/or Tantalum between 2 ‰ by weight and 17 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight, where, that is, the sum of Platinum, Tin and Ruthenium and, optionally, Niobium and/or Tantalum, reaches 1000 ‰ by weight. Such an alloy is therefore either a ternary or quaternary or, optionally, quinary alloy.

[0068] Composition 320 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 10 ‰ by weight and 20 ‰ by weight, Ruthenium between 26 ‰ by weight and 40 ‰ by weight.

[0069] Composition 322 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 10 ‰ by weight and 20 ‰ by weight, Ruthenium, between 18 ‰ by weight and 28 ‰ by weight, Tantalum, between 5 ‰ by weight and 15 ‰ by weight.

[0070] Composition 325 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 10 ‰ by weight and 20 ‰ by weight, Ruthenium, between 23 ‰ by weight and 33 ‰ by weight, Niobium, between 2 ‰ by weight and 10 ‰ by weight.

[0071] Composition 326 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 10 ‰ by weight and 20 ‰ by weight, Ruthenium, between 18 ‰ by weight and 28 ‰ by weight, Chromium, between 5 ‰ by weight and 15 ‰ by weight.

[0072] Composition 327 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 10 ‰ by weight and 20 ‰ by weight, Ruthenium, between 18 ‰ by weight and 28 ‰ by weight, Molybdenum, between 5 ‰ by weight and 15 ‰ by weight.

[0073] Composition 528 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 9 ‰ by weight and 19 ‰ by weight, Copper, between 15 ‰ by weight and 25 ‰ by weight, Gallium between 7 ‰ by weight and 21 ‰ by weight.

[0074] Composition 530 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 13 ‰ by weight and 23 ‰ by weight, Copper, between 25 ‰ by weight and 35 ‰ by weight.

[0075] Composition 531 is part of a subfamily of a Platinum alloy consisting of Platinum, between 947 ‰ by weight and 957 ‰ by weight, Tin, between 5 ‰ by weight and 15 ‰ by weight, Copper, between 25 ‰ by weight and 35 ‰ by weight, Tantalum, between 2 ‰ by weight and 13 ‰ by weight.

[0076] Composition 561 is part of a subfamily of a Platinum alloy consisting of Platinum, between 948 ‰ by weight and 958 ‰ by weight, Tin, between 5 ‰ by weight and 15 ‰ by weight, Copper, between 24 ‰ by weight and 34 ‰ by weight, Niobium, between 2 ‰ by weight and 13 ‰ by weight.

[0077] The Applicant notes in particular that compositions 531 and 561 may be included in a specific subfamily of Platinum alloys consisting of: – Platinum, between 942 ‰ by weight and 963 ‰ by weight, preferably between 947 ‰ by weight and 957 ‰ by weight or between 948 ‰ by weight and 958 ‰, – Tin, between 2 ‰ by weight and 17 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight, – Copper, between 21 ‰ by weight and 39 ‰ by weight, preferably between 25 ‰ by weight and 35 ‰ by weight or between 24 ‰ by weight and 34 ‰ by weight, – at least one of, preferably one of, Tantalum, 2 ‰ by weight and 13 ‰ by weight preferably between 3 ‰ by weight and 12 ‰ by weight, or Niobium, between 2 ‰ by weight and 13 ‰ by weight, preferably between 3 ‰ by weight and 12 ‰ by weight, where the sum of Platinum, Tin, Copper and, optionally, Tantalum and/or Niobium, reaches 1000 ‰ by weight.

[0078] Composition 567 is part of a subfamily of a Platinum alloy consisting of Platinum, between 948 ‰ by weight and 958 ‰ by weight, Tin, between 20 ‰ by weight and 30 ‰ by weight, Copper, between 7 ‰ by weight and 17 ‰ by weight, Palladium, between 5 ‰ by weight and 15 ‰ by weight.

[0079] Composition 569 is part of a subfamily of a Platinum alloy consisting of Platinum, between 948 ‰ by weight and 958 ‰ by weight, Tin, between 20 ‰ by weight and 30 ‰ by weight, Copper, between 9 ‰ by weight and 19 ‰ by weight.

[0080] Table 2, below, presents some physical characteristics of the specific Platinum alloy compositions described in Table 1. The two tables are divided for convenience of graphical representation.

[0081] In the table below there is a column that shows the qualitative characteristic of the grain, in particular after an annealing phase of the alloy. This qualitative characteristic is defined by an index in accordance with what is described in the UNI EN ISO 643 standard, which provides for the use of a standardized grid and the use of optical or electronic microscopy to evaluate the size and/or homogeneity of the grain.

[0082] The annealing of the Platinum alloy described here is performed at a lower temperature than the melting temperature, and is subsequently followed by a slow and/or controlled cooling phase.

[0083] The higher the value reported in the above column, the smaller the average grain size, and the higher the quality of the Platinum alloy. A further column shows the L* coordinate, which on the CIELAB color scale identifies the brightness of the alloy. A higher brightness value corresponds to a better quality of the alloy. 309 176 8/9 87.62 318 186 8/9 87.20 319 206 9/10 86.65 320 190 7/8 87.20 322 190 9 87.45 325 194 9 87.64 326 217 9 87.41 327 196 9 87.18 528 184 7 85.90 530 157 7 86.80 531 190 8 86.70 561 172 8/9 86.40 567 178 6/7 86.40 569 171 7 86.30

Table 2

[0084] In Table 2, the hardness values are presented according to the Vickers scale. All the specific compositions described in Table 2 show better workability characteristics than known alloys, both before and after remelting.

[0085] All the specific compositions described in Table 2 have homogeneous grain.

[0086] The brightness of the alloy, which is physically expressed as reflectance, is partially related to the grain size. The larger the grain size, the more non-uniform the surface of an object made with the alloy. For this reason, the reflectance decreases as the grain size increases and, conversely, increases as the grain size decreases. However, it can be stated that a higher L* coordinate does not necessarily correspond to an equivalent grain of smaller average size. In fact, the L* coordinate can be influenced by other factors.

[0087] In particular, it is observed that the Platinum alloys in which Ruthenium is present (compositions 309, 318, 319, 320, 322, 325, 326, 327) have on average a higher brightness than the Platinum alloys in which Copper is present (compositions 528, 530, 531, 561, 567, 569). However, as previously indicated, the Platinum alloys thus conceived have a higher cost than those in which Ruthenium is replaced by Copper.

[0088] The Applicant observes, for comparison, that under the same measurement conditions as the compositions in Table 2, pure Platinum has a coordinate L* = 87.5. Compositions 309, 325 therefore have a brightness even higher than that of pure Platinum.

[0089] In Table 2, from the column relating to the grain size index, it is observed that the use of Ruthenium as an alternative to Copper allows to obtain on average better and, above all, uniform grains. Consequently, the surface finish of the Platinum - Tin - Ruthenium compositions in the quantities described in this disclosure can be on average superior to the surface finish of the Platinum - Tin - Copper compositions in the quantities described in this disclosure.

[0090] It is also observed that the presence of Tantalum can determine a perceptible improvement of the grain. In fact, comparing composition 320 and composition 322, where the latter has 10‰ less Ruthenium, replaced with an equivalent quantity by weight of Tantalum, it is observed that composition 322 has a grain size index of 9 against 7/8 of composition 320.

[0091] In terms of hardness in the annealed state, Platinum-Tin alloys that include Ruthenium are on average harder than Platinum-Tin alloys that include Copper as an alternative to Ruthenium; the exception is composition 531, which - due to the presence of Tantalum - has a hardness comparable to the hardness of Platinum-Tin-Ruthenium alloys.

[0092] From table 2 the graph in figure 1 was extracted, which shows on the abscissa the grain quality (index according to UNI EN ISO 643 standard) as per the penultimate column of table 2 and on the ordinate the L* coordinate as per the last column of table 2. From the graph in figure 1 it emerges that the overall best compositions in terms of grain quality/brightness ratio can be considered initially as compositions 325, 322, 309, 318, 319 and subsequently, in a closer group, compositions 325 and 322.

[0093] The colours of platinum alloys are uniquely measured in the CIELAB 1976 colour space, which defines a colour on the basis of a first parameter L*, a second parameter a* and a third parameter b*, in which the first parameter L* identifies the brightness and assumes values between 0 (black) and 100 (white) while the second parameter a* and the third parameter b* represent chromaticity parameters. In particular, in the CIELAB 1976 colour chart, the achromatic grey scale is identified by the points where a*=b*=0; positive values for the second parameter a* indicate a colour tending more towards red the higher the value of the second parameter; negative values for the second parameter a* indicate a colour tending more towards green the higher the value of the second parameter a* is in absolute value, even if negative; positive values for the third parameter b* indicate a colour tending more towards yellow the higher the value of the third parameter; negative values for the third parameter b* indicate a color that tends more towards blue the higher the value of the third parameter b* is in absolute value, even if negative. Furthermore, it is possible to transform the second parameter a* and the third parameter b* into polar parameters defined as follows:

[0094] The Cab* parameter is defined as „chroma“; the higher the value of the Cab* parameter, the higher the color saturation; the lower the value of the Cab* parameter, the lower the color saturation, which tends to grayscale.

[0095] From Table 2, and in particular from studies carried out by the Applicant on the various families of Platinum alloys described herein, it has been observed that particular interest is given by those specific compositions which, falling within the ranges of the elements described previously, assume a colour which in the CIELAB 1976 colour space, and in accordance with the colour measurement conditions according to CIE D65, presents an L* coordinate at least equal to 85. Preferably, the alloys of particular interest present an L* coordinate at least equal to 85.5.

[0096] Furthermore, particular interest can be observed from the compositions in Table 2 for those alloys characterised by a hardness of at least 150 on the Vickers scale.

[0097] In particular when comprising Copper, the Platinum alloy which is the subject of this disclosure is characterised by having a hardness of at least 155 on the Vickers scale.

[0098] When the alloy contains Ruthenium, the said Platinum alloy is characterised by having a hardness of at least 160 on the Vickers scale, preferably at least 170 on the Vickers scale.

[0099] In one embodiment, the process for melting the Platinum alloy described herein is a batch melting process. The batch melting process is a process in which the mixture is melted and cast into a mold or ingot, made of graphite. In this case the above-mentioned elements are melted and cast in a controlled atmosphere.

[0100] More specifically, the melting operations are carried out only after preferably having carried out at least 3 conditioning cycles of the atmosphere of the melting chamber. This conditioning first involves reaching a vacuum level down to pressures lower than 1×10<-2>mbar and a subsequent partial saturation with Argon at 500mbar. During melting, the Argon pressure is maintained at pressure levels between 500mbar and 800mbar. When complete melting of the pure elements has been achieved, a mixture overheating phase occurs, in which the mixture is heated up to a temperature between 1600 °C and 1850 °C in order to homogenize the chemical composition of the metal bath. During the overheating phase, the pressure value in the melting chamber again reaches a vacuum level lower than 1×10<-2>mbar, useful for eliminating part of the slag produced by the melting of the pure elements.

[0101] At this point, in a casting stage, the molten material is poured into a mold or ingot mold.

[0102] Once solidified, the bars or spindles are extracted from the flask. When the alloy has solidified, Platinum alloy bars or spindles are obtained from the graphite duct and are subjected to rapid cooling by means of an immersion phase in water, in order to reduce and possibly avoid phase variations. In other words, the bars or spindles are subjected to a rapid cooling phase, preferably but not limited to in water, in order to avoid phase variations in the solid state.

[0103] Platinum alloys according to the present disclosure can also be machined particularly effectively to result in uniform surfaces, free from visible second phases or carbides. Therefore, Platinum alloys according to the present disclosure may be favorably employed for fine jewelry applications, and in particular for making fine jewelry objects.

[0104] Non-limiting examples of jewellery items made at least partially from the platinum alloy described herein are: bracelets, watch bracelets, buckles, watch cases, hands, internal mechanisms of watches, bezels for bracelets, earrings, ornaments, rings, supports for precious stones, ingots, in particular collector's ingots, collector's coins, necklaces, closure elements for necklaces, for earrings or for bracelets.

[0105] Platinum alloys according to the present disclosure may be applicable for objects that come into direct contact with human skin, and are substantially free of allergic risk.

[0106] The platinum alloys which are the subject of this disclosure have particular brightness and excellent mechanical workability, making them particularly useful for use in jewellery applications.

[0107] Finally, it is clear that additions, modifications or variations, obvious to a technician in the field, may be applied to the object of this disclosure without thereby departing from the scope of protection provided by the attached claims.

Claims (12)

1. Platinum alloy for jewellery applications, comprising: – Platinum, between 920 ‰ by weight and 980 ‰ by weight; – Tin, between 5 ‰ by weight and 35 ‰ by weight; – Ruthenium, between 8 ‰ by weight and 45 ‰ by weight or Copper, between 2 ‰ by weight and 45 ‰ by weight. 2. Platinum alloy according to claim 1, wherein the Tin is present between 10 ‰ by weight and 30 ‰ by weight, preferably between 12 ‰ by weight and 28 ‰ by weight. 3. Platinum alloy according to claim 1 or 2, wherein the Copper is present between 4 ‰ by weight and 41 ‰ by weight, preferably between 8 ‰ by weight and 39 ‰ by weight, more preferably between 8 ‰ by weight and 34 ‰ by weight. 4. Platinum alloy according to claim 1 or 2, wherein the Ruthenium is present between 10 ‰ by weight and 43 ‰ by weight, preferably between 15 ‰ by weight and 38 ‰ by weight, more preferably between 15 ‰ by weight and 35 ‰ by weight. 5. Platinum alloy according to one or more of the preceding claims, wherein the Platinum is present between 930 ‰ by weight and 970 ‰ by weight, preferably between 940 ‰ by weight and 960 ‰ by weight. 6. Platinum alloy according to one or more of the preceding claims, comprising: – Tantalum, between 2 ‰ by weight and 30 ‰ by weight, preferably between 4 ‰ by weight and 25 ‰ by weight, more preferably between 8 ‰ by weight and 20 ‰ by weight, and/or – Niobium, between 2 ‰ by weight and 20 ‰ by weight, preferably between 4 ‰ by weight and 15 ‰ by weight, more preferably between 5 ‰ by weight and 10 ‰ by weight; wherein the sum by weight of Platinum, Tin, Ruthenium, Tantalum and/or Niobium, or the sum by weight of Platinum, Tin, Copper, Tantalum and/or Niobium is such as to determine the achievement of 1000 ‰ by weight of the alloy. 7. Platinum alloy according to one or more of the preceding claims, comprising: – Chromium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight; and/or – Molybdenum, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight; wherein the sum by weight of Platinum, Tin, Ruthenium, Chromium and/or Molybdenum, or the sum by weight of Platinum, Tin, Copper, Chromium and/or Molybdenum is such as to determine the achievement of 1000‰ by weight of the alloy. 8. Platinum alloy according to one or more of the preceding claims, comprising: – Gallium, between 5 ‰ by weight and 23 ‰ by weight, preferably between 8 ‰ by weight and 20 ‰ by weight, more preferably between 10 ‰ by weight and 18 ‰ by weight; or – Gold, between 2 ‰ by weight and 14 ‰ by weight, preferably between 4 ‰ by weight and 12 ‰ by weight, more preferably between 6 ‰ by weight and 8 ‰ by weight; or – Palladium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 4 ‰ by weight and 16 ‰ by weight, more preferably between 6 ‰ by weight and 14 ‰ by weight; where the sum by weight of Platinum, Tin, Copper, Gallium or Gold or Palladium is such as to determine the achievement of 1000 ‰ by weight of the alloy. 9. Platinum alloy according to one or more of claims 1 to 5, wherein the sum by weight of Platinum, Tin, Ruthenium, or Platinum Tin, Copper reaches 970 ‰ by weight of the alloy, preferably 975 ‰ by weight of the alloy and more preferably 980 ‰ by weight of the alloy, the Platinum alloy comprising at least one of Iridium, Rhenium, Vanadium, Indium, Hafnium, in an overall amount not exceeding 30 ‰ by weight, preferably not exceeding 25 ‰ by weight and more preferably not exceeding 20 ‰ by weight. 10. Platinum alloy according to one or more of the preceding claims, characterized by being ternary or quaternary and/or by having a color that in the CIELAB 1976 color space, and in accordance with the color measurement conditions according to CIE D65, has a coordinate L* at least equal to 85, and/or characterized by having a hardness at least equal to 150 Vickers points, optionally wherein when comprising Copper, said Platinum alloy is characterized by having a hardness at least equal to 155 Vickers points or wherein when comprising Ruthenium, said Platinum alloy is characterized by having a hardness at least equal to 160 Vickers points, preferably at least equal to 170 Vickers points. 11. Platinum alloy according to one or more of the preceding claims, consisting of: – Platinum, between 920 ‰ by weight and 980 ‰ by weight, preferably between 930 ‰ by weight and 970 ‰ by weight, more preferably between 940 ‰ by weight and 960 ‰ by weight; – Tin, between 5 ‰ by weight and 35 ‰ by weight, preferably between 10 ‰ by weight and 30 ‰ by weight, more preferably between 12 ‰ by weight and 28 ‰ by weight; – alternatively: – Ruthenium, between 8 ‰ by weight and 45 ‰ by weight, – Copper, between 2 ‰ by weight and 45 ‰ by weight, – at least one of: – Tantalum, between 2 ‰ by weight and 30 ‰ by weight, preferably between 4 ‰ by weight and 25 ‰ by weight, more preferably between 8 ‰ by weight and 20 ‰ by weight, and/or – Niobium, between 2 ‰ by weight and 20 ‰ by weight, preferably between 4 ‰ by weight and 15 ‰ by weight, more preferably between 5 ‰ by weight and 10 ‰ by weight, – or, alternatively to Tantalum and/or Niobium, at least one of: – Chromium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight; and/or – Molybdenum, between 2 ‰ by weight and 18 ‰ by weight, preferably between 5 ‰ by weight and 15 ‰ by weight, – or, alternatively to Tantalum and/or Niobium and/or Chromium and/or Molybdenum, at least one of: – Gallium, between 5 ‰ by weight and 23 ‰ by weight, preferably between 8 ‰ by weight and 20 ‰ by weight, more preferably between 10 ‰ by weight and 18 ‰ by weight; o – Gold, between 2 ‰ by weight and 14 ‰ by weight, preferably between 4 ‰ by weight and 12 ‰ by weight, more preferably between 6 ‰ by weight and 8 ‰ by weight; o – Palladium, between 2 ‰ by weight and 18 ‰ by weight, preferably between 4 ‰ by weight and 16 ‰ by weight, more preferably between 6 ‰ by weight and 14 ‰ by weight. 12. An article of jewellery comprising a Platinum alloy according to one or more of the preceding claims.