CH720418A2 - Gold alloy with deformation recovery properties - Google Patents

Abstract

Gold alloy for jewelery or watchmaking applications, specifically intended for making jewelery objects having properties of at least partial recovery of shape and/or size following the application of a deformation force, comprising: – Gold, between 700 ‰ in weight and 800 ‰ by weight, – Copper, between 25 ‰ by weight and 170 ‰ by weight, – Palladium, between 50 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight. The Gold alloy is a gray colored alloy.

Description

Field of technology

[0001] The present disclosure pertains to the metallurgy sector, in particular to the gold alloys sector. In particular, the present disclosure concerns a gold alloy for jewelery and watchmaking applications.

[0002] The present disclosure also concerns a jewelery and watchmaking object made at least partially using the gold alloy described here.

Field of technology

[0003] Objects made of metallic material have deformability characteristics. The deformation of a body can be elastic or plastic. The deformation occurs following the application of a tensile, compressive or bending force on the material.

[0004] An elastic deformation is characterized by the fact that the body, when a deformation force ceases, is able to return to an original size and/or shape.

[0005] A plastic deformation is characterized by the fact that the body, when a deformation force ceases, is no longer able to return to an original size and/or shape; in other words, its size and/or shape is irreversibly modified compared to the original one.

[0006] Plastic deformation typically takes place with the application of forces greater than the forces necessary to deform a body elastically. The yield load is that force which, when applied to the aforementioned body, determines the transition from elastic behavior to plastic behavior.

[0007] The maximum limit of deformation force that a body can withstand is called breaking load.

[0008] In particular, objects made of gold alloy can also be subject to elastic or plastic deformations.

[0009] Certain objects made of Gold alloy are subjected, during their operational life, to various applications of static or cyclic deformation forces: where the object made of Gold alloy is connected to other similar or different objects, or is integrated into a more complex object, any plastic deformations can form plays, friction, misalignments.

[0010] Consequently, objects made of gold alloy may, over time, have a modified size and/or shape compared to the original one.

[0011] Altering the shape of the object made of Gold alloy is inconvenient, because the functionality of the object can be compromised by the difference in size or shape due to the application of a force greater than the yield strength.

[0012] Normally, it is observed that yellow (according to 3N ISO 8654) and red (according to 5N ISO 8654) Gold alloys are typically known to exhibit good mechanical properties, including high yield strength, hardness and resilience, and are therefore commonly used successfully where the use is aimed at jewelery or watchmaking objects which, during their operational life, are subject to particularly significant stress.

[0013] Gray gold alloys with properties of recovery of the deformation undergone are also known, capable of showing significant mechanical properties including high yield strength, hardness and resilience. Normally, these alloys exploit the properties of nickel to obtain higher mechanical performance in return to deformation compared to nickel-free gold alloys.

[0014] Document US 5,173,132 illustrates a 14k Gold alloy in which Cobalt is present in the range 1 ‰ and 7 ‰ and Nickel between 10 ‰ and 50 ‰; Cobalt and Nickel are used for grain refining to further improve the workability of the alloy.

[0015] However, the use of Nickel is strongly discouraged where the alloys must be used for objects intended to come into direct contact with human skin, and in particular for Gold alloys intended for jewelery applications intended for the creation of objects that come into direct contact with human skin. In fact, Nickel is known to cause allergic reactions.

[0016] The aim of the present disclosure is to describe a gold alloy which allows the drawbacks described above to be resolved. The purpose of the present disclosure is also to describe a jewelery or watchmaking object comprising the gold alloy which allows the drawbacks described above to be resolved.

[0017] The aim of the present disclosure is finally to describe a production method for a gold alloy which allows the drawbacks described above to be resolved.

Summary

[0018] The Applicant has conceived a plurality of Gold alloys with improved mechanical characteristics, which is described here in some of its main aspects. Such aspects may be combined with each other or with portions of the detailed description or claims.

[0019] In accordance with an aspect of the disclosure, described herein is a Gold alloy for jewelry applications, comprising: – Gold, between 700 ‰ by weight and 800 ‰ by weight, – Copper, between 25 ‰ by weight and 170 ‰ by weight, – Palladium, between 50 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight,

[0020] The Applicant observes that the Gold alloy is specifically intended for making jewelery objects having improved mechanical properties, in particular characterized by an increase in yield stress in order to make it comparable to that of 3N and 5N alloys.

[0021] The Applicant observes that the yield stress is considerably greater than that of commercial nickel-free gray gold alloys.

[0022] According to a further non-limiting aspect, the alloy includes: – Gold, between 700 ‰ by weight and 800 ‰ by weight, – Copper, between 25 ‰ by weight and 95 ‰ by weight, – Palladium, between 85 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight, – Silver, between 7 ‰ by weight and 60 ‰ by weight.

[0023] According to a further non-limiting aspect, the alloy comprises: Gallium and/or at least one grain refiner element, preferably at least one of Iridium, Rhenium and Ruthenium.

[0024] According to a further non-limiting aspect, said at least one grain refiner element is present in pre-alloy, said pre-alloy having the following base: – Copper, where the grain refiner element is Iridium, or – Palladium, where the grain refining element is Rhenium or Ruthenium.

[0025] According to a further non-limiting aspect, the amount by weight of Gallium and/or of said at least one grain refining element, preferably at least one of Iridium, Rhenium and Ruthenium, determines the achievement of 1000 ‰ in weight.

[0026] According to a further non-limiting aspect, said gold alloy is characterized by the fact that it is free of nickel.

[0027] According to a further non-limiting aspect, said gold alloy is characterized by the fact that it is free of arsenic.

[0028] According to a further non-limiting aspect, said Gold alloy is characterized by the fact that it is free of Platinum.

[0029] According to a further non-limiting aspect, said Gold alloy includes Gallium between 1 ‰ by weight and 10 ‰ by weight, preferably between 2 ‰ by weight and 9 ‰ by weight, more preferably between 3 ‰ by weight and 8 ‰ by weight.

[0030] According to a further non-limiting aspect, Gallium is present in an amount substantially between 4 ‰ by weight and 7 ‰ by weight.

[0031] According to a further non-limiting aspect, Gallium is present in amounts between 3.5 ‰ by weight and 4.5 ‰ by weight.

[0032] According to a further non-limiting aspect, said alloy comprises at least one grain refiner element, preferably at least one of Iridium, Rhenium or Ruthenium.

[0033] According to a further non-limiting aspect, said Iridium is pre-alloyed with Copper.

[0034] According to a further non-limiting aspect, said Rhenium and/or Ruthenium is pre-alloyed with Palladium.

[0035] According to a further non-limiting aspect, the at least one grain refiner element, in particular the at least one of Iridium, Rhenium or Ruthenium, is present in amounts of up to 1 ‰ by weight.

[0036] According to a further non-limiting aspect, the Gold alloy includes: – Gold, between 730 ‰ in weight and 770 ‰ in weight, – Copper, between 40 ‰ in weight and 90 ‰ in weight, – Palladium, between 100 ‰ by weight and 150 ‰ by weight, – Cobalt, between 8 ‰ by weight and 30 ‰ by weight, – Silver, between 8 ‰ by weight and 55 ‰ by weight.

[0037] According to a further non-limiting aspect, the Gold alloy includes: – Gold, between 740 ‰ in weight and 760 ‰ in weight, – Copper, between 50 ‰ in weight and 90 ‰ in weight, – Palladium, between 100 ‰ by weight and 150 ‰ by weight, – Cobalt, between 8 ‰ by weight and 30 ‰ by weight, – Silver, between 8 ‰ by weight and 55 ‰ by weight.

[0038] According to a further non-limiting aspect, the Gold alloy includes: – Gold, between 740 ‰ in weight and 760 ‰ in weight, – Copper, between 50 ‰ in weight and 90 ‰ in weight, – Palladium, between 110 ‰ by weight and 140 ‰ by weight, preferably between 115 ‰ by weight and 135 ‰ by weight, – Cobalt, between 10 ‰ by weight and 25 ‰ by weight, – Silver, between 8 ‰ by weight and 50 ‰ by weight.

[0039] According to a further non-limiting aspect, the Gold alloy includes: – Palladium, between 120 ‰ in weight and 130 ‰ in weight.

[0040] According to a further non-limiting aspect, the Gold alloy according to one or more of the previous aspects includes: – Copper, between 45 ‰ by weight and 65 ‰ by weight, preferably between 50 ‰ by weight and 60 ‰ by weight weight, and Silver, between 35 ‰ by weight and 52 ‰ by weight; or – Copper, between 75 ‰ by weight and 95 ‰ by weight, preferably between 80 ‰ by weight and 90 ‰ by weight, and Silver, between 7 ‰ by weight and 13 ‰ by weight, preferably between 8 ‰ by weight and 12 ‰ by weight.

[0041] According to a further non-limiting aspect, the Gold alloy has a color defined, on the CIELAB 1976 color scale, and in accordance with the color measurement conditions according to CIE D65, by the following color coordinates: L*, inclusive between 80 and 84.5, preferably between 81 and 84; a*, between 1.2 and 3.7, preferably between 1.5 and 3.5; b*, between 6.2 and 10.5, preferably between 6.6 and 10.

[0042] According to a further non-limiting aspect, said color is gray and/or said Gold alloy is a gray Gold alloy.

[0043] According to a further non-limiting aspect, the Gold alloy has a color defined, on the CIELAB 1976 color scale, and in accordance with the color measurement conditions according to CIE D65, by the following color coordinates: L*, inclusive between 80 and 84.5, preferably between 81 and 84; a*, between 1.2 and 2.4, preferably between 1.5 and 2.1; b*, between 6.7 and 8.5, preferably between 7 and 8.3.

[0044] For the purposes of this disclosure, Gold alloys whose color falls within the coordinates reported above, and in particular within a square defined on the a* and b* coordinates when positioned on orthogonal axes in a map in color, it is considered gray.

[0045] According to a further non-limiting aspect, said gold alloy is a gray gold alloy.

[0046] According to a further non-limiting aspect, the Gold alloy has a color defined, on the CIELAB 1976 color scale, and in accordance with the color measurement conditions according to CIE D65, by the following color coordinates: L*, inclusive between 83 and 84.5, preferably between 83.2 and 84.3; a*, between 2.7 and 3.7, preferably between 2.9 and 3.5; b*, between 8.9 and 9.9, preferably between 8.7 and 9.7.

[0047] According to a further non-limiting aspect, the Gold alloy includes: – Gold, between 730 ‰ by weight and 770 ‰ by weight, preferably between 740 ‰ by weight and 760 ‰ by weight, – Copper, between 150 ‰ by weight weight and 170‰ by weight, preferably between 155‰ by weight and 165‰ by weight, – Palladium, between 50‰ by weight and 70‰ by weight, preferably between 55‰ by weight and 65‰ by weight, – Cobalt, between 7 ‰ by weight and 13 ‰ by weight, – Iron, between 10 ‰ by weight and 30 ‰ by weight, optionally at least one grain refiner element, preferably at least one of Iridium, Rhenium or Ruthenium, in amounts up to 1 ‰ by weight .

[0048] According to a further non-limiting aspect, the sum of Gold, Copper, Palladium, Cobalt, Iron, and optionally the at least one grain refiner element, reaches 1000 ‰ by weight.

[0049] According to a further non-limiting aspect, the gold alloy consists of: – Gold, between 700 ‰ in weight and 800 ‰ in weight, – Copper, between 25 ‰ in weight and 75 ‰ in weight, – Palladium, between 85 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight, – Silver, between 7 ‰ by weight and 60 ‰ by weight, – Gallium, between 1 ‰ by weight and 10 ‰ by weight weight, preferably between 2 ‰ by weight and 9 ‰ by weight, more preferably between 3 ‰ by weight and 8 ‰ by weight, – at least one grain refiner element, preferably at least one of Iridium, Rhenium or Ruthenium, in an amount up to 1 ‰ by weight.

[0050] According to a further aspect, a jewelery item comprising a Gold alloy is also described in accordance with one or more of the aspects described herein.

[0051] According to a further non-limiting aspect, a jewelery object has a yield stress comparable to that of a corresponding jewelery object made of 3N or 5N alloy.

[0052] In particular, said yield stress is higher than that of the yield stress of a corresponding jewelery object made of gray gold alloy not containing nickel and commercially known.

[0053] According to a further non-limiting aspect, said gold alloy is a gray gold alloy.

[0054] According to a further non-limiting aspect, the jewelery item includes a jewel or a watch or a watch bracelet or a movement or part of a mechanical movement for a watch.

[0055] According to a further non-limiting aspect, the watch or mechanical watch movement are configured to be respectively worn or installed in wristwatches.

[0056] In accordance with the present disclosure, a method of producing a Gold alloy is also described, comprising a mixing step of at least Gold, Copper, Palladium and Cobalt in the amounts described in one or more of the above-mentioned aspects.

[0057] According to a further non-limiting aspect, the method includes a mixing phase of: – Gold, between 700 ‰ by weight and 800 ‰ by weight, – Copper, between 9 ‰ by weight and 79 ‰ by weight, – Palladium, between 85 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight, – Silver, between 7 ‰ by weight and 60 ‰ by weight, with a Culr pre-alloy at 16 ‰ by weight weight.

Figures

[0058] The alloy which is the subject of the present disclosure will now be described with reference to some preferred embodiments, and with reference to the attached figures. A brief description of the figures is given below. Figure 1 illustrates a Cartesian diagram showing a monotonic tensile test in which the relative deformation (percentage) suffered by the specimen is shown on the abscissa and the stress to which it is subjected is shown on the ordinate. Figure 2 illustrates a Cartesian diagram in which on the abscissa there is a distance corresponding to a displacement at a midpoint of a test sample of a Gold alloy when subjected to bending force in three points and in which in a bending force is present. Figure 3 illustrates a Cartesian diagram representing a color card according to the a* and b* coordinates of the CIELAB 1976 card, in which there are some compositions specifically studied by the Applicant. The colors detected on the graph in figure 2 are obtained according to measurements in accordance with CIE D65.

Detailed description

[0059] The present disclosure illustrates a Gold alloy with improved strain recovery properties. The gold alloy described here is advantageously preferably applicable to objects which during their operational life are subjected to various applications of deformation force, which must remain below the yield strength. Such objects may be fine jewelery or watchmaking objects, and be connected to other same or similar objects or be integrated into a more complex object. In one non-limiting embodiment, such objects may be parts of bracelets, bracelets, or parts of a watch movement.

[0060] As will be better clarified from the following description, the Applicant has concentrated on embodiments of the Gold alloy which present an observably different color compared to that codified by the 0N-6N standards in accordance with the ISO 8654 standard. In particular, the family of alloys conceived by the Applicant is a family of gray gold alloys.

[0061] The Applicant has conceived a family of gray gold alloys with an amount of gold substantially equal to 18k, with the following characteristics: – Gold, between 700 ‰ in weight and 800 ‰ in weight, – Copper, between 25 ‰ in weight and 170‰ by weight, – Palladium, between 50 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight.

[0062] This family of alloys, optionally, includes Silver, between 7 ‰ by weight and 60 ‰ by weight.

[0063] Depending on whether Silver is present or not, in a non-limiting embodiment, the sum of the amount by weight of Gold, Copper, Palladium, Cobalt, or of Gold, Copper, Palladium, Cobalt and Silver, is equal to 1000 ‰ by weight. For this reason, it is clear that the present disclosure illustrates a specific family of gold alloys consisting of Gold, between 700 ‰ by weight and 800 ‰ by weight, Copper, between 25 ‰ by weight and 170 ‰ by weight, Palladium, between 50 ‰ by weight and 165 ‰ by weight, Cobalt, between 7 ‰ by weight and 40 ‰ by weight or consisting of Gold, between 700 ‰ by weight and 800 ‰ by weight, Copper, between 25 ‰ by weight and 170 ‰ by weight , Palladium, between 50 ‰ by weight and 165 ‰ by weight, Cobalt, between 7 ‰ by weight and 40 ‰ by weight and Silver, between 7 ‰ by weight and 60 ‰ by weight.

[0064] The Applicant has highlighted, starting from this general family of Gold alloys, a more restricted family including the following elements in the following compositions: – Gold, between 700 ‰ in weight and 800 ‰ in weight, – Copper, between 25 ‰ by weight and 95 ‰ by weight, – Palladium, between 85 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight, – Silver, between 7 ‰ by weight and 60 ‰ by weight weight.

[0065] Preferably, but not limitedly, the Gold alloys according to the composition described above can be made exclusively with the materials mentioned above, i.e. the amount of Gold, Copper, Palladium, Cobalt, Silver reaches 1000 ‰ in weight.

[0066] The alloys of the family described here are Nickel-free, so as to guarantee compatibility with all those applications in which the object made with the Gold alloy must come into direct contact with human skin.

[0067] The gold alloys of the family described here are also free of arsenic.

[0068] Some embodiments of the alloys of the present disclosure exhibit improved performance in terms of mechanical performance, further include Gallium, between 1 ‰ and 10 ‰ by weight, preferably between 2 ‰ by weight and 9 ‰ by weight, more preferably between 3 ‰ by weight and 8 ‰ by weight.

[0069] Some embodiments, in particular, have Gallium in an amount substantially between 4 ‰ by weight and 7 ‰ by weight. In particular, the Applicant has studied two main families of Gold alloys, which present Gallium in an amount equal to 4 ‰ by weight, or which present Gallium in an amount equal to 7 ‰ by weight.

[0070] Cobalt, in particular, and Gallium, perform their function as thermosets through a process of solubilization and precipitation.

[0071] Among the alloys studied by the Applicant, some preferred embodiments include Iridium as a grain refiner. Other Gold alloy embodiments disclosed herein include grain refiners selected from Rhenium and/or Ruthenium. Multiple grain refiners can be present at the same time.

[0072] In one embodiment, the amount by weight of Gallium and/or at least one grain refiner, preferably at least one of Iridium, Rhenium or Ruthenium, results in reaching 1000 ‰ by weight. Grain refiner may be present in amounts up to 1‰ by weight

[0073] In fact, the Applicant has conceived particular embodiments of Gold alloy in which the amount of Gold, Copper, Silver, Cobalt, Palladium and Gallium reaches 1000 ‰ in weight. These alloys are alloys exclusively composed of six elements.

[0074] Furthermore, the Applicant has conceived particular embodiments of Gold alloy in which the amount of Gold, Copper, Silver, Cobalt, Palladium, Gallium and at least one grain refining element (Iridium and/or Rhenium and/ or Ruthenium) reaches 1000 ‰ in weight.

[0075] However, it is noted that the use of the at least one grain refiner element, in particular the at least one of Iridium, Rhenium or Ruthenium, may be subject to inclusion in the pre-alloy.

[0076] In particular, the alloys which form the subject of the present disclosure are platinum-free alloys.

[0077] From the previous general family, the Applicant has studied the behavior of a family of Gold alloys including: – Gold, between 730 ‰ by weight and 770 ‰ by weight, – Copper, between 40 ‰ by weight and 90 ‰ by weight weight, – Palladium, between 100 ‰ in weight and 150 ‰ in weight, – Cobalt, between 8 ‰ in weight and 30 ‰ in weight, – Silver, between 8 ‰ in weight and 55 ‰ in weight, subsequently narrowing the interest towards a family of Gold alloys including Gold, between 740 ‰ by weight and 760 ‰ by weight, Copper, between 50 ‰ by weight and 90 ‰ by weight, and Palladium, Cobalt and Silver in the ranges described above, optionally with the presence of Gallium is a grain refiner element as described above.

[0078] Further studies were carried out on a family of gold alloys including: – Gold, between 730 ‰ by weight and 770 ‰ by weight, – Copper, between 40 ‰ by weight and 90 ‰ by weight, – Palladium, between 110 ‰ by weight and 140 ‰ by weight, preferably between 115 ‰ by weight and 135 ‰ by weight, – Cobalt, between 10 ‰ by weight and 25 ‰ by weight, – Silver, between 8 ‰ by weight and 50 ‰ by weight.

[0079] The Applicant has carried out studies on two subfamilies of Gold alloys which are centered on a Copper content equal to 55 ‰ by weight and a Silver content between 40 ‰ and 50 ‰ by weight, or on a Copper content higher, substantially equal to 85 ‰ in weight and having a smaller silver content, around 10 ‰ in weight.

[0080] In particular, two subfamilies of alloys have been identified, which present: Copper, between 45 ‰ in weight and 65 ‰ in weight, preferably between 50 ‰ in weight and 60 ‰ in weight, and Silver, between 35 ‰ in weight and 52 ‰ by weight; or Copper, between 75 ‰ by weight and 95 ‰ by weight, preferably between 80 ‰ by weight and 90 ‰ by weight, and Silver, between 7 ‰ by weight and 13 ‰ by weight, preferably between 8 ‰ by weight and 12 ‰ by weight weight. These subfamilies have been studied with combinations of Gold, between 700 ‰ in weight and 800 ‰ in weight, Palladium, between 85 ‰ in weight and 165 ‰ in weight, Cobalt, between 7 ‰ in weight and 40 ‰ in weight, and with further combinations of Gallium and/or Iridium as described above. From these two subfamilies some specific forms of gold alloy have been obtained, which have been codified with the references 848, 849, 850.

[0081] The following table illustrates some specific compositions studied in detail by the Applicant. The amount of gold alloy elements is shown in the table in ‰ by weight. 848 751 54 40 125 25 4 849 751 84 10 125 25 4 850 751 54 47 125 15 7

Table 1

[0082] In the compositions according to table 1, the addition of 1‰ of a grain refiner element comprising at least one of Iridium, Rhenium or Ruthenium, preferably in pre-alloy with Copper or Palladium, and/or of at least one of Copper, Silver, Palladium, Cobalt or Gallium, determines the achievement of 1000‰ in weight of the alloy.

[0083] Further variants of the Gold alloys according to compositions 848, 849 and 850 are for example those according to the following subfamily: Gold, between 740 ‰ by weight and 760 ‰ by weight, Copper, between 50 ‰ by weight and 60 ‰ by weight, Palladium, between 100 ‰ by weight and 150 ‰ by weight and preferably between 115 ‰ by weight and 135 ‰ by weight, Cobalt, between 20 ‰ and 30 ‰ by weight, Silver, between 35 ‰ and 55 ‰ by weight weight, Gallium between 3 ‰ by weight and 8 ‰ by weight and preferably between 3 ‰ by weight and 5 ‰ by weight or between 6 ‰ by weight and 8 ‰ by weight, and optionally at least one grain refiner element comprising at least one of Iridium , Rhenium or Ruthenium, preferably in pre-alloy with Copper or Palladium, and/or at least one of Copper, Silver, Palladium, Cobalt or Gallium in an amount up to 1‰ in weight is such as to determine the achievement of 1000 ‰ in weight for the Golden League.

[0084] Furthermore, further variants of the Gold alloys according to compositions 848, 849 and 850 are for example those according to the following subfamily: Gold, between 740 ‰ by weight and 760 ‰ by weight, Copper, between 50 ‰ by weight weight and 60 ‰ by weight, Palladium, between 100 ‰ by weight and 150 ‰ by weight and preferably between 115 ‰ by weight and 135 ‰ by weight, Cobalt, between 20 ‰ and 30 ‰ by weight, Silver, between 35 ‰ and 55 ‰ by weight, Gallium between 3 ‰ by weight and 8 ‰ by weight and preferably between 3 ‰ by weight and 5 ‰ by weight or between 6 ‰ by weight and 8 ‰ by weight, and optionally at least one grain refiner element comprising at least one between Iridium, Rhenium or Ruthenium, preferably in pre-alloy with Copper or Palladium, in which the amount of Gold, Copper, Silver, Palladium, Cobalt, Gallium and optionally the at least one grain refiner element, is such as to determine the reaching 1000 ‰ in weight.

[0085] Furthermore, further variants of the Gold alloys according to compositions 848, 849 and 850 are for example those according to the following subfamily: Gold, between 740 ‰ by weight and 760 ‰ by weight, Copper, between 70 ‰ by weight weight and 95 ‰ by weight, Palladium, between 100 ‰ by weight and 150 ‰ by weight and preferably between 115 ‰ by weight and 135 ‰ by weight, Cobalt, between 20 ‰ and 30 ‰ by weight, Silver, between 7 ‰ and 13 ‰ by weight, Gallium between 3 ‰ by weight and 8 ‰ by weight, and optionally at least one grain refiner element comprising at least one of Iridium, Rhenium or Ruthenium, preferably pre-alloyed with Copper or Palladium, and/or at least one of Copper, Silver, Palladium, Cobalt or Gallium in amounts up to 1‰ in weight is such as to determine the achievement of 1000 ‰ in weight for the Gold alloy.

[0086] Furthermore, further variants of the Gold alloys according to compositions 848, 849 and 850 are for example those according to the following subfamily: Gold, between 740 ‰ by weight and 760 ‰ by weight, Copper, between 70 ‰ by weight weight and 95 ‰ by weight, Palladium, between 100 ‰ by weight and 150 ‰ by weight and preferably between 115 ‰ by weight and 135 ‰ by weight, Cobalt, between 20 ‰ and 30 ‰ by weight, Silver, between 7 ‰ and 13 ‰ by weight, Gallium between 3 ‰ by weight and 8 ‰ by weight, and optionally at least one grain refiner element comprising Iridium, Rhenium or Ruthenium, in which the amount of Gold, Copper, Silver, Palladium, Cobalt, Gallium and optionally the at least one grain refiner element is such as to determine the achievement of 1000 ‰ in weight.

[0087] A further family of gold alloys studied by the Applicant is that comprising: – Gold, between 730 ‰ in weight and 770 ‰ in weight, preferably between 740 ‰ in weight and 760 ‰ in weight, – Copper, between 150 ‰ in weight by weight and 170‰ by weight, preferably between 155‰ by weight and 165‰ by weight, – Palladium, between 50‰ by weight and 70‰ by weight, preferably between 55‰ by weight and 65‰ by weight, – Cobalt, between 7 ‰ by weight and 13 ‰ by weight.

[0088] In particular, a Gold alloy has been studied which includes, in addition to the amounts of the elements described in the previous paragraph, Iron, between 10 ‰ by weight and 30 ‰ by weight.

[0089] The applicant's studies have focused in particular on a family of alloys in which, in addition to iron, iridium can also be present as a grain refiner. Composition 844 was extracted from this particular family and is shown in the following table. 844 751 159 60 10 20

Table 2

[0090] In composition 844, the missing 1‰ by weight to complete the 1000 ‰ by weight may be at least one grain refiner, preferably at least one of Iridium, Rhenium or Ruthenium, and/or may be one of Copper, Silver , Palladium, Cobalt, Gallium or Iron.

[0091] Further variants of Gold alloys according to composition 844 are for example the following: – Gold, between 740 ‰ by weight and 760 ‰ by weight, Copper, between 150 ‰ by weight and 170 ‰ by weight, Palladium, between 40 ‰ by weight and 80 ‰ by weight and preferably between 50 ‰ by weight and 70 ‰ by weight, Cobalt, between 5 ‰ by weight and 15 ‰ by weight, Iron, between 10 ‰ by weight and 30 ‰ by weight, and optionally at least one grain refiner element, preferably comprising at least one of Iridium, Rhenium or Ruthenium; the amount of Gold, Copper, Palladium, Cobalt, Iron, and optionally the at least one grain refining element, preferably including at least one of Iridium, Rhenium or Ruthenium, is such as to determine the achievement of 1000 ‰ in weight.

[0092] The performances of the gold alloys described above were compared with those of two reference gold alloys, which are reported below: Pd125 751 110 125 10 4 Pd60 751 169 60 20 5N 750 205 45 3N 750 125 125

Table 3

[0093] As shown in figure 1, the alloys of the previously described family, when tested in the thermally aged (hardened) state, show a tensile yield stress value comparable to that shown by a 5N alloy in turn tested in the hardened state . Furthermore, the yield stress achieved by the alloy object of the invention appears to be greater than that shown by a 3N alloy and commercial gray alloys not containing nickel, which in turn are subjected to traction in the thermally aged (hardened) state.

[0094] In particular, the graph in figure 1 shows the stress-deformation curves of monotonic tensile tests conducted on different alloys, including those which are the subject of the present disclosure.

[0095] The yield stress value (Rp 0.2) measured in MPa and identified according to ISO 6892 standard for tensile tests on metallic materials was considered as an index of improved mechanical properties, as that point determined by the intersection of the curve stress, deformation and a straight line with a slope equal to the elastic modulus of the material and intercepting the abscissa axis at the value 0.002.

[0096] From the results obtained it was observed that the yield stress value obtained for the compositions object of the disclosure is substantially at least comparable with the yield stress value of a 5N alloy tested in the hardened state.

[0097] In particular, for the LRS 848 composition shown in figure 3, the yield stress value is higher than the yield stress of a corresponding test sample made of 3N alloy.

[0098] Test samples made from the alloys in accordance with the present disclosure, and in particular the test sample made from the LRS 848 composition, show a higher yield stress value than that of corresponding test samples made from the Pd125 and Pd125 alloys. Pd60, commercially known, when subjected to traction and after thermal aging.

[0099] From an application point of view, the mechanical properties obtained for the alloy object of the invention, improved compared to those shown by commercial gray gold alloys, have allowed the material to guarantee an increase in elastic recovery following deformation undergone .

[0100] The 3N and 5N alloys present good behavior in terms of springback, while the Pd125 and Pd60 compositions present poor behavior. The Applicant notes that Pd125 and Pd60 alloys are used for their thermosetting properties.

[0101] The Applicant has observed that composition 844 has limited effectiveness in terms of elastic recovery, if compared with the other compositions previously mentioned in table 1. It is observed that the 5N alloy is a red gold alloy, and by composition, the Alloys close to the 5N standard typically present optimal behavior in terms of return following deformation. The 3N alloy is a yellow gold alloy.

[0102] The embodiments described above have the colors indicated in table 5. 848 82.0 1.7 7.6 849 82.2 1.7 7.2 850 81.6 1.9 8.0 844 84 3 ,2 9.4 Pd60 83.6 3.8 10 Pd125 81.5 2.2 7.1

Table 4 Figure 3 shows the colors of the alloys in Table 4 in a Cartesian graph on the color coordinates a* and b*.

[0103] The color of the alloy was measured using a light source according to the CIE D65 standard, according to which a source with a color temperature of approximately 6500K is used. In particular, the Applicant carried out color measurements using a spectrophotometer mod. Konica-Minolta CM3610d, using a light source in accordance with the D65 standard with a color temperature of 6504K, and with an observation angle of 2° and a measurement area of 6mm.

[0104] Table 5 includes color coordinates that are expressed according to a particular color scale and according to a particular color measurement described below.

[0105] Within the general family of alloys described above, we focused on alloys that have a substantially gray color, defined, on the CIELAB 1976 color scale, and in accordance with the color measurement conditions according to CIE D65, from the following color coordinates: L*, between 80 and 84.5, preferably between 81 and 84; a*, between 1.2 and 3.7, preferably between 1.5 and 3.5; b*, between 6.2 and 10.5, preferably between 6.6 and 10.

[0106] The Applicant notes that the color measurement standard used to obtain the values described above is ISO 8654.

[0107] In particular, the alloys of the subfamily to which the compositions 848, 849 and 850 belong have a substantially gray colour, defined, on the CIELAB 1976 color scale, and in accordance with the color measurement conditions according to CIE D65, by the following color coordinates: L*, between 80 and 84.5, preferably between 81 and 84; a*, between 1.2 and 2.4, preferably between 1.5 and 2.1; b*, between 6.7 and 8.5, preferably between 7 and 8.3.

[0108] In particular, the alloys of the subfamily to which composition 844 belongs present a substantially gray colour, defined, on the CIELAB 1976 color scale, and in accordance with the color measurement conditions according to CIE D65 by the following color coordinates: L *, between 83 and 84.5, preferably between 83.2 and 84.3; a*, between 2.7 and 3.7, preferably between 2.9 and 3.5; b*, between 8.9 and 9.9, preferably between 8.7 and 9.7.

[0109] The colors of Gold alloys are uniquely measured in the CIELAB 1976 color space, which defines a color based on a first parameter L*, a second parameter a* and a third parameter b*, where the first parameter L* identifies the brightness and takes on 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 color chart, the achromatic gray scale is identified by the points where a*=b*=0; positive values for the second parameter a* indicate a color tending more towards red the higher the value of the second parameter is; negative values for the second parameter a* indicate a color 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 color tending more towards yellow the higher the value of the third parameter is; Negative values for the third parameter b* indicate a color tending 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:

[0110] 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 will tend towards the gray scale. To the knowledge of the Applicant, alloys with a gold content greater than 750‰, which can be used as such as white or gray gold alloys and do not require rhodium plating surface treatments, arbitrarily have Cab* values <8. The hab∗ parameter instead identifies the color tone.

[0111] In particular, the ISO 8654:2017 standard defines seven color designations regarding Gold alloys for jewellery. In particular, these alloys are defined according to the following table, in which the color is defined on a standard reference named between 0N and 6N. 0N Yellow-green 1N Pale yellow 2N Light yellow 3N Yellow 4N Pink 5N Red 6N Dark red

Table 5

[0112] For the measurement of the color of a gold alloy, in particular, the ISO 8654 standard specifies that the measuring device must comply with CIE publication N° 15.

[0113] The ISO 8654:2017 standard also tabulates nominal L*, a*, b* values in trichromatic coordinates for standard color alloys 0N-6N, including tolerances. Below is an extract from the standard which defines the chromatic limits of the alloys defined by the ISO 8654:2017 standard as pink/red. 0N 93.9 -3.02 21.39 95.4 -1.65 23.14 -1.40 19.21 92.2 -4.14 19.58 -4.88 23.55 1N 92.4 0.32 22.25 94.0 1.47 23.67 1.29 20.41. 7 -0.70 20.79 -0.79 24.11 2N 91.1 1.19 25.62 92.8 2.36 26.89 2.13 23.91 89.4 0.13 24.33 0.14 27.34 3N 89.9 3.67 23.62 91.6 4.96 25.06 4.38 21.67 88.2 2.49 22.14 2.82 25.59 4N 88.9 6.13 21.23 90.6 7.48 22.45 6.63 19.44 87.1 4.89 19.98 5.48 23.06 5N 87.7 8.32 189. 62 16.97 85.9 6.96 17.55 7.89 20.19 6n 86.3 10.13 15.57 88.1 11.65 16.44 10.14 14.06 84.4 8.70 14.65 9.99 17.12

Table 6

[0114] In relation to the previous table it is therefore possible to obtain, within the CIELAB 1976 color space, a plurality of areas, each of which represents the color intervals within which it is possible to assert that an alloy has a 0N color... 6N. The gray alloys disclosed herein have significantly different color coordinates compared to those of the alloys according to the 0N-6N compositions.

[0115] ISO 8654 also proposes recommended chemical compositions for each of the 0N-6N alloys. In particular for the pink/red alloys, the compositions are those shown in the table: 4N 75.0 8.5 - 9.5 Remaining part 5N 75.0 4.5 - 5.5 6N 75.0 0 - 1.0

Table 7

[0116] It has previously been described that Gold alloys exhibit improved mechanical characteristics.

[0117] The graph in figure 2 illustrates a Cartesian diagram in which on the abscissa there is a distance corresponding to a displacement of a test sample of a gold alloy when subjected to a bending force and in which on the ordinate there is a force of flexion. The displacement of the test sample is measured in µm. The bending force is measured in N.

[0118] The graph in figure 2 is obtained according to a 3-point bending test method, in which each test sample is subjected to an increasing bending force at the center line, until reaching a linear displacement, along the direction of application of the force, equal to 4000µm. Upon reaching a linear deformation, along the direction of application of the force, equal to 4000µm, the bending force of the test sample is progressively reduced, and the residual deformation value when the test sample is subjected to a bending force of 10N has been identified.

[0119] In general, in order to evaluate the goodness of the Gold alloy in terms of deformation recovery, some Gold alloy test samples are subjected to an initially increasing deformation force F, in particular progressively increasing and subsequently progressively decreasing. In a 3-point bending test, during the application of an increasing force, the height or position L1 of the midpoint is measured, evaluated at a predetermined deformation force (Ftest). Subsequently, the deformation force continues to be increased until a predetermined maximum displacement value of the midpoint (Lt) is reached. Once the predetermined maximum displacement value has been reached, the deformation force F is progressively reduced until the predetermined deformation force value (Ftest) is reached and in this condition the new height or position L2 of the center point is detected.

[0120] For the Applicant, the performance of the alloy in terms of deformation recovery was better the smaller the difference ΔL defined as: ΔL = L2,Ftest,increasing - L1,Ftest,decreasing

[0121] According to the measurement process carried out to obtain the graph in figure 2, the smaller the difference mentioned above, the more the Gold alloy examined has optimal characteristics from the point of view of return following deformation, in as a smaller residual displacement of the test sample will also determine a smaller deformation of the object made using the alloy itself.

[0122] In the example of the graph in figure 2, Ftest= 10N, Dt=4000µm

[0123] The graph in figure 2 compares the Gold alloy according to the embodiment 848, 849 and 850 with some further alloys: 3N, 5N and Pd125 according to the compositions given in table 5.

[0124] The following values were obtained: ΔL848= 470 µm ΔL849= 600 µm ΔL850= 950 µm ΔL844= 1250 µm ΔL5N= 400 µm ΔL3N= 600 µm ΔLPd125= 1700 µm

[0125] It is also observed that with the same Palladium content (compositions 848, 849, 850), Gold alloys perform better if the Cobalt content increases.

[0126] The following table illustrates the hardness values of the specific embodiments of gold alloy conceived by the Applicant. 844 164 246 848 170 293 849 174 285 850 163 253 Pd125 155 210 Pd60 169 263

Table 8

[0127] The hardening process for the gold alloys described here takes place by exposing the aforementioned alloys to a specific and predefined hardening temperature for each specific formulation, for a time substantially equal to 1h, subsequently allowing the alloy to cool down to environment. The purpose of hardening is to encourage the formation of precipitates and/or crystalline phase changes, activated by the high temperature, which allow the alloy to acquire a higher hardness than the hardness after annealing.

[0128] The curing temperatures described in this formulation are indicated in the following table: 5N 280 1 3N 280 1 Pd125 475 2 Pd60 300 1 844 300 1 848 450 1 849 400 1 850 450 1

Table 9

[0129] The cooling of the test samples of the alloys referred to in Table 9 occurred by immersion in water at room temperature.

[0130] It is noted in particular that compositions 848 and 849, due to the high Cobalt content, have a significantly greater hardness than the other compositions, particularly following hardening. The hardnesses according to table 8 are measured in Vickers scale with an applied load of 1 kgf.

[0131] The present disclosure also refers to a process of producing a Gold alloy.

[0132] In a more general embodiment, the production process of the Gold alloy according to the invention includes, starting from the pure elements in accordance with what has been described above, the mixing of at least: – Gold, between 700 ‰ by weight and 800 ‰ by weight, – Copper, between 25 ‰ by weight and 170 ‰ by weight, – Palladium, between 50 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight .

[0133] Additional blend weight ranges are described above and not repeated below.

[0134] The method described here includes a step of introducing the mixture into a melting crucible, and of subsequent melting by heating until complete melting by introduction into the melting crucible.

[0135] The starting elements from which the alloys described here are made are pure elements; preferably, Gold has 99.99% purity, Copper has 99.99% purity, Palladium has 99.95% purity, Silver has 99.99% purity, Cobalt and Iridium have 99.95% purity and Gallium has 99.95% purity 99.99%.

[0136] The method may comprise a step of mixing a Culr pre-alloy within the assembly of the elements previously described.

[0137] Therefore, a particular embodiment includes a step of making a Culr pre-alloy, and mixing: – Gold, between 700 ‰ and 800 ‰ by weight, – Copper, between 9 ‰ and 79 ‰ by weight , – Palladium, between 85 ‰ and 165 ‰ by weight, – Cobalt, between 7 ‰ and 40 ‰ by weight, – Silver, between 7 ‰ and 60 ‰ by weight, with a Culr pre-alloy at 16 ‰ by weight.

[0138] The melting process is preferably a continuous casting melting process, i.e. a process in which the solidification and extraction of the solidified Gold are carried out continuously starting from a free end of a Gold bar or melt . In particular, a graphite die is used in the continuous melting process.

[0139] The use of a graphite die is useful since graphite is a solid lubricant, and typically has low friction between its surfaces and those of the molten metal, typically allowing easy extraction of the element contained therein without fractures and with the minimum amount of defects present on its surface.

[0140] The pure element melting process for the creation of Gold alloys according to the invention can be in detail a discontinuous Gold melting process or a continuous Gold melting process.

[0141] The discontinuous Gold melting process is a process in which the mixture is melted and poured into a mold or ingot, made of graphite. In this case the elements indicated above are melted and poured in a controlled atmosphere. More specifically, the melting operations are carried out only after preferably having carried out at least 3 cycles of conditioning the atmosphere of the melting chamber. This conditioning involves first reaching a vacuum level up to pressures lower than 1×10<-2>mbar and a subsequent partial saturation with Argon at 500mbar. During fusion, the Argon pressure is maintained at pressure levels between 500mbar and 800mbar. When complete fusion of the pure elements has been achieved, an overheating phase of the mixture occurs, in which the mixture is heated up to a temperature of approximately 1250°C, and in any case to a temperature above 1200°C, in order to 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 waste produced by the fusion of pure elements.

[0142] At this point, in a casting phase, the molten material is poured into a mold or ingot made of graphite, and the melting chamber is pressurized again with an inert gas, preferably argon, injected at a pressure higher than 700mbar and especially above 800mbar.

[0143] Once solidification has taken place, the bars or spindles are extracted from the mold. When the alloy is solidified, bars or melts of Gold alloy are obtained from the graphite conduit which are subjected to rapid cooling through 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 limitedly in water, in order to avoid phase variations in the solid state.

[0144] The advantages of Gold alloys in accordance with the present disclosure are clear in light of the foregoing description. In particular, thanks to their improved mechanical properties, they allow the creation of objects - even for high-end jewelery - which, even when subjected to significant and/or repeated deformation forces, vary very little in size, and consequently provide a longer operational life both at themselves and to any objects with which they are connected or within which they are included. The buckling properties are comparable to those of 3N and 5N alloys and significantly better than those of commercial gray alloys not containing Ni.

[0145] Furthermore, the Gold alloys according to the present disclosure can also be machined particularly effectively to result in uniform surfaces, free of visible second phases or carbides. Therefore the gold alloys according to the present disclosure can be favorably used for high jewelery applications, and in particular for making high jewelery objects.

[0146] Non-limiting examples of jewelery items made at least partially from the gold alloy described here are: bracelets, watch bracelets, buckles, watch cases, hands, internal watch mechanisms, bracelet settings, earrings, ornaments, rings, holders for precious stones, ingots, in particular collector's bars, collector's coins, necklaces, clasps for necklaces, for earrings or for bracelets.

[0147] Gold alloys in accordance with the present disclosure may be applicable for objects that come into direct contact with human skin, and are of low allergic risk.

[0148] Finally, it is clear that additions, modifications or variations that are obvious to those skilled in the art can be applied to what is the object of the present invention, without thereby departing from the scope of protection provided by the attached claims.

Claims (11)

1. Gold alloy for jewelery applications, specifically intended for making jewelery objects having at least partial shape and/or size recovery properties following the application of a deformation force, comprising: – Gold, between 700 ‰ by weight and 800 ‰ by weight, – Copper, between 25 ‰ by weight and 170 ‰ by weight, – Palladium, between 50 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight. 2. Gold Alloy according to claim 1, comprising: – Gold, between 700 ‰ by weight and 800 ‰ by weight, – Copper, between 25‰ by weight and 95‰ by weight, – Palladium, between 85 ‰ by weight and 165 ‰ by weight, – Cobalt, between 7 ‰ by weight and 40 ‰ by weight, – Silver, between 7 ‰ in weight and 60 ‰ in weight. 3. Gold alloy according to claim 1 or 2, further comprising Gallium and/or at least one grain refining element, preferably at least one of Iridium, Rhenium or Ruthenium, and wherein the amount by weight of Gallium and/or the said at least one grain refiner element, preferably at least one of Iridium, Rhenium or Ruthenium, determines the achievement of 1000 ‰ in weight; said Gold alloy being characterized by the fact of being free of Nickel, by the fact of being free of Arsenic, and by the fact of being free of Platinum; said alloy being a gray colored alloy, said gray color being defined, on the CIELAB 1976 color scale, and in accordance with the color measurement conditions according to CIE D65, by the following color coordinates: L*, between 80 and 84.5, preferably between 81 and 84; a*, between 1.2 and 3.7, preferably between 1.5 and 3.5; b*, between 6.2 and 10.5, preferably between 6.6 and 10. 4. Gold alloy according to claims 2 or 3, comprising Gallium between 1 ‰ by weight and 10 ‰ by weight, preferably between 2 ‰ by weight and 9 ‰ by weight, more preferably between 3 ‰ by weight and 8 ‰ by weight . 5. Gold alloy according to claim 3, wherein said at least one grain refining element is present in amounts up to 1 ‰ by weight; optionally in which said Iridium is pre-alloyed with Copper and/or in which said Rhenium and/or Ruthenium is pre-alloyed with Palladium. 6. Gold Alloy according to one or more of claims 2-5, comprising: – Gold, between 730 ‰ by weight and 770 ‰ by weight, – Copper, between 40 ‰ by weight and 90 ‰ by weight, – Palladium, between 100 ‰ in weight and 150 ‰ in weight, – Cobalt, between 8 ‰ by weight and 30 ‰ by weight, – Silver, between 8 ‰ in weight and 55 ‰ in weight. 7. Gold Alloy according to claim 6, comprising: – Gold, between 740 ‰ by weight and 760 ‰ by weight, – Copper, between 50 ‰ by weight and 90 ‰ by weight, – Palladium, between 100 ‰ in weight and 150 ‰ in weight, – Cobalt, between 8 ‰ by weight and 30 ‰ by weight, – Silver, between 8 ‰ in weight and 55 ‰ in weight. 8. Gold Alloy according to claim 7, comprising: – Gold, between 740 ‰ by weight and 760 ‰ by weight, – Copper, between 50 ‰ by weight and 90 ‰ by weight, – Palladium, between 110 ‰ by weight and 140 ‰ by weight, preferably between 115 ‰ by weight and 135 ‰ by weight, – Cobalt, between 10 ‰ by weight and 25 ‰ by weight, – Silver, between 8 ‰ by weight and 50 ‰ by weight. 9. Gold alloy according to one or more of the preceding claims 1-5, in which: – Copper is present between 45 ‰ by weight and 65 ‰ by weight, preferably between 50 ‰ by weight and 60 ‰ by weight, and Silver, between 35 ‰ by weight and 52 ‰ by weight; or – Copper is present, between 75 ‰ by weight and 95 ‰ by weight, preferably between 80 ‰ by weight and 90 ‰ by weight, and Silver, between 7 ‰ by weight and 13 ‰ by weight, preferably between 8 ‰ by weight and 12 ‰ in weight. 10. Gold alloy according to one or more of the previous claims, characterized by being nickel-free. 11. Gold Alloy according to claim 1, comprising: – Gold, between 730 ‰ by weight and 770 ‰ by weight, preferably between 740 ‰ by weight and 760 ‰ by weight, – Copper, between 150‰ by weight and 170‰ by weight, preferably between 155‰ by weight and 165‰ by weight, – Palladium, between 50‰ by weight and 70‰ by weight, preferably between 55‰ by weight and 65‰ by weight, – Cobalt, between 7 ‰ by weight and 13 ‰ by weight, – Iron, between 10 ‰ by weight and 30 ‰ by weight, optionally at least one grain refiner element, preferably at least one of Iridium, Rhenium or Ruthenium, wherein the sum of Gold, Copper, Palladium, Cobalt, Iron, and optionally the at least one grain refiner element, preferably at least one of Iridium, Rhenium or Ruthenium, reaches 1000 ‰ by weight.